!!MODULE module_ra_rrtmg_sw module parrrsw use parkind ,only : im => kind_im, rb => kind_rb ! implicit none save !------------------------------------------------------------------ ! rrtmg_sw main parameters ! ! Initial version: JJMorcrette, ECMWF, jul1998 ! Revised: MJIacono, AER, jun2006 ! Revised: MJIacono, AER, aug2008 !------------------------------------------------------------------ ! name type purpose ! ----- : ---- : ---------------------------------------------- ! mxlay : integer: maximum number of layers ! mg : integer: number of original g-intervals per spectral band ! nbndsw : integer: number of spectral bands ! naerec : integer: number of aerosols (iaer=6, ecmwf aerosol option) ! ngptsw : integer: total number of reduced g-intervals for rrtmg_lw ! ngNN : integer: number of reduced g-intervals per spectral band ! ngsNN : integer: cumulative number of g-intervals per band !------------------------------------------------------------------ integer(kind=im), parameter :: mxlay = 203 !jplay, klev integer(kind=im), parameter :: mg = 16 !jpg integer(kind=im), parameter :: nbndsw = 14 !jpsw, ksw integer(kind=im), parameter :: naerec = 6 !jpaer integer(kind=im), parameter :: mxmol = 38 integer(kind=im), parameter :: nstr = 2 integer(kind=im), parameter :: nmol = 7 ! Use for 112 g-point model integer(kind=im), parameter :: ngptsw = 112 !jpgpt ! Use for 224 g-point model ! integer(kind=im), parameter :: ngptsw = 224 !jpgpt ! may need to rename these - from v2.6 integer(kind=im), parameter :: jpband = 29 integer(kind=im), parameter :: jpb1 = 16 !istart integer(kind=im), parameter :: jpb2 = 29 !iend integer(kind=im), parameter :: jmcmu = 32 integer(kind=im), parameter :: jmumu = 32 integer(kind=im), parameter :: jmphi = 3 integer(kind=im), parameter :: jmxang = 4 integer(kind=im), parameter :: jmxstr = 16 ! Use for 112 g-point model integer(kind=im), parameter :: ng16 = 6 integer(kind=im), parameter :: ng17 = 12 integer(kind=im), parameter :: ng18 = 8 integer(kind=im), parameter :: ng19 = 8 integer(kind=im), parameter :: ng20 = 10 integer(kind=im), parameter :: ng21 = 10 integer(kind=im), parameter :: ng22 = 2 integer(kind=im), parameter :: ng23 = 10 integer(kind=im), parameter :: ng24 = 8 integer(kind=im), parameter :: ng25 = 6 integer(kind=im), parameter :: ng26 = 6 integer(kind=im), parameter :: ng27 = 8 integer(kind=im), parameter :: ng28 = 6 integer(kind=im), parameter :: ng29 = 12 integer(kind=im), parameter :: ngs16 = 6 integer(kind=im), parameter :: ngs17 = 18 integer(kind=im), parameter :: ngs18 = 26 integer(kind=im), parameter :: ngs19 = 34 integer(kind=im), parameter :: ngs20 = 44 integer(kind=im), parameter :: ngs21 = 54 integer(kind=im), parameter :: ngs22 = 56 integer(kind=im), parameter :: ngs23 = 66 integer(kind=im), parameter :: ngs24 = 74 integer(kind=im), parameter :: ngs25 = 80 integer(kind=im), parameter :: ngs26 = 86 integer(kind=im), parameter :: ngs27 = 94 integer(kind=im), parameter :: ngs28 = 100 integer(kind=im), parameter :: ngs29 = 112 ! Use for 224 g-point model ! integer(kind=im), parameter :: ng16 = 16 ! integer(kind=im), parameter :: ng17 = 16 ! integer(kind=im), parameter :: ng18 = 16 ! integer(kind=im), parameter :: ng19 = 16 ! integer(kind=im), parameter :: ng20 = 16 ! integer(kind=im), parameter :: ng21 = 16 ! integer(kind=im), parameter :: ng22 = 16 ! integer(kind=im), parameter :: ng23 = 16 ! integer(kind=im), parameter :: ng24 = 16 ! integer(kind=im), parameter :: ng25 = 16 ! integer(kind=im), parameter :: ng26 = 16 ! integer(kind=im), parameter :: ng27 = 16 ! integer(kind=im), parameter :: ng28 = 16 ! integer(kind=im), parameter :: ng29 = 16 ! integer(kind=im), parameter :: ngs16 = 16 ! integer(kind=im), parameter :: ngs17 = 32 ! integer(kind=im), parameter :: ngs18 = 48 ! integer(kind=im), parameter :: ngs19 = 64 ! integer(kind=im), parameter :: ngs20 = 80 ! integer(kind=im), parameter :: ngs21 = 96 ! integer(kind=im), parameter :: ngs22 = 112 ! integer(kind=im), parameter :: ngs23 = 128 ! integer(kind=im), parameter :: ngs24 = 144 ! integer(kind=im), parameter :: ngs25 = 160 ! integer(kind=im), parameter :: ngs26 = 176 ! integer(kind=im), parameter :: ngs27 = 192 ! integer(kind=im), parameter :: ngs28 = 208 ! integer(kind=im), parameter :: ngs29 = 224 ! Source function solar constant real(kind=rb), parameter :: rrsw_scon = 1.36822e+03 ! W/m2 end module parrrsw module rrsw_aer use parkind, only : im => kind_im, rb => kind_rb use parrrsw, only : nbndsw, naerec ! implicit none save !------------------------------------------------------------------ ! rrtmg_sw aerosol optical properties ! ! Data derived from six ECMWF aerosol types and defined for ! the rrtmg_sw spectral intervals ! ! Initial: J.-J. Morcrette, ECMWF, mar2003 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !------------------------------------------------------------------ ! !-- The six ECMWF aerosol types are respectively: ! ! 1/ continental average 2/ maritime ! 3/ desert 4/ urban ! 5/ volcanic active 6/ stratospheric background ! ! computed from Hess and Koepke (con, mar, des, urb) ! from Bonnel et al. (vol, str) ! ! rrtmg_sw 14 spectral intervals (microns): ! 3.846 - 3.077 ! 3.077 - 2.500 ! 2.500 - 2.150 ! 2.150 - 1.942 ! 1.942 - 1.626 ! 1.626 - 1.299 ! 1.299 - 1.242 ! 1.242 - 0.7782 ! 0.7782- 0.6250 ! 0.6250- 0.4415 ! 0.4415- 0.3448 ! 0.3448- 0.2632 ! 0.2632- 0.2000 ! 12.195 - 3.846 ! !------------------------------------------------------------------ ! ! name type purpose ! ----- : ---- : ---------------------------------------------- ! rsrtaua : real : ratio of average optical thickness in ! spectral band to that at 0.55 micron ! rsrpiza : real : average single scattering albedo (unitless) ! rsrasya : real : average asymmetry parameter (unitless) !------------------------------------------------------------------ real(kind=rb) :: rsrtaua(nbndsw,naerec) real(kind=rb) :: rsrpiza(nbndsw,naerec) real(kind=rb) :: rsrasya(nbndsw,naerec) end module rrsw_aer module rrsw_cld use parkind, only : im => kind_im, rb => kind_rb ! implicit none save !------------------------------------------------------------------ ! rrtmg_sw cloud property coefficients ! ! Initial: J.-J. Morcrette, ECMWF, oct1999 ! Revised: J. Delamere/MJIacono, AER, aug2005 ! Revised: MJIacono, AER, nov2005 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !------------------------------------------------------------------ ! ! name type purpose ! ----- : ---- : ---------------------------------------------- ! xxxliq1 : real : optical properties (extinction coefficient, single ! scattering albedo, assymetry factor) from ! Hu & Stamnes, j. clim., 6, 728-742, 1993. ! xxxice2 : real : optical properties (extinction coefficient, single ! scattering albedo, assymetry factor) from streamer v3.0, ! Key, streamer user's guide, cooperative institude ! for meteorological studies, 95 pp., 2001. ! xxxice3 : real : optical properties (extinction coefficient, single ! scattering albedo, assymetry factor) from ! Fu, j. clim., 9, 1996. ! xbari : real : optical property coefficients for five spectral ! intervals (2857-4000, 4000-5263, 5263-7692, 7692-14285, ! and 14285-40000 wavenumbers) following ! Ebert and Curry, jgr, 97, 3831-3836, 1992. !------------------------------------------------------------------ real(kind=rb) :: extliq1(58,16:29), ssaliq1(58,16:29), asyliq1(58,16:29) real(kind=rb) :: extice2(43,16:29), ssaice2(43,16:29), asyice2(43,16:29) real(kind=rb) :: extice3(46,16:29), ssaice3(46,16:29), asyice3(46,16:29) real(kind=rb) :: fdlice3(46,16:29) real(kind=rb) :: abari(5),bbari(5),cbari(5),dbari(5),ebari(5),fbari(5) end module rrsw_cld module rrsw_con use parkind, only : im => kind_im, rb => kind_rb ! implicit none save !------------------------------------------------------------------ ! rrtmg_sw constants ! Initial version: MJIacono, AER, jun2006 ! Revised: MJIacono, AER, aug2008 !------------------------------------------------------------------ ! name type purpose ! ----- : ---- : ---------------------------------------------- ! fluxfac: real : radiance to flux conversion factor ! heatfac: real : flux to heating rate conversion factor !oneminus: real : 1.-1.e-6 ! pi : real : pi ! grav : real : acceleration of gravity ! planck : real : planck constant ! boltz : real : boltzmann constant ! clight : real : speed of light ! avogad : real : avogadro constant ! alosmt : real : loschmidt constant ! gascon : real : molar gas constant ! radcn1 : real : first radiation constant ! radcn2 : real : second radiation constant ! sbcnst : real : stefan-boltzmann constant ! secdy : real : seconds per day !------------------------------------------------------------------ real(kind=rb) :: fluxfac, heatfac real(kind=rb) :: oneminus, pi, grav real(kind=rb) :: planck, boltz, clight real(kind=rb) :: avogad, alosmt, gascon real(kind=rb) :: radcn1, radcn2 real(kind=rb) :: sbcnst, secdy end module rrsw_con module rrsw_kg16 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng16 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 16 ! band 16: 2600-3250 cm-1 (low - h2o,ch4; high - ch4) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real !----------------------------------------------------------------- integer(kind=im), parameter :: no16 = 16 real(kind=rb) :: kao(9,5,13,no16) real(kind=rb) :: kbo(5,13:59,no16) real(kind=rb) :: selfrefo(10,no16), forrefo(3,no16) real(kind=rb) :: sfluxrefo(no16) integer(kind=im) :: layreffr real(kind=rb) :: rayl, strrat1 !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 16 ! band 16: 2600-3250 cm-1 (low - h2o,ch4; high - ch4) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! selfref : real ! forref : real ! sfluxref: real !----------------------------------------------------------------- real(kind=rb) :: ka(9,5,13,ng16) , absa(585,ng16) real(kind=rb) :: kb(5,13:59,ng16), absb(235,ng16) real(kind=rb) :: selfref(10,ng16), forref(3,ng16) real(kind=rb) :: sfluxref(ng16) equivalence (ka(1,1,1,1),absa(1,1)), (kb(1,13,1),absb(1,1)) end module rrsw_kg16 module rrsw_kg17 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng17 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 17 ! band 17: 3250-4000 cm-1 (low - h2o,co2; high - h2o,co2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real !----------------------------------------------------------------- integer(kind=im), parameter :: no17 = 16 real(kind=rb) :: kao(9,5,13,no17) real(kind=rb) :: kbo(5,5,13:59,no17) real(kind=rb) :: selfrefo(10,no17), forrefo(4,no17) real(kind=rb) :: sfluxrefo(no17,5) integer(kind=im) :: layreffr real(kind=rb) :: rayl, strrat !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 17 ! band 17: 3250-4000 cm-1 (low - h2o,co2; high - h2o,co2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! selfref : real ! forref : real ! sfluxref: real !----------------------------------------------------------------- real(kind=rb) :: ka(9,5,13,ng17) , absa(585,ng17) real(kind=rb) :: kb(5,5,13:59,ng17), absb(1175,ng17) real(kind=rb) :: selfref(10,ng17), forref(4,ng17) real(kind=rb) :: sfluxref(ng17,5) equivalence (ka(1,1,1,1),absa(1,1)), (kb(1,1,13,1),absb(1,1)) end module rrsw_kg17 module rrsw_kg18 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng18 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 18 ! band 18: 4000-4650 cm-1 (low - h2o,ch4; high - ch4) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real !----------------------------------------------------------------- integer(kind=im), parameter :: no18 = 16 real(kind=rb) :: kao(9,5,13,no18) real(kind=rb) :: kbo(5,13:59,no18) real(kind=rb) :: selfrefo(10,no18), forrefo(3,no18) real(kind=rb) :: sfluxrefo(no18,9) integer(kind=im) :: layreffr real(kind=rb) :: rayl, strrat !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 18 ! band 18: 4000-4650 cm-1 (low - h2o,ch4; high - ch4) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! selfref : real ! forref : real ! sfluxref: real !----------------------------------------------------------------- real(kind=rb) :: ka(9,5,13,ng18), absa(585,ng18) real(kind=rb) :: kb(5,13:59,ng18), absb(235,ng18) real(kind=rb) :: selfref(10,ng18), forref(3,ng18) real(kind=rb) :: sfluxref(ng18,9) equivalence (ka(1,1,1,1),absa(1,1)), (kb(1,13,1),absb(1,1)) end module rrsw_kg18 module rrsw_kg19 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng19 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 19 ! band 19: 4650-5150 cm-1 (low - h2o,co2; high - co2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real !----------------------------------------------------------------- integer(kind=im), parameter :: no19 = 16 real(kind=rb) :: kao(9,5,13,no19) real(kind=rb) :: kbo(5,13:59,no19) real(kind=rb) :: selfrefo(10,no19), forrefo(3,no19) real(kind=rb) :: sfluxrefo(no19,9) integer(kind=im) :: layreffr real(kind=rb) :: rayl, strrat !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 19 ! band 19: 4650-5150 cm-1 (low - h2o,co2; high - co2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! selfref : real ! forref : real ! sfluxref: real !----------------------------------------------------------------- real(kind=rb) :: ka(9,5,13,ng19), absa(585,ng19) real(kind=rb) :: kb(5,13:59,ng19), absb(235,ng19) real(kind=rb) :: selfref(10,ng19), forref(3,ng19) real(kind=rb) :: sfluxref(ng19,9) equivalence (ka(1,1,1,1),absa(1,1)), (kb(1,13,1),absb(1,1)) end module rrsw_kg19 module rrsw_kg20 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng20 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 20 ! band 20: 5150-6150 cm-1 (low - h2o; high - h2o) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real ! absch4o : real !----------------------------------------------------------------- integer(kind=im), parameter :: no20 = 16 real(kind=rb) :: kao(5,13,no20) real(kind=rb) :: kbo(5,13:59,no20) real(kind=rb) :: selfrefo(10,no20), forrefo(4,no20) real(kind=rb) :: sfluxrefo(no20) real(kind=rb) :: absch4o(no20) integer(kind=im) :: layreffr real(kind=rb) :: rayl !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 20 ! band 20: 5150-6150 cm-1 (low - h2o; high - h2o) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! selfref : real ! forref : real ! sfluxref: real ! absch4 : real !----------------------------------------------------------------- real(kind=rb) :: ka(5,13,ng20), absa(65,ng20) real(kind=rb) :: kb(5,13:59,ng20), absb(235,ng20) real(kind=rb) :: selfref(10,ng20), forref(4,ng20) real(kind=rb) :: sfluxref(ng20) real(kind=rb) :: absch4(ng20) equivalence (ka(1,1,1),absa(1,1)), (kb(1,13,1),absb(1,1)) end module rrsw_kg20 module rrsw_kg21 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng21 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 21 ! band 21: 6150-7700 cm-1 (low - h2o,co2; high - h2o,co2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real !----------------------------------------------------------------- integer(kind=im), parameter :: no21 = 16 real(kind=rb) :: kao(9,5,13,no21) real(kind=rb) :: kbo(5,5,13:59,no21) real(kind=rb) :: selfrefo(10,no21), forrefo(4,no21) real(kind=rb) :: sfluxrefo(no21,9) integer(kind=im) :: layreffr real(kind=rb) :: rayl, strrat !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 21 ! band 21: 6150-7700 cm-1 (low - h2o,co2; high - h2o,co2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! selfref : real ! forref : real ! sfluxref: real !----------------------------------------------------------------- real(kind=rb) :: ka(9,5,13,ng21), absa(585,ng21) real(kind=rb) :: kb(5,5,13:59,ng21), absb(1175,ng21) real(kind=rb) :: selfref(10,ng21), forref(4,ng21) real(kind=rb) :: sfluxref(ng21,9) equivalence (ka(1,1,1,1),absa(1,1)), (kb(1,1,13,1),absb(1,1)) end module rrsw_kg21 module rrsw_kg22 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng22 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 22 ! band 22: 7700-8050 cm-1 (low - h2o,o2; high - o2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real !----------------------------------------------------------------- integer(kind=im), parameter :: no22 = 16 real(kind=rb) :: kao(9,5,13,no22) real(kind=rb) :: kbo(5,13:59,no22) real(kind=rb) :: selfrefo(10,no22), forrefo(3,no22) real(kind=rb) :: sfluxrefo(no22,9) integer(kind=im) :: layreffr real(kind=rb) :: rayl, strrat !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 22 ! band 22: 7700-8050 cm-1 (low - h2o,o2; high - o2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! selfref : real ! forref : real ! sfluxref: real !----------------------------------------------------------------- real(kind=rb) :: ka(9,5,13,ng22), absa(585,ng22) real(kind=rb) :: kb(5,13:59,ng22), absb(235,ng22) real(kind=rb) :: selfref(10,ng22), forref(3,ng22) real(kind=rb) :: sfluxref(ng22,9) equivalence (ka(1,1,1,1),absa(1,1)), (kb(1,13,1),absb(1,1)) end module rrsw_kg22 module rrsw_kg23 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng23 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 23 ! band 23: 8050-12850 cm-1 (low - h2o; high - nothing) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real !----------------------------------------------------------------- integer(kind=im), parameter :: no23 = 16 real(kind=rb) :: kao(5,13,no23) real(kind=rb) :: selfrefo(10,no23), forrefo(3,no23) real(kind=rb) :: sfluxrefo(no23) real(kind=rb) :: raylo(no23) integer(kind=im) :: layreffr real(kind=rb) :: givfac !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 23 ! band 23: 8050-12850 cm-1 (low - h2o; high - nothing) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! selfref : real ! forref : real ! sfluxref: real !----------------------------------------------------------------- real(kind=rb) :: ka(5,13,ng23), absa(65,ng23) real(kind=rb) :: selfref(10,ng23), forref(3,ng23) real(kind=rb) :: sfluxref(ng23), rayl(ng23) equivalence (ka(1,1,1),absa(1,1)) end module rrsw_kg23 module rrsw_kg24 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng24 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 24 ! band 24: 12850-16000 cm-1 (low - h2o,o2; high - o2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real ! abso3ao : real ! abso3bo : real ! raylao : real ! raylbo : real !----------------------------------------------------------------- integer(kind=im), parameter :: no24 = 16 real(kind=rb) :: kao(9,5,13,no24) real(kind=rb) :: kbo(5,13:59,no24) real(kind=rb) :: selfrefo(10,no24), forrefo(3,no24) real(kind=rb) :: sfluxrefo(no24,9) real(kind=rb) :: abso3ao(no24), abso3bo(no24) real(kind=rb) :: raylao(no24,9), raylbo(no24) integer(kind=im) :: layreffr real(kind=rb) :: strrat !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 24 ! band 24: 12850-16000 cm-1 (low - h2o,o2; high - o2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! selfref : real ! forref : real ! sfluxref: real ! abso3a : real ! abso3b : real ! rayla : real ! raylb : real !----------------------------------------------------------------- real(kind=rb) :: ka(9,5,13,ng24), absa(585,ng24) real(kind=rb) :: kb(5,13:59,ng24), absb(235,ng24) real(kind=rb) :: selfref(10,ng24), forref(3,ng24) real(kind=rb) :: sfluxref(ng24,9) real(kind=rb) :: abso3a(ng24), abso3b(ng24) real(kind=rb) :: rayla(ng24,9), raylb(ng24) equivalence (ka(1,1,1,1),absa(1,1)), (kb(1,13,1),absb(1,1)) end module rrsw_kg24 module rrsw_kg25 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng25 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 25 ! band 25: 16000-22650 cm-1 (low - h2o; high - nothing) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real !sfluxrefo: real ! abso3ao : real ! abso3bo : real ! raylo : real !----------------------------------------------------------------- integer(kind=im), parameter :: no25 = 16 real(kind=rb) :: kao(5,13,no25) real(kind=rb) :: sfluxrefo(no25) real(kind=rb) :: abso3ao(no25), abso3bo(no25) real(kind=rb) :: raylo(no25) integer(kind=im) :: layreffr !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 25 ! band 25: 16000-22650 cm-1 (low - h2o; high - nothing) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! absa : real ! sfluxref: real ! abso3a : real ! abso3b : real ! rayl : real !----------------------------------------------------------------- real(kind=rb) :: ka(5,13,ng25), absa(65,ng25) real(kind=rb) :: sfluxref(ng25) real(kind=rb) :: abso3a(ng25), abso3b(ng25) real(kind=rb) :: rayl(ng25) equivalence (ka(1,1,1),absa(1,1)) end module rrsw_kg25 module rrsw_kg26 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng26 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 26 ! band 26: 22650-29000 cm-1 (low - nothing; high - nothing) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- !sfluxrefo: real ! raylo : real !----------------------------------------------------------------- integer(kind=im), parameter :: no26 = 16 real(kind=rb) :: sfluxrefo(no26) real(kind=rb) :: raylo(no26) !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 26 ! band 26: 22650-29000 cm-1 (low - nothing; high - nothing) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! sfluxref: real ! rayl : real !----------------------------------------------------------------- real(kind=rb) :: sfluxref(ng26) real(kind=rb) :: rayl(ng26) end module rrsw_kg26 module rrsw_kg27 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng27 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 27 ! band 27: 29000-38000 cm-1 (low - o3; high - o3) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real !sfluxrefo: real ! raylo : real !----------------------------------------------------------------- integer(kind=im), parameter :: no27 = 16 real(kind=rb) :: kao(5,13,no27) real(kind=rb) :: kbo(5,13:59,no27) real(kind=rb) :: sfluxrefo(no27) real(kind=rb) :: raylo(no27) integer(kind=im) :: layreffr real(kind=rb) :: scalekur !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 27 ! band 27: 29000-38000 cm-1 (low - o3; high - o3) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! absa : real ! absb : real ! sfluxref: real ! rayl : real !----------------------------------------------------------------- real(kind=rb) :: ka(5,13,ng27), absa(65,ng27) real(kind=rb) :: kb(5,13:59,ng27), absb(235,ng27) real(kind=rb) :: sfluxref(ng27) real(kind=rb) :: rayl(ng27) equivalence (ka(1,1,1),absa(1,1)), (kb(1,13,1),absb(1,1)) end module rrsw_kg27 module rrsw_kg28 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng28 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 28 ! band 28: 38000-50000 cm-1 (low - o3, o2; high - o3, o2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real !sfluxrefo: real !----------------------------------------------------------------- integer(kind=im), parameter :: no28 = 16 real(kind=rb) :: kao(9,5,13,no28) real(kind=rb) :: kbo(5,5,13:59,no28) real(kind=rb) :: sfluxrefo(no28,5) integer(kind=im) :: layreffr real(kind=rb) :: rayl, strrat !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 28 ! band 28: 38000-50000 cm-1 (low - o3, o2; high - o3, o2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! sfluxref: real !----------------------------------------------------------------- real(kind=rb) :: ka(9,5,13,ng28), absa(585,ng28) real(kind=rb) :: kb(5,5,13:59,ng28), absb(1175,ng28) real(kind=rb) :: sfluxref(ng28,5) equivalence (ka(1,1,1,1),absa(1,1)), (kb(1,1,13,1),absb(1,1)) end module rrsw_kg28 module rrsw_kg29 use parkind ,only : im => kind_im, rb => kind_rb use parrrsw, only : ng29 ! implicit none save !----------------------------------------------------------------- ! rrtmg_sw ORIGINAL abs. coefficients for interval 29 ! band 29: 820-2600 cm-1 (low - h2o; high - co2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! kao : real ! kbo : real ! selfrefo: real ! forrefo : real !sfluxrefo: real ! absh2oo : real ! absco2o : real !----------------------------------------------------------------- integer(kind=im), parameter :: no29 = 16 real(kind=rb) :: kao(5,13,no29) real(kind=rb) :: kbo(5,13:59,no29) real(kind=rb) :: selfrefo(10,no29), forrefo(4,no29) real(kind=rb) :: sfluxrefo(no29) real(kind=rb) :: absh2oo(no29), absco2o(no29) integer(kind=im) :: layreffr real(kind=rb) :: rayl !----------------------------------------------------------------- ! rrtmg_sw COMBINED abs. coefficients for interval 29 ! band 29: 820-2600 cm-1 (low - h2o; high - co2) ! ! Initial version: JJMorcrette, ECMWF, oct1999 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !----------------------------------------------------------------- ! ! name type purpose ! ---- : ---- : --------------------------------------------- ! ka : real ! kb : real ! selfref : real ! forref : real ! sfluxref: real ! absh2o : real ! absco2 : real !----------------------------------------------------------------- real(kind=rb) :: ka(5,13,ng29), absa(65,ng29) real(kind=rb) :: kb(5,13:59,ng29), absb(235,ng29) real(kind=rb) :: selfref(10,ng29), forref(4,ng29) real(kind=rb) :: sfluxref(ng29) real(kind=rb) :: absh2o(ng29), absco2(ng29) equivalence (ka(1,1,1),absa(1,1)), (kb(1,13,1),absb(1,1)) end module rrsw_kg29 module rrsw_ref use parkind, only : im => kind_im, rb => kind_rb ! implicit none save !------------------------------------------------------------------ ! rrtmg_sw reference atmosphere ! Based on standard mid-latitude summer profile ! ! Initial version: JJMorcrette, ECMWF, jul1998 ! Revised: MJIacono, AER, jun2006 ! Revised: MJIacono, AER, aug2008 !------------------------------------------------------------------ ! name type purpose ! ----- : ---- : ---------------------------------------------- ! pref : real : Reference pressure levels ! preflog: real : Reference pressure levels, ln(pref) ! tref : real : Reference temperature levels for MLS profile !------------------------------------------------------------------ real(kind=rb) , dimension(59) :: pref real(kind=rb) , dimension(59) :: preflog real(kind=rb) , dimension(59) :: tref end module rrsw_ref module rrsw_tbl use parkind, only : im => kind_im, rb => kind_rb ! implicit none save !------------------------------------------------------------------ ! rrtmg_sw lookup table arrays ! Initial version: MJIacono, AER, may2007 ! Revised: MJIacono, AER, aug2007 ! Revised: MJIacono, AER, aug2008 !------------------------------------------------------------------ ! name type purpose ! ----- : ---- : ---------------------------------------------- ! ntbl : integer: Lookup table dimension ! tblint : real : Lookup table conversion factor ! tau_tbl: real : Clear-sky optical depth ! exp_tbl: real : Exponential lookup table for transmittance ! od_lo : real : Value of tau below which expansion is used ! : in place of lookup table ! pade : real : Pade approximation constant ! bpade : real : Inverse of Pade constant !------------------------------------------------------------------ integer(kind=im), parameter :: ntbl = 10000 real(kind=rb), parameter :: tblint = 10000.0_rb real(kind=rb), parameter :: od_lo = 0.06_rb real(kind=rb) :: tau_tbl real(kind=rb) , dimension(0:ntbl) :: exp_tbl real(kind=rb), parameter :: pade = 0.278_rb real(kind=rb) :: bpade end module rrsw_tbl module rrsw_vsn ! implicit none save !------------------------------------------------------------------ ! rrtmg_sw version information ! Initial version: JJMorcrette, ECMWF, jul1998 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !------------------------------------------------------------------ ! name type purpose ! ----- : ---- : ---------------------------------------------- !hnamrtm :character: !hnamini :character: !hnamcld :character: !hnamclc :character: !hnamrft :character: !hnamspv :character: !hnamspc :character: !hnamset :character: !hnamtau :character: !hnamvqd :character: !hnamatm :character: !hnamutl :character: !hnamext :character: !hnamkg :character: ! ! hvrrtm :character: ! hvrini :character: ! hvrcld :character: ! hvrclc :character: ! hvrrft :character: ! hvrspv :character: ! hvrspc :character: ! hvrset :character: ! hvrtau :character: ! hvrvqd :character: ! hvratm :character: ! hvrutl :character: ! hvrext :character: ! hvrkg :character: !------------------------------------------------------------------ character*18 hvrrtm,hvrini,hvrcld,hvrclc,hvrrft,hvrspv, & hvrspc,hvrset,hvrtau,hvrvqd,hvratm,hvrutl,hvrext character*20 hnamrtm,hnamini,hnamcld,hnamclc,hnamrft,hnamspv, & hnamspc,hnamset,hnamtau,hnamvqd,hnamatm,hnamutl,hnamext character*18 hvrkg character*20 hnamkg end module rrsw_vsn module rrsw_wvn use parkind, only : im => kind_im, rb => kind_rb use parrrsw, only : nbndsw, mg, ngptsw, jpb1, jpb2 ! implicit none save !------------------------------------------------------------------ ! rrtmg_sw spectral information ! Initial version: JJMorcrette, ECMWF, jul1998 ! Revised: MJIacono, AER, jul2006 ! Revised: MJIacono, AER, aug2008 !------------------------------------------------------------------ ! name type purpose ! ----- : ---- : ---------------------------------------------- ! ng : integer: Number of original g-intervals in each spectral band ! nspa : integer: ! nspb : integer: !wavenum1: real : Spectral band lower boundary in wavenumbers !wavenum2: real : Spectral band upper boundary in wavenumbers ! delwave: real : Spectral band width in wavenumbers ! ! ngc : integer: The number of new g-intervals in each band ! ngs : integer: The cumulative sum of new g-intervals for each band ! ngm : integer: The index of each new g-interval relative to the ! original 16 g-intervals in each band ! ngn : integer: The number of original g-intervals that are ! combined to make each new g-intervals in each band ! ngb : integer: The band index for each new g-interval ! wt : real : RRTM weights for the original 16 g-intervals ! rwgt : real : Weights for combining original 16 g-intervals ! (224 total) into reduced set of g-intervals ! (112 total) !------------------------------------------------------------------ integer(kind=im) :: ng(jpb1:jpb2) integer(kind=im) :: nspa(jpb1:jpb2) integer(kind=im) :: nspb(jpb1:jpb2) real(kind=rb) :: wavenum1(jpb1:jpb2) real(kind=rb) :: wavenum2(jpb1:jpb2) real(kind=rb) :: delwave(jpb1:jpb2) integer(kind=im) :: ngc(nbndsw) integer(kind=im) :: ngs(nbndsw) integer(kind=im) :: ngn(ngptsw) integer(kind=im) :: ngb(ngptsw) integer(kind=im) :: ngm(nbndsw*mg) real(kind=rb) :: wt(mg) real(kind=rb) :: rwgt(nbndsw*mg) end module rrsw_wvn ! path: $Source: /cvsroot/NWP/WRFV3/phys/module_ra_rrtmg_sw.F,v $ ! author: $Author: trn $ ! revision: $Revision: 1.3 $ ! created: $Date: 2009/04/16 19:54:22 $ ! module mcica_subcol_gen_sw ! -------------------------------------------------------------------------- ! | | ! | Copyright 2006-2008, Atmospheric & Environmental Research, Inc. (AER). | ! | This software may be used, copied, or redistributed as long as it is | ! | not sold and this copyright notice is reproduced on each copy made. | ! | This model is provided as is without any express or implied warranties. | ! | (http://www.rtweb.aer.com/) | ! | | ! -------------------------------------------------------------------------- ! Purpose: Create McICA stochastic arrays for cloud physical or optical properties. ! Two options are possible: ! 1) Input cloud physical properties: cloud fraction, ice and liquid water ! paths, ice fraction, and particle sizes. Output will be stochastic ! arrays of these variables. (inflag = 1) ! 2) Input cloud optical properties directly: cloud optical depth, single ! scattering albedo and asymmetry parameter. Output will be stochastic ! arrays of these variables. (inflag = 0) ! --------- Modules ---------- use parkind, only : im => kind_im, rb => kind_rb use parrrsw, only : nbndsw, ngptsw use rrsw_con, only: grav use rrsw_wvn, only: ngb use rrsw_vsn implicit none ! public interfaces/functions/subroutines public :: mcica_subcol_sw, generate_stochastic_clouds_sw contains !------------------------------------------------------------------ ! Public subroutines !------------------------------------------------------------------ subroutine mcica_subcol_sw(iplon, ncol, nlay, icld, permuteseed, irng, play, & cldfrac, ciwp, clwp, rei, rel, tauc, ssac, asmc, fsfc, & cldfmcl, ciwpmcl, clwpmcl, reicmcl, relqmcl, & taucmcl, ssacmcl, asmcmcl, fsfcmcl) ! ----- Input ----- ! Control integer(kind=im), intent(in) :: iplon ! column/longitude dimension integer(kind=im), intent(in) :: ncol ! number of columns integer(kind=im), intent(in) :: nlay ! number of model layers integer(kind=im), intent(in) :: icld ! clear/cloud, cloud overlap flag integer(kind=im), intent(in) :: permuteseed ! if the cloud generator is called multiple times, ! permute the seed between each call; ! between calls for LW and SW, recommended ! permuteseed differs by 'ngpt' integer(kind=im), intent(inout) :: irng ! flag for random number generator ! 0 = kissvec ! 1 = Mersenne Twister ! Atmosphere real(kind=rb), intent(in) :: play(:,:) ! layer pressures (mb) ! Dimensions: (ncol,nlay) ! Atmosphere/clouds - cldprop real(kind=rb), intent(in) :: cldfrac(:,:) ! layer cloud fraction ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: tauc(:,:,:) ! in-cloud optical depth ! Dimensions: (nbndsw,ncol,nlay) real(kind=rb), intent(in) :: ssac(:,:,:) ! in-cloud single scattering albedo (non-delta scaled) ! Dimensions: (nbndsw,ncol,nlay) real(kind=rb), intent(in) :: asmc(:,:,:) ! in-cloud asymmetry parameter (non-delta scaled) ! Dimensions: (nbndsw,ncol,nlay) real(kind=rb), intent(in) :: fsfc(:,:,:) ! in-cloud forward scattering fraction (non-delta scaled) ! Dimensions: (nbndsw,ncol,nlay) real(kind=rb), intent(in) :: ciwp(:,:) ! in-cloud ice water path ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: clwp(:,:) ! in-cloud liquid water path ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: rei(:,:) ! cloud ice particle size ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: rel(:,:) ! cloud liquid particle size ! Dimensions: (ncol,nlay) ! ----- Output ----- ! Atmosphere/clouds - cldprmc [mcica] real(kind=rb), intent(out) :: cldfmcl(:,:,:) ! cloud fraction [mcica] ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: ciwpmcl(:,:,:) ! in-cloud ice water path [mcica] ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: clwpmcl(:,:,:) ! in-cloud liquid water path [mcica] ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: relqmcl(:,:) ! liquid particle size (microns) ! Dimensions: (ncol,nlay) real(kind=rb), intent(out) :: reicmcl(:,:) ! ice partcle size (microns) ! Dimensions: (ncol,nlay) real(kind=rb), intent(out) :: taucmcl(:,:,:) ! in-cloud optical depth [mcica] ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: ssacmcl(:,:,:) ! in-cloud single scattering albedo [mcica] ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: asmcmcl(:,:,:) ! in-cloud asymmetry parameter [mcica] ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: fsfcmcl(:,:,:) ! in-cloud forward scattering fraction [mcica] ! Dimensions: (ngptsw,ncol,nlay) ! ----- Local ----- ! Stochastic cloud generator variables [mcica] integer(kind=im), parameter :: nsubcsw = ngptsw ! number of sub-columns (g-point intervals) integer(kind=im) :: ilev ! loop index real(kind=rb) :: pmid(ncol,nlay) ! layer pressures (Pa) ! real(kind=rb) :: pdel(ncol,nlay) ! layer pressure thickness (Pa) ! real(kind=rb) :: qi(ncol,nlay) ! ice water (specific humidity) ! real(kind=rb) :: ql(ncol,nlay) ! liq water (specific humidity) ! Return if clear sky; or stop if icld out of range if (icld.eq.0) return if (icld.lt.0.or.icld.gt.3) then stop 'MCICA_SUBCOL: INVALID ICLD' endif ! NOTE: For GCM mode, permuteseed must be offset between LW and SW by at least number of subcolumns ! Pass particle sizes to new arrays, no subcolumns for these properties yet ! Convert pressures from mb to Pa reicmcl(:ncol,:nlay) = rei(:ncol,:nlay) relqmcl(:ncol,:nlay) = rel(:ncol,:nlay) pmid(:ncol,:nlay) = play(:ncol,:nlay)*1.e2_rb ! Convert input ice and liquid cloud water paths to specific humidity ice and liquid components ! cwp = (q * pdel * 1000.) / gravit) ! = (kg/kg * kg m-1 s-2 *1000.) / m s-2 ! = (g m-2) ! ! q = (cwp * gravit) / (pdel *1000.) ! = (g m-2 * m s-2) / (kg m-1 s-2 * 1000.) ! = kg/kg ! do ilev = 1, nlay ! qi(ilev) = (ciwp(ilev) * grav) / (pdel(ilev) * 1000._rb) ! ql(ilev) = (clwp(ilev) * grav) / (pdel(ilev) * 1000._rb) ! enddo ! Generate the stochastic subcolumns of cloud optical properties for the shortwave; call generate_stochastic_clouds_sw (ncol, nlay, nsubcsw, icld, irng, pmid, cldfrac, clwp, ciwp, & tauc, ssac, asmc, fsfc, cldfmcl, clwpmcl, ciwpmcl, & taucmcl, ssacmcl, asmcmcl, fsfcmcl, permuteseed) end subroutine mcica_subcol_sw !------------------------------------------------------------------------------------------------- subroutine generate_stochastic_clouds_sw(ncol, nlay, nsubcol, icld, irng, pmid, cld, clwp, ciwp, & tauc, ssac, asmc, fsfc, cld_stoch, clwp_stoch, ciwp_stoch, & tauc_stoch, ssac_stoch, asmc_stoch, fsfc_stoch, changeSeed) !------------------------------------------------------------------------------------------------- !---------------------------------------------------------------------------------------------------------------- ! --------------------- ! Contact: Cecile Hannay (hannay@ucar.edu) ! ! Original code: Based on Raisanen et al., QJRMS, 2004. ! ! Modifications: Generalized for use with RRTMG and added Mersenne Twister as the default ! random number generator, which can be changed to the optional kissvec random number generator ! with flag 'irng'. Some extra functionality has been commented or removed. ! Michael J. Iacono, AER, Inc., February 2007 ! ! Given a profile of cloud fraction, cloud water and cloud ice, we produce a set of subcolumns. ! Each layer within each subcolumn is homogeneous, with cloud fraction equal to zero or one ! and uniform cloud liquid and cloud ice concentration. ! The ensemble as a whole reproduces the probability function of cloud liquid and ice within each layer ! and obeys an overlap assumption in the vertical. ! ! Overlap assumption: ! The cloud are consistent with 4 overlap assumptions: random, maximum, maximum-random and exponential. ! The default option is maximum-random (option 3) ! The options are: 1=random overlap, 2=max/random, 3=maximum overlap, 4=exponential overlap ! This is set with the variable "overlap" !mji - Exponential overlap option (overlap=4) has been deactivated in this version ! The exponential overlap uses also a length scale, Zo. (real, parameter :: Zo = 2500. ) ! ! Seed: ! If the stochastic cloud generator is called several times during the same timestep, ! one should change the seed between the call to insure that the subcolumns are different. ! This is done by changing the argument 'changeSeed' ! For example, if one wants to create a set of columns for the shortwave and another set for the longwave , ! use 'changeSeed = 1' for the first call and'changeSeed = 2' for the second call ! ! PDF assumption: ! We can use arbitrary complicated PDFS. ! In the present version, we produce homogeneuous clouds (the simplest case). ! Future developments include using the PDF scheme of Ben Johnson. ! ! History file: ! Option to add diagnostics variables in the history file. (using FINCL in the namelist) ! nsubcol = number of subcolumns ! overlap = overlap type (1-3) ! Zo = length scale ! CLOUD_S = mean of the subcolumn cloud fraction ('_S" means Stochastic) ! CLDLIQ_S = mean of the subcolumn cloud water ! CLDICE_S = mean of the subcolumn cloud ice ! ! Note: ! Here: we force that the cloud condensate to be consistent with the cloud fraction ! i.e we only have cloud condensate when the cell is cloudy. ! In CAM: The cloud condensate and the cloud fraction are obtained from 2 different equations ! and the 2 quantities can be inconsistent (i.e. CAM can produce cloud fraction ! without cloud condensate or the opposite). !--------------------------------------------------------------------------------------------------------------- use mcica_random_numbers ! The Mersenne Twister random number engine use MersenneTwister, only: randomNumberSequence, & new_RandomNumberSequence, getRandomReal type(randomNumberSequence) :: randomNumbers ! -- Arguments integer(kind=im), intent(in) :: ncol ! number of layers integer(kind=im), intent(in) :: nlay ! number of layers integer(kind=im), intent(in) :: icld ! clear/cloud, cloud overlap flag integer(kind=im), intent(inout) :: irng ! flag for random number generator ! 0 = kissvec ! 1 = Mersenne Twister integer(kind=im), intent(in) :: nsubcol ! number of sub-columns (g-point intervals) integer(kind=im), optional, intent(in) :: changeSeed ! allows permuting seed ! Column state (cloud fraction, cloud water, cloud ice) + variables needed to read physics state real(kind=rb), intent(in) :: pmid(:,:) ! layer pressure (Pa) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: cld(:,:) ! cloud fraction ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: clwp(:,:) ! in-cloud liquid water path (g/m2) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: ciwp(:,:) ! in-cloud ice water path (g/m2) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: tauc(:,:,:) ! in-cloud optical depth (non-delta scaled) ! Dimensions: (nbndsw,ncol,nlay) real(kind=rb), intent(in) :: ssac(:,:,:) ! in-cloud single scattering albedo (non-delta scaled) ! Dimensions: (nbndsw,ncol,nlay) real(kind=rb), intent(in) :: asmc(:,:,:) ! in-cloud asymmetry parameter (non-delta scaled) ! Dimensions: (nbndsw,ncol,nlay) real(kind=rb), intent(in) :: fsfc(:,:,:) ! in-cloud forward scattering fraction (non-delta scaled) ! Dimensions: (nbndsw,ncol,nlay) real(kind=rb), intent(out) :: cld_stoch(:,:,:) ! subcolumn cloud fraction ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: clwp_stoch(:,:,:) ! subcolumn in-cloud liquid water path ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: ciwp_stoch(:,:,:) ! subcolumn in-cloud ice water path ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: tauc_stoch(:,:,:) ! subcolumn in-cloud optical depth ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: ssac_stoch(:,:,:) ! subcolumn in-cloud single scattering albedo ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: asmc_stoch(:,:,:) ! subcolumn in-cloud asymmetry parameter ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(out) :: fsfc_stoch(:,:,:) ! subcolumn in-cloud forward scattering fraction ! Dimensions: (ngptsw,ncol,nlay) ! -- Local variables real(kind=rb) :: cldf(ncol,nlay) ! cloud fraction ! Dimensions: (ncol,nlay) ! Mean over the subcolumns (cloud fraction, cloud water , cloud ice) - inactive ! real(kind=rb) :: mean_cld_stoch(ncol,nlay) ! cloud fraction ! real(kind=rb) :: mean_clwp_stoch(ncol,nlay) ! cloud water ! real(kind=rb) :: mean_ciwp_stoch(ncol,nlay) ! cloud ice ! real(kind=rb) :: mean_tauc_stoch(ncol,nlay) ! cloud optical depth ! real(kind=rb) :: mean_ssac_stoch(ncol,nlay) ! cloud single scattering albedo ! real(kind=rb) :: mean_asmc_stoch(ncol,nlay) ! cloud asymmetry parameter ! real(kind=rb) :: mean_fsfc_stoch(ncol,nlay) ! cloud forward scattering fraction ! Set overlap integer(kind=im) :: overlap ! 1 = random overlap, 2 = maximum/random, ! 3 = maximum overlap, ! real(kind=rb), parameter :: Zo = 2500._rb ! length scale (m) ! real(kind=rb) :: zm(ncon,nlay) ! Height of midpoints (above surface) ! real(kind=rb), dimension(nlay) :: alpha=0.0_rb ! overlap parameter ! Constants (min value for cloud fraction and cloud water and ice) real(kind=rb), parameter :: cldmin = 1.0e-20_rb ! min cloud fraction ! real(kind=rb), parameter :: qmin = 1.0e-10_rb ! min cloud water and cloud ice (not used) ! Variables related to random number and seed real(kind=rb), dimension(nsubcol, ncol, nlay) :: CDF, CDF2 ! random numbers integer(kind=im), dimension(ncol) :: seed1, seed2, seed3, seed4 ! seed to create random number real(kind=rb), dimension(ncol) :: rand_num ! random number (kissvec) integer(kind=im) :: iseed ! seed to create random number (Mersenne Twister) real(kind=rb) :: rand_num_mt ! random number (Mersenne Twister) ! Flag to identify cloud fraction in subcolumns logical, dimension(nsubcol, ncol, nlay) :: isCloudy ! flag that says whether a gridbox is cloudy ! Indices integer(kind=im) :: ilev, isubcol, i, n, ngbm ! indices !------------------------------------------------------------------------------------------ ! Check that irng is in bounds; if not, set to default if (irng .ne. 0) irng = 1 ! Pass input cloud overlap setting to local variable overlap = icld ! Ensure that cloud fractions are in bounds do ilev = 1, nlay do i = 1, ncol cldf(i,ilev) = cld(i,ilev) if (cldf(i,ilev) < cldmin) then cldf(i,ilev) = 0._rb endif enddo enddo ! ----- Create seed -------- ! Advance randum number generator by changeseed values if (irng.eq.0) then ! For kissvec, create a seed that depends on the state of the columns. Maybe not the best way, but it works. ! Must use pmid from bottom four layers. do i=1,ncol if (pmid(i,1).lt.pmid(i,2)) then stop 'MCICA_SUBCOL: KISSVEC SEED GENERATOR REQUIRES PMID FROM BOTTOM FOUR LAYERS.' endif seed1(i) = (pmid(i,1) - int(pmid(i,1))) * 1000000000_im seed2(i) = (pmid(i,2) - int(pmid(i,2))) * 1000000000_im seed3(i) = (pmid(i,3) - int(pmid(i,3))) * 1000000000_im seed4(i) = (pmid(i,4) - int(pmid(i,4))) * 1000000000_im enddo do i=1,changeSeed call kissvec(seed1, seed2, seed3, seed4, rand_num) enddo elseif (irng.eq.1) then randomNumbers = new_RandomNumberSequence(seed = changeSeed) endif ! ------ Apply overlap assumption -------- ! generate the random numbers select case (overlap) case(1) ! Random overlap ! i) pick a random value at every level if (irng.eq.0) then do isubcol = 1,nsubcol do ilev = 1,nlay call kissvec(seed1, seed2, seed3, seed4, rand_num) CDF(isubcol,:,ilev) = rand_num enddo enddo elseif (irng.eq.1) then do isubcol = 1, nsubcol do i = 1, ncol do ilev = 1, nlay rand_num_mt = getRandomReal(randomNumbers) CDF(isubcol,i,ilev) = rand_num_mt enddo enddo enddo endif case(2) ! Maximum-Random overlap ! i) pick a random number for top layer. ! ii) walk down the column: ! - if the layer above is cloudy, we use the same random number than in the layer above ! - if the layer above is clear, we use a new random number if (irng.eq.0) then do isubcol = 1,nsubcol do ilev = 1,nlay call kissvec(seed1, seed2, seed3, seed4, rand_num) CDF(isubcol,:,ilev) = rand_num enddo enddo elseif (irng.eq.1) then do isubcol = 1, nsubcol do i = 1, ncol do ilev = 1, nlay rand_num_mt = getRandomReal(randomNumbers) CDF(isubcol,i,ilev) = rand_num_mt enddo enddo enddo endif do ilev = 2,nlay do i = 1, ncol do isubcol = 1, nsubcol if (CDF(isubcol, i, ilev-1) > 1._rb - cldf(i,ilev-1) ) then CDF(isubcol,i,ilev) = CDF(isubcol,i,ilev-1) else CDF(isubcol,i,ilev) = CDF(isubcol,i,ilev) * (1._rb - cldf(i,ilev-1)) endif enddo enddo enddo case(3) ! Maximum overlap ! i) pick same random numebr at every level if (irng.eq.0) then do isubcol = 1,nsubcol call kissvec(seed1, seed2, seed3, seed4, rand_num) do ilev = 1,nlay CDF(isubcol,:,ilev) = rand_num enddo enddo elseif (irng.eq.1) then do isubcol = 1, nsubcol do i = 1, ncol rand_num_mt = getRandomReal(randomNumbers) do ilev = 1, nlay CDF(isubcol,i,ilev) = rand_num_mt enddo enddo enddo endif ! case(4) - inactive ! ! Exponential overlap: weighting between maximum and random overlap increases with the distance. ! ! The random numbers for exponential overlap verify: ! ! j=1 RAN(j)=RND1 ! ! j>1 if RND1 < alpha(j,j-1) => RAN(j) = RAN(j-1) ! ! RAN(j) = RND2 ! ! alpha is obtained from the equation ! ! alpha = exp(- (Zi-Zj-1)/Zo) where Zo is a characteristic length scale ! ! compute alpha ! zm = state%zm ! alpha(:, 1) = 0._rb ! do ilev = 2,nlay ! alpha(:, ilev) = exp( -( zm (:, ilev-1) - zm (:, ilev)) / Zo) ! end do ! ! generate 2 streams of random numbers ! do isubcol = 1,nsubcol ! do ilev = 1,nlay ! call kissvec(seed1, seed2, seed3, seed4, rand_num) ! CDF(isubcol, :, ilev) = rand_num ! call kissvec(seed1, seed2, seed3, seed4, rand_num) ! CDF2(isubcol, :, ilev) = rand_num ! end do ! end do ! ! generate random numbers ! do ilev = 2,nlay ! where (CDF2(:, :, ilev) < spread(alpha (:,ilev), dim=1, nCopies=nsubcol) ) ! CDF(:,:,ilev) = CDF(:,:,ilev-1) ! end where ! end do end select ! -- generate subcolumns for homogeneous clouds ----- do ilev = 1, nlay isCloudy(:,:,ilev) = (CDF(:,:,ilev) >= 1._rb - spread(cldf(:,ilev), dim=1, nCopies=nsubcol) ) enddo ! where the subcolumn is cloudy, the subcolumn cloud fraction is 1; ! where the subcolumn is not cloudy, the subcolumn cloud fraction is 0; ! where there is a cloud, define the subcolumn cloud properties, ! otherwise set these to zero ngbm = ngb(1) - 1 do ilev = 1,nlay do i = 1, ncol do isubcol = 1, nsubcol if ( iscloudy(isubcol,i,ilev) ) then cld_stoch(isubcol,i,ilev) = 1._rb clwp_stoch(isubcol,i,ilev) = clwp(i,ilev) ciwp_stoch(isubcol,i,ilev) = ciwp(i,ilev) n = ngb(isubcol) - ngbm tauc_stoch(isubcol,i,ilev) = tauc(n,i,ilev) ssac_stoch(isubcol,i,ilev) = ssac(n,i,ilev) asmc_stoch(isubcol,i,ilev) = asmc(n,i,ilev) fsfc_stoch(isubcol,i,ilev) = fsfc(n,i,ilev) else cld_stoch(isubcol,i,ilev) = 0._rb clwp_stoch(isubcol,i,ilev) = 0._rb ciwp_stoch(isubcol,i,ilev) = 0._rb tauc_stoch(isubcol,i,ilev) = 0._rb ssac_stoch(isubcol,i,ilev) = 1._rb asmc_stoch(isubcol,i,ilev) = 0._rb fsfc_stoch(isubcol,i,ilev) = 0._rb endif enddo enddo enddo ! -- compute the means of the subcolumns --- ! mean_cld_stoch(:,:) = 0._rb ! mean_clwp_stoch(:,:) = 0._rb ! mean_ciwp_stoch(:,:) = 0._rb ! mean_tauc_stoch(:,:) = 0._rb ! mean_ssac_stoch(:,:) = 0._rb ! mean_asmc_stoch(:,:) = 0._rb ! mean_fsfc_stoch(:,:) = 0._rb ! do i = 1, nsubcol ! mean_cld_stoch(:,:) = cld_stoch(i,:,:) + mean_cld_stoch(:,:) ! mean_clwp_stoch(:,:) = clwp_stoch( i,:,:) + mean_clwp_stoch(:,:) ! mean_ciwp_stoch(:,:) = ciwp_stoch( i,:,:) + mean_ciwp_stoch(:,:) ! mean_tauc_stoch(:,:) = tauc_stoch( i,:,:) + mean_tauc_stoch(:,:) ! mean_ssac_stoch(:,:) = ssac_stoch( i,:,:) + mean_ssac_stoch(:,:) ! mean_asmc_stoch(:,:) = asmc_stoch( i,:,:) + mean_asmc_stoch(:,:) ! mean_fsfc_stoch(:,:) = fsfc_stoch( i,:,:) + mean_fsfc_stoch(:,:) ! end do ! mean_cld_stoch(:,:) = mean_cld_stoch(:,:) / nsubcol ! mean_clwp_stoch(:,:) = mean_clwp_stoch(:,:) / nsubcol ! mean_ciwp_stoch(:,:) = mean_ciwp_stoch(:,:) / nsubcol ! mean_tauc_stoch(:,:) = mean_tauc_stoch(:,:) / nsubcol ! mean_ssac_stoch(:,:) = mean_ssac_stoch(:,:) / nsubcol ! mean_asmc_stoch(:,:) = mean_asmc_stoch(:,:) / nsubcol ! mean_fsfc_stoch(:,:) = mean_fsfc_stoch(:,:) / nsubcol end subroutine generate_stochastic_clouds_sw !-------------------------------------------------------------------------------------------------- subroutine kissvec(seed1,seed2,seed3,seed4,ran_arr) !-------------------------------------------------------------------------------------------------- ! public domain code ! made available from http://www.fortran.com/ ! downloaded by pjr on 03/16/04 for NCAR CAM ! converted to vector form, functions inlined by pjr,mvr on 05/10/2004 ! The KISS (Keep It Simple Stupid) random number generator. Combines: ! (1) The congruential generator x(n)=69069*x(n-1)+1327217885, period 2^32. ! (2) A 3-shift shift-register generator, period 2^32-1, ! (3) Two 16-bit multiply-with-carry generators, period 597273182964842497>2^59 ! Overall period>2^123; ! real(kind=rb), dimension(:), intent(inout) :: ran_arr integer(kind=im), dimension(:), intent(inout) :: seed1,seed2,seed3,seed4 integer(kind=im) :: i,sz,kiss integer(kind=im) :: m, k, n ! inline function m(k, n) = ieor (k, ishft (k, n) ) sz = size(ran_arr) do i = 1, sz seed1(i) = 69069_im * seed1(i) + 1327217885_im seed2(i) = m (m (m (seed2(i), 13_im), - 17_im), 5_im) seed3(i) = 18000_im * iand (seed3(i), 65535_im) + ishft (seed3(i), - 16_im) seed4(i) = 30903_im * iand (seed4(i), 65535_im) + ishft (seed4(i), - 16_im) kiss = seed1(i) + seed2(i) + ishft (seed3(i), 16_im) + seed4(i) ran_arr(i) = kiss*2.328306e-10_rb + 0.5_rb end do end subroutine kissvec end module mcica_subcol_gen_sw ! path: $Source: /cvsroot/NWP/WRFV3/phys/module_ra_rrtmg_sw.F,v $ ! author: $Author: trn $ ! revision: $Revision: 1.3 $ ! created: $Date: 2009/04/16 19:54:22 $ module rrtmg_sw_cldprmc ! -------------------------------------------------------------------------- ! | | ! | Copyright 2002-2008, Atmospheric & Environmental Research, Inc. (AER). | ! | This software may be used, copied, or redistributed as long as it is | ! | not sold and this copyright notice is reproduced on each copy made. | ! | This model is provided as is without any express or implied warranties. | ! | (http://www.rtweb.aer.com/) | ! | | ! -------------------------------------------------------------------------- ! ------- Modules ------- use parkind, only : im => kind_im, rb => kind_rb use parrrsw, only : ngptsw, jpband, jpb1, jpb2 use rrsw_cld, only : extliq1, ssaliq1, asyliq1, & extice2, ssaice2, asyice2, & extice3, ssaice3, asyice3, fdlice3, & abari, bbari, cbari, dbari, ebari, fbari use rrsw_wvn, only : wavenum1, wavenum2, ngb use rrsw_vsn, only : hvrclc, hnamclc implicit none contains ! ---------------------------------------------------------------------------- subroutine cldprmc_sw(nlayers, inflag, iceflag, liqflag, cldfmc, & ciwpmc, clwpmc, reicmc, relqmc, & taormc, taucmc, ssacmc, asmcmc, fsfcmc) ! ---------------------------------------------------------------------------- ! Purpose: Compute the cloud optical properties for each cloudy layer ! and g-point interval for use by the McICA method. ! Note: Only inflag = 0 and inflag=2/liqflag=1/iceflag=2,3 are available; ! (Hu & Stamnes, Key, and Fu) are implemented. ! ------- Input ------- integer(kind=im), intent(in) :: nlayers ! total number of layers integer(kind=im), intent(in) :: inflag ! see definitions integer(kind=im), intent(in) :: iceflag ! see definitions integer(kind=im), intent(in) :: liqflag ! see definitions real(kind=rb), intent(in) :: cldfmc(:,:) ! cloud fraction [mcica] ! Dimensions: (ngptsw,nlayers) real(kind=rb), intent(in) :: ciwpmc(:,:) ! cloud ice water path [mcica] ! Dimensions: (ngptsw,nlayers) real(kind=rb), intent(in) :: clwpmc(:,:) ! cloud liquid water path [mcica] ! Dimensions: (ngptsw,nlayers) real(kind=rb), intent(in) :: relqmc(:) ! cloud liquid particle effective radius (microns) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: reicmc(:) ! cloud ice particle effective radius (microns) ! Dimensions: (nlayers) ! specific definition of reicmc depends on setting of iceflag: ! iceflag = 1: ice effective radius, r_ec, (Ebert and Curry, 1992), ! r_ec range is limited to 13.0 to 130.0 microns ! iceflag = 2: ice effective radius, r_k, (Key, Streamer Ref. Manual, 1996) ! r_k range is limited to 5.0 to 131.0 microns ! iceflag = 3: generalized effective size, dge, (Fu, 1996), ! dge range is limited to 5.0 to 140.0 microns ! [dge = 1.0315 * r_ec] real(kind=rb), intent(in) :: fsfcmc(:,:) ! cloud forward scattering fraction ! Dimensions: (ngptsw,nlayers) ! ------- Output ------- real(kind=rb), intent(inout) :: taucmc(:,:) ! cloud optical depth (delta scaled) ! Dimensions: (ngptsw,nlayers) real(kind=rb), intent(inout) :: ssacmc(:,:) ! single scattering albedo (delta scaled) ! Dimensions: (ngptsw,nlayers) real(kind=rb), intent(inout) :: asmcmc(:,:) ! asymmetry parameter (delta scaled) ! Dimensions: (ngptsw,nlayers) real(kind=rb), intent(out) :: taormc(:,:) ! cloud optical depth (non-delta scaled) ! Dimensions: (ngptsw,nlayers) ! ------- Local ------- ! integer(kind=im) :: ncbands integer(kind=im) :: ib, lay, istr, index, icx, ig real(kind=rb), parameter :: eps = 1.e-06_rb ! epsilon real(kind=rb), parameter :: cldmin = 1.e-20_rb ! minimum value for cloud quantities real(kind=rb) :: cwp ! total cloud water path real(kind=rb) :: radliq ! cloud liquid droplet radius (microns) real(kind=rb) :: radice ! cloud ice effective size (microns) real(kind=rb) :: factor real(kind=rb) :: fint real(kind=rb) :: taucldorig_a, taucloud_a, ssacloud_a, ffp, ffp1, ffpssa real(kind=rb) :: tauiceorig, scatice, ssaice, tauice, tauliqorig, scatliq, ssaliq, tauliq real(kind=rb) :: fdelta(ngptsw) real(kind=rb) :: extcoice(ngptsw), gice(ngptsw) real(kind=rb) :: ssacoice(ngptsw), forwice(ngptsw) real(kind=rb) :: extcoliq(ngptsw), gliq(ngptsw) real(kind=rb) :: ssacoliq(ngptsw), forwliq(ngptsw) ! Initialize hvrclc = '$Revision: 1.3 $' ! Some of these initializations are done elsewhere do lay = 1, nlayers do ig = 1, ngptsw taormc(ig,lay) = taucmc(ig,lay) ! taucmc(ig,lay) = 0.0_rb ! ssacmc(ig,lay) = 1.0_rb ! asmcmc(ig,lay) = 0.0_rb enddo enddo ! Main layer loop do lay = 1, nlayers ! Main g-point interval loop do ig = 1, ngptsw cwp = ciwpmc(ig,lay) + clwpmc(ig,lay) if (cldfmc(ig,lay) .ge. cldmin .and. & (cwp .ge. cldmin .or. taucmc(ig,lay) .ge. cldmin)) then ! (inflag=0): Cloud optical properties input directly if (inflag .eq. 0) then ! Cloud optical properties already defined in taucmc, ssacmc, asmcmc are unscaled; ! Apply delta-M scaling here (using Henyey-Greenstein approximation) taucldorig_a = taucmc(ig,lay) ffp = fsfcmc(ig,lay) ffp1 = 1.0_rb - ffp ffpssa = 1.0_rb - ffp * ssacmc(ig,lay) ssacloud_a = ffp1 * ssacmc(ig,lay) / ffpssa taucloud_a = ffpssa * taucldorig_a taormc(ig,lay) = taucldorig_a ssacmc(ig,lay) = ssacloud_a taucmc(ig,lay) = taucloud_a asmcmc(ig,lay) = (asmcmc(ig,lay) - ffp) / (ffp1) elseif (inflag .eq. 1) then stop 'INFLAG = 1 OPTION NOT AVAILABLE WITH MCICA' ! (inflag=2): Separate treatement of ice clouds and water clouds. elseif (inflag .eq. 2) then radice = reicmc(lay) ! Calculation of absorption coefficients due to ice clouds. if (ciwpmc(ig,lay) .eq. 0.0_rb) then extcoice(ig) = 0.0_rb ssacoice(ig) = 0.0_rb gice(ig) = 0.0_rb forwice(ig) = 0.0_rb ! (iceflag = 1): ! Note: This option uses Ebert and Curry approach for all particle sizes similar to ! CAM3 implementation, though this is somewhat unjustified for large ice particles elseif (iceflag .eq. 1) then ib = ngb(ig) if (wavenum2(ib) .gt. 1.43e04_rb) then icx = 1 elseif (wavenum2(ib) .gt. 7.7e03_rb) then icx = 2 elseif (wavenum2(ib) .gt. 5.3e03_rb) then icx = 3 elseif (wavenum2(ib) .gt. 4.0e03_rb) then icx = 4 elseif (wavenum2(ib) .ge. 2.5e03_rb) then icx = 5 endif extcoice(ig) = (abari(icx) + bbari(icx)/radice) ssacoice(ig) = 1._rb - cbari(icx) - dbari(icx) * radice gice(ig) = ebari(icx) + fbari(icx) * radice ! Check to ensure upper limit of gice is within physical limits for large particles if (gice(ig).ge.1._rb) gice(ig) = 1._rb - eps forwice(ig) = gice(ig)*gice(ig) ! Check to ensure all calculated quantities are within physical limits. if (extcoice(ig) .lt. 0.0_rb) stop 'ICE EXTINCTION LESS THAN 0.0' if (ssacoice(ig) .gt. 1.0_rb) stop 'ICE SSA GRTR THAN 1.0' if (ssacoice(ig) .lt. 0.0_rb) stop 'ICE SSA LESS THAN 0.0' if (gice(ig) .gt. 1.0_rb) stop 'ICE ASYM GRTR THAN 1.0' if (gice(ig) .lt. 0.0_rb) stop 'ICE ASYM LESS THAN 0.0' ! For iceflag=2 option, ice particle effective radius is limited to 5.0 to 131.0 microns elseif (iceflag .eq. 2) then if (radice .lt. 5.0_rb .or. radice .gt. 131.0_rb) stop 'ICE RADIUS OUT OF BOUNDS' factor = (radice - 2._rb)/3._rb index = int(factor) if (index .eq. 43) index = 42 fint = factor - float(index) ib = ngb(ig) extcoice(ig) = extice2(index,ib) + fint * & (extice2(index+1,ib) - extice2(index,ib)) ssacoice(ig) = ssaice2(index,ib) + fint * & (ssaice2(index+1,ib) - ssaice2(index,ib)) gice(ig) = asyice2(index,ib) + fint * & (asyice2(index+1,ib) - asyice2(index,ib)) forwice(ig) = gice(ig)*gice(ig) ! Check to ensure all calculated quantities are within physical limits. if (extcoice(ig) .lt. 0.0_rb) stop 'ICE EXTINCTION LESS THAN 0.0' if (ssacoice(ig) .gt. 1.0_rb) stop 'ICE SSA GRTR THAN 1.0' if (ssacoice(ig) .lt. 0.0_rb) stop 'ICE SSA LESS THAN 0.0' if (gice(ig) .gt. 1.0_rb) stop 'ICE ASYM GRTR THAN 1.0' if (gice(ig) .lt. 0.0_rb) stop 'ICE ASYM LESS THAN 0.0' ! For iceflag=3 option, ice particle generalized effective size is limited to 5.0 to 140.0 microns elseif (iceflag .eq. 3) then if (radice .lt. 5.0_rb .or. radice .gt. 140.0_rb) stop 'ICE GENERALIZED EFFECTIVE SIZE OUT OF BOUNDS' factor = (radice - 2._rb)/3._rb index = int(factor) if (index .eq. 46) index = 45 fint = factor - float(index) ib = ngb(ig) extcoice(ig) = extice3(index,ib) + fint * & (extice3(index+1,ib) - extice3(index,ib)) ssacoice(ig) = ssaice3(index,ib) + fint * & (ssaice3(index+1,ib) - ssaice3(index,ib)) gice(ig) = asyice3(index,ib) + fint * & (asyice3(index+1,ib) - asyice3(index,ib)) fdelta(ig) = fdlice3(index,ib) + fint * & (fdlice3(index+1,ib) - fdlice3(index,ib)) if (fdelta(ig) .lt. 0.0_rb) stop 'FDELTA LESS THAN 0.0' if (fdelta(ig) .gt. 1.0_rb) stop 'FDELTA GT THAN 1.0' forwice(ig) = fdelta(ig) + 0.5_rb / ssacoice(ig) ! See Fu 1996 p. 2067 if (forwice(ig) .gt. gice(ig)) forwice(ig) = gice(ig) ! Check to ensure all calculated quantities are within physical limits. if (extcoice(ig) .lt. 0.0_rb) stop 'ICE EXTINCTION LESS THAN 0.0' if (ssacoice(ig) .gt. 1.0_rb) stop 'ICE SSA GRTR THAN 1.0' if (ssacoice(ig) .lt. 0.0_rb) stop 'ICE SSA LESS THAN 0.0' if (gice(ig) .gt. 1.0_rb) stop 'ICE ASYM GRTR THAN 1.0' if (gice(ig) .lt. 0.0_rb) stop 'ICE ASYM LESS THAN 0.0' endif ! Calculation of absorption coefficients due to water clouds. if (clwpmc(ig,lay) .eq. 0.0_rb) then extcoliq(ig) = 0.0_rb ssacoliq(ig) = 0.0_rb gliq(ig) = 0.0_rb forwliq(ig) = 0.0_rb elseif (liqflag .eq. 1) then radliq = relqmc(lay) if (radliq .lt. 1.5_rb .or. radliq .gt. 60._rb) stop & 'liquid effective radius out of bounds' index = int(radliq - 1.5_rb) if (index .eq. 0) index = 1 if (index .eq. 58) index = 57 fint = radliq - 1.5_rb - float(index) ib = ngb(ig) extcoliq(ig) = extliq1(index,ib) + fint * & (extliq1(index+1,ib) - extliq1(index,ib)) ssacoliq(ig) = ssaliq1(index,ib) + fint * & (ssaliq1(index+1,ib) - ssaliq1(index,ib)) if (fint .lt. 0._rb .and. ssacoliq(ig) .gt. 1._rb) & ssacoliq(ig) = ssaliq1(index,ib) gliq(ig) = asyliq1(index,ib) + fint * & (asyliq1(index+1,ib) - asyliq1(index,ib)) forwliq(ig) = gliq(ig)*gliq(ig) ! Check to ensure all calculated quantities are within physical limits. if (extcoliq(ig) .lt. 0.0_rb) stop 'LIQUID EXTINCTION LESS THAN 0.0' if (ssacoliq(ig) .gt. 1.0_rb) stop 'LIQUID SSA GRTR THAN 1.0' if (ssacoliq(ig) .lt. 0.0_rb) stop 'LIQUID SSA LESS THAN 0.0' if (gliq(ig) .gt. 1.0_rb) stop 'LIQUID ASYM GRTR THAN 1.0' if (gliq(ig) .lt. 0.0_rb) stop 'LIQUID ASYM LESS THAN 0.0' endif tauliqorig = clwpmc(ig,lay) * extcoliq(ig) tauiceorig = ciwpmc(ig,lay) * extcoice(ig) taormc(ig,lay) = tauliqorig + tauiceorig ssaliq = ssacoliq(ig) * (1._rb - forwliq(ig)) / & (1._rb - forwliq(ig) * ssacoliq(ig)) tauliq = (1._rb - forwliq(ig) * ssacoliq(ig)) * tauliqorig ssaice = ssacoice(ig) * (1._rb - forwice(ig)) / & (1._rb - forwice(ig) * ssacoice(ig)) tauice = (1._rb - forwice(ig) * ssacoice(ig)) * tauiceorig scatliq = ssaliq * tauliq scatice = ssaice * tauice taucmc(ig,lay) = tauliq + tauice ! Ensure non-zero taucmc and scatice if(taucmc(ig,lay).eq.0.) taucmc(ig,lay) = cldmin if(scatice.eq.0.) scatice = cldmin ssacmc(ig,lay) = (scatliq + scatice) / taucmc(ig,lay) if (iceflag .eq. 3) then ! In accordance with the 1996 Fu paper, equation A.3, ! the moments for ice were calculated depending on whether using spheres ! or hexagonal ice crystals. ! Set asymetry parameter to first moment (istr=1) istr = 1 asmcmc(ig,lay) = (1.0_rb/(scatliq+scatice))* & (scatliq*(gliq(ig)**istr - forwliq(ig)) / & (1.0_rb - forwliq(ig)) + scatice * ((gice(ig)-forwice(ig))/ & (1.0_rb - forwice(ig)))**istr) else ! This code is the standard method for delta-m scaling. ! Set asymetry parameter to first moment (istr=1) istr = 1 asmcmc(ig,lay) = (scatliq * & (gliq(ig)**istr - forwliq(ig)) / & (1.0_rb - forwliq(ig)) + scatice * (gice(ig)**istr - forwice(ig)) / & (1.0_rb - forwice(ig)))/(scatliq + scatice) endif endif endif ! End g-point interval loop enddo ! End layer loop enddo end subroutine cldprmc_sw end module rrtmg_sw_cldprmc ! path: $Source: /cvsroot/NWP/WRFV3/phys/module_ra_rrtmg_sw.F,v $ ! author: $Author: trn $ ! revision: $Revision: 1.3 $ ! created: $Date: 2009/04/16 19:54:22 $ module rrtmg_sw_reftra ! -------------------------------------------------------------------------- ! | | ! | Copyright 2002-2008, Atmospheric & Environmental Research, Inc. (AER). | ! | This software may be used, copied, or redistributed as long as it is | ! | not sold and this copyright notice is reproduced on each copy made. | ! | This model is provided as is without any express or implied warranties. | ! | (http://www.rtweb.aer.com/) | ! | | ! -------------------------------------------------------------------------- ! ------- Modules ------- use parkind, only : im => kind_im, rb => kind_rb use rrsw_tbl, only : tblint, bpade, od_lo, exp_tbl use rrsw_vsn, only : hvrrft, hnamrft implicit none contains ! -------------------------------------------------------------------- subroutine reftra_sw(nlayers, lrtchk, pgg, prmuz, ptau, pw, & pref, prefd, ptra, ptrad) ! -------------------------------------------------------------------- ! Purpose: computes the reflectivity and transmissivity of a clear or ! cloudy layer using a choice of various approximations. ! ! Interface: *rrtmg_sw_reftra* is called by *rrtmg_sw_spcvrt* ! ! Description: ! explicit arguments : ! -------------------- ! inputs ! ------ ! lrtchk = .t. for all layers in clear profile ! lrtchk = .t. for cloudy layers in cloud profile ! = .f. for clear layers in cloud profile ! pgg = assymetry factor ! prmuz = cosine solar zenith angle ! ptau = optical thickness ! pw = single scattering albedo ! ! outputs ! ------- ! pref : collimated beam reflectivity ! prefd : diffuse beam reflectivity ! ptra : collimated beam transmissivity ! ptrad : diffuse beam transmissivity ! ! ! Method: ! ------- ! standard delta-eddington, p.i.f.m., or d.o.m. layer calculations. ! kmodts = 1 eddington (joseph et al., 1976) ! = 2 pifm (zdunkowski et al., 1980) ! = 3 discrete ordinates (liou, 1973) ! ! ! Modifications: ! -------------- ! Original: J-JMorcrette, ECMWF, Feb 2003 ! Revised for F90 reformatting: MJIacono, AER, Jul 2006 ! Revised to add exponential lookup table: MJIacono, AER, Aug 2007 ! Reformulated some code to avoid potential fpes: MJIacono, AER, Nov 2008 ! ! ------------------------------------------------------------------ ! ------- Declarations ------ ! ------- Input ------- integer(kind=im), intent(in) :: nlayers logical, intent(in) :: lrtchk(:) ! Logical flag for reflectivity and ! and transmissivity calculation; ! Dimensions: (nlayers) real(kind=rb), intent(in) :: pgg(:) ! asymmetry parameter ! Dimensions: (nlayers) real(kind=rb), intent(in) :: ptau(:) ! optical depth ! Dimensions: (nlayers) real(kind=rb), intent(in) :: pw(:) ! single scattering albedo ! Dimensions: (nlayers) real(kind=rb), intent(in) :: prmuz ! cosine of solar zenith angle ! ------- Output ------- real(kind=rb), intent(inout) :: pref(:) ! direct beam reflectivity ! Dimensions: (nlayers+1) real(kind=rb), intent(inout) :: prefd(:) ! diffuse beam reflectivity ! Dimensions: (nlayers+1) real(kind=rb), intent(inout) :: ptra(:) ! direct beam transmissivity ! Dimensions: (nlayers+1) real(kind=rb), intent(inout) :: ptrad(:) ! diffuse beam transmissivity ! Dimensions: (nlayers+1) ! ------- Local ------- integer(kind=im) :: jk, jl, kmodts integer(kind=im) :: itind real(kind=rb) :: tblind real(kind=rb) :: za, za1, za2 real(kind=rb) :: zbeta, zdend, zdenr, zdent real(kind=rb) :: ze1, ze2, zem1, zem2, zemm, zep1, zep2 real(kind=rb) :: zg, zg3, zgamma1, zgamma2, zgamma3, zgamma4, zgt real(kind=rb) :: zr1, zr2, zr3, zr4, zr5 real(kind=rb) :: zrk, zrk2, zrkg, zrm1, zrp, zrp1, zrpp real(kind=rb) :: zsr3, zt1, zt2, zt3, zt4, zt5, zto1 real(kind=rb) :: zw, zwcrit, zwo real(kind=rb), parameter :: eps = 1.e-08_rb ! ------------------------------------------------------------------ ! Initialize hvrrft = '$Revision: 1.3 $' zsr3=sqrt(3._rb) zwcrit=0.9999995_rb kmodts=2 do jk=1, nlayers if (.not.lrtchk(jk)) then pref(jk) =0._rb ptra(jk) =1._rb prefd(jk)=0._rb ptrad(jk)=1._rb else zto1=ptau(jk) zw =pw(jk) zg =pgg(jk) ! General two-stream expressions zg3= 3._rb * zg if (kmodts == 1) then zgamma1= (7._rb - zw * (4._rb + zg3)) * 0.25_rb zgamma2=-(1._rb - zw * (4._rb - zg3)) * 0.25_rb zgamma3= (2._rb - zg3 * prmuz ) * 0.25_rb else if (kmodts == 2) then zgamma1= (8._rb - zw * (5._rb + zg3)) * 0.25_rb zgamma2= 3._rb *(zw * (1._rb - zg )) * 0.25_rb zgamma3= (2._rb - zg3 * prmuz ) * 0.25_rb else if (kmodts == 3) then zgamma1= zsr3 * (2._rb - zw * (1._rb + zg)) * 0.5_rb zgamma2= zsr3 * zw * (1._rb - zg ) * 0.5_rb zgamma3= (1._rb - zsr3 * zg * prmuz ) * 0.5_rb end if zgamma4= 1._rb - zgamma3 ! Recompute original s.s.a. to test for conservative solution zwo= zw / (1._rb - (1._rb - zw) * (zg / (1._rb - zg))**2) if (zwo >= zwcrit) then ! Conservative scattering za = zgamma1 * prmuz za1 = za - zgamma3 zgt = zgamma1 * zto1 ! Homogeneous reflectance and transmittance, ! collimated beam ze1 = min ( zto1 / prmuz , 500._rb) ! ze2 = exp( -ze1 ) ! Use exponential lookup table for transmittance, or expansion of ! exponential for low tau if (ze1 .le. od_lo) then ze2 = 1._rb - ze1 + 0.5_rb * ze1 * ze1 else tblind = ze1 / (bpade + ze1) itind = tblint * tblind + 0.5_rb ze2 = exp_tbl(itind) endif ! pref(jk) = (zgt - za1 * (1._rb - ze2)) / (1._rb + zgt) ptra(jk) = 1._rb - pref(jk) ! isotropic incidence prefd(jk) = zgt / (1._rb + zgt) ptrad(jk) = 1._rb - prefd(jk) ! This is applied for consistency between total (delta-scaled) and direct (unscaled) ! calculations at very low optical depths (tau < 1.e-4) when the exponential lookup ! table returns a transmittance of 1.0. if (ze2 .eq. 1.0_rb) then pref(jk) = 0.0_rb ptra(jk) = 1.0_rb prefd(jk) = 0.0_rb ptrad(jk) = 1.0_rb endif else ! Non-conservative scattering za1 = zgamma1 * zgamma4 + zgamma2 * zgamma3 za2 = zgamma1 * zgamma3 + zgamma2 * zgamma4 zrk = sqrt ( zgamma1**2 - zgamma2**2) zrp = zrk * prmuz zrp1 = 1._rb + zrp zrm1 = 1._rb - zrp zrk2 = 2._rb * zrk zrpp = 1._rb - zrp*zrp zrkg = zrk + zgamma1 zr1 = zrm1 * (za2 + zrk * zgamma3) zr2 = zrp1 * (za2 - zrk * zgamma3) zr3 = zrk2 * (zgamma3 - za2 * prmuz ) zr4 = zrpp * zrkg zr5 = zrpp * (zrk - zgamma1) zt1 = zrp1 * (za1 + zrk * zgamma4) zt2 = zrm1 * (za1 - zrk * zgamma4) zt3 = zrk2 * (zgamma4 + za1 * prmuz ) zt4 = zr4 zt5 = zr5 ! mji - reformulated code to avoid potential floating point exceptions ! zbeta = - zr5 / zr4 zbeta = (zgamma1 - zrk) / zrkg !! ! Homogeneous reflectance and transmittance ze1 = min ( zrk * zto1, 500._rb) ze2 = min ( zto1 / prmuz , 500._rb) ! ! Original ! zep1 = exp( ze1 ) ! zem1 = exp(-ze1 ) ! zep2 = exp( ze2 ) ! zem2 = exp(-ze2 ) ! ! Revised original, to reduce exponentials ! zep1 = exp( ze1 ) ! zem1 = 1._rb / zep1 ! zep2 = exp( ze2 ) ! zem2 = 1._rb / zep2 ! ! Use exponential lookup table for transmittance, or expansion of ! exponential for low tau if (ze1 .le. od_lo) then zem1 = 1._rb - ze1 + 0.5_rb * ze1 * ze1 zep1 = 1._rb / zem1 else tblind = ze1 / (bpade + ze1) itind = tblint * tblind + 0.5_rb zem1 = exp_tbl(itind) zep1 = 1._rb / zem1 endif if (ze2 .le. od_lo) then zem2 = 1._rb - ze2 + 0.5_rb * ze2 * ze2 zep2 = 1._rb / zem2 else tblind = ze2 / (bpade + ze2) itind = tblint * tblind + 0.5_rb zem2 = exp_tbl(itind) zep2 = 1._rb / zem2 endif ! collimated beam ! mji - reformulated code to avoid potential floating point exceptions ! zdenr = zr4*zep1 + zr5*zem1 ! pref(jk) = zw * (zr1*zep1 - zr2*zem1 - zr3*zem2) / zdenr ! zdent = zt4*zep1 + zt5*zem1 ! ptra(jk) = zem2 - zem2 * zw * (zt1*zep1 - zt2*zem1 - zt3*zep2) / zdent zdenr = zr4*zep1 + zr5*zem1 zdent = zt4*zep1 + zt5*zem1 if (zdenr .ge. -eps .and. zdenr .le. eps) then pref(jk) = eps ptra(jk) = zem2 else pref(jk) = zw * (zr1*zep1 - zr2*zem1 - zr3*zem2) / zdenr ptra(jk) = zem2 - zem2 * zw * (zt1*zep1 - zt2*zem1 - zt3*zep2) / zdent endif !! ! diffuse beam zemm = zem1*zem1 zdend = 1._rb / ( (1._rb - zbeta*zemm ) * zrkg) prefd(jk) = zgamma2 * (1._rb - zemm) * zdend ptrad(jk) = zrk2*zem1*zdend endif endif enddo end subroutine reftra_sw end module rrtmg_sw_reftra ! path: $Source: /cvsroot/NWP/WRFV3/phys/module_ra_rrtmg_sw.F,v $ ! author: $Author: trn $ ! revision: $Revision: 1.3 $ ! created: $Date: 2009/04/16 19:54:22 $ module rrtmg_sw_setcoef ! -------------------------------------------------------------------------- ! | | ! | Copyright 2002-2008, Atmospheric & Environmental Research, Inc. (AER). | ! | This software may be used, copied, or redistributed as long as it is | ! | not sold and this copyright notice is reproduced on each copy made. | ! | This model is provided as is without any express or implied warranties. | ! | (http://www.rtweb.aer.com/) | ! | | ! -------------------------------------------------------------------------- ! ------- Modules ------- use parkind, only : im => kind_im, rb => kind_rb use parrrsw, only : mxmol use rrsw_ref, only : pref, preflog, tref use rrsw_vsn, only : hvrset, hnamset implicit none contains !---------------------------------------------------------------------------- subroutine setcoef_sw(nlayers, pavel, tavel, pz, tz, tbound, coldry, wkl, & laytrop, layswtch, laylow, jp, jt, jt1, & co2mult, colch4, colco2, colh2o, colmol, coln2o, & colo2, colo3, fac00, fac01, fac10, fac11, & selffac, selffrac, indself, forfac, forfrac, indfor) !---------------------------------------------------------------------------- ! ! Purpose: For a given atmosphere, calculate the indices and ! fractions related to the pressure and temperature interpolations. ! Modifications: ! Original: J. Delamere, AER, Inc. (version 2.5, 02/04/01) ! Revised: Rewritten and adapted to ECMWF F90, JJMorcrette 030224 ! Revised: For uniform rrtmg formatting, MJIacono, Jul 2006 ! ------ Declarations ------- ! ----- Input ----- integer(kind=im), intent(in) :: nlayers ! total number of layers real(kind=rb), intent(in) :: pavel(:) ! layer pressures (mb) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: tavel(:) ! layer temperatures (K) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: pz(0:) ! level (interface) pressures (hPa, mb) ! Dimensions: (0:nlayers) real(kind=rb), intent(in) :: tz(0:) ! level (interface) temperatures (K) ! Dimensions: (0:nlayers) real(kind=rb), intent(in) :: tbound ! surface temperature (K) real(kind=rb), intent(in) :: coldry(:) ! dry air column density (mol/cm2) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: wkl(:,:) ! molecular amounts (mol/cm-2) ! Dimensions: (mxmol,nlayers) ! ----- Output ----- integer(kind=im), intent(out) :: laytrop ! tropopause layer index integer(kind=im), intent(out) :: layswtch ! integer(kind=im), intent(out) :: laylow ! integer(kind=im), intent(out) :: jp(:) ! ! Dimensions: (nlayers) integer(kind=im), intent(out) :: jt(:) ! ! Dimensions: (nlayers) integer(kind=im), intent(out) :: jt1(:) ! ! Dimensions: (nlayers) real(kind=rb), intent(out) :: colh2o(:) ! column amount (h2o) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: colco2(:) ! column amount (co2) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: colo3(:) ! column amount (o3) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: coln2o(:) ! column amount (n2o) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: colch4(:) ! column amount (ch4) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: colo2(:) ! column amount (o2) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: colmol(:) ! ! Dimensions: (nlayers) real(kind=rb), intent(out) :: co2mult(:) ! ! Dimensions: (nlayers) integer(kind=im), intent(out) :: indself(:) ! Dimensions: (nlayers) integer(kind=im), intent(out) :: indfor(:) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: selffac(:) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: selffrac(:) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: forfac(:) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: forfrac(:) ! Dimensions: (nlayers) real(kind=rb), intent(out) :: & ! fac00(:), fac01(:), & ! Dimensions: (nlayers) fac10(:), fac11(:) ! ----- Local ----- integer(kind=im) :: indbound integer(kind=im) :: indlev0 integer(kind=im) :: lay integer(kind=im) :: jp1 real(kind=rb) :: stpfac real(kind=rb) :: tbndfrac real(kind=rb) :: t0frac real(kind=rb) :: plog real(kind=rb) :: fp real(kind=rb) :: ft real(kind=rb) :: ft1 real(kind=rb) :: water real(kind=rb) :: scalefac real(kind=rb) :: factor real(kind=rb) :: co2reg real(kind=rb) :: compfp ! Initializations stpfac = 296._rb/1013._rb indbound = tbound - 159._rb tbndfrac = tbound - int(tbound) indlev0 = tz(0) - 159._rb t0frac = tz(0) - int(tz(0)) laytrop = 0 layswtch = 0 laylow = 0 ! Begin layer loop do lay = 1, nlayers ! Find the two reference pressures on either side of the ! layer pressure. Store them in JP and JP1. Store in FP the ! fraction of the difference (in ln(pressure)) between these ! two values that the layer pressure lies. plog = log(pavel(lay)) jp(lay) = int(36._rb - 5*(plog+0.04_rb)) if (jp(lay) .lt. 1) then jp(lay) = 1 elseif (jp(lay) .gt. 58) then jp(lay) = 58 endif jp1 = jp(lay) + 1 fp = 5._rb * (preflog(jp(lay)) - plog) ! Determine, for each reference pressure (JP and JP1), which ! reference temperature (these are different for each ! reference pressure) is nearest the layer temperature but does ! not exceed it. Store these indices in JT and JT1, resp. ! Store in FT (resp. FT1) the fraction of the way between JT ! (JT1) and the next highest reference temperature that the ! layer temperature falls. jt(lay) = int(3._rb + (tavel(lay)-tref(jp(lay)))/15._rb) if (jt(lay) .lt. 1) then jt(lay) = 1 elseif (jt(lay) .gt. 4) then jt(lay) = 4 endif ft = ((tavel(lay)-tref(jp(lay)))/15._rb) - float(jt(lay)-3) jt1(lay) = int(3._rb + (tavel(lay)-tref(jp1))/15._rb) if (jt1(lay) .lt. 1) then jt1(lay) = 1 elseif (jt1(lay) .gt. 4) then jt1(lay) = 4 endif ft1 = ((tavel(lay)-tref(jp1))/15._rb) - float(jt1(lay)-3) water = wkl(1,lay)/coldry(lay) scalefac = pavel(lay) * stpfac / tavel(lay) ! If the pressure is less than ~100mb, perform a different ! set of species interpolations. if (plog .le. 4.56_rb) go to 5300 laytrop = laytrop + 1 if (plog .ge. 6.62_rb) laylow = laylow + 1 ! Set up factors needed to separately include the water vapor ! foreign-continuum in the calculation of absorption coefficient. forfac(lay) = scalefac / (1.+water) factor = (332.0_rb-tavel(lay))/36.0_rb indfor(lay) = min(2, max(1, int(factor))) forfrac(lay) = factor - float(indfor(lay)) ! Set up factors needed to separately include the water vapor ! self-continuum in the calculation of absorption coefficient. selffac(lay) = water * forfac(lay) factor = (tavel(lay)-188.0_rb)/7.2_rb indself(lay) = min(9, max(1, int(factor)-7)) selffrac(lay) = factor - float(indself(lay) + 7) ! Calculate needed column amounts. colh2o(lay) = 1.e-20_rb * wkl(1,lay) colco2(lay) = 1.e-20_rb * wkl(2,lay) colo3(lay) = 1.e-20_rb * wkl(3,lay) ! colo3(lay) = 0._rb ! colo3(lay) = colo3(lay)/1.16_rb coln2o(lay) = 1.e-20_rb * wkl(4,lay) colch4(lay) = 1.e-20_rb * wkl(6,lay) colo2(lay) = 1.e-20_rb * wkl(7,lay) colmol(lay) = 1.e-20_rb * coldry(lay) + colh2o(lay) ! colco2(lay) = 0._rb ! colo3(lay) = 0._rb ! coln2o(lay) = 0._rb ! colch4(lay) = 0._rb ! colo2(lay) = 0._rb ! colmol(lay) = 0._rb if (colco2(lay) .eq. 0._rb) colco2(lay) = 1.e-32_rb * coldry(lay) if (coln2o(lay) .eq. 0._rb) coln2o(lay) = 1.e-32_rb * coldry(lay) if (colch4(lay) .eq. 0._rb) colch4(lay) = 1.e-32_rb * coldry(lay) if (colo2(lay) .eq. 0._rb) colo2(lay) = 1.e-32_rb * coldry(lay) ! Using E = 1334.2 cm-1. co2reg = 3.55e-24_rb * coldry(lay) co2mult(lay)= (colco2(lay) - co2reg) * & 272.63_rb*exp(-1919.4_rb/tavel(lay))/(8.7604e-4_rb*tavel(lay)) goto 5400 ! Above laytrop. 5300 continue ! Set up factors needed to separately include the water vapor ! foreign-continuum in the calculation of absorption coefficient. forfac(lay) = scalefac / (1.+water) factor = (tavel(lay)-188.0_rb)/36.0_rb indfor(lay) = 3 forfrac(lay) = factor - 1.0_rb ! Calculate needed column amounts. colh2o(lay) = 1.e-20_rb * wkl(1,lay) colco2(lay) = 1.e-20_rb * wkl(2,lay) colo3(lay) = 1.e-20_rb * wkl(3,lay) coln2o(lay) = 1.e-20_rb * wkl(4,lay) colch4(lay) = 1.e-20_rb * wkl(6,lay) colo2(lay) = 1.e-20_rb * wkl(7,lay) colmol(lay) = 1.e-20_rb * coldry(lay) + colh2o(lay) if (colco2(lay) .eq. 0._rb) colco2(lay) = 1.e-32_rb * coldry(lay) if (coln2o(lay) .eq. 0._rb) coln2o(lay) = 1.e-32_rb * coldry(lay) if (colch4(lay) .eq. 0._rb) colch4(lay) = 1.e-32_rb * coldry(lay) if (colo2(lay) .eq. 0._rb) colo2(lay) = 1.e-32_rb * coldry(lay) co2reg = 3.55e-24_rb * coldry(lay) co2mult(lay)= (colco2(lay) - co2reg) * & 272.63_rb*exp(-1919.4_rb/tavel(lay))/(8.7604e-4_rb*tavel(lay)) selffac(lay) = 0._rb selffrac(lay)= 0._rb indself(lay) = 0 5400 continue ! We have now isolated the layer ln pressure and temperature, ! between two reference pressures and two reference temperatures ! (for each reference pressure). We multiply the pressure ! fraction FP with the appropriate temperature fractions to get ! the factors that will be needed for the interpolation that yields ! the optical depths (performed in routines TAUGBn for band n). compfp = 1._rb - fp fac10(lay) = compfp * ft fac00(lay) = compfp * (1._rb - ft) fac11(lay) = fp * ft1 fac01(lay) = fp * (1._rb - ft1) ! End layer loop enddo end subroutine setcoef_sw !*************************************************************************** subroutine swatmref !*************************************************************************** save ! These pressures are chosen such that the ln of the first pressure ! has only a few non-zero digits (i.e. ln(PREF(1)) = 6.96000) and ! each subsequent ln(pressure) differs from the previous one by 0.2. pref(:) = (/ & 1.05363e+03_rb,8.62642e+02_rb,7.06272e+02_rb,5.78246e+02_rb,4.73428e+02_rb, & 3.87610e+02_rb,3.17348e+02_rb,2.59823e+02_rb,2.12725e+02_rb,1.74164e+02_rb, & 1.42594e+02_rb,1.16746e+02_rb,9.55835e+01_rb,7.82571e+01_rb,6.40715e+01_rb, & 5.24573e+01_rb,4.29484e+01_rb,3.51632e+01_rb,2.87892e+01_rb,2.35706e+01_rb, & 1.92980e+01_rb,1.57998e+01_rb,1.29358e+01_rb,1.05910e+01_rb,8.67114e+00_rb, & 7.09933e+00_rb,5.81244e+00_rb,4.75882e+00_rb,3.89619e+00_rb,3.18993e+00_rb, & 2.61170e+00_rb,2.13828e+00_rb,1.75067e+00_rb,1.43333e+00_rb,1.17351e+00_rb, & 9.60789e-01_rb,7.86628e-01_rb,6.44036e-01_rb,5.27292e-01_rb,4.31710e-01_rb, & 3.53455e-01_rb,2.89384e-01_rb,2.36928e-01_rb,1.93980e-01_rb,1.58817e-01_rb, & 1.30029e-01_rb,1.06458e-01_rb,8.71608e-02_rb,7.13612e-02_rb,5.84256e-02_rb, & 4.78349e-02_rb,3.91639e-02_rb,3.20647e-02_rb,2.62523e-02_rb,2.14936e-02_rb, & 1.75975e-02_rb,1.44076e-02_rb,1.17959e-02_rb,9.65769e-03_rb /) preflog(:) = (/ & 6.9600e+00_rb, 6.7600e+00_rb, 6.5600e+00_rb, 6.3600e+00_rb, 6.1600e+00_rb, & 5.9600e+00_rb, 5.7600e+00_rb, 5.5600e+00_rb, 5.3600e+00_rb, 5.1600e+00_rb, & 4.9600e+00_rb, 4.7600e+00_rb, 4.5600e+00_rb, 4.3600e+00_rb, 4.1600e+00_rb, & 3.9600e+00_rb, 3.7600e+00_rb, 3.5600e+00_rb, 3.3600e+00_rb, 3.1600e+00_rb, & 2.9600e+00_rb, 2.7600e+00_rb, 2.5600e+00_rb, 2.3600e+00_rb, 2.1600e+00_rb, & 1.9600e+00_rb, 1.7600e+00_rb, 1.5600e+00_rb, 1.3600e+00_rb, 1.1600e+00_rb, & 9.6000e-01_rb, 7.6000e-01_rb, 5.6000e-01_rb, 3.6000e-01_rb, 1.6000e-01_rb, & -4.0000e-02_rb,-2.4000e-01_rb,-4.4000e-01_rb,-6.4000e-01_rb,-8.4000e-01_rb, & -1.0400e+00_rb,-1.2400e+00_rb,-1.4400e+00_rb,-1.6400e+00_rb,-1.8400e+00_rb, & -2.0400e+00_rb,-2.2400e+00_rb,-2.4400e+00_rb,-2.6400e+00_rb,-2.8400e+00_rb, & -3.0400e+00_rb,-3.2400e+00_rb,-3.4400e+00_rb,-3.6400e+00_rb,-3.8400e+00_rb, & -4.0400e+00_rb,-4.2400e+00_rb,-4.4400e+00_rb,-4.6400e+00_rb /) ! These are the temperatures associated with the respective ! pressures for the MLS standard atmosphere. tref(:) = (/ & 2.9420e+02_rb, 2.8799e+02_rb, 2.7894e+02_rb, 2.6925e+02_rb, 2.5983e+02_rb, & 2.5017e+02_rb, 2.4077e+02_rb, 2.3179e+02_rb, 2.2306e+02_rb, 2.1578e+02_rb, & 2.1570e+02_rb, 2.1570e+02_rb, 2.1570e+02_rb, 2.1706e+02_rb, 2.1858e+02_rb, & 2.2018e+02_rb, 2.2174e+02_rb, 2.2328e+02_rb, 2.2479e+02_rb, 2.2655e+02_rb, & 2.2834e+02_rb, 2.3113e+02_rb, 2.3401e+02_rb, 2.3703e+02_rb, 2.4022e+02_rb, & 2.4371e+02_rb, 2.4726e+02_rb, 2.5085e+02_rb, 2.5457e+02_rb, 2.5832e+02_rb, & 2.6216e+02_rb, 2.6606e+02_rb, 2.6999e+02_rb, 2.7340e+02_rb, 2.7536e+02_rb, & 2.7568e+02_rb, 2.7372e+02_rb, 2.7163e+02_rb, 2.6955e+02_rb, 2.6593e+02_rb, & 2.6211e+02_rb, 2.5828e+02_rb, 2.5360e+02_rb, 2.4854e+02_rb, 2.4348e+02_rb, & 2.3809e+02_rb, 2.3206e+02_rb, 2.2603e+02_rb, 2.2000e+02_rb, 2.1435e+02_rb, & 2.0887e+02_rb, 2.0340e+02_rb, 1.9792e+02_rb, 1.9290e+02_rb, 1.8809e+02_rb, & 1.8329e+02_rb, 1.7849e+02_rb, 1.7394e+02_rb, 1.7212e+02_rb /) end subroutine swatmref end module rrtmg_sw_setcoef ! path: $Source: /cvsroot/NWP/WRFV3/phys/module_ra_rrtmg_sw.F,v $ ! author: $Author: trn $ ! revision: $Revision: 1.3 $ ! created: $Date: 2009/04/16 19:54:22 $ module rrtmg_sw_taumol ! -------------------------------------------------------------------------- ! | | ! | Copyright 2002-2008, Atmospheric & Environmental Research, Inc. (AER). | ! | This software may be used, copied, or redistributed as long as it is | ! | not sold and this copyright notice is reproduced on each copy made. | ! | This model is provided as is without any express or implied warranties. | ! | (http://www.rtweb.aer.com/) | ! | | ! -------------------------------------------------------------------------- ! ------- Modules ------- use parkind, only : im => kind_im, rb => kind_rb ! use parrrsw, only : mg, jpband, nbndsw, ngptsw use rrsw_con, only: oneminus use rrsw_wvn, only: nspa, nspb use rrsw_vsn, only: hvrtau, hnamtau implicit none contains !---------------------------------------------------------------------------- subroutine taumol_sw(nlayers, & colh2o, colco2, colch4, colo2, colo3, colmol, & laytrop, jp, jt, jt1, & fac00, fac01, fac10, fac11, & selffac, selffrac, indself, forfac, forfrac, indfor, & sfluxzen, taug, taur) !---------------------------------------------------------------------------- ! ****************************************************************************** ! * * ! * Optical depths developed for the * ! * * ! * RAPID RADIATIVE TRANSFER MODEL (RRTM) * ! * * ! * * ! * ATMOSPHERIC AND ENVIRONMENTAL RESEARCH, INC. * ! * 131 HARTWELL AVENUE * ! * LEXINGTON, MA 02421 * ! * * ! * * ! * ELI J. MLAWER * ! * JENNIFER DELAMERE * ! * STEVEN J. TAUBMAN * ! * SHEPARD A. CLOUGH * ! * * ! * * ! * * ! * * ! * email: mlawer@aer.com * ! * email: jdelamer@aer.com * ! * * ! * The authors wish to acknowledge the contributions of the * ! * following people: Patrick D. Brown, Michael J. Iacono, * ! * Ronald E. Farren, Luke Chen, Robert Bergstrom. * ! * * ! ****************************************************************************** ! * TAUMOL * ! * * ! * This file contains the subroutines TAUGBn (where n goes from * ! * 1 to 28). TAUGBn calculates the optical depths and Planck fractions * ! * per g-value and layer for band n. * ! * * ! * Output: optical depths (unitless) * ! * fractions needed to compute Planck functions at every layer * ! * and g-value * ! * * ! * COMMON /TAUGCOM/ TAUG(MXLAY,MG) * ! * COMMON /PLANKG/ FRACS(MXLAY,MG) * ! * * ! * Input * ! * * ! * PARAMETER (MG=16, MXLAY=203, NBANDS=14) * ! * * ! * COMMON /FEATURES/ NG(NBANDS),NSPA(NBANDS),NSPB(NBANDS) * ! * COMMON /PRECISE/ ONEMINUS * ! * COMMON /PROFILE/ NLAYERS,PAVEL(MXLAY),TAVEL(MXLAY), * ! * & PZ(0:MXLAY),TZ(0:MXLAY),TBOUND * ! * COMMON /PROFDATA/ LAYTROP,LAYSWTCH,LAYLOW, * ! * & COLH2O(MXLAY),COLCO2(MXLAY), * ! * & COLO3(MXLAY),COLN2O(MXLAY),COLCH4(MXLAY), * ! * & COLO2(MXLAY),CO2MULT(MXLAY) * ! * COMMON /INTFAC/ FAC00(MXLAY),FAC01(MXLAY), * ! * & FAC10(MXLAY),FAC11(MXLAY) * ! * COMMON /INTIND/ JP(MXLAY),JT(MXLAY),JT1(MXLAY) * ! * COMMON /SELF/ SELFFAC(MXLAY), SELFFRAC(MXLAY), INDSELF(MXLAY) * ! * * ! * Description: * ! * NG(IBAND) - number of g-values in band IBAND * ! * NSPA(IBAND) - for the lower atmosphere, the number of reference * ! * atmospheres that are stored for band IBAND per * ! * pressure level and temperature. Each of these * ! * atmospheres has different relative amounts of the * ! * key species for the band (i.e. different binary * ! * species parameters). * ! * NSPB(IBAND) - same for upper atmosphere * ! * ONEMINUS - since problems are caused in some cases by interpolation * ! * parameters equal to or greater than 1, for these cases * ! * these parameters are set to this value, slightly < 1. * ! * PAVEL - layer pressures (mb) * ! * TAVEL - layer temperatures (degrees K) * ! * PZ - level pressures (mb) * ! * TZ - level temperatures (degrees K) * ! * LAYTROP - layer at which switch is made from one combination of * ! * key species to another * ! * COLH2O, COLCO2, COLO3, COLN2O, COLCH4 - column amounts of water * ! * vapor,carbon dioxide, ozone, nitrous ozide, methane, * ! * respectively (molecules/cm**2) * ! * CO2MULT - for bands in which carbon dioxide is implemented as a * ! * trace species, this is the factor used to multiply the * ! * band's average CO2 absorption coefficient to get the added * ! * contribution to the optical depth relative to 355 ppm. * ! * FACij(LAY) - for layer LAY, these are factors that are needed to * ! * compute the interpolation factors that multiply the * ! * appropriate reference k-values. A value of 0 (1) for * ! * i,j indicates that the corresponding factor multiplies * ! * reference k-value for the lower (higher) of the two * ! * appropriate temperatures, and altitudes, respectively. * ! * JP - the index of the lower (in altitude) of the two appropriate * ! * reference pressure levels needed for interpolation * ! * JT, JT1 - the indices of the lower of the two appropriate reference * ! * temperatures needed for interpolation (for pressure * ! * levels JP and JP+1, respectively) * ! * SELFFAC - scale factor needed to water vapor self-continuum, equals * ! * (water vapor density)/(atmospheric density at 296K and * ! * 1013 mb) * ! * SELFFRAC - factor needed for temperature interpolation of reference * ! * water vapor self-continuum data * ! * INDSELF - index of the lower of the two appropriate reference * ! * temperatures needed for the self-continuum interpolation * ! * * ! * Data input * ! * COMMON /Kn/ KA(NSPA(n),5,13,MG), KB(NSPB(n),5,13:59,MG), SELFREF(10,MG) * ! * (note: n is the band number) * ! * * ! * Description: * ! * KA - k-values for low reference atmospheres (no water vapor * ! * self-continuum) (units: cm**2/molecule) * ! * KB - k-values for high reference atmospheres (all sources) * ! * (units: cm**2/molecule) * ! * SELFREF - k-values for water vapor self-continuum for reference * ! * atmospheres (used below LAYTROP) * ! * (units: cm**2/molecule) * ! * * ! * DIMENSION ABSA(65*NSPA(n),MG), ABSB(235*NSPB(n),MG) * ! * EQUIVALENCE (KA,ABSA),(KB,ABSB) * ! * * ! ***************************************************************************** ! ! Modifications ! ! Revised: Adapted to F90 coding, J.-J.Morcrette, ECMWF, Feb 2003 ! Revised: Modified for g-point reduction, MJIacono, AER, Dec 2003 ! Revised: Reformatted for consistency with rrtmg_lw, MJIacono, AER, Jul 2006 ! ! ------- Declarations ------- ! ----- Input ----- integer(kind=im), intent(in) :: nlayers ! total number of layers integer(kind=im), intent(in) :: laytrop ! tropopause layer index integer(kind=im), intent(in) :: jp(:) ! ! Dimensions: (nlayers) integer(kind=im), intent(in) :: jt(:) ! ! Dimensions: (nlayers) integer(kind=im), intent(in) :: jt1(:) ! ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colh2o(:) ! column amount (h2o) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colco2(:) ! column amount (co2) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colo3(:) ! column amount (o3) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colch4(:) ! column amount (ch4) ! Dimensions: (nlayers) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colo2(:) ! column amount (o2) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colmol(:) ! ! Dimensions: (nlayers) integer(kind=im), intent(in) :: indself(:) ! Dimensions: (nlayers) integer(kind=im), intent(in) :: indfor(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: selffac(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: selffrac(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: forfac(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: forfrac(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: & ! fac00(:), fac01(:), & ! Dimensions: (nlayers) fac10(:), fac11(:) ! ----- Output ----- real(kind=rb), intent(out) :: sfluxzen(:) ! solar source function ! Dimensions: (ngptsw) real(kind=rb), intent(out) :: taug(:,:) ! gaseous optical depth ! Dimensions: (nlayers,ngptsw) real(kind=rb), intent(out) :: taur(:,:) ! Rayleigh ! Dimensions: (nlayers,ngptsw) ! real(kind=rb), intent(out) :: ssa(:,:) ! single scattering albedo (inactive) ! Dimensions: (nlayers,ngptsw) hvrtau = '$Revision: 1.3 $' ! Calculate gaseous optical depth and planck fractions for each spectral band. call taumol16 call taumol17 call taumol18 call taumol19 call taumol20 call taumol21 call taumol22 call taumol23 call taumol24 call taumol25 call taumol26 call taumol27 call taumol28 call taumol29 !------------- contains !------------- !---------------------------------------------------------------------------- subroutine taumol16 !---------------------------------------------------------------------------- ! ! band 16: 2600-3250 cm-1 (low - h2o,ch4; high - ch4) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng16 use rrsw_kg16, only : absa, ka, absb, kb, forref, selfref, & sfluxref, rayl, layreffr, strrat1 ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. ! Lower atmosphere loop do lay = 1, laytrop speccomb = colh2o(lay) + strrat1*colch4(lay) specparm = colh2o(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 8._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(16) + js ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(16) + js inds = indself(lay) indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng16 taug(lay,ig) = speccomb * & (fac000 * absa(ind0 ,ig) + & fac100 * absa(ind0 +1,ig) + & fac010 * absa(ind0 +9,ig) + & fac110 * absa(ind0+10,ig) + & fac001 * absa(ind1 ,ig) + & fac101 * absa(ind1 +1,ig) + & fac011 * absa(ind1 +9,ig) + & fac111 * absa(ind1+10,ig)) + & colh2o(lay) * & (selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) ! ssa(lay,ig) = tauray/taug(lay,ig) taur(lay,ig) = tauray enddo enddo laysolfr = nlayers ! Upper atmosphere loop do lay = laytrop+1, nlayers if (jp(lay-1) .lt. layreffr .and. jp(lay) .ge. layreffr) & laysolfr = lay ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(16) + 1 ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(16) + 1 tauray = colmol(lay) * rayl do ig = 1, ng16 taug(lay,ig) = colch4(lay) * & (fac00(lay) * absb(ind0 ,ig) + & fac10(lay) * absb(ind0+1,ig) + & fac01(lay) * absb(ind1 ,ig) + & fac11(lay) * absb(ind1+1,ig)) ! ssa(lay,ig) = tauray/taug(lay,ig) if (lay .eq. laysolfr) sfluxzen(ig) = sfluxref(ig) taur(lay,ig) = tauray enddo enddo end subroutine taumol16 !---------------------------------------------------------------------------- subroutine taumol17 !---------------------------------------------------------------------------- ! ! band 17: 3250-4000 cm-1 (low - h2o,co2; high - h2o,co2) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng17, ngs16 use rrsw_kg17, only : absa, ka, absb, kb, forref, selfref, & sfluxref, rayl, layreffr, strrat ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. ! Lower atmosphere loop do lay = 1, laytrop speccomb = colh2o(lay) + strrat*colco2(lay) specparm = colh2o(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 8._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(17) + js ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(17) + js inds = indself(lay) indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng17 taug(lay,ngs16+ig) = speccomb * & (fac000 * absa(ind0,ig) + & fac100 * absa(ind0+1,ig) + & fac010 * absa(ind0+9,ig) + & fac110 * absa(ind0+10,ig) + & fac001 * absa(ind1,ig) + & fac101 * absa(ind1+1,ig) + & fac011 * absa(ind1+9,ig) + & fac111 * absa(ind1+10,ig)) + & colh2o(lay) * & (selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) ! ssa(lay,ngs16+ig) = tauray/taug(lay,ngs16+ig) taur(lay,ngs16+ig) = tauray enddo enddo laysolfr = nlayers ! Upper atmosphere loop do lay = laytrop+1, nlayers if (jp(lay-1) .lt. layreffr .and. jp(lay) .ge. layreffr) & laysolfr = lay speccomb = colh2o(lay) + strrat*colco2(lay) specparm = colh2o(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 4._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(17) + js ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(17) + js indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng17 taug(lay,ngs16+ig) = speccomb * & (fac000 * absb(ind0,ig) + & fac100 * absb(ind0+1,ig) + & fac010 * absb(ind0+5,ig) + & fac110 * absb(ind0+6,ig) + & fac001 * absb(ind1,ig) + & fac101 * absb(ind1+1,ig) + & fac011 * absb(ind1+5,ig) + & fac111 * absb(ind1+6,ig)) + & colh2o(lay) * & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig))) ! ssa(lay,ngs16+ig) = tauray/taug(lay,ngs16+ig) if (lay .eq. laysolfr) sfluxzen(ngs16+ig) = sfluxref(ig,js) & + fs * (sfluxref(ig,js+1) - sfluxref(ig,js)) taur(lay,ngs16+ig) = tauray enddo enddo end subroutine taumol17 !---------------------------------------------------------------------------- subroutine taumol18 !---------------------------------------------------------------------------- ! ! band 18: 4000-4650 cm-1 (low - h2o,ch4; high - ch4) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng18, ngs17 use rrsw_kg18, only : absa, ka, absb, kb, forref, selfref, & sfluxref, rayl, layreffr, strrat ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. laysolfr = laytrop ! Lower atmosphere loop do lay = 1, laytrop if (jp(lay) .lt. layreffr .and. jp(lay+1) .ge. layreffr) & laysolfr = min(lay+1,laytrop) speccomb = colh2o(lay) + strrat*colch4(lay) specparm = colh2o(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 8._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(18) + js ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(18) + js inds = indself(lay) indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng18 taug(lay,ngs17+ig) = speccomb * & (fac000 * absa(ind0,ig) + & fac100 * absa(ind0+1,ig) + & fac010 * absa(ind0+9,ig) + & fac110 * absa(ind0+10,ig) + & fac001 * absa(ind1,ig) + & fac101 * absa(ind1+1,ig) + & fac011 * absa(ind1+9,ig) + & fac111 * absa(ind1+10,ig)) + & colh2o(lay) * & (selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) ! ssa(lay,ngs17+ig) = tauray/taug(lay,ngs17+ig) if (lay .eq. laysolfr) sfluxzen(ngs17+ig) = sfluxref(ig,js) & + fs * (sfluxref(ig,js+1) - sfluxref(ig,js)) taur(lay,ngs17+ig) = tauray enddo enddo ! Upper atmosphere loop do lay = laytrop+1, nlayers ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(18) + 1 ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(18) + 1 tauray = colmol(lay) * rayl do ig = 1, ng18 taug(lay,ngs17+ig) = colch4(lay) * & (fac00(lay) * absb(ind0,ig) + & fac10(lay) * absb(ind0+1,ig) + & fac01(lay) * absb(ind1,ig) + & fac11(lay) * absb(ind1+1,ig)) ! ssa(lay,ngs17+ig) = tauray/taug(lay,ngs17+ig) taur(lay,ngs17+ig) = tauray enddo enddo end subroutine taumol18 !---------------------------------------------------------------------------- subroutine taumol19 !---------------------------------------------------------------------------- ! ! band 19: 4650-5150 cm-1 (low - h2o,co2; high - co2) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng19, ngs18 use rrsw_kg19, only : absa, ka, absb, kb, forref, selfref, & sfluxref, rayl, layreffr, strrat ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. laysolfr = laytrop ! Lower atmosphere loop do lay = 1, laytrop if (jp(lay) .lt. layreffr .and. jp(lay+1) .ge. layreffr) & laysolfr = min(lay+1,laytrop) speccomb = colh2o(lay) + strrat*colco2(lay) specparm = colh2o(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 8._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(19) + js ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(19) + js inds = indself(lay) indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1 , ng19 taug(lay,ngs18+ig) = speccomb * & (fac000 * absa(ind0,ig) + & fac100 * absa(ind0+1,ig) + & fac010 * absa(ind0+9,ig) + & fac110 * absa(ind0+10,ig) + & fac001 * absa(ind1,ig) + & fac101 * absa(ind1+1,ig) + & fac011 * absa(ind1+9,ig) + & fac111 * absa(ind1+10,ig)) + & colh2o(lay) * & (selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) ! ssa(lay,ngs18+ig) = tauray/taug(lay,ngs18+ig) if (lay .eq. laysolfr) sfluxzen(ngs18+ig) = sfluxref(ig,js) & + fs * (sfluxref(ig,js+1) - sfluxref(ig,js)) taur(lay,ngs18+ig) = tauray enddo enddo ! Upper atmosphere loop do lay = laytrop+1, nlayers ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(19) + 1 ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(19) + 1 tauray = colmol(lay) * rayl do ig = 1 , ng19 taug(lay,ngs18+ig) = colco2(lay) * & (fac00(lay) * absb(ind0,ig) + & fac10(lay) * absb(ind0+1,ig) + & fac01(lay) * absb(ind1,ig) + & fac11(lay) * absb(ind1+1,ig)) ! ssa(lay,ngs18+ig) = tauray/taug(lay,ngs18+ig) taur(lay,ngs18+ig) = tauray enddo enddo end subroutine taumol19 !---------------------------------------------------------------------------- subroutine taumol20 !---------------------------------------------------------------------------- ! ! band 20: 5150-6150 cm-1 (low - h2o; high - h2o) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng20, ngs19 use rrsw_kg20, only : absa, ka, absb, kb, forref, selfref, & sfluxref, absch4, rayl, layreffr implicit none ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. laysolfr = laytrop ! Lower atmosphere loop do lay = 1, laytrop if (jp(lay) .lt. layreffr .and. jp(lay+1) .ge. layreffr) & laysolfr = min(lay+1,laytrop) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(20) + 1 ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(20) + 1 inds = indself(lay) indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng20 taug(lay,ngs19+ig) = colh2o(lay) * & ((fac00(lay) * absa(ind0,ig) + & fac10(lay) * absa(ind0+1,ig) + & fac01(lay) * absa(ind1,ig) + & fac11(lay) * absa(ind1+1,ig)) + & selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) & + colch4(lay) * absch4(ig) ! ssa(lay,ngs19+ig) = tauray/taug(lay,ngs19+ig) taur(lay,ngs19+ig) = tauray if (lay .eq. laysolfr) sfluxzen(ngs19+ig) = sfluxref(ig) enddo enddo ! Upper atmosphere loop do lay = laytrop+1, nlayers ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(20) + 1 ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(20) + 1 indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng20 taug(lay,ngs19+ig) = colh2o(lay) * & (fac00(lay) * absb(ind0,ig) + & fac10(lay) * absb(ind0+1,ig) + & fac01(lay) * absb(ind1,ig) + & fac11(lay) * absb(ind1+1,ig) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) + & colch4(lay) * absch4(ig) ! ssa(lay,ngs19+ig) = tauray/taug(lay,ngs19+ig) taur(lay,ngs19+ig) = tauray enddo enddo end subroutine taumol20 !---------------------------------------------------------------------------- subroutine taumol21 !---------------------------------------------------------------------------- ! ! band 21: 6150-7700 cm-1 (low - h2o,co2; high - h2o,co2) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng21, ngs20 use rrsw_kg21, only : absa, ka, absb, kb, forref, selfref, & sfluxref, rayl, layreffr, strrat ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. laysolfr = laytrop ! Lower atmosphere loop do lay = 1, laytrop if (jp(lay) .lt. layreffr .and. jp(lay+1) .ge. layreffr) & laysolfr = min(lay+1,laytrop) speccomb = colh2o(lay) + strrat*colco2(lay) specparm = colh2o(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 8._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(21) + js ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(21) + js inds = indself(lay) indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng21 taug(lay,ngs20+ig) = speccomb * & (fac000 * absa(ind0,ig) + & fac100 * absa(ind0+1,ig) + & fac010 * absa(ind0+9,ig) + & fac110 * absa(ind0+10,ig) + & fac001 * absa(ind1,ig) + & fac101 * absa(ind1+1,ig) + & fac011 * absa(ind1+9,ig) + & fac111 * absa(ind1+10,ig)) + & colh2o(lay) * & (selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) ! ssa(lay,ngs20+ig) = tauray/taug(lay,ngs20+ig) if (lay .eq. laysolfr) sfluxzen(ngs20+ig) = sfluxref(ig,js) & + fs * (sfluxref(ig,js+1) - sfluxref(ig,js)) taur(lay,ngs20+ig) = tauray enddo enddo ! Upper atmosphere loop do lay = laytrop+1, nlayers speccomb = colh2o(lay) + strrat*colco2(lay) specparm = colh2o(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 4._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(21) + js ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(21) + js indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng21 taug(lay,ngs20+ig) = speccomb * & (fac000 * absb(ind0,ig) + & fac100 * absb(ind0+1,ig) + & fac010 * absb(ind0+5,ig) + & fac110 * absb(ind0+6,ig) + & fac001 * absb(ind1,ig) + & fac101 * absb(ind1+1,ig) + & fac011 * absb(ind1+5,ig) + & fac111 * absb(ind1+6,ig)) + & colh2o(lay) * & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig))) ! ssa(lay,ngs20+ig) = tauray/taug(lay,ngs20+ig) taur(lay,ngs20+ig) = tauray enddo enddo end subroutine taumol21 !---------------------------------------------------------------------------- subroutine taumol22 !---------------------------------------------------------------------------- ! ! band 22: 7700-8050 cm-1 (low - h2o,o2; high - o2) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng22, ngs21 use rrsw_kg22, only : absa, ka, absb, kb, forref, selfref, & sfluxref, rayl, layreffr, strrat ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray, o2adj, o2cont ! The following factor is the ratio of total O2 band intensity (lines ! and Mate continuum) to O2 band intensity (line only). It is needed ! to adjust the optical depths since the k's include only lines. o2adj = 1.6_rb ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. laysolfr = laytrop ! Lower atmosphere loop do lay = 1, laytrop if (jp(lay) .lt. layreffr .and. jp(lay+1) .ge. layreffr) & laysolfr = min(lay+1,laytrop) o2cont = 4.35e-4_rb*colo2(lay)/(350.0_rb*2.0_rb) speccomb = colh2o(lay) + o2adj*strrat*colo2(lay) specparm = colh2o(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 8._rb*(specparm) ! odadj = specparm + o2adj * (1._rb - specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(22) + js ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(22) + js inds = indself(lay) indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng22 taug(lay,ngs21+ig) = speccomb * & (fac000 * absa(ind0,ig) + & fac100 * absa(ind0+1,ig) + & fac010 * absa(ind0+9,ig) + & fac110 * absa(ind0+10,ig) + & fac001 * absa(ind1,ig) + & fac101 * absa(ind1+1,ig) + & fac011 * absa(ind1+9,ig) + & fac111 * absa(ind1+10,ig)) + & colh2o(lay) * & (selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) & + o2cont ! ssa(lay,ngs21+ig) = tauray/taug(lay,ngs21+ig) if (lay .eq. laysolfr) sfluxzen(ngs21+ig) = sfluxref(ig,js) & + fs * (sfluxref(ig,js+1) - sfluxref(ig,js)) taur(lay,ngs21+ig) = tauray enddo enddo ! Upper atmosphere loop do lay = laytrop+1, nlayers o2cont = 4.35e-4_rb*colo2(lay)/(350.0_rb*2.0_rb) ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(22) + 1 ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(22) + 1 tauray = colmol(lay) * rayl do ig = 1, ng22 taug(lay,ngs21+ig) = colo2(lay) * o2adj * & (fac00(lay) * absb(ind0,ig) + & fac10(lay) * absb(ind0+1,ig) + & fac01(lay) * absb(ind1,ig) + & fac11(lay) * absb(ind1+1,ig)) + & o2cont ! ssa(lay,ngs21+ig) = tauray/taug(lay,ngs21+ig) taur(lay,ngs21+ig) = tauray enddo enddo end subroutine taumol22 !---------------------------------------------------------------------------- subroutine taumol23 !---------------------------------------------------------------------------- ! ! band 23: 8050-12850 cm-1 (low - h2o; high - nothing) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng23, ngs22 use rrsw_kg23, only : absa, ka, forref, selfref, & sfluxref, rayl, layreffr, givfac ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. laysolfr = laytrop ! Lower atmosphere loop do lay = 1, laytrop if (jp(lay) .lt. layreffr .and. jp(lay+1) .ge. layreffr) & laysolfr = min(lay+1,laytrop) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(23) + 1 ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(23) + 1 inds = indself(lay) indf = indfor(lay) do ig = 1, ng23 tauray = colmol(lay) * rayl(ig) taug(lay,ngs22+ig) = colh2o(lay) * & (givfac * (fac00(lay) * absa(ind0,ig) + & fac10(lay) * absa(ind0+1,ig) + & fac01(lay) * absa(ind1,ig) + & fac11(lay) * absa(ind1+1,ig)) + & selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) ! ssa(lay,ngs22+ig) = tauray/taug(lay,ngs22+ig) if (lay .eq. laysolfr) sfluxzen(ngs22+ig) = sfluxref(ig) taur(lay,ngs22+ig) = tauray enddo enddo ! Upper atmosphere loop do lay = laytrop+1, nlayers do ig = 1, ng23 ! taug(lay,ngs22+ig) = colmol(lay) * rayl(ig) ! ssa(lay,ngs22+ig) = 1.0_rb taug(lay,ngs22+ig) = 0._rb taur(lay,ngs22+ig) = colmol(lay) * rayl(ig) enddo enddo end subroutine taumol23 !---------------------------------------------------------------------------- subroutine taumol24 !---------------------------------------------------------------------------- ! ! band 24: 12850-16000 cm-1 (low - h2o,o2; high - o2) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng24, ngs23 use rrsw_kg24, only : absa, ka, absb, kb, forref, selfref, & sfluxref, abso3a, abso3b, rayla, raylb, & layreffr, strrat ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. laysolfr = laytrop ! Lower atmosphere loop do lay = 1, laytrop if (jp(lay) .lt. layreffr .and. jp(lay+1) .ge. layreffr) & laysolfr = min(lay+1,laytrop) speccomb = colh2o(lay) + strrat*colo2(lay) specparm = colh2o(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 8._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(24) + js ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(24) + js inds = indself(lay) indf = indfor(lay) do ig = 1, ng24 tauray = colmol(lay) * (rayla(ig,js) + & fs * (rayla(ig,js+1) - rayla(ig,js))) taug(lay,ngs23+ig) = speccomb * & (fac000 * absa(ind0,ig) + & fac100 * absa(ind0+1,ig) + & fac010 * absa(ind0+9,ig) + & fac110 * absa(ind0+10,ig) + & fac001 * absa(ind1,ig) + & fac101 * absa(ind1+1,ig) + & fac011 * absa(ind1+9,ig) + & fac111 * absa(ind1+10,ig)) + & colo3(lay) * abso3a(ig) + & colh2o(lay) * & (selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) ! ssa(lay,ngs23+ig) = tauray/taug(lay,ngs23+ig) if (lay .eq. laysolfr) sfluxzen(ngs23+ig) = sfluxref(ig,js) & + fs * (sfluxref(ig,js+1) - sfluxref(ig,js)) taur(lay,ngs23+ig) = tauray enddo enddo ! Upper atmosphere loop do lay = laytrop+1, nlayers ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(24) + 1 ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(24) + 1 do ig = 1, ng24 tauray = colmol(lay) * raylb(ig) taug(lay,ngs23+ig) = colo2(lay) * & (fac00(lay) * absb(ind0,ig) + & fac10(lay) * absb(ind0+1,ig) + & fac01(lay) * absb(ind1,ig) + & fac11(lay) * absb(ind1+1,ig)) + & colo3(lay) * abso3b(ig) ! ssa(lay,ngs23+ig) = tauray/taug(lay,ngs23+ig) taur(lay,ngs23+ig) = tauray enddo enddo end subroutine taumol24 !---------------------------------------------------------------------------- subroutine taumol25 !---------------------------------------------------------------------------- ! ! band 25: 16000-22650 cm-1 (low - h2o; high - nothing) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng25, ngs24 use rrsw_kg25, only : absa, ka, & sfluxref, abso3a, abso3b, rayl, layreffr ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. laysolfr = laytrop ! Lower atmosphere loop do lay = 1, laytrop if (jp(lay) .lt. layreffr .and. jp(lay+1) .ge. layreffr) & laysolfr = min(lay+1,laytrop) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(25) + 1 ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(25) + 1 do ig = 1, ng25 tauray = colmol(lay) * rayl(ig) taug(lay,ngs24+ig) = colh2o(lay) * & (fac00(lay) * absa(ind0,ig) + & fac10(lay) * absa(ind0+1,ig) + & fac01(lay) * absa(ind1,ig) + & fac11(lay) * absa(ind1+1,ig)) + & colo3(lay) * abso3a(ig) ! ssa(lay,ngs24+ig) = tauray/taug(lay,ngs24+ig) if (lay .eq. laysolfr) sfluxzen(ngs24+ig) = sfluxref(ig) taur(lay,ngs24+ig) = tauray enddo enddo ! Upper atmosphere loop do lay = laytrop+1, nlayers do ig = 1, ng25 tauray = colmol(lay) * rayl(ig) taug(lay,ngs24+ig) = colo3(lay) * abso3b(ig) ! ssa(lay,ngs24+ig) = tauray/taug(lay,ngs24+ig) taur(lay,ngs24+ig) = tauray enddo enddo end subroutine taumol25 !---------------------------------------------------------------------------- subroutine taumol26 !---------------------------------------------------------------------------- ! ! band 26: 22650-29000 cm-1 (low - nothing; high - nothing) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng26, ngs25 use rrsw_kg26, only : sfluxref, rayl ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. laysolfr = laytrop ! Lower atmosphere loop do lay = 1, laytrop do ig = 1, ng26 ! taug(lay,ngs25+ig) = colmol(lay) * rayl(ig) ! ssa(lay,ngs25+ig) = 1.0_rb if (lay .eq. laysolfr) sfluxzen(ngs25+ig) = sfluxref(ig) taug(lay,ngs25+ig) = 0._rb taur(lay,ngs25+ig) = colmol(lay) * rayl(ig) enddo enddo ! Upper atmosphere loop do lay = laytrop+1, nlayers do ig = 1, ng26 ! taug(lay,ngs25+ig) = colmol(lay) * rayl(ig) ! ssa(lay,ngs25+ig) = 1.0_rb taug(lay,ngs25+ig) = 0._rb taur(lay,ngs25+ig) = colmol(lay) * rayl(ig) enddo enddo end subroutine taumol26 !---------------------------------------------------------------------------- subroutine taumol27 !---------------------------------------------------------------------------- ! ! band 27: 29000-38000 cm-1 (low - o3; high - o3) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng27, ngs26 use rrsw_kg27, only : absa, ka, absb, kb, & sfluxref, rayl, layreffr, scalekur ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. ! Lower atmosphere loop do lay = 1, laytrop ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(27) + 1 ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(27) + 1 do ig = 1, ng27 tauray = colmol(lay) * rayl(ig) taug(lay,ngs26+ig) = colo3(lay) * & (fac00(lay) * absa(ind0,ig) + & fac10(lay) * absa(ind0+1,ig) + & fac01(lay) * absa(ind1,ig) + & fac11(lay) * absa(ind1+1,ig)) ! ssa(lay,ngs26+ig) = tauray/taug(lay,ngs26+ig) taur(lay,ngs26+ig) = tauray enddo enddo laysolfr = nlayers ! Upper atmosphere loop do lay = laytrop+1, nlayers if (jp(lay-1) .lt. layreffr .and. jp(lay) .ge. layreffr) & laysolfr = lay ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(27) + 1 ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(27) + 1 do ig = 1, ng27 tauray = colmol(lay) * rayl(ig) taug(lay,ngs26+ig) = colo3(lay) * & (fac00(lay) * absb(ind0,ig) + & fac10(lay) * absb(ind0+1,ig) + & fac01(lay) * absb(ind1,ig) + & fac11(lay) * absb(ind1+1,ig)) ! ssa(lay,ngs26+ig) = tauray/taug(lay,ngs26+ig) if (lay.eq.laysolfr) sfluxzen(ngs26+ig) = scalekur * sfluxref(ig) taur(lay,ngs26+ig) = tauray enddo enddo end subroutine taumol27 !---------------------------------------------------------------------------- subroutine taumol28 !---------------------------------------------------------------------------- ! ! band 28: 38000-50000 cm-1 (low - o3,o2; high - o3,o2) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng28, ngs27 use rrsw_kg28, only : absa, ka, absb, kb, & sfluxref, rayl, layreffr, strrat ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. ! Lower atmosphere loop do lay = 1, laytrop speccomb = colo3(lay) + strrat*colo2(lay) specparm = colo3(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 8._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(28) + js ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(28) + js tauray = colmol(lay) * rayl do ig = 1, ng28 taug(lay,ngs27+ig) = speccomb * & (fac000 * absa(ind0,ig) + & fac100 * absa(ind0+1,ig) + & fac010 * absa(ind0+9,ig) + & fac110 * absa(ind0+10,ig) + & fac001 * absa(ind1,ig) + & fac101 * absa(ind1+1,ig) + & fac011 * absa(ind1+9,ig) + & fac111 * absa(ind1+10,ig)) ! ssa(lay,ngs27+ig) = tauray/taug(lay,ngs27+ig) taur(lay,ngs27+ig) = tauray enddo enddo laysolfr = nlayers ! Upper atmosphere loop do lay = laytrop+1, nlayers if (jp(lay-1) .lt. layreffr .and. jp(lay) .ge. layreffr) & laysolfr = lay speccomb = colo3(lay) + strrat*colo2(lay) specparm = colo3(lay)/speccomb if (specparm .ge. oneminus) specparm = oneminus specmult = 4._rb*(specparm) js = 1 + int(specmult) fs = mod(specmult, 1._rb ) fac000 = (1._rb - fs) * fac00(lay) fac010 = (1._rb - fs) * fac10(lay) fac100 = fs * fac00(lay) fac110 = fs * fac10(lay) fac001 = (1._rb - fs) * fac01(lay) fac011 = (1._rb - fs) * fac11(lay) fac101 = fs * fac01(lay) fac111 = fs * fac11(lay) ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(28) + js ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(28) + js tauray = colmol(lay) * rayl do ig = 1, ng28 taug(lay,ngs27+ig) = speccomb * & (fac000 * absb(ind0,ig) + & fac100 * absb(ind0+1,ig) + & fac010 * absb(ind0+5,ig) + & fac110 * absb(ind0+6,ig) + & fac001 * absb(ind1,ig) + & fac101 * absb(ind1+1,ig) + & fac011 * absb(ind1+5,ig) + & fac111 * absb(ind1+6,ig)) ! ssa(lay,ngs27+ig) = tauray/taug(lay,ngs27+ig) if (lay .eq. laysolfr) sfluxzen(ngs27+ig) = sfluxref(ig,js) & + fs * (sfluxref(ig,js+1) - sfluxref(ig,js)) taur(lay,ngs27+ig) = tauray enddo enddo end subroutine taumol28 !---------------------------------------------------------------------------- subroutine taumol29 !---------------------------------------------------------------------------- ! ! band 29: 820-2600 cm-1 (low - h2o; high - co2) ! !---------------------------------------------------------------------------- ! ------- Modules ------- use parrrsw, only : ng29, ngs28 use rrsw_kg29, only : absa, ka, absb, kb, forref, selfref, & sfluxref, absh2o, absco2, rayl, layreffr ! ------- Declarations ------- ! Local integer(kind=im) :: ig, ind0, ind1, inds, indf, js, lay, laysolfr real(kind=rb) :: fac000, fac001, fac010, fac011, fac100, fac101, & fac110, fac111, fs, speccomb, specmult, specparm, & tauray ! Compute the optical depth by interpolating in ln(pressure), ! temperature, and appropriate species. Below LAYTROP, the water ! vapor self-continuum is interpolated (in temperature) separately. ! Lower atmosphere loop do lay = 1, laytrop ind0 = ((jp(lay)-1)*5+(jt(lay)-1))*nspa(29) + 1 ind1 = (jp(lay)*5+(jt1(lay)-1))*nspa(29) + 1 inds = indself(lay) indf = indfor(lay) tauray = colmol(lay) * rayl do ig = 1, ng29 taug(lay,ngs28+ig) = colh2o(lay) * & ((fac00(lay) * absa(ind0,ig) + & fac10(lay) * absa(ind0+1,ig) + & fac01(lay) * absa(ind1,ig) + & fac11(lay) * absa(ind1+1,ig)) + & selffac(lay) * (selfref(inds,ig) + & selffrac(lay) * & (selfref(inds+1,ig) - selfref(inds,ig))) + & forfac(lay) * (forref(indf,ig) + & forfrac(lay) * & (forref(indf+1,ig) - forref(indf,ig)))) & + colco2(lay) * absco2(ig) ! ssa(lay,ngs28+ig) = tauray/taug(lay,ngs28+ig) taur(lay,ngs28+ig) = tauray enddo enddo laysolfr = nlayers ! Upper atmosphere loop do lay = laytrop+1, nlayers if (jp(lay-1) .lt. layreffr .and. jp(lay) .ge. layreffr) & laysolfr = lay ind0 = ((jp(lay)-13)*5+(jt(lay)-1))*nspb(29) + 1 ind1 = ((jp(lay)-12)*5+(jt1(lay)-1))*nspb(29) + 1 tauray = colmol(lay) * rayl do ig = 1, ng29 taug(lay,ngs28+ig) = colco2(lay) * & (fac00(lay) * absb(ind0,ig) + & fac10(lay) * absb(ind0+1,ig) + & fac01(lay) * absb(ind1,ig) + & fac11(lay) * absb(ind1+1,ig)) & + colh2o(lay) * absh2o(ig) ! ssa(lay,ngs28+ig) = tauray/taug(lay,ngs28+ig) if (lay .eq. laysolfr) sfluxzen(ngs28+ig) = sfluxref(ig) taur(lay,ngs28+ig) = tauray enddo enddo end subroutine taumol29 end subroutine taumol_sw end module rrtmg_sw_taumol ! path: $Source: /cvsroot/NWP/WRFV3/phys/module_ra_rrtmg_sw.F,v $ ! author: $Author: trn $ ! revision: $Revision: 1.3 $ ! created: $Date: 2009/04/16 19:54:22 $ module rrtmg_sw_init ! -------------------------------------------------------------------------- ! | | ! | Copyright 2002-2008, Atmospheric & Environmental Research, Inc. (AER). | ! | This software may be used, copied, or redistributed as long as it is | ! | not sold and this copyright notice is reproduced on each copy made. | ! | This model is provided as is without any express or implied warranties. | ! | (http://www.rtweb.aer.com/) | ! | | ! -------------------------------------------------------------------------- ! ------- Modules ------- use parkind, only : im => kind_im, rb => kind_rb use rrsw_wvn use rrtmg_sw_setcoef, only: swatmref implicit none contains ! ************************************************************************** subroutine rrtmg_sw_ini(cpdair) ! ************************************************************************** ! ! Original version: Michael J. Iacono; February, 2004 ! Revision for F90 formatting: M. J. Iacono, July, 2006 ! ! This subroutine performs calculations necessary for the initialization ! of the shortwave model. Lookup tables are computed for use in the SW ! radiative transfer, and input absorption coefficient data for each ! spectral band are reduced from 224 g-point intervals to 112. ! ************************************************************************** use parrrsw, only : mg, nbndsw, ngptsw use rrsw_tbl, only: ntbl, tblint, pade, bpade, tau_tbl, exp_tbl use rrsw_vsn, only: hvrini, hnamini real(kind=rb), intent(in) :: cpdair ! Specific heat capacity of dry air ! at constant pressure at 273 K ! (J kg-1 K-1) ! ------- Local ------- integer(kind=im) :: ibnd, igc, ig, ind, ipr integer(kind=im) :: igcsm, iprsm integer(kind=im) :: itr real(kind=rb) :: wtsum, wtsm(mg) real(kind=rb) :: tfn real(kind=rb), parameter :: expeps = 1.e-20 ! Smallest value for exponential table ! ------- Definitions ------- ! Arrays for 10000-point look-up tables: ! TAU_TBL Clear-sky optical depth ! EXP_TBL Exponential lookup table for transmittance ! PADE Pade approximation constant (= 0.278) ! BPADE Inverse of the Pade approximation constant ! hvrini = '$Revision: 1.3 $' ! Initialize model data call swdatinit(cpdair) call swcmbdat ! g-point interval reduction data call swaerpr ! aerosol optical properties call swcldpr ! cloud optical properties call swatmref ! reference MLS profile ! Moved to module_ra_rrtmg_sw for WRF ! call sw_kgb16 ! molecular absorption coefficients ! call sw_kgb17 ! call sw_kgb18 ! call sw_kgb19 ! call sw_kgb20 ! call sw_kgb21 ! call sw_kgb22 ! call sw_kgb23 ! call sw_kgb24 ! call sw_kgb25 ! call sw_kgb26 ! call sw_kgb27 ! call sw_kgb28 ! call sw_kgb29 ! Define exponential lookup tables for transmittance. Tau is ! computed as a function of the tau transition function, and transmittance ! is calculated as a function of tau. All tables are computed at intervals ! of 0.0001. The inverse of the constant used in the Pade approximation to ! the tau transition function is set to bpade. exp_tbl(0) = 1.0_rb exp_tbl(ntbl) = expeps bpade = 1.0_rb / pade do itr = 1, ntbl-1 tfn = float(itr) / float(ntbl) tau_tbl = bpade * tfn / (1._rb - tfn) exp_tbl(itr) = exp(-tau_tbl) if (exp_tbl(itr) .le. expeps) exp_tbl(itr) = expeps enddo ! Perform g-point reduction from 16 per band (224 total points) to ! a band dependent number (112 total points) for all absorption ! coefficient input data and Planck fraction input data. ! Compute relative weighting for new g-point combinations. igcsm = 0 do ibnd = 1,nbndsw iprsm = 0 if (ngc(ibnd).lt.mg) then do igc = 1,ngc(ibnd) igcsm = igcsm + 1 wtsum = 0. do ipr = 1, ngn(igcsm) iprsm = iprsm + 1 wtsum = wtsum + wt(iprsm) enddo wtsm(igc) = wtsum enddo do ig = 1, ng(ibnd+15) ind = (ibnd-1)*mg + ig rwgt(ind) = wt(ig)/wtsm(ngm(ind)) enddo else do ig = 1, ng(ibnd+15) igcsm = igcsm + 1 ind = (ibnd-1)*mg + ig rwgt(ind) = 1.0_rb enddo endif enddo ! Reduce g-points for absorption coefficient data in each LW spectral band. call cmbgb16s call cmbgb17 call cmbgb18 call cmbgb19 call cmbgb20 call cmbgb21 call cmbgb22 call cmbgb23 call cmbgb24 call cmbgb25 call cmbgb26 call cmbgb27 call cmbgb28 call cmbgb29 end subroutine rrtmg_sw_ini !*************************************************************************** subroutine swdatinit(cpdair) !*************************************************************************** ! --------- Modules ---------- use rrsw_con, only: heatfac, grav, planck, boltz, & clight, avogad, alosmt, gascon, radcn1, radcn2, & sbcnst, secdy use rrsw_vsn save real(kind=rb), intent(in) :: cpdair ! Specific heat capacity of dry air ! at constant pressure at 273 K ! (J kg-1 K-1) ! Shortwave spectral band limits (wavenumbers) wavenum1(:) = (/2600._rb, 3250._rb, 4000._rb, 4650._rb, 5150._rb, 6150._rb, 7700._rb, & 8050._rb,12850._rb,16000._rb,22650._rb,29000._rb,38000._rb, 820._rb/) wavenum2(:) = (/3250._rb, 4000._rb, 4650._rb, 5150._rb, 6150._rb, 7700._rb, 8050._rb, & 12850._rb,16000._rb,22650._rb,29000._rb,38000._rb,50000._rb, 2600._rb/) delwave(:) = (/ 650._rb, 750._rb, 650._rb, 500._rb, 1000._rb, 1550._rb, 350._rb, & 4800._rb, 3150._rb, 6650._rb, 6350._rb, 9000._rb,12000._rb, 1780._rb/) ! Spectral band information ng(:) = (/16,16,16,16,16,16,16,16,16,16,16,16,16,16/) nspa(:) = (/9,9,9,9,1,9,9,1,9,1,0,1,9,1/) nspb(:) = (/1,5,1,1,1,5,1,0,1,0,0,1,5,1/) ! Fundamental physical constants from NIST 2002 grav = 9.8066_rb ! Acceleration of gravity ! (m s-2) planck = 6.62606876e-27_rb ! Planck constant ! (ergs s; g cm2 s-1) boltz = 1.3806503e-16_rb ! Boltzmann constant ! (ergs K-1; g cm2 s-2 K-1) clight = 2.99792458e+10_rb ! Speed of light in a vacuum ! (cm s-1) avogad = 6.02214199e+23_rb ! Avogadro constant ! (mol-1) alosmt = 2.6867775e+19_rb ! Loschmidt constant ! (cm-3) gascon = 8.31447200e+07_rb ! Molar gas constant ! (ergs mol-1 K-1) radcn1 = 1.191042772e-12_rb ! First radiation constant ! (W cm2 sr-1) radcn2 = 1.4387752_rb ! Second radiation constant ! (cm K) sbcnst = 5.670400e-04_rb ! Stefan-Boltzmann constant ! (W cm-2 K-4) secdy = 8.6400e4_rb ! Number of seconds per day ! (s d-1) ! ! units are generally cgs ! ! The first and second radiation constants are taken from NIST. ! They were previously obtained from the relations: ! radcn1 = 2.*planck*clight*clight*1.e-07 ! radcn2 = planck*clight/boltz ! Heatfac is the factor by which delta-flux / delta-pressure is ! multiplied, with flux in W/m-2 and pressure in mbar, to get ! the heating rate in units of degrees/day. It is equal to: ! Original value: ! (g)x(#sec/day)x(1e-5)/(specific heat of air at const. p) ! Here, cpdair (1.004) is in units of J g-1 K-1, and the ! constant (1.e-5) converts mb to Pa and g-1 to kg-1. ! = (9.8066)(86400)(1e-5)/(1.004) ! heatfac = 8.4391_rb ! ! Modified value for consistency with CAM3: ! (g)x(#sec/day)x(1e-5)/(specific heat of air at const. p) ! Here, cpdair (1.00464) is in units of J g-1 K-1, and the ! constant (1.e-5) converts mb to Pa and g-1 to kg-1. ! = (9.80616)(86400)(1e-5)/(1.00464) ! heatfac = 8.43339130434_rb ! ! Calculated value (from constants above and input cpdair) ! (grav) x (#sec/day) / (specific heat of dry air at const. p x 1.e2) ! Here, cpdair is in units of J kg-1 K-1, and the constant (1.e2) ! converts mb to Pa when heatfac is multiplied by W m-2 mb-1. heatfac = grav * secdy / (cpdair * 1.e2_rb) end subroutine swdatinit !*************************************************************************** subroutine swcmbdat !*************************************************************************** save ! ------- Definitions ------- ! Arrays for the g-point reduction from 224 to 112 for the 16 LW bands: ! This mapping from 224 to 112 points has been carefully selected to ! minimize the effect on the resulting fluxes and cooling rates, and ! caution should be used if the mapping is modified. The full 224 ! g-point set can be restored with ngpt=224, ngc=16*16, ngn=224*1., etc. ! ngpt The total number of new g-points ! ngc The number of new g-points in each band ! ngs The cumulative sum of new g-points for each band ! ngm The index of each new g-point relative to the original ! 16 g-points for each band. ! ngn The number of original g-points that are combined to make ! each new g-point in each band. ! ngb The band index for each new g-point. ! wt RRTM weights for 16 g-points. ! Use this set for 112 quadrature point (g-point) model ! ------- Data statements ------- ngc(:) = (/ 6,12, 8, 8,10,10, 2,10, 8, 6, 6, 8, 6,12 /) ngs(:) = (/ 6,18,26,34,44,54,56,66,74,80,86,94,100,112 /) ngm(:) = (/ 1,1,2,2,3,3,4,4,5,5,5,5,6,6,6,6, & ! band 16 1,2,3,4,5,6,6,7,8,8,9,10,10,11,12,12, & ! band 17 1,2,3,4,5,5,6,6,7,7,7,7,8,8,8,8, & ! band 18 1,2,3,4,5,5,6,6,7,7,7,7,8,8,8,8, & ! band 19 1,2,3,4,5,6,7,8,9,9,10,10,10,10,10,10, & ! band 20 1,2,3,4,5,6,7,8,9,9,10,10,10,10,10,10, & ! band 21 1,1,1,1,1,1,1,1,2,2,2,2,2,2,2,2, & ! band 22 1,1,2,2,3,4,5,6,7,8,9,9,10,10,10,10, & ! band 23 1,1,2,2,3,3,4,4,5,5,6,6,7,7,8,8, & ! band 24 1,2,3,3,4,4,5,5,5,5,6,6,6,6,6,6, & ! band 25 1,2,3,3,4,4,5,5,5,5,6,6,6,6,6,6, & ! band 26 1,2,3,4,5,6,7,7,7,7,8,8,8,8,8,8, & ! band 27 1,2,3,3,4,4,5,5,5,5,6,6,6,6,6,6, & ! band 28 1,2,3,4,5,5,6,6,7,7,8,8,9,10,11,12 /) ! band 29 ngn(:) = (/ 2,2,2,2,4,4, & ! band 16 1,1,1,1,1,2,1,2,1,2,1,2, & ! band 17 1,1,1,1,2,2,4,4, & ! band 18 1,1,1,1,2,2,4,4, & ! band 19 1,1,1,1,1,1,1,1,2,6, & ! band 20 1,1,1,1,1,1,1,1,2,6, & ! band 21 8,8, & ! band 22 2,2,1,1,1,1,1,1,2,4, & ! band 23 2,2,2,2,2,2,2,2, & ! band 24 1,1,2,2,4,6, & ! band 25 1,1,2,2,4,6, & ! band 26 1,1,1,1,1,1,4,6, & ! band 27 1,1,2,2,4,6, & ! band 28 1,1,1,1,2,2,2,2,1,1,1,1 /) ! band 29 ngb(:) = (/ 16,16,16,16,16,16, & ! band 16 17,17,17,17,17,17,17,17,17,17,17,17, & ! band 17 18,18,18,18,18,18,18,18, & ! band 18 19,19,19,19,19,19,19,19, & ! band 19 20,20,20,20,20,20,20,20,20,20, & ! band 20 21,21,21,21,21,21,21,21,21,21, & ! band 21 22,22, & ! band 22 23,23,23,23,23,23,23,23,23,23, & ! band 23 24,24,24,24,24,24,24,24, & ! band 24 25,25,25,25,25,25, & ! band 25 26,26,26,26,26,26, & ! band 26 27,27,27,27,27,27,27,27, & ! band 27 28,28,28,28,28,28, & ! band 28 29,29,29,29,29,29,29,29,29,29,29,29 /) ! band 29 ! Use this set for full 224 quadrature point (g-point) model ! ------- Data statements ------- ! ngc(:) = (/ 16,16,16,16,16,16,16,16,16,16,16,16,16,16 /) ! ngs(:) = (/ 16,32,48,64,80,96,112,128,144,160,176,192,208,224 /) ! ngm(:) = (/ 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 16 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 17 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 18 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 19 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 20 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 21 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 22 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 23 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 24 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 25 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 26 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 27 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! band 28 ! 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16 /) ! band 29 ! ngn(:) = (/ 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 16 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 17 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 18 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 19 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 20 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 21 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 22 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 23 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 24 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 25 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 26 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 27 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, & ! band 28 ! 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1 /) ! band 29 ! ngb(:) = (/ 16,16,16,16,16,16,16,16,16,16,16,16,16,16,16,16, & ! band 16 ! 17,17,17,17,17,17,17,17,17,17,17,17,17,17,17,17, & ! band 17 ! 18,18,18,18,18,18,18,18,18,18,18,18,18,18,18,18, & ! band 18 ! 19,19,19,19,19,19,19,19,19,19,19,19,19,19,19,19, & ! band 19 ! 20,20,20,20,20,20,20,20,20,20,20,20,20,20,20,20, & ! band 20 ! 21,21,21,21,21,21,21,21,21,21,21,21,21,21,21,21, & ! band 21 ! 22,22,22,22,22,22,22,22,22,22,22,22,22,22,22,22, & ! band 22 ! 23,23,23,23,23,23,23,23,23,23,23,23,23,23,23,23, & ! band 23 ! 24,24,24,24,24,24,24,24,24,24,24,24,24,24,24,24, & ! band 24 ! 25,25,25,25,25,25,25,25,25,25,25,25,25,25,25,25, & ! band 25 ! 26,26,26,26,26,26,26,26,26,26,26,26,26,26,26,26, & ! band 26 ! 27,27,27,27,27,27,27,27,27,27,27,27,27,27,27,27, & ! band 27 ! 28,28,28,28,28,28,28,28,28,28,28,28,28,28,28,28, & ! band 28 ! 29,29,29,29,29,29,29,29,29,29,29,29,29,29,29,29 /) ! band 29 wt(:) = (/ 0.1527534276_rb, 0.1491729617_rb, 0.1420961469_rb, & 0.1316886544_rb, 0.1181945205_rb, 0.1019300893_rb, & 0.0832767040_rb, 0.0626720116_rb, 0.0424925000_rb, & 0.0046269894_rb, 0.0038279891_rb, 0.0030260086_rb, & 0.0022199750_rb, 0.0014140010_rb, 0.0005330000_rb, & 0.0000750000_rb /) end subroutine swcmbdat !*************************************************************************** subroutine swaerpr !*************************************************************************** ! Purpose: Define spectral aerosol properties for six ECMWF aerosol types ! as used in the ECMWF IFS model (see module rrsw_aer.F90 for details) ! ! Original: Defined for rrtmg_sw 14 spectral bands, JJMorcrette, ECMWF Feb 2003 ! Revision: Reformatted for consistency with rrtmg_lw, MJIacono, AER, Jul 2006 use rrsw_aer, only : rsrtaua, rsrpiza, rsrasya save rsrtaua( 1, :) = (/ & 0.10849_rb, 0.66699_rb, 0.65255_rb, 0.11600_rb, 0.06529_rb, 0.04468_rb/) rsrtaua( 2, :) = (/ & 0.10849_rb, 0.66699_rb, 0.65255_rb, 0.11600_rb, 0.06529_rb, 0.04468_rb/) rsrtaua( 3, :) = (/ & 0.20543_rb, 0.84642_rb, 0.84958_rb, 0.21673_rb, 0.28270_rb, 0.10915_rb/) rsrtaua( 4, :) = (/ & 0.20543_rb, 0.84642_rb, 0.84958_rb, 0.21673_rb, 0.28270_rb, 0.10915_rb/) rsrtaua( 5, :) = (/ & 0.20543_rb, 0.84642_rb, 0.84958_rb, 0.21673_rb, 0.28270_rb, 0.10915_rb/) rsrtaua( 6, :) = (/ & 0.20543_rb, 0.84642_rb, 0.84958_rb, 0.21673_rb, 0.28270_rb, 0.10915_rb/) rsrtaua( 7, :) = (/ & 0.20543_rb, 0.84642_rb, 0.84958_rb, 0.21673_rb, 0.28270_rb, 0.10915_rb/) rsrtaua( 8, :) = (/ & 0.52838_rb, 0.93285_rb, 0.93449_rb, 0.53078_rb, 0.67148_rb, 0.46608_rb/) rsrtaua( 9, :) = (/ & 0.52838_rb, 0.93285_rb, 0.93449_rb, 0.53078_rb, 0.67148_rb, 0.46608_rb/) rsrtaua(10, :) = (/ & 1.69446_rb, 1.11855_rb, 1.09212_rb, 1.72145_rb, 1.03858_rb, 1.12044_rb/) rsrtaua(11, :) = (/ & 1.69446_rb, 1.11855_rb, 1.09212_rb, 1.72145_rb, 1.03858_rb, 1.12044_rb/) rsrtaua(12, :) = (/ & 1.69446_rb, 1.11855_rb, 1.09212_rb, 1.72145_rb, 1.03858_rb, 1.12044_rb/) rsrtaua(13, :) = (/ & 1.69446_rb, 1.11855_rb, 1.09212_rb, 1.72145_rb, 1.03858_rb, 1.12044_rb/) rsrtaua(14, :) = (/ & 0.10849_rb, 0.66699_rb, 0.65255_rb, 0.11600_rb, 0.06529_rb, 0.04468_rb/) rsrpiza( 1, :) = (/ & .5230504_rb, .7868518_rb, .8531531_rb, .4048149_rb, .8748231_rb, .2355667_rb/) rsrpiza( 2, :) = (/ & .5230504_rb, .7868518_rb, .8531531_rb, .4048149_rb, .8748231_rb, .2355667_rb/) rsrpiza( 3, :) = (/ & .8287144_rb, .9949396_rb, .9279543_rb, .6765051_rb, .9467578_rb, .9955938_rb/) rsrpiza( 4, :) = (/ & .8287144_rb, .9949396_rb, .9279543_rb, .6765051_rb, .9467578_rb, .9955938_rb/) rsrpiza( 5, :) = (/ & .8287144_rb, .9949396_rb, .9279543_rb, .6765051_rb, .9467578_rb, .9955938_rb/) rsrpiza( 6, :) = (/ & .8287144_rb, .9949396_rb, .9279543_rb, .6765051_rb, .9467578_rb, .9955938_rb/) rsrpiza( 7, :) = (/ & .8287144_rb, .9949396_rb, .9279543_rb, .6765051_rb, .9467578_rb, .9955938_rb/) rsrpiza( 8, :) = (/ & .8970131_rb, .9984940_rb, .9245594_rb, .7768385_rb, .9532763_rb, .9999999_rb/) rsrpiza( 9, :) = (/ & .8970131_rb, .9984940_rb, .9245594_rb, .7768385_rb, .9532763_rb, .9999999_rb/) rsrpiza(10, :) = (/ & .9148907_rb, .9956173_rb, .7504584_rb, .8131335_rb, .9401905_rb, .9999999_rb/) rsrpiza(11, :) = (/ & .9148907_rb, .9956173_rb, .7504584_rb, .8131335_rb, .9401905_rb, .9999999_rb/) rsrpiza(12, :) = (/ & .9148907_rb, .9956173_rb, .7504584_rb, .8131335_rb, .9401905_rb, .9999999_rb/) rsrpiza(13, :) = (/ & .9148907_rb, .9956173_rb, .7504584_rb, .8131335_rb, .9401905_rb, .9999999_rb/) rsrpiza(14, :) = (/ & .5230504_rb, .7868518_rb, .8531531_rb, .4048149_rb, .8748231_rb, .2355667_rb/) rsrasya( 1, :) = (/ & 0.700610_rb, 0.818871_rb, 0.702399_rb, 0.689886_rb, .4629866_rb, .1907639_rb/) rsrasya( 2, :) = (/ & 0.700610_rb, 0.818871_rb, 0.702399_rb, 0.689886_rb, .4629866_rb, .1907639_rb/) rsrasya( 3, :) = (/ & 0.636342_rb, 0.802467_rb, 0.691305_rb, 0.627497_rb, .6105750_rb, .4760794_rb/) rsrasya( 4, :) = (/ & 0.636342_rb, 0.802467_rb, 0.691305_rb, 0.627497_rb, .6105750_rb, .4760794_rb/) rsrasya( 5, :) = (/ & 0.636342_rb, 0.802467_rb, 0.691305_rb, 0.627497_rb, .6105750_rb, .4760794_rb/) rsrasya( 6, :) = (/ & 0.636342_rb, 0.802467_rb, 0.691305_rb, 0.627497_rb, .6105750_rb, .4760794_rb/) rsrasya( 7, :) = (/ & 0.636342_rb, 0.802467_rb, 0.691305_rb, 0.627497_rb, .6105750_rb, .4760794_rb/) rsrasya( 8, :) = (/ & 0.668431_rb, 0.788530_rb, 0.698682_rb, 0.657422_rb, .6735182_rb, .6519706_rb/) rsrasya( 9, :) = (/ & 0.668431_rb, 0.788530_rb, 0.698682_rb, 0.657422_rb, .6735182_rb, .6519706_rb/) rsrasya(10, :) = (/ & 0.729019_rb, 0.803129_rb, 0.784592_rb, 0.712208_rb, .7008249_rb, .7270548_rb/) rsrasya(11, :) = (/ & 0.729019_rb, 0.803129_rb, 0.784592_rb, 0.712208_rb, .7008249_rb, .7270548_rb/) rsrasya(12, :) = (/ & 0.729019_rb, 0.803129_rb, 0.784592_rb, 0.712208_rb, .7008249_rb, .7270548_rb/) rsrasya(13, :) = (/ & 0.729019_rb, 0.803129_rb, 0.784592_rb, 0.712208_rb, .7008249_rb, .7270548_rb/) rsrasya(14, :) = (/ & 0.700610_rb, 0.818871_rb, 0.702399_rb, 0.689886_rb, .4629866_rb, .1907639_rb/) end subroutine swaerpr !*************************************************************************** subroutine cmbgb16s !*************************************************************************** ! ! Original version: MJIacono; July 1998 ! Revision for RRTM_SW: MJIacono; November 2002 ! Revision for RRTMG_SW: MJIacono; December 2003 ! Revision for F90 reformatting: MJIacono; July 2006 ! ! The subroutines CMBGB16->CMBGB29 input the absorption coefficient ! data for each band, which are defined for 16 g-points and 14 spectral ! bands. The data are combined with appropriate weighting following the ! g-point mapping arrays specified in RRTMG_SW_INIT. Solar source ! function data in array SFLUXREF are combined without weighting. All ! g-point reduced data are put into new arrays for use in RRTMG_SW. ! ! band 16: 2600-3250 cm-1 (low key- h2o,ch4; high key - ch4) ! !----------------------------------------------------------------------- use rrsw_kg16, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & absa, ka, absb, kb, selfref, forref, sfluxref ! ------- Local ------- integer(kind=im) :: jn, jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf do jn = 1,9 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(1) sumk = 0. do ipr = 1, ngn(igc) iprsm = iprsm + 1 sumk = sumk + kao(jn,jt,jp,iprsm)*rwgt(iprsm) enddo ka(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jt = 1,5 do jp = 13,59 iprsm = 0 do igc = 1,ngc(1) sumk = 0. do ipr = 1, ngn(igc) iprsm = iprsm + 1 sumk = sumk + kbo(jt,jp,iprsm)*rwgt(iprsm) enddo kb(jt,jp,igc) = sumk enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(1) sumk = 0. do ipr = 1, ngn(igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,3 iprsm = 0 do igc = 1,ngc(1) sumk = 0. do ipr = 1, ngn(igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm) enddo forref(jt,igc) = sumk enddo enddo iprsm = 0 do igc = 1,ngc(1) sumf = 0. do ipr = 1, ngn(igc) iprsm = iprsm + 1 sumf = sumf + sfluxrefo(iprsm) enddo sfluxref(igc) = sumf enddo end subroutine cmbgb16s !*************************************************************************** subroutine cmbgb17 !*************************************************************************** ! ! band 17: 3250-4000 cm-1 (low - h2o,co2; high - h2o,co2) !----------------------------------------------------------------------- use rrsw_kg17, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & absa, ka, absb, kb, selfref, forref, sfluxref ! ------- Local ------- integer(kind=im) :: jn, jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf do jn = 1,9 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(2) sumk = 0. do ipr = 1, ngn(ngs(1)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jn,jt,jp,iprsm)*rwgt(iprsm+16) enddo ka(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jn = 1,5 do jt = 1,5 do jp = 13,59 iprsm = 0 do igc = 1,ngc(2) sumk = 0. do ipr = 1, ngn(ngs(1)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jn,jt,jp,iprsm)*rwgt(iprsm+16) enddo kb(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(2) sumk = 0. do ipr = 1, ngn(ngs(1)+igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm+16) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,4 iprsm = 0 do igc = 1,ngc(2) sumk = 0. do ipr = 1, ngn(ngs(1)+igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm+16) enddo forref(jt,igc) = sumk enddo enddo do jp = 1,5 iprsm = 0 do igc = 1,ngc(2) sumf = 0. do ipr = 1, ngn(ngs(1)+igc) iprsm = iprsm + 1 sumf = sumf + sfluxrefo(iprsm,jp) enddo sfluxref(igc,jp) = sumf enddo enddo end subroutine cmbgb17 !*************************************************************************** subroutine cmbgb18 !*************************************************************************** ! ! band 18: 4000-4650 cm-1 (low - h2o,ch4; high - ch4) !----------------------------------------------------------------------- use rrsw_kg18, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & absa, ka, absb, kb, selfref, forref, sfluxref ! ------- Local ------- integer(kind=im) :: jn, jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf do jn = 1,9 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(3) sumk = 0. do ipr = 1, ngn(ngs(2)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jn,jt,jp,iprsm)*rwgt(iprsm+32) enddo ka(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jt = 1,5 do jp = 13,59 iprsm = 0 do igc = 1,ngc(3) sumk = 0. do ipr = 1, ngn(ngs(2)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jt,jp,iprsm)*rwgt(iprsm+32) enddo kb(jt,jp,igc) = sumk enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(3) sumk = 0. do ipr = 1, ngn(ngs(2)+igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm+32) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,3 iprsm = 0 do igc = 1,ngc(3) sumk = 0. do ipr = 1, ngn(ngs(2)+igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm+32) enddo forref(jt,igc) = sumk enddo enddo do jp = 1,9 iprsm = 0 do igc = 1,ngc(3) sumf = 0. do ipr = 1, ngn(ngs(2)+igc) iprsm = iprsm + 1 sumf = sumf + sfluxrefo(iprsm,jp) enddo sfluxref(igc,jp) = sumf enddo enddo end subroutine cmbgb18 !*************************************************************************** subroutine cmbgb19 !*************************************************************************** ! ! band 19: 4650-5150 cm-1 (low - h2o,co2; high - co2) !----------------------------------------------------------------------- use rrsw_kg19, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & absa, ka, absb, kb, selfref, forref, sfluxref ! ------- Local ------- integer(kind=im) :: jn, jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf do jn = 1,9 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(4) sumk = 0. do ipr = 1, ngn(ngs(3)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jn,jt,jp,iprsm)*rwgt(iprsm+48) enddo ka(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jt = 1,5 do jp = 13,59 iprsm = 0 do igc = 1,ngc(4) sumk = 0. do ipr = 1, ngn(ngs(3)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jt,jp,iprsm)*rwgt(iprsm+48) enddo kb(jt,jp,igc) = sumk enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(4) sumk = 0. do ipr = 1, ngn(ngs(3)+igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm+48) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,3 iprsm = 0 do igc = 1,ngc(4) sumk = 0. do ipr = 1, ngn(ngs(3)+igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm+48) enddo forref(jt,igc) = sumk enddo enddo do jp = 1,9 iprsm = 0 do igc = 1,ngc(4) sumf = 0. do ipr = 1, ngn(ngs(3)+igc) iprsm = iprsm + 1 sumf = sumf + sfluxrefo(iprsm,jp) enddo sfluxref(igc,jp) = sumf enddo enddo end subroutine cmbgb19 !*************************************************************************** subroutine cmbgb20 !*************************************************************************** ! ! band 20: 5150-6150 cm-1 (low - h2o; high - h2o) !----------------------------------------------------------------------- use rrsw_kg20, only : kao, kbo, selfrefo, forrefo, sfluxrefo, absch4o, & absa, ka, absb, kb, selfref, forref, sfluxref, absch4 ! ------- Local ------- integer(kind=im) :: jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf1, sumf2 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(5) sumk = 0. do ipr = 1, ngn(ngs(4)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jt,jp,iprsm)*rwgt(iprsm+64) enddo ka(jt,jp,igc) = sumk enddo enddo do jp = 13,59 iprsm = 0 do igc = 1,ngc(5) sumk = 0. do ipr = 1, ngn(ngs(4)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jt,jp,iprsm)*rwgt(iprsm+64) enddo kb(jt,jp,igc) = sumk enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(5) sumk = 0. do ipr = 1, ngn(ngs(4)+igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm+64) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,4 iprsm = 0 do igc = 1,ngc(5) sumk = 0. do ipr = 1, ngn(ngs(4)+igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm+64) enddo forref(jt,igc) = sumk enddo enddo iprsm = 0 do igc = 1,ngc(5) sumf1 = 0. sumf2 = 0. do ipr = 1, ngn(ngs(4)+igc) iprsm = iprsm + 1 sumf1 = sumf1 + sfluxrefo(iprsm) sumf2 = sumf2 + absch4o(iprsm)*rwgt(iprsm+64) enddo sfluxref(igc) = sumf1 absch4(igc) = sumf2 enddo end subroutine cmbgb20 !*************************************************************************** subroutine cmbgb21 !*************************************************************************** ! ! band 21: 6150-7700 cm-1 (low - h2o,co2; high - h2o,co2) !----------------------------------------------------------------------- use rrsw_kg21, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & absa, ka, absb, kb, selfref, forref, sfluxref ! ------- Local ------- integer(kind=im) :: jn, jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf do jn = 1,9 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(6) sumk = 0. do ipr = 1, ngn(ngs(5)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jn,jt,jp,iprsm)*rwgt(iprsm+80) enddo ka(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jn = 1,5 do jt = 1,5 do jp = 13,59 iprsm = 0 do igc = 1,ngc(6) sumk = 0. do ipr = 1, ngn(ngs(5)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jn,jt,jp,iprsm)*rwgt(iprsm+80) enddo kb(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(6) sumk = 0. do ipr = 1, ngn(ngs(5)+igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm+80) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,4 iprsm = 0 do igc = 1,ngc(6) sumk = 0. do ipr = 1, ngn(ngs(5)+igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm+80) enddo forref(jt,igc) = sumk enddo enddo do jp = 1,9 iprsm = 0 do igc = 1,ngc(6) sumf = 0. do ipr = 1, ngn(ngs(5)+igc) iprsm = iprsm + 1 sumf = sumf + sfluxrefo(iprsm,jp) enddo sfluxref(igc,jp) = sumf enddo enddo end subroutine cmbgb21 !*************************************************************************** subroutine cmbgb22 !*************************************************************************** ! ! band 22: 7700-8050 cm-1 (low - h2o,o2; high - o2) !----------------------------------------------------------------------- use rrsw_kg22, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & absa, ka, absb, kb, selfref, forref, sfluxref ! ------- Local ------- integer(kind=im) :: jn, jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf do jn = 1,9 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(7) sumk = 0. do ipr = 1, ngn(ngs(6)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jn,jt,jp,iprsm)*rwgt(iprsm+96) enddo ka(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jt = 1,5 do jp = 13,59 iprsm = 0 do igc = 1,ngc(7) sumk = 0. do ipr = 1, ngn(ngs(6)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jt,jp,iprsm)*rwgt(iprsm+96) enddo kb(jt,jp,igc) = sumk enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(7) sumk = 0. do ipr = 1, ngn(ngs(6)+igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm+96) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,3 iprsm = 0 do igc = 1,ngc(7) sumk = 0. do ipr = 1, ngn(ngs(6)+igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm+96) enddo forref(jt,igc) = sumk enddo enddo do jp = 1,9 iprsm = 0 do igc = 1,ngc(7) sumf = 0. do ipr = 1, ngn(ngs(6)+igc) iprsm = iprsm + 1 sumf = sumf + sfluxrefo(iprsm,jp) enddo sfluxref(igc,jp) = sumf enddo enddo end subroutine cmbgb22 !*************************************************************************** subroutine cmbgb23 !*************************************************************************** ! ! band 23: 8050-12850 cm-1 (low - h2o; high - nothing) !----------------------------------------------------------------------- use rrsw_kg23, only : kao, selfrefo, forrefo, sfluxrefo, raylo, & absa, ka, selfref, forref, sfluxref, rayl ! ------- Local ------- integer(kind=im) :: jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf1, sumf2 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(8) sumk = 0. do ipr = 1, ngn(ngs(7)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jt,jp,iprsm)*rwgt(iprsm+112) enddo ka(jt,jp,igc) = sumk enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(8) sumk = 0. do ipr = 1, ngn(ngs(7)+igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm+112) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,3 iprsm = 0 do igc = 1,ngc(8) sumk = 0. do ipr = 1, ngn(ngs(7)+igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm+112) enddo forref(jt,igc) = sumk enddo enddo iprsm = 0 do igc = 1,ngc(8) sumf1 = 0. sumf2 = 0. do ipr = 1, ngn(ngs(7)+igc) iprsm = iprsm + 1 sumf1 = sumf1 + sfluxrefo(iprsm) sumf2 = sumf2 + raylo(iprsm)*rwgt(iprsm+112) enddo sfluxref(igc) = sumf1 rayl(igc) = sumf2 enddo end subroutine cmbgb23 !*************************************************************************** subroutine cmbgb24 !*************************************************************************** ! ! band 24: 12850-16000 cm-1 (low - h2o,o2; high - o2) !----------------------------------------------------------------------- use rrsw_kg24, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & abso3ao, abso3bo, raylao, raylbo, & absa, ka, absb, kb, selfref, forref, sfluxref, & abso3a, abso3b, rayla, raylb ! ------- Local ------- integer(kind=im) :: jn, jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf1, sumf2, sumf3 do jn = 1,9 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(9) sumk = 0. do ipr = 1, ngn(ngs(8)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jn,jt,jp,iprsm)*rwgt(iprsm+128) enddo ka(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jt = 1,5 do jp = 13,59 iprsm = 0 do igc = 1,ngc(9) sumk = 0. do ipr = 1, ngn(ngs(8)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jt,jp,iprsm)*rwgt(iprsm+128) enddo kb(jt,jp,igc) = sumk enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(9) sumk = 0. do ipr = 1, ngn(ngs(8)+igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm+128) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,3 iprsm = 0 do igc = 1,ngc(9) sumk = 0. do ipr = 1, ngn(ngs(8)+igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm+128) enddo forref(jt,igc) = sumk enddo enddo iprsm = 0 do igc = 1,ngc(9) sumf1 = 0. sumf2 = 0. sumf3 = 0. do ipr = 1, ngn(ngs(8)+igc) iprsm = iprsm + 1 sumf1 = sumf1 + raylbo(iprsm)*rwgt(iprsm+128) sumf2 = sumf2 + abso3ao(iprsm)*rwgt(iprsm+128) sumf3 = sumf3 + abso3bo(iprsm)*rwgt(iprsm+128) enddo raylb(igc) = sumf1 abso3a(igc) = sumf2 abso3b(igc) = sumf3 enddo do jp = 1,9 iprsm = 0 do igc = 1,ngc(9) sumf1 = 0. sumf2 = 0. do ipr = 1, ngn(ngs(8)+igc) iprsm = iprsm + 1 sumf1 = sumf1 + sfluxrefo(iprsm,jp) sumf2 = sumf2 + raylao(iprsm,jp)*rwgt(iprsm+128) enddo sfluxref(igc,jp) = sumf1 rayla(igc,jp) = sumf2 enddo enddo end subroutine cmbgb24 !*************************************************************************** subroutine cmbgb25 !*************************************************************************** ! ! band 25: 16000-22650 cm-1 (low - h2o; high - nothing) !----------------------------------------------------------------------- use rrsw_kg25, only : kao, sfluxrefo, & abso3ao, abso3bo, raylo, & absa, ka, sfluxref, & abso3a, abso3b, rayl ! ------- Local ------- integer(kind=im) :: jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf1, sumf2, sumf3, sumf4 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(10) sumk = 0. do ipr = 1, ngn(ngs(9)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jt,jp,iprsm)*rwgt(iprsm+144) enddo ka(jt,jp,igc) = sumk enddo enddo enddo iprsm = 0 do igc = 1,ngc(10) sumf1 = 0. sumf2 = 0. sumf3 = 0. sumf4 = 0. do ipr = 1, ngn(ngs(9)+igc) iprsm = iprsm + 1 sumf1 = sumf1 + sfluxrefo(iprsm) sumf2 = sumf2 + abso3ao(iprsm)*rwgt(iprsm+144) sumf3 = sumf3 + abso3bo(iprsm)*rwgt(iprsm+144) sumf4 = sumf4 + raylo(iprsm)*rwgt(iprsm+144) enddo sfluxref(igc) = sumf1 abso3a(igc) = sumf2 abso3b(igc) = sumf3 rayl(igc) = sumf4 enddo end subroutine cmbgb25 !*************************************************************************** subroutine cmbgb26 !*************************************************************************** ! ! band 26: 22650-29000 cm-1 (low - nothing; high - nothing) !----------------------------------------------------------------------- use rrsw_kg26, only : sfluxrefo, raylo, & sfluxref, rayl ! ------- Local ------- integer(kind=im) :: igc, ipr, iprsm real(kind=rb) :: sumf1, sumf2 iprsm = 0 do igc = 1,ngc(11) sumf1 = 0. sumf2 = 0. do ipr = 1, ngn(ngs(10)+igc) iprsm = iprsm + 1 sumf1 = sumf1 + raylo(iprsm)*rwgt(iprsm+160) sumf2 = sumf2 + sfluxrefo(iprsm) enddo rayl(igc) = sumf1 sfluxref(igc) = sumf2 enddo end subroutine cmbgb26 !*************************************************************************** subroutine cmbgb27 !*************************************************************************** ! ! band 27: 29000-38000 cm-1 (low - o3; high - o3) !----------------------------------------------------------------------- use rrsw_kg27, only : kao, kbo, sfluxrefo, raylo, & absa, ka, absb, kb, sfluxref, rayl ! ------- Local ------- integer(kind=im) :: jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf1, sumf2 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(12) sumk = 0. do ipr = 1, ngn(ngs(11)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jt,jp,iprsm)*rwgt(iprsm+176) enddo ka(jt,jp,igc) = sumk enddo enddo do jp = 13,59 iprsm = 0 do igc = 1,ngc(12) sumk = 0. do ipr = 1, ngn(ngs(11)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jt,jp,iprsm)*rwgt(iprsm+176) enddo kb(jt,jp,igc) = sumk enddo enddo enddo iprsm = 0 do igc = 1,ngc(12) sumf1 = 0. sumf2 = 0. do ipr = 1, ngn(ngs(11)+igc) iprsm = iprsm + 1 sumf1 = sumf1 + sfluxrefo(iprsm) sumf2 = sumf2 + raylo(iprsm)*rwgt(iprsm+176) enddo sfluxref(igc) = sumf1 rayl(igc) = sumf2 enddo end subroutine cmbgb27 !*************************************************************************** subroutine cmbgb28 !*************************************************************************** ! ! band 28: 38000-50000 cm-1 (low - o3,o2; high - o3,o2) !----------------------------------------------------------------------- use rrsw_kg28, only : kao, kbo, sfluxrefo, & absa, ka, absb, kb, sfluxref ! ------- Local ------- integer(kind=im) :: jn, jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf do jn = 1,9 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(13) sumk = 0. do ipr = 1, ngn(ngs(12)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jn,jt,jp,iprsm)*rwgt(iprsm+192) enddo ka(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jn = 1,5 do jt = 1,5 do jp = 13,59 iprsm = 0 do igc = 1,ngc(13) sumk = 0. do ipr = 1, ngn(ngs(12)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jn,jt,jp,iprsm)*rwgt(iprsm+192) enddo kb(jn,jt,jp,igc) = sumk enddo enddo enddo enddo do jp = 1,5 iprsm = 0 do igc = 1,ngc(13) sumf = 0. do ipr = 1, ngn(ngs(12)+igc) iprsm = iprsm + 1 sumf = sumf + sfluxrefo(iprsm,jp) enddo sfluxref(igc,jp) = sumf enddo enddo end subroutine cmbgb28 !*************************************************************************** subroutine cmbgb29 !*************************************************************************** ! ! band 29: 820-2600 cm-1 (low - h2o; high - co2) !----------------------------------------------------------------------- use rrsw_kg29, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & absh2oo, absco2o, & absa, ka, absb, kb, selfref, forref, sfluxref, & absh2o, absco2 ! ------- Local ------- integer(kind=im) :: jt, jp, igc, ipr, iprsm real(kind=rb) :: sumk, sumf1, sumf2, sumf3 do jt = 1,5 do jp = 1,13 iprsm = 0 do igc = 1,ngc(14) sumk = 0. do ipr = 1, ngn(ngs(13)+igc) iprsm = iprsm + 1 sumk = sumk + kao(jt,jp,iprsm)*rwgt(iprsm+208) enddo ka(jt,jp,igc) = sumk enddo enddo do jp = 13,59 iprsm = 0 do igc = 1,ngc(14) sumk = 0. do ipr = 1, ngn(ngs(13)+igc) iprsm = iprsm + 1 sumk = sumk + kbo(jt,jp,iprsm)*rwgt(iprsm+208) enddo kb(jt,jp,igc) = sumk enddo enddo enddo do jt = 1,10 iprsm = 0 do igc = 1,ngc(14) sumk = 0. do ipr = 1, ngn(ngs(13)+igc) iprsm = iprsm + 1 sumk = sumk + selfrefo(jt,iprsm)*rwgt(iprsm+208) enddo selfref(jt,igc) = sumk enddo enddo do jt = 1,4 iprsm = 0 do igc = 1,ngc(14) sumk = 0. do ipr = 1, ngn(ngs(13)+igc) iprsm = iprsm + 1 sumk = sumk + forrefo(jt,iprsm)*rwgt(iprsm+208) enddo forref(jt,igc) = sumk enddo enddo iprsm = 0 do igc = 1,ngc(14) sumf1 = 0. sumf2 = 0. sumf3 = 0. do ipr = 1, ngn(ngs(13)+igc) iprsm = iprsm + 1 sumf1 = sumf1 + sfluxrefo(iprsm) sumf2 = sumf2 + absco2o(iprsm)*rwgt(iprsm+208) sumf3 = sumf3 + absh2oo(iprsm)*rwgt(iprsm+208) enddo sfluxref(igc) = sumf1 absco2(igc) = sumf2 absh2o(igc) = sumf3 enddo end subroutine cmbgb29 !*********************************************************************** subroutine swcldpr !*********************************************************************** ! Purpose: Define cloud extinction coefficient, single scattering albedo ! and asymmetry parameter data. ! ! ------- Modules ------- use rrsw_cld, only : extliq1, ssaliq1, asyliq1, & extice2, ssaice2, asyice2, & extice3, ssaice3, asyice3, fdlice3, & abari, bbari, cbari, dbari, ebari, fbari save !----------------------------------------------------------------------- ! ! Explanation of the method for each value of INFLAG. A value of ! 0 for INFLAG do not distingish being liquid and ice clouds. ! INFLAG = 2 does distinguish between liquid and ice clouds, and ! requires further user input to specify the method to be used to ! compute the aborption due to each. ! INFLAG = 0: For each cloudy layer, the cloud fraction, the cloud optical ! depth, the cloud single-scattering albedo, and the ! moments of the phase function (0:NSTREAM). Note ! that these values are delta-m scaled within this ! subroutine. ! INFLAG = 2: For each cloudy layer, the cloud fraction, cloud ! water path (g/m2), and cloud ice fraction are input. ! ICEFLAG = 2: The ice effective radius (microns) is input and the ! optical properties due to ice clouds are computed from ! the optical properties stored in the RT code, STREAMER v3.0 ! (Reference: Key. J., Streamer User's Guide, Cooperative ! Institute for Meteorological Satellite Studies, 2001, 96 pp.). ! Valid range of values for re are between 5.0 and ! 131.0 micron. ! This version uses Ebert and Curry, JGR, (1992) method for ! ice particles larger than 131.0 microns. ! ICEFLAG = 3: The ice generalized effective size (dge) is input ! and the optical depths, single-scattering albedo, ! and phase function moments are calculated as in ! Q. Fu, J. Climate, (1996). Q. Fu provided high resolution ! tables which were appropriately averaged for the ! bands in RRTM_SW. Linear interpolation is used to ! get the coefficients from the stored tables. ! Valid range of values for dge are between 5.0 and ! 140.0 micron. ! This version uses Ebert and Curry, JGR, (1992) method for ! ice particles larger than 140.0 microns. ! LIQFLAG = 1: The water droplet effective radius (microns) is input ! and the optical depths due to water clouds are computed ! as in Hu and Stamnes, J., Clim., 6, 728-742, (1993). ! The values for absorption coefficients appropriate for ! the spectral bands in RRTM have been obtained for a ! range of effective radii by an averaging procedure ! based on the work of J. Pinto (private communication). ! Linear interpolation is used to get the absorption ! coefficients for the input effective radius. ! ! ------------------------------------------------------------------ ! Everything below is for INFLAG = 2. ! Coefficients for Ebert and Curry method abari(:) = (/ & & 3.448e-03_rb,3.448e-03_rb,3.448e-03_rb,3.448e-03_rb,3.448e-03_rb /) bbari(:) = (/ & & 2.431e+00_rb,2.431e+00_rb,2.431e+00_rb,2.431e+00_rb,2.431e+00_rb /) cbari(:) = (/ & & 1.000e-05_rb,1.100e-04_rb,1.240e-02_rb,3.779e-02_rb,4.666e-01_rb /) dbari(:) = (/ & & 0.000e+00_rb,1.405e-05_rb,6.867e-04_rb,1.284e-03_rb,2.050e-05_rb /) ebari(:) = (/ & & 7.661e-01_rb,7.730e-01_rb,7.865e-01_rb,8.172e-01_rb,9.595e-01_rb /) fbari(:) = (/ & & 5.851e-04_rb,5.665e-04_rb,7.204e-04_rb,7.463e-04_rb,1.076e-04_rb /) ! Extinction coefficient extliq1(:, 16) = (/ & & 8.981463e-01_rb,6.317895e-01_rb,4.557508e-01_rb,3.481624e-01_rb,2.797950e-01_rb,& & 2.342753e-01_rb,2.026934e-01_rb,1.800102e-01_rb,1.632408e-01_rb,1.505384e-01_rb,& & 1.354524e-01_rb,1.246520e-01_rb,1.154342e-01_rb,1.074756e-01_rb,1.005353e-01_rb,& & 9.442987e-02_rb,8.901760e-02_rb,8.418693e-02_rb,7.984904e-02_rb,7.593229e-02_rb,& & 7.237827e-02_rb,6.913887e-02_rb,6.617415e-02_rb,6.345061e-02_rb,6.094001e-02_rb,& & 5.861834e-02_rb,5.646506e-02_rb,5.446250e-02_rb,5.249596e-02_rb,5.081114e-02_rb,& & 4.922243e-02_rb,4.772189e-02_rb,4.630243e-02_rb,4.495766e-02_rb,4.368189e-02_rb,& & 4.246995e-02_rb,4.131720e-02_rb,4.021941e-02_rb,3.917276e-02_rb,3.817376e-02_rb,& & 3.721926e-02_rb,3.630635e-02_rb,3.543237e-02_rb,3.459491e-02_rb,3.379171e-02_rb,& & 3.302073e-02_rb,3.228007e-02_rb,3.156798e-02_rb,3.088284e-02_rb,3.022315e-02_rb,& & 2.958753e-02_rb,2.897468e-02_rb,2.838340e-02_rb,2.781258e-02_rb,2.726117e-02_rb,& & 2.672821e-02_rb,2.621278e-02_rb,2.5714e-02_rb /) extliq1(:, 17) = (/ & & 8.293797e-01_rb,6.048371e-01_rb,4.465706e-01_rb,3.460387e-01_rb,2.800064e-01_rb,& & 2.346584e-01_rb,2.022399e-01_rb,1.782626e-01_rb,1.600153e-01_rb,1.457903e-01_rb,& & 1.334061e-01_rb,1.228548e-01_rb,1.138396e-01_rb,1.060486e-01_rb,9.924856e-02_rb,& & 9.326208e-02_rb,8.795158e-02_rb,8.320883e-02_rb,7.894750e-02_rb,7.509792e-02_rb,& & 7.160323e-02_rb,6.841653e-02_rb,6.549889e-02_rb,6.281763e-02_rb,6.034516e-02_rb,& & 5.805802e-02_rb,5.593615e-02_rb,5.396226e-02_rb,5.202302e-02_rb,5.036246e-02_rb,& & 4.879606e-02_rb,4.731610e-02_rb,4.591565e-02_rb,4.458852e-02_rb,4.332912e-02_rb,& & 4.213243e-02_rb,4.099390e-02_rb,3.990941e-02_rb,3.887522e-02_rb,3.788792e-02_rb,& & 3.694440e-02_rb,3.604183e-02_rb,3.517760e-02_rb,3.434934e-02_rb,3.355485e-02_rb,& & 3.279211e-02_rb,3.205925e-02_rb,3.135458e-02_rb,3.067648e-02_rb,3.002349e-02_rb,& & 2.939425e-02_rb,2.878748e-02_rb,2.820200e-02_rb,2.763673e-02_rb,2.709062e-02_rb,& & 2.656272e-02_rb,2.605214e-02_rb,2.5558e-02_rb /) extliq1(:, 18) = (/ & & 9.193685e-01_rb,6.128292e-01_rb,4.344150e-01_rb,3.303048e-01_rb,2.659500e-01_rb,& & 2.239727e-01_rb,1.953457e-01_rb,1.751012e-01_rb,1.603515e-01_rb,1.493360e-01_rb,& & 1.323791e-01_rb,1.219335e-01_rb,1.130076e-01_rb,1.052926e-01_rb,9.855839e-02_rb,& & 9.262925e-02_rb,8.736918e-02_rb,8.267112e-02_rb,7.844965e-02_rb,7.463585e-02_rb,& & 7.117343e-02_rb,6.801601e-02_rb,6.512503e-02_rb,6.246815e-02_rb,6.001806e-02_rb,& & 5.775154e-02_rb,5.564872e-02_rb,5.369250e-02_rb,5.176284e-02_rb,5.011536e-02_rb,& & 4.856099e-02_rb,4.709211e-02_rb,4.570193e-02_rb,4.438430e-02_rb,4.313375e-02_rb,& & 4.194529e-02_rb,4.081443e-02_rb,3.973712e-02_rb,3.870966e-02_rb,3.772866e-02_rb,& & 3.679108e-02_rb,3.589409e-02_rb,3.503514e-02_rb,3.421185e-02_rb,3.342206e-02_rb,& & 3.266377e-02_rb,3.193513e-02_rb,3.123447e-02_rb,3.056018e-02_rb,2.991081e-02_rb,& & 2.928502e-02_rb,2.868154e-02_rb,2.809920e-02_rb,2.753692e-02_rb,2.699367e-02_rb,& & 2.646852e-02_rb,2.596057e-02_rb,2.5469e-02_rb /) extliq1(:, 19) = (/ & & 9.136931e-01_rb,5.743244e-01_rb,4.080708e-01_rb,3.150572e-01_rb,2.577261e-01_rb,& & 2.197900e-01_rb,1.933037e-01_rb,1.740212e-01_rb,1.595056e-01_rb,1.482756e-01_rb,& & 1.312164e-01_rb,1.209246e-01_rb,1.121227e-01_rb,1.045095e-01_rb,9.785967e-02_rb,& & 9.200149e-02_rb,8.680170e-02_rb,8.215531e-02_rb,7.797850e-02_rb,7.420361e-02_rb,& & 7.077530e-02_rb,6.764798e-02_rb,6.478369e-02_rb,6.215063e-02_rb,5.972189e-02_rb,& & 5.747458e-02_rb,5.538913e-02_rb,5.344866e-02_rb,5.153216e-02_rb,4.989745e-02_rb,& & 4.835476e-02_rb,4.689661e-02_rb,4.551629e-02_rb,4.420777e-02_rb,4.296563e-02_rb,& & 4.178497e-02_rb,4.066137e-02_rb,3.959081e-02_rb,3.856963e-02_rb,3.759452e-02_rb,& & 3.666244e-02_rb,3.577061e-02_rb,3.491650e-02_rb,3.409777e-02_rb,3.331227e-02_rb,& & 3.255803e-02_rb,3.183322e-02_rb,3.113617e-02_rb,3.046530e-02_rb,2.981918e-02_rb,& & 2.919646e-02_rb,2.859591e-02_rb,2.801635e-02_rb,2.745671e-02_rb,2.691599e-02_rb,& & 2.639324e-02_rb,2.588759e-02_rb,2.5398e-02_rb /) extliq1(:, 20) = (/ & & 8.447548e-01_rb,5.326840e-01_rb,3.921523e-01_rb,3.119082e-01_rb,2.597055e-01_rb,& & 2.228737e-01_rb,1.954157e-01_rb,1.741155e-01_rb,1.570881e-01_rb,1.431520e-01_rb,& & 1.302034e-01_rb,1.200491e-01_rb,1.113571e-01_rb,1.038330e-01_rb,9.725657e-02_rb,& & 9.145949e-02_rb,8.631112e-02_rb,8.170840e-02_rb,7.756901e-02_rb,7.382641e-02_rb,& & 7.042616e-02_rb,6.732338e-02_rb,6.448069e-02_rb,6.186672e-02_rb,5.945494e-02_rb,& & 5.722277e-02_rb,5.515089e-02_rb,5.322262e-02_rb,5.132153e-02_rb,4.969799e-02_rb,& & 4.816556e-02_rb,4.671686e-02_rb,4.534525e-02_rb,4.404480e-02_rb,4.281014e-02_rb,& & 4.163643e-02_rb,4.051930e-02_rb,3.945479e-02_rb,3.843927e-02_rb,3.746945e-02_rb,& & 3.654234e-02_rb,3.565518e-02_rb,3.480547e-02_rb,3.399088e-02_rb,3.320930e-02_rb,& & 3.245876e-02_rb,3.173745e-02_rb,3.104371e-02_rb,3.037600e-02_rb,2.973287e-02_rb,& & 2.911300e-02_rb,2.851516e-02_rb,2.793818e-02_rb,2.738101e-02_rb,2.684264e-02_rb,& & 2.632214e-02_rb,2.581863e-02_rb,2.5331e-02_rb /) extliq1(:, 21) = (/ & & 7.727642e-01_rb,5.034865e-01_rb,3.808673e-01_rb,3.080333e-01_rb,2.586453e-01_rb,& & 2.224989e-01_rb,1.947060e-01_rb,1.725821e-01_rb,1.545096e-01_rb,1.394456e-01_rb,& & 1.288683e-01_rb,1.188852e-01_rb,1.103317e-01_rb,1.029214e-01_rb,9.643967e-02_rb,& & 9.072239e-02_rb,8.564194e-02_rb,8.109758e-02_rb,7.700875e-02_rb,7.331026e-02_rb,& & 6.994879e-02_rb,6.688028e-02_rb,6.406807e-02_rb,6.148133e-02_rb,5.909400e-02_rb,& & 5.688388e-02_rb,5.483197e-02_rb,5.292185e-02_rb,5.103763e-02_rb,4.942905e-02_rb,& & 4.791039e-02_rb,4.647438e-02_rb,4.511453e-02_rb,4.382497e-02_rb,4.260043e-02_rb,& & 4.143616e-02_rb,4.032784e-02_rb,3.927155e-02_rb,3.826375e-02_rb,3.730117e-02_rb,& & 3.638087e-02_rb,3.550013e-02_rb,3.465646e-02_rb,3.384759e-02_rb,3.307141e-02_rb,& & 3.232598e-02_rb,3.160953e-02_rb,3.092040e-02_rb,3.025706e-02_rb,2.961810e-02_rb,& & 2.900220e-02_rb,2.840814e-02_rb,2.783478e-02_rb,2.728106e-02_rb,2.674599e-02_rb,& & 2.622864e-02_rb,2.572816e-02_rb,2.5244e-02_rb /) extliq1(:, 22) = (/ & & 7.416833e-01_rb,4.959591e-01_rb,3.775057e-01_rb,3.056353e-01_rb,2.565943e-01_rb,& & 2.206935e-01_rb,1.931479e-01_rb,1.712860e-01_rb,1.534837e-01_rb,1.386906e-01_rb,& & 1.281198e-01_rb,1.182344e-01_rb,1.097595e-01_rb,1.024137e-01_rb,9.598552e-02_rb,& & 9.031320e-02_rb,8.527093e-02_rb,8.075927e-02_rb,7.669869e-02_rb,7.302481e-02_rb,& & 6.968491e-02_rb,6.663542e-02_rb,6.384008e-02_rb,6.126838e-02_rb,5.889452e-02_rb,& & 5.669654e-02_rb,5.465558e-02_rb,5.275540e-02_rb,5.087937e-02_rb,4.927904e-02_rb,& & 4.776796e-02_rb,4.633895e-02_rb,4.498557e-02_rb,4.370202e-02_rb,4.248306e-02_rb,& & 4.132399e-02_rb,4.022052e-02_rb,3.916878e-02_rb,3.816523e-02_rb,3.720665e-02_rb,& & 3.629011e-02_rb,3.541290e-02_rb,3.457257e-02_rb,3.376685e-02_rb,3.299365e-02_rb,& & 3.225105e-02_rb,3.153728e-02_rb,3.085069e-02_rb,3.018977e-02_rb,2.955310e-02_rb,& & 2.893940e-02_rb,2.834742e-02_rb,2.777606e-02_rb,2.722424e-02_rb,2.669099e-02_rb,& & 2.617539e-02_rb,2.567658e-02_rb,2.5194e-02_rb /) extliq1(:, 23) = (/ & & 7.058580e-01_rb,4.866573e-01_rb,3.712238e-01_rb,2.998638e-01_rb,2.513441e-01_rb,& & 2.161972e-01_rb,1.895576e-01_rb,1.686669e-01_rb,1.518437e-01_rb,1.380046e-01_rb,& & 1.267564e-01_rb,1.170399e-01_rb,1.087026e-01_rb,1.014704e-01_rb,9.513729e-02_rb,& & 8.954555e-02_rb,8.457221e-02_rb,8.012009e-02_rb,7.611136e-02_rb,7.248294e-02_rb,& & 6.918317e-02_rb,6.616934e-02_rb,6.340584e-02_rb,6.086273e-02_rb,5.851465e-02_rb,& & 5.634001e-02_rb,5.432027e-02_rb,5.243946e-02_rb,5.058070e-02_rb,4.899628e-02_rb,& & 4.749975e-02_rb,4.608411e-02_rb,4.474303e-02_rb,4.347082e-02_rb,4.226237e-02_rb,& & 4.111303e-02_rb,4.001861e-02_rb,3.897528e-02_rb,3.797959e-02_rb,3.702835e-02_rb,& & 3.611867e-02_rb,3.524791e-02_rb,3.441364e-02_rb,3.361360e-02_rb,3.284577e-02_rb,& & 3.210823e-02_rb,3.139923e-02_rb,3.071716e-02_rb,3.006052e-02_rb,2.942791e-02_rb,& & 2.881806e-02_rb,2.822974e-02_rb,2.766185e-02_rb,2.711335e-02_rb,2.658326e-02_rb,& & 2.607066e-02_rb,2.557473e-02_rb,2.5095e-02_rb /) extliq1(:, 24) = (/ & & 6.822779e-01_rb,4.750373e-01_rb,3.634834e-01_rb,2.940726e-01_rb,2.468060e-01_rb,& & 2.125768e-01_rb,1.866586e-01_rb,1.663588e-01_rb,1.500326e-01_rb,1.366192e-01_rb,& & 1.253472e-01_rb,1.158052e-01_rb,1.076101e-01_rb,1.004954e-01_rb,9.426089e-02_rb,& & 8.875268e-02_rb,8.385090e-02_rb,7.946063e-02_rb,7.550578e-02_rb,7.192466e-02_rb,& & 6.866669e-02_rb,6.569001e-02_rb,6.295971e-02_rb,6.044642e-02_rb,5.812526e-02_rb,& & 5.597500e-02_rb,5.397746e-02_rb,5.211690e-02_rb,5.027505e-02_rb,4.870703e-02_rb,& & 4.722555e-02_rb,4.582373e-02_rb,4.449540e-02_rb,4.323497e-02_rb,4.203742e-02_rb,& & 4.089821e-02_rb,3.981321e-02_rb,3.877867e-02_rb,3.779118e-02_rb,3.684762e-02_rb,& & 3.594514e-02_rb,3.508114e-02_rb,3.425322e-02_rb,3.345917e-02_rb,3.269698e-02_rb,& & 3.196477e-02_rb,3.126082e-02_rb,3.058352e-02_rb,2.993141e-02_rb,2.930310e-02_rb,& & 2.869732e-02_rb,2.811289e-02_rb,2.754869e-02_rb,2.700371e-02_rb,2.647698e-02_rb,& & 2.596760e-02_rb,2.547473e-02_rb,2.4998e-02_rb /) extliq1(:, 25) = (/ & & 6.666233e-01_rb,4.662044e-01_rb,3.579517e-01_rb,2.902984e-01_rb,2.440475e-01_rb,& & 2.104431e-01_rb,1.849277e-01_rb,1.648970e-01_rb,1.487555e-01_rb,1.354714e-01_rb,& & 1.244173e-01_rb,1.149913e-01_rb,1.068903e-01_rb,9.985323e-02_rb,9.368351e-02_rb,& & 8.823009e-02_rb,8.337507e-02_rb,7.902511e-02_rb,7.510529e-02_rb,7.155482e-02_rb,& & 6.832386e-02_rb,6.537113e-02_rb,6.266218e-02_rb,6.016802e-02_rb,5.786408e-02_rb,& & 5.572939e-02_rb,5.374598e-02_rb,5.189830e-02_rb,5.006825e-02_rb,4.851081e-02_rb,& & 4.703906e-02_rb,4.564623e-02_rb,4.432621e-02_rb,4.307349e-02_rb,4.188312e-02_rb,& & 4.075060e-02_rb,3.967183e-02_rb,3.864313e-02_rb,3.766111e-02_rb,3.672269e-02_rb,& & 3.582505e-02_rb,3.496559e-02_rb,3.414196e-02_rb,3.335198e-02_rb,3.259362e-02_rb,& & 3.186505e-02_rb,3.116454e-02_rb,3.049052e-02_rb,2.984152e-02_rb,2.921617e-02_rb,& & 2.861322e-02_rb,2.803148e-02_rb,2.746986e-02_rb,2.692733e-02_rb,2.640295e-02_rb,& & 2.589582e-02_rb,2.540510e-02_rb,2.4930e-02_rb /) extliq1(:, 26) = (/ & & 6.535669e-01_rb,4.585865e-01_rb,3.529226e-01_rb,2.867245e-01_rb,2.413848e-01_rb,& & 2.083956e-01_rb,1.833191e-01_rb,1.636150e-01_rb,1.477247e-01_rb,1.346392e-01_rb,& & 1.236449e-01_rb,1.143095e-01_rb,1.062828e-01_rb,9.930773e-02_rb,9.319029e-02_rb,& & 8.778150e-02_rb,8.296497e-02_rb,7.864847e-02_rb,7.475799e-02_rb,7.123343e-02_rb,& & 6.802549e-02_rb,6.509332e-02_rb,6.240285e-02_rb,5.992538e-02_rb,5.763657e-02_rb,& & 5.551566e-02_rb,5.354483e-02_rb,5.170870e-02_rb,4.988866e-02_rb,4.834061e-02_rb,& & 4.687751e-02_rb,4.549264e-02_rb,4.417999e-02_rb,4.293410e-02_rb,4.175006e-02_rb,& & 4.062344e-02_rb,3.955019e-02_rb,3.852663e-02_rb,3.754943e-02_rb,3.661553e-02_rb,& & 3.572214e-02_rb,3.486669e-02_rb,3.404683e-02_rb,3.326040e-02_rb,3.250542e-02_rb,& & 3.178003e-02_rb,3.108254e-02_rb,3.041139e-02_rb,2.976511e-02_rb,2.914235e-02_rb,& & 2.854187e-02_rb,2.796247e-02_rb,2.740309e-02_rb,2.686271e-02_rb,2.634038e-02_rb,& & 2.583520e-02_rb,2.534636e-02_rb,2.4873e-02_rb /) extliq1(:, 27) = (/ & & 6.448790e-01_rb,4.541425e-01_rb,3.503348e-01_rb,2.850494e-01_rb,2.401966e-01_rb,& & 2.074811e-01_rb,1.825631e-01_rb,1.629515e-01_rb,1.471142e-01_rb,1.340574e-01_rb,& & 1.231462e-01_rb,1.138628e-01_rb,1.058802e-01_rb,9.894286e-02_rb,9.285818e-02_rb,& & 8.747802e-02_rb,8.268676e-02_rb,7.839271e-02_rb,7.452230e-02_rb,7.101580e-02_rb,& & 6.782418e-02_rb,6.490685e-02_rb,6.222991e-02_rb,5.976484e-02_rb,5.748742e-02_rb,& & 5.537703e-02_rb,5.341593e-02_rb,5.158883e-02_rb,4.977355e-02_rb,4.823172e-02_rb,& & 4.677430e-02_rb,4.539465e-02_rb,4.408680e-02_rb,4.284533e-02_rb,4.166539e-02_rb,& & 4.054257e-02_rb,3.947283e-02_rb,3.845256e-02_rb,3.747842e-02_rb,3.654737e-02_rb,& & 3.565665e-02_rb,3.480370e-02_rb,3.398620e-02_rb,3.320198e-02_rb,3.244908e-02_rb,& & 3.172566e-02_rb,3.103002e-02_rb,3.036062e-02_rb,2.971600e-02_rb,2.909482e-02_rb,& & 2.849582e-02_rb,2.791785e-02_rb,2.735982e-02_rb,2.682072e-02_rb,2.629960e-02_rb,& & 2.579559e-02_rb,2.530786e-02_rb,2.4836e-02_rb /) extliq1(:, 28) = (/ & & 6.422688e-01_rb,4.528453e-01_rb,3.497232e-01_rb,2.847724e-01_rb,2.400815e-01_rb,& & 2.074403e-01_rb,1.825502e-01_rb,1.629415e-01_rb,1.470934e-01_rb,1.340183e-01_rb,& & 1.230935e-01_rb,1.138049e-01_rb,1.058201e-01_rb,9.888245e-02_rb,9.279878e-02_rb,& & 8.742053e-02_rb,8.263175e-02_rb,7.834058e-02_rb,7.447327e-02_rb,7.097000e-02_rb,& & 6.778167e-02_rb,6.486765e-02_rb,6.219400e-02_rb,5.973215e-02_rb,5.745790e-02_rb,& & 5.535059e-02_rb,5.339250e-02_rb,5.156831e-02_rb,4.975308e-02_rb,4.821235e-02_rb,& & 4.675596e-02_rb,4.537727e-02_rb,4.407030e-02_rb,4.282968e-02_rb,4.165053e-02_rb,& & 4.052845e-02_rb,3.945941e-02_rb,3.843980e-02_rb,3.746628e-02_rb,3.653583e-02_rb,& & 3.564567e-02_rb,3.479326e-02_rb,3.397626e-02_rb,3.319253e-02_rb,3.244008e-02_rb,& & 3.171711e-02_rb,3.102189e-02_rb,3.035289e-02_rb,2.970866e-02_rb,2.908784e-02_rb,& & 2.848920e-02_rb,2.791156e-02_rb,2.735385e-02_rb,2.681507e-02_rb,2.629425e-02_rb,& & 2.579053e-02_rb,2.530308e-02_rb,2.4831e-02_rb /) extliq1(:, 29) = (/ & & 4.614710e-01_rb,4.556116e-01_rb,4.056568e-01_rb,3.529833e-01_rb,3.060334e-01_rb,& & 2.658127e-01_rb,2.316095e-01_rb,2.024325e-01_rb,1.773749e-01_rb,1.556867e-01_rb,& & 1.455558e-01_rb,1.332882e-01_rb,1.229052e-01_rb,1.140067e-01_rb,1.062981e-01_rb,& & 9.955703e-02_rb,9.361333e-02_rb,8.833420e-02_rb,8.361467e-02_rb,7.937071e-02_rb,& & 7.553420e-02_rb,7.204942e-02_rb,6.887031e-02_rb,6.595851e-02_rb,6.328178e-02_rb,& & 6.081286e-02_rb,5.852854e-02_rb,5.640892e-02_rb,5.431269e-02_rb,5.252561e-02_rb,& & 5.084345e-02_rb,4.925727e-02_rb,4.775910e-02_rb,4.634182e-02_rb,4.499907e-02_rb,& & 4.372512e-02_rb,4.251484e-02_rb,4.136357e-02_rb,4.026710e-02_rb,3.922162e-02_rb,& & 3.822365e-02_rb,3.727004e-02_rb,3.635790e-02_rb,3.548457e-02_rb,3.464764e-02_rb,& & 3.384488e-02_rb,3.307424e-02_rb,3.233384e-02_rb,3.162192e-02_rb,3.093688e-02_rb,& & 3.027723e-02_rb,2.964158e-02_rb,2.902864e-02_rb,2.843722e-02_rb,2.786621e-02_rb,& & 2.731457e-02_rb,2.678133e-02_rb,2.6266e-02_rb /) ! Single scattering albedo ssaliq1(:, 16) = (/ & & 8.143821e-01_rb,7.836739e-01_rb,7.550722e-01_rb,7.306269e-01_rb,7.105612e-01_rb,& & 6.946649e-01_rb,6.825556e-01_rb,6.737762e-01_rb,6.678448e-01_rb,6.642830e-01_rb,& & 6.679741e-01_rb,6.584607e-01_rb,6.505598e-01_rb,6.440951e-01_rb,6.388901e-01_rb,& & 6.347689e-01_rb,6.315549e-01_rb,6.290718e-01_rb,6.271432e-01_rb,6.255928e-01_rb,& & 6.242441e-01_rb,6.229207e-01_rb,6.214464e-01_rb,6.196445e-01_rb,6.173388e-01_rb,& & 6.143527e-01_rb,6.105099e-01_rb,6.056339e-01_rb,6.108290e-01_rb,6.073939e-01_rb,& & 6.043073e-01_rb,6.015473e-01_rb,5.990913e-01_rb,5.969173e-01_rb,5.950028e-01_rb,& & 5.933257e-01_rb,5.918636e-01_rb,5.905944e-01_rb,5.894957e-01_rb,5.885453e-01_rb,& & 5.877209e-01_rb,5.870003e-01_rb,5.863611e-01_rb,5.857811e-01_rb,5.852381e-01_rb,& & 5.847098e-01_rb,5.841738e-01_rb,5.836081e-01_rb,5.829901e-01_rb,5.822979e-01_rb,& & 5.815089e-01_rb,5.806011e-01_rb,5.795521e-01_rb,5.783396e-01_rb,5.769413e-01_rb,& & 5.753351e-01_rb,5.734986e-01_rb,5.7141e-01_rb /) ssaliq1(:, 17) = (/ & & 8.165821e-01_rb,8.002015e-01_rb,7.816921e-01_rb,7.634131e-01_rb,7.463721e-01_rb,& & 7.312469e-01_rb,7.185883e-01_rb,7.088975e-01_rb,7.026671e-01_rb,7.004020e-01_rb,& & 7.042138e-01_rb,6.960930e-01_rb,6.894243e-01_rb,6.840459e-01_rb,6.797957e-01_rb,& & 6.765119e-01_rb,6.740325e-01_rb,6.721955e-01_rb,6.708391e-01_rb,6.698013e-01_rb,& & 6.689201e-01_rb,6.680339e-01_rb,6.669805e-01_rb,6.655982e-01_rb,6.637250e-01_rb,& & 6.611992e-01_rb,6.578588e-01_rb,6.535420e-01_rb,6.584449e-01_rb,6.553992e-01_rb,& & 6.526547e-01_rb,6.501917e-01_rb,6.479905e-01_rb,6.460313e-01_rb,6.442945e-01_rb,& & 6.427605e-01_rb,6.414094e-01_rb,6.402217e-01_rb,6.391775e-01_rb,6.382573e-01_rb,& & 6.374413e-01_rb,6.367099e-01_rb,6.360433e-01_rb,6.354218e-01_rb,6.348257e-01_rb,& & 6.342355e-01_rb,6.336313e-01_rb,6.329935e-01_rb,6.323023e-01_rb,6.315383e-01_rb,& & 6.306814e-01_rb,6.297122e-01_rb,6.286110e-01_rb,6.273579e-01_rb,6.259333e-01_rb,& & 6.243176e-01_rb,6.224910e-01_rb,6.2043e-01_rb /) ssaliq1(:, 18) = (/ & & 9.900163e-01_rb,9.854307e-01_rb,9.797730e-01_rb,9.733113e-01_rb,9.664245e-01_rb,& & 9.594976e-01_rb,9.529055e-01_rb,9.470112e-01_rb,9.421695e-01_rb,9.387304e-01_rb,& & 9.344918e-01_rb,9.305302e-01_rb,9.267048e-01_rb,9.230072e-01_rb,9.194289e-01_rb,& & 9.159616e-01_rb,9.125968e-01_rb,9.093260e-01_rb,9.061409e-01_rb,9.030330e-01_rb,& & 8.999940e-01_rb,8.970154e-01_rb,8.940888e-01_rb,8.912058e-01_rb,8.883579e-01_rb,& & 8.855368e-01_rb,8.827341e-01_rb,8.799413e-01_rb,8.777423e-01_rb,8.749566e-01_rb,& & 8.722298e-01_rb,8.695605e-01_rb,8.669469e-01_rb,8.643875e-01_rb,8.618806e-01_rb,& & 8.594246e-01_rb,8.570179e-01_rb,8.546589e-01_rb,8.523459e-01_rb,8.500773e-01_rb,& & 8.478516e-01_rb,8.456670e-01_rb,8.435219e-01_rb,8.414148e-01_rb,8.393439e-01_rb,& & 8.373078e-01_rb,8.353047e-01_rb,8.333330e-01_rb,8.313911e-01_rb,8.294774e-01_rb,& & 8.275904e-01_rb,8.257282e-01_rb,8.238893e-01_rb,8.220721e-01_rb,8.202751e-01_rb,& & 8.184965e-01_rb,8.167346e-01_rb,8.1499e-01_rb /) ssaliq1(:, 19) = (/ & & 9.999916e-01_rb,9.987396e-01_rb,9.966900e-01_rb,9.950738e-01_rb,9.937531e-01_rb,& & 9.925912e-01_rb,9.914525e-01_rb,9.902018e-01_rb,9.887046e-01_rb,9.868263e-01_rb,& & 9.849039e-01_rb,9.832372e-01_rb,9.815265e-01_rb,9.797770e-01_rb,9.779940e-01_rb,& & 9.761827e-01_rb,9.743481e-01_rb,9.724955e-01_rb,9.706303e-01_rb,9.687575e-01_rb,& & 9.668823e-01_rb,9.650100e-01_rb,9.631457e-01_rb,9.612947e-01_rb,9.594622e-01_rb,& & 9.576534e-01_rb,9.558734e-01_rb,9.541275e-01_rb,9.522059e-01_rb,9.504258e-01_rb,& & 9.486459e-01_rb,9.468676e-01_rb,9.450921e-01_rb,9.433208e-01_rb,9.415548e-01_rb,& & 9.397955e-01_rb,9.380441e-01_rb,9.363022e-01_rb,9.345706e-01_rb,9.328510e-01_rb,& & 9.311445e-01_rb,9.294524e-01_rb,9.277761e-01_rb,9.261167e-01_rb,9.244755e-01_rb,& & 9.228540e-01_rb,9.212534e-01_rb,9.196748e-01_rb,9.181197e-01_rb,9.165894e-01_rb,& & 9.150851e-01_rb,9.136080e-01_rb,9.121596e-01_rb,9.107410e-01_rb,9.093536e-01_rb,& & 9.079987e-01_rb,9.066775e-01_rb,9.0539e-01_rb /) ssaliq1(:, 20) = (/ & & 9.979493e-01_rb,9.964113e-01_rb,9.950014e-01_rb,9.937045e-01_rb,9.924964e-01_rb,& & 9.913546e-01_rb,9.902575e-01_rb,9.891843e-01_rb,9.881136e-01_rb,9.870238e-01_rb,& & 9.859934e-01_rb,9.849372e-01_rb,9.838873e-01_rb,9.828434e-01_rb,9.818052e-01_rb,& & 9.807725e-01_rb,9.797450e-01_rb,9.787225e-01_rb,9.777047e-01_rb,9.766914e-01_rb,& & 9.756823e-01_rb,9.746771e-01_rb,9.736756e-01_rb,9.726775e-01_rb,9.716827e-01_rb,& & 9.706907e-01_rb,9.697014e-01_rb,9.687145e-01_rb,9.678060e-01_rb,9.668108e-01_rb,& & 9.658218e-01_rb,9.648391e-01_rb,9.638629e-01_rb,9.628936e-01_rb,9.619313e-01_rb,& & 9.609763e-01_rb,9.600287e-01_rb,9.590888e-01_rb,9.581569e-01_rb,9.572330e-01_rb,& & 9.563176e-01_rb,9.554108e-01_rb,9.545128e-01_rb,9.536239e-01_rb,9.527443e-01_rb,& & 9.518741e-01_rb,9.510137e-01_rb,9.501633e-01_rb,9.493230e-01_rb,9.484931e-01_rb,& & 9.476740e-01_rb,9.468656e-01_rb,9.460683e-01_rb,9.452824e-01_rb,9.445080e-01_rb,& & 9.437454e-01_rb,9.429948e-01_rb,9.4226e-01_rb /) ssaliq1(:, 21) = (/ & & 9.988742e-01_rb,9.982668e-01_rb,9.976935e-01_rb,9.971497e-01_rb,9.966314e-01_rb,& & 9.961344e-01_rb,9.956545e-01_rb,9.951873e-01_rb,9.947286e-01_rb,9.942741e-01_rb,& & 9.938457e-01_rb,9.933947e-01_rb,9.929473e-01_rb,9.925032e-01_rb,9.920621e-01_rb,& & 9.916237e-01_rb,9.911875e-01_rb,9.907534e-01_rb,9.903209e-01_rb,9.898898e-01_rb,& & 9.894597e-01_rb,9.890304e-01_rb,9.886015e-01_rb,9.881726e-01_rb,9.877435e-01_rb,& & 9.873138e-01_rb,9.868833e-01_rb,9.864516e-01_rb,9.860698e-01_rb,9.856317e-01_rb,& & 9.851957e-01_rb,9.847618e-01_rb,9.843302e-01_rb,9.839008e-01_rb,9.834739e-01_rb,& & 9.830494e-01_rb,9.826275e-01_rb,9.822083e-01_rb,9.817918e-01_rb,9.813782e-01_rb,& & 9.809675e-01_rb,9.805598e-01_rb,9.801552e-01_rb,9.797538e-01_rb,9.793556e-01_rb,& & 9.789608e-01_rb,9.785695e-01_rb,9.781817e-01_rb,9.777975e-01_rb,9.774171e-01_rb,& & 9.770404e-01_rb,9.766676e-01_rb,9.762988e-01_rb,9.759340e-01_rb,9.755733e-01_rb,& & 9.752169e-01_rb,9.748649e-01_rb,9.7452e-01_rb /) ssaliq1(:, 22) = (/ & & 9.994441e-01_rb,9.991608e-01_rb,9.988949e-01_rb,9.986439e-01_rb,9.984054e-01_rb,& & 9.981768e-01_rb,9.979557e-01_rb,9.977396e-01_rb,9.975258e-01_rb,9.973120e-01_rb,& & 9.971011e-01_rb,9.968852e-01_rb,9.966708e-01_rb,9.964578e-01_rb,9.962462e-01_rb,& & 9.960357e-01_rb,9.958264e-01_rb,9.956181e-01_rb,9.954108e-01_rb,9.952043e-01_rb,& & 9.949987e-01_rb,9.947937e-01_rb,9.945892e-01_rb,9.943853e-01_rb,9.941818e-01_rb,& & 9.939786e-01_rb,9.937757e-01_rb,9.935728e-01_rb,9.933922e-01_rb,9.931825e-01_rb,& & 9.929739e-01_rb,9.927661e-01_rb,9.925592e-01_rb,9.923534e-01_rb,9.921485e-01_rb,& & 9.919447e-01_rb,9.917421e-01_rb,9.915406e-01_rb,9.913403e-01_rb,9.911412e-01_rb,& & 9.909435e-01_rb,9.907470e-01_rb,9.905519e-01_rb,9.903581e-01_rb,9.901659e-01_rb,& & 9.899751e-01_rb,9.897858e-01_rb,9.895981e-01_rb,9.894120e-01_rb,9.892276e-01_rb,& & 9.890447e-01_rb,9.888637e-01_rb,9.886845e-01_rb,9.885070e-01_rb,9.883314e-01_rb,& & 9.881576e-01_rb,9.879859e-01_rb,9.8782e-01_rb /) ssaliq1(:, 23) = (/ & & 9.999138e-01_rb,9.998730e-01_rb,9.998338e-01_rb,9.997965e-01_rb,9.997609e-01_rb,& & 9.997270e-01_rb,9.996944e-01_rb,9.996629e-01_rb,9.996321e-01_rb,9.996016e-01_rb,& & 9.995690e-01_rb,9.995372e-01_rb,9.995057e-01_rb,9.994744e-01_rb,9.994433e-01_rb,& & 9.994124e-01_rb,9.993817e-01_rb,9.993510e-01_rb,9.993206e-01_rb,9.992903e-01_rb,& & 9.992600e-01_rb,9.992299e-01_rb,9.991998e-01_rb,9.991698e-01_rb,9.991398e-01_rb,& & 9.991098e-01_rb,9.990799e-01_rb,9.990499e-01_rb,9.990231e-01_rb,9.989920e-01_rb,& & 9.989611e-01_rb,9.989302e-01_rb,9.988996e-01_rb,9.988690e-01_rb,9.988386e-01_rb,& & 9.988084e-01_rb,9.987783e-01_rb,9.987485e-01_rb,9.987187e-01_rb,9.986891e-01_rb,& & 9.986598e-01_rb,9.986306e-01_rb,9.986017e-01_rb,9.985729e-01_rb,9.985443e-01_rb,& & 9.985160e-01_rb,9.984879e-01_rb,9.984600e-01_rb,9.984324e-01_rb,9.984050e-01_rb,& & 9.983778e-01_rb,9.983509e-01_rb,9.983243e-01_rb,9.982980e-01_rb,9.982719e-01_rb,& & 9.982461e-01_rb,9.982206e-01_rb,9.9820e-01_rb /) ssaliq1(:, 24) = (/ & & 9.999985e-01_rb,9.999979e-01_rb,9.999972e-01_rb,9.999966e-01_rb,9.999961e-01_rb,& & 9.999955e-01_rb,9.999950e-01_rb,9.999944e-01_rb,9.999938e-01_rb,9.999933e-01_rb,& & 9.999927e-01_rb,9.999921e-01_rb,9.999915e-01_rb,9.999910e-01_rb,9.999904e-01_rb,& & 9.999899e-01_rb,9.999893e-01_rb,9.999888e-01_rb,9.999882e-01_rb,9.999877e-01_rb,& & 9.999871e-01_rb,9.999866e-01_rb,9.999861e-01_rb,9.999855e-01_rb,9.999850e-01_rb,& & 9.999844e-01_rb,9.999839e-01_rb,9.999833e-01_rb,9.999828e-01_rb,9.999823e-01_rb,& & 9.999817e-01_rb,9.999812e-01_rb,9.999807e-01_rb,9.999801e-01_rb,9.999796e-01_rb,& & 9.999791e-01_rb,9.999786e-01_rb,9.999781e-01_rb,9.999776e-01_rb,9.999770e-01_rb,& & 9.999765e-01_rb,9.999761e-01_rb,9.999756e-01_rb,9.999751e-01_rb,9.999746e-01_rb,& & 9.999741e-01_rb,9.999736e-01_rb,9.999732e-01_rb,9.999727e-01_rb,9.999722e-01_rb,& & 9.999718e-01_rb,9.999713e-01_rb,9.999709e-01_rb,9.999705e-01_rb,9.999701e-01_rb,& & 9.999697e-01_rb,9.999692e-01_rb,9.9997e-01_rb /) ssaliq1(:, 25) = (/ & & 9.999999e-01_rb,9.999998e-01_rb,9.999997e-01_rb,9.999997e-01_rb,9.999997e-01_rb,& & 9.999996e-01_rb,9.999996e-01_rb,9.999995e-01_rb,9.999995e-01_rb,9.999994e-01_rb,& & 9.999994e-01_rb,9.999993e-01_rb,9.999993e-01_rb,9.999992e-01_rb,9.999992e-01_rb,& & 9.999991e-01_rb,9.999991e-01_rb,9.999991e-01_rb,9.999990e-01_rb,9.999989e-01_rb,& & 9.999989e-01_rb,9.999989e-01_rb,9.999988e-01_rb,9.999988e-01_rb,9.999987e-01_rb,& & 9.999987e-01_rb,9.999986e-01_rb,9.999986e-01_rb,9.999985e-01_rb,9.999985e-01_rb,& & 9.999984e-01_rb,9.999984e-01_rb,9.999984e-01_rb,9.999983e-01_rb,9.999983e-01_rb,& & 9.999982e-01_rb,9.999982e-01_rb,9.999982e-01_rb,9.999981e-01_rb,9.999980e-01_rb,& & 9.999980e-01_rb,9.999980e-01_rb,9.999979e-01_rb,9.999979e-01_rb,9.999978e-01_rb,& & 9.999978e-01_rb,9.999977e-01_rb,9.999977e-01_rb,9.999977e-01_rb,9.999976e-01_rb,& & 9.999976e-01_rb,9.999975e-01_rb,9.999975e-01_rb,9.999974e-01_rb,9.999974e-01_rb,& & 9.999974e-01_rb,9.999973e-01_rb,1.0000e+00_rb /) ssaliq1(:, 26) = (/ & & 9.999997e-01_rb,9.999995e-01_rb,9.999993e-01_rb,9.999992e-01_rb,9.999990e-01_rb,& & 9.999989e-01_rb,9.999988e-01_rb,9.999987e-01_rb,9.999986e-01_rb,9.999985e-01_rb,& & 9.999984e-01_rb,9.999983e-01_rb,9.999982e-01_rb,9.999981e-01_rb,9.999980e-01_rb,& & 9.999978e-01_rb,9.999977e-01_rb,9.999976e-01_rb,9.999975e-01_rb,9.999974e-01_rb,& & 9.999973e-01_rb,9.999972e-01_rb,9.999970e-01_rb,9.999969e-01_rb,9.999968e-01_rb,& & 9.999967e-01_rb,9.999966e-01_rb,9.999965e-01_rb,9.999964e-01_rb,9.999963e-01_rb,& & 9.999962e-01_rb,9.999961e-01_rb,9.999959e-01_rb,9.999958e-01_rb,9.999957e-01_rb,& & 9.999956e-01_rb,9.999955e-01_rb,9.999954e-01_rb,9.999953e-01_rb,9.999952e-01_rb,& & 9.999951e-01_rb,9.999949e-01_rb,9.999949e-01_rb,9.999947e-01_rb,9.999946e-01_rb,& & 9.999945e-01_rb,9.999944e-01_rb,9.999943e-01_rb,9.999942e-01_rb,9.999941e-01_rb,& & 9.999940e-01_rb,9.999939e-01_rb,9.999938e-01_rb,9.999937e-01_rb,9.999936e-01_rb,& & 9.999935e-01_rb,9.999934e-01_rb,9.9999e-01_rb /) ssaliq1(:, 27) = (/ & & 9.999984e-01_rb,9.999976e-01_rb,9.999969e-01_rb,9.999962e-01_rb,9.999956e-01_rb,& & 9.999950e-01_rb,9.999945e-01_rb,9.999940e-01_rb,9.999935e-01_rb,9.999931e-01_rb,& & 9.999926e-01_rb,9.999920e-01_rb,9.999914e-01_rb,9.999908e-01_rb,9.999903e-01_rb,& & 9.999897e-01_rb,9.999891e-01_rb,9.999886e-01_rb,9.999880e-01_rb,9.999874e-01_rb,& & 9.999868e-01_rb,9.999863e-01_rb,9.999857e-01_rb,9.999851e-01_rb,9.999846e-01_rb,& & 9.999840e-01_rb,9.999835e-01_rb,9.999829e-01_rb,9.999824e-01_rb,9.999818e-01_rb,& & 9.999812e-01_rb,9.999806e-01_rb,9.999800e-01_rb,9.999795e-01_rb,9.999789e-01_rb,& & 9.999783e-01_rb,9.999778e-01_rb,9.999773e-01_rb,9.999767e-01_rb,9.999761e-01_rb,& & 9.999756e-01_rb,9.999750e-01_rb,9.999745e-01_rb,9.999739e-01_rb,9.999734e-01_rb,& & 9.999729e-01_rb,9.999723e-01_rb,9.999718e-01_rb,9.999713e-01_rb,9.999708e-01_rb,& & 9.999703e-01_rb,9.999697e-01_rb,9.999692e-01_rb,9.999687e-01_rb,9.999683e-01_rb,& & 9.999678e-01_rb,9.999673e-01_rb,9.9997e-01_rb /) ssaliq1(:, 28) = (/ & & 9.999981e-01_rb,9.999973e-01_rb,9.999965e-01_rb,9.999958e-01_rb,9.999951e-01_rb,& & 9.999943e-01_rb,9.999937e-01_rb,9.999930e-01_rb,9.999924e-01_rb,9.999918e-01_rb,& & 9.999912e-01_rb,9.999905e-01_rb,9.999897e-01_rb,9.999890e-01_rb,9.999883e-01_rb,& & 9.999876e-01_rb,9.999869e-01_rb,9.999862e-01_rb,9.999855e-01_rb,9.999847e-01_rb,& & 9.999840e-01_rb,9.999834e-01_rb,9.999827e-01_rb,9.999819e-01_rb,9.999812e-01_rb,& & 9.999805e-01_rb,9.999799e-01_rb,9.999791e-01_rb,9.999785e-01_rb,9.999778e-01_rb,& & 9.999771e-01_rb,9.999764e-01_rb,9.999757e-01_rb,9.999750e-01_rb,9.999743e-01_rb,& & 9.999736e-01_rb,9.999729e-01_rb,9.999722e-01_rb,9.999715e-01_rb,9.999709e-01_rb,& & 9.999701e-01_rb,9.999695e-01_rb,9.999688e-01_rb,9.999682e-01_rb,9.999675e-01_rb,& & 9.999669e-01_rb,9.999662e-01_rb,9.999655e-01_rb,9.999649e-01_rb,9.999642e-01_rb,& & 9.999636e-01_rb,9.999630e-01_rb,9.999624e-01_rb,9.999618e-01_rb,9.999612e-01_rb,& & 9.999606e-01_rb,9.999600e-01_rb,9.9996e-01_rb /) ssaliq1(:, 29) = (/ & & 8.505737e-01_rb,8.465102e-01_rb,8.394829e-01_rb,8.279508e-01_rb,8.110806e-01_rb,& & 7.900397e-01_rb,7.669615e-01_rb,7.444422e-01_rb,7.253055e-01_rb,7.124831e-01_rb,& & 7.016434e-01_rb,6.885485e-01_rb,6.767340e-01_rb,6.661029e-01_rb,6.565577e-01_rb,& & 6.480013e-01_rb,6.403373e-01_rb,6.334697e-01_rb,6.273034e-01_rb,6.217440e-01_rb,& & 6.166983e-01_rb,6.120740e-01_rb,6.077796e-01_rb,6.037249e-01_rb,5.998207e-01_rb,& & 5.959788e-01_rb,5.921123e-01_rb,5.881354e-01_rb,5.891285e-01_rb,5.851143e-01_rb,& & 5.814653e-01_rb,5.781606e-01_rb,5.751792e-01_rb,5.724998e-01_rb,5.701016e-01_rb,& & 5.679634e-01_rb,5.660642e-01_rb,5.643829e-01_rb,5.628984e-01_rb,5.615898e-01_rb,& & 5.604359e-01_rb,5.594158e-01_rb,5.585083e-01_rb,5.576924e-01_rb,5.569470e-01_rb,& & 5.562512e-01_rb,5.555838e-01_rb,5.549239e-01_rb,5.542503e-01_rb,5.535420e-01_rb,& & 5.527781e-01_rb,5.519374e-01_rb,5.509989e-01_rb,5.499417e-01_rb,5.487445e-01_rb,& & 5.473865e-01_rb,5.458466e-01_rb,5.4410e-01_rb /) ! asymmetry parameter asyliq1(:, 16) = (/ & & 8.133297e-01_rb,8.133528e-01_rb,8.173865e-01_rb,8.243205e-01_rb,8.333063e-01_rb,& & 8.436317e-01_rb,8.546611e-01_rb,8.657934e-01_rb,8.764345e-01_rb,8.859837e-01_rb,& & 8.627394e-01_rb,8.824569e-01_rb,8.976887e-01_rb,9.089541e-01_rb,9.167699e-01_rb,& & 9.216517e-01_rb,9.241147e-01_rb,9.246743e-01_rb,9.238469e-01_rb,9.221504e-01_rb,& & 9.201045e-01_rb,9.182299e-01_rb,9.170491e-01_rb,9.170862e-01_rb,9.188653e-01_rb,& & 9.229111e-01_rb,9.297468e-01_rb,9.398950e-01_rb,9.203269e-01_rb,9.260693e-01_rb,& & 9.309373e-01_rb,9.349918e-01_rb,9.382935e-01_rb,9.409030e-01_rb,9.428809e-01_rb,& & 9.442881e-01_rb,9.451851e-01_rb,9.456331e-01_rb,9.456926e-01_rb,9.454247e-01_rb,& & 9.448902e-01_rb,9.441503e-01_rb,9.432661e-01_rb,9.422987e-01_rb,9.413094e-01_rb,& & 9.403594e-01_rb,9.395102e-01_rb,9.388230e-01_rb,9.383594e-01_rb,9.381810e-01_rb,& & 9.383489e-01_rb,9.389251e-01_rb,9.399707e-01_rb,9.415475e-01_rb,9.437167e-01_rb,& & 9.465399e-01_rb,9.500786e-01_rb,9.5439e-01_rb /) asyliq1(:, 17) = (/ & & 8.794448e-01_rb,8.819306e-01_rb,8.837667e-01_rb,8.853832e-01_rb,8.871010e-01_rb,& & 8.892675e-01_rb,8.922584e-01_rb,8.964666e-01_rb,9.022940e-01_rb,9.101456e-01_rb,& & 8.839999e-01_rb,9.035610e-01_rb,9.184568e-01_rb,9.292315e-01_rb,9.364282e-01_rb,& & 9.405887e-01_rb,9.422554e-01_rb,9.419703e-01_rb,9.402759e-01_rb,9.377159e-01_rb,& & 9.348345e-01_rb,9.321769e-01_rb,9.302888e-01_rb,9.297166e-01_rb,9.310075e-01_rb,& & 9.347080e-01_rb,9.413643e-01_rb,9.515216e-01_rb,9.306286e-01_rb,9.361781e-01_rb,& & 9.408374e-01_rb,9.446692e-01_rb,9.477363e-01_rb,9.501013e-01_rb,9.518268e-01_rb,& & 9.529756e-01_rb,9.536105e-01_rb,9.537938e-01_rb,9.535886e-01_rb,9.530574e-01_rb,& & 9.522633e-01_rb,9.512688e-01_rb,9.501370e-01_rb,9.489306e-01_rb,9.477126e-01_rb,& & 9.465459e-01_rb,9.454934e-01_rb,9.446183e-01_rb,9.439833e-01_rb,9.436519e-01_rb,& & 9.436866e-01_rb,9.441508e-01_rb,9.451073e-01_rb,9.466195e-01_rb,9.487501e-01_rb,& & 9.515621e-01_rb,9.551185e-01_rb,9.5948e-01_rb /) asyliq1(:, 18) = (/ & & 8.478817e-01_rb,8.269312e-01_rb,8.161352e-01_rb,8.135960e-01_rb,8.173586e-01_rb,& & 8.254167e-01_rb,8.357072e-01_rb,8.461167e-01_rb,8.544952e-01_rb,8.586776e-01_rb,& & 8.335562e-01_rb,8.524273e-01_rb,8.669052e-01_rb,8.775014e-01_rb,8.847277e-01_rb,& & 8.890958e-01_rb,8.911173e-01_rb,8.913038e-01_rb,8.901669e-01_rb,8.882182e-01_rb,& & 8.859692e-01_rb,8.839315e-01_rb,8.826164e-01_rb,8.825356e-01_rb,8.842004e-01_rb,& & 8.881223e-01_rb,8.948131e-01_rb,9.047837e-01_rb,8.855951e-01_rb,8.911796e-01_rb,& & 8.959229e-01_rb,8.998837e-01_rb,9.031209e-01_rb,9.056939e-01_rb,9.076609e-01_rb,& & 9.090812e-01_rb,9.100134e-01_rb,9.105167e-01_rb,9.106496e-01_rb,9.104712e-01_rb,& & 9.100404e-01_rb,9.094159e-01_rb,9.086568e-01_rb,9.078218e-01_rb,9.069697e-01_rb,& & 9.061595e-01_rb,9.054499e-01_rb,9.048999e-01_rb,9.045683e-01_rb,9.045142e-01_rb,& & 9.047962e-01_rb,9.054730e-01_rb,9.066037e-01_rb,9.082472e-01_rb,9.104623e-01_rb,& & 9.133079e-01_rb,9.168427e-01_rb,9.2113e-01_rb /) asyliq1(:, 19) = (/ & & 8.216697e-01_rb,7.982871e-01_rb,7.891147e-01_rb,7.909083e-01_rb,8.003833e-01_rb,& & 8.142516e-01_rb,8.292290e-01_rb,8.420356e-01_rb,8.493945e-01_rb,8.480316e-01_rb,& & 8.212381e-01_rb,8.394984e-01_rb,8.534095e-01_rb,8.634813e-01_rb,8.702242e-01_rb,& & 8.741483e-01_rb,8.757638e-01_rb,8.755808e-01_rb,8.741095e-01_rb,8.718604e-01_rb,& & 8.693433e-01_rb,8.670686e-01_rb,8.655464e-01_rb,8.652872e-01_rb,8.668006e-01_rb,& & 8.705973e-01_rb,8.771874e-01_rb,8.870809e-01_rb,8.678284e-01_rb,8.732315e-01_rb,& & 8.778084e-01_rb,8.816166e-01_rb,8.847146e-01_rb,8.871603e-01_rb,8.890116e-01_rb,& & 8.903266e-01_rb,8.911632e-01_rb,8.915796e-01_rb,8.916337e-01_rb,8.913834e-01_rb,& & 8.908869e-01_rb,8.902022e-01_rb,8.893873e-01_rb,8.885001e-01_rb,8.875986e-01_rb,& & 8.867411e-01_rb,8.859852e-01_rb,8.853891e-01_rb,8.850111e-01_rb,8.849089e-01_rb,& & 8.851405e-01_rb,8.857639e-01_rb,8.868372e-01_rb,8.884185e-01_rb,8.905656e-01_rb,& & 8.933368e-01_rb,8.967899e-01_rb,9.0098e-01_rb /) asyliq1(:, 20) = (/ & & 8.063610e-01_rb,7.938147e-01_rb,7.921304e-01_rb,7.985092e-01_rb,8.101339e-01_rb,& & 8.242175e-01_rb,8.379913e-01_rb,8.486920e-01_rb,8.535547e-01_rb,8.498083e-01_rb,& & 8.224849e-01_rb,8.405509e-01_rb,8.542436e-01_rb,8.640770e-01_rb,8.705653e-01_rb,& & 8.742227e-01_rb,8.755630e-01_rb,8.751004e-01_rb,8.733491e-01_rb,8.708231e-01_rb,& & 8.680365e-01_rb,8.655035e-01_rb,8.637381e-01_rb,8.632544e-01_rb,8.645665e-01_rb,& & 8.681885e-01_rb,8.746346e-01_rb,8.844188e-01_rb,8.648180e-01_rb,8.700563e-01_rb,& & 8.744672e-01_rb,8.781087e-01_rb,8.810393e-01_rb,8.833174e-01_rb,8.850011e-01_rb,& & 8.861485e-01_rb,8.868183e-01_rb,8.870687e-01_rb,8.869579e-01_rb,8.865441e-01_rb,& & 8.858857e-01_rb,8.850412e-01_rb,8.840686e-01_rb,8.830263e-01_rb,8.819726e-01_rb,& & 8.809658e-01_rb,8.800642e-01_rb,8.793260e-01_rb,8.788099e-01_rb,8.785737e-01_rb,& & 8.786758e-01_rb,8.791746e-01_rb,8.801283e-01_rb,8.815955e-01_rb,8.836340e-01_rb,& & 8.863024e-01_rb,8.896592e-01_rb,8.9376e-01_rb /) asyliq1(:, 21) = (/ & & 7.885899e-01_rb,7.937172e-01_rb,8.020658e-01_rb,8.123971e-01_rb,8.235502e-01_rb,& & 8.343776e-01_rb,8.437336e-01_rb,8.504711e-01_rb,8.534421e-01_rb,8.514978e-01_rb,& & 8.238888e-01_rb,8.417463e-01_rb,8.552057e-01_rb,8.647853e-01_rb,8.710038e-01_rb,& & 8.743798e-01_rb,8.754319e-01_rb,8.746786e-01_rb,8.726386e-01_rb,8.698303e-01_rb,& & 8.667724e-01_rb,8.639836e-01_rb,8.619823e-01_rb,8.612870e-01_rb,8.624165e-01_rb,& & 8.658893e-01_rb,8.722241e-01_rb,8.819394e-01_rb,8.620216e-01_rb,8.671239e-01_rb,& & 8.713983e-01_rb,8.749032e-01_rb,8.776970e-01_rb,8.798385e-01_rb,8.813860e-01_rb,& & 8.823980e-01_rb,8.829332e-01_rb,8.830500e-01_rb,8.828068e-01_rb,8.822623e-01_rb,& & 8.814750e-01_rb,8.805031e-01_rb,8.794056e-01_rb,8.782407e-01_rb,8.770672e-01_rb,& & 8.759432e-01_rb,8.749275e-01_rb,8.740784e-01_rb,8.734547e-01_rb,8.731146e-01_rb,& & 8.731170e-01_rb,8.735199e-01_rb,8.743823e-01_rb,8.757625e-01_rb,8.777191e-01_rb,& & 8.803105e-01_rb,8.835953e-01_rb,8.8763e-01_rb /) asyliq1(:, 22) = (/ & & 7.811516e-01_rb,7.962229e-01_rb,8.096199e-01_rb,8.212996e-01_rb,8.312212e-01_rb,& & 8.393430e-01_rb,8.456236e-01_rb,8.500214e-01_rb,8.524950e-01_rb,8.530031e-01_rb,& & 8.251485e-01_rb,8.429043e-01_rb,8.562461e-01_rb,8.656954e-01_rb,8.717737e-01_rb,& & 8.750020e-01_rb,8.759022e-01_rb,8.749953e-01_rb,8.728027e-01_rb,8.698461e-01_rb,& & 8.666466e-01_rb,8.637257e-01_rb,8.616047e-01_rb,8.608051e-01_rb,8.618483e-01_rb,& & 8.652557e-01_rb,8.715487e-01_rb,8.812485e-01_rb,8.611645e-01_rb,8.662052e-01_rb,& & 8.704173e-01_rb,8.738594e-01_rb,8.765901e-01_rb,8.786678e-01_rb,8.801517e-01_rb,& & 8.810999e-01_rb,8.815713e-01_rb,8.816246e-01_rb,8.813185e-01_rb,8.807114e-01_rb,& & 8.798621e-01_rb,8.788290e-01_rb,8.776713e-01_rb,8.764470e-01_rb,8.752152e-01_rb,& & 8.740343e-01_rb,8.729631e-01_rb,8.720602e-01_rb,8.713842e-01_rb,8.709936e-01_rb,& & 8.709475e-01_rb,8.713041e-01_rb,8.721221e-01_rb,8.734602e-01_rb,8.753774e-01_rb,& & 8.779319e-01_rb,8.811825e-01_rb,8.8519e-01_rb /) asyliq1(:, 23) = (/ & & 7.865744e-01_rb,8.093340e-01_rb,8.257596e-01_rb,8.369940e-01_rb,8.441574e-01_rb,& & 8.483602e-01_rb,8.507096e-01_rb,8.523139e-01_rb,8.542834e-01_rb,8.577321e-01_rb,& & 8.288960e-01_rb,8.465308e-01_rb,8.597175e-01_rb,8.689830e-01_rb,8.748542e-01_rb,& & 8.778584e-01_rb,8.785222e-01_rb,8.773728e-01_rb,8.749370e-01_rb,8.717419e-01_rb,& & 8.683145e-01_rb,8.651816e-01_rb,8.628704e-01_rb,8.619077e-01_rb,8.628205e-01_rb,& & 8.661356e-01_rb,8.723803e-01_rb,8.820815e-01_rb,8.616715e-01_rb,8.666389e-01_rb,& & 8.707753e-01_rb,8.741398e-01_rb,8.767912e-01_rb,8.787885e-01_rb,8.801908e-01_rb,& & 8.810570e-01_rb,8.814460e-01_rb,8.814167e-01_rb,8.810283e-01_rb,8.803395e-01_rb,& & 8.794095e-01_rb,8.782971e-01_rb,8.770613e-01_rb,8.757610e-01_rb,8.744553e-01_rb,& & 8.732031e-01_rb,8.720634e-01_rb,8.710951e-01_rb,8.703572e-01_rb,8.699086e-01_rb,& & 8.698084e-01_rb,8.701155e-01_rb,8.708887e-01_rb,8.721872e-01_rb,8.740698e-01_rb,& & 8.765957e-01_rb,8.798235e-01_rb,8.8381e-01_rb /) asyliq1(:, 24) = (/ & & 8.069513e-01_rb,8.262939e-01_rb,8.398241e-01_rb,8.486352e-01_rb,8.538213e-01_rb,& & 8.564743e-01_rb,8.576854e-01_rb,8.585455e-01_rb,8.601452e-01_rb,8.635755e-01_rb,& & 8.337383e-01_rb,8.512655e-01_rb,8.643049e-01_rb,8.733896e-01_rb,8.790535e-01_rb,& & 8.818295e-01_rb,8.822518e-01_rb,8.808533e-01_rb,8.781676e-01_rb,8.747284e-01_rb,& & 8.710690e-01_rb,8.677229e-01_rb,8.652236e-01_rb,8.641047e-01_rb,8.648993e-01_rb,& & 8.681413e-01_rb,8.743640e-01_rb,8.841007e-01_rb,8.633558e-01_rb,8.682719e-01_rb,& & 8.723543e-01_rb,8.756621e-01_rb,8.782547e-01_rb,8.801915e-01_rb,8.815318e-01_rb,& & 8.823347e-01_rb,8.826598e-01_rb,8.825663e-01_rb,8.821135e-01_rb,8.813608e-01_rb,& & 8.803674e-01_rb,8.791928e-01_rb,8.778960e-01_rb,8.765366e-01_rb,8.751738e-01_rb,& & 8.738670e-01_rb,8.726755e-01_rb,8.716585e-01_rb,8.708755e-01_rb,8.703856e-01_rb,& & 8.702483e-01_rb,8.705229e-01_rb,8.712687e-01_rb,8.725448e-01_rb,8.744109e-01_rb,& & 8.769260e-01_rb,8.801496e-01_rb,8.8414e-01_rb /) asyliq1(:, 25) = (/ & & 8.252182e-01_rb,8.379244e-01_rb,8.471709e-01_rb,8.535760e-01_rb,8.577540e-01_rb,& & 8.603183e-01_rb,8.618820e-01_rb,8.630578e-01_rb,8.644587e-01_rb,8.666970e-01_rb,& & 8.362159e-01_rb,8.536817e-01_rb,8.666387e-01_rb,8.756240e-01_rb,8.811746e-01_rb,& & 8.838273e-01_rb,8.841191e-01_rb,8.825871e-01_rb,8.797681e-01_rb,8.761992e-01_rb,& & 8.724174e-01_rb,8.689593e-01_rb,8.663623e-01_rb,8.651632e-01_rb,8.658988e-01_rb,& & 8.691064e-01_rb,8.753226e-01_rb,8.850847e-01_rb,8.641620e-01_rb,8.690500e-01_rb,& & 8.731026e-01_rb,8.763795e-01_rb,8.789400e-01_rb,8.808438e-01_rb,8.821503e-01_rb,& & 8.829191e-01_rb,8.832095e-01_rb,8.830813e-01_rb,8.825938e-01_rb,8.818064e-01_rb,& & 8.807787e-01_rb,8.795704e-01_rb,8.782408e-01_rb,8.768493e-01_rb,8.754557e-01_rb,& & 8.741193e-01_rb,8.728995e-01_rb,8.718561e-01_rb,8.710484e-01_rb,8.705360e-01_rb,& & 8.703782e-01_rb,8.706347e-01_rb,8.713650e-01_rb,8.726285e-01_rb,8.744849e-01_rb,& & 8.769933e-01_rb,8.802136e-01_rb,8.8421e-01_rb /) asyliq1(:, 26) = (/ & & 8.370583e-01_rb,8.467920e-01_rb,8.537769e-01_rb,8.585136e-01_rb,8.615034e-01_rb,& & 8.632474e-01_rb,8.642468e-01_rb,8.650026e-01_rb,8.660161e-01_rb,8.677882e-01_rb,& & 8.369760e-01_rb,8.543821e-01_rb,8.672699e-01_rb,8.761782e-01_rb,8.816454e-01_rb,& & 8.842103e-01_rb,8.844114e-01_rb,8.827872e-01_rb,8.798766e-01_rb,8.762179e-01_rb,& & 8.723500e-01_rb,8.688112e-01_rb,8.661403e-01_rb,8.648758e-01_rb,8.655563e-01_rb,& & 8.687206e-01_rb,8.749072e-01_rb,8.846546e-01_rb,8.636289e-01_rb,8.684849e-01_rb,& & 8.725054e-01_rb,8.757501e-01_rb,8.782785e-01_rb,8.801503e-01_rb,8.814249e-01_rb,& & 8.821620e-01_rb,8.824211e-01_rb,8.822620e-01_rb,8.817440e-01_rb,8.809268e-01_rb,& & 8.798699e-01_rb,8.786330e-01_rb,8.772756e-01_rb,8.758572e-01_rb,8.744374e-01_rb,& & 8.730760e-01_rb,8.718323e-01_rb,8.707660e-01_rb,8.699366e-01_rb,8.694039e-01_rb,& & 8.692271e-01_rb,8.694661e-01_rb,8.701803e-01_rb,8.714293e-01_rb,8.732727e-01_rb,& & 8.757702e-01_rb,8.789811e-01_rb,8.8297e-01_rb /) asyliq1(:, 27) = (/ & & 8.430819e-01_rb,8.510060e-01_rb,8.567270e-01_rb,8.606533e-01_rb,8.631934e-01_rb,& & 8.647554e-01_rb,8.657471e-01_rb,8.665760e-01_rb,8.676496e-01_rb,8.693754e-01_rb,& & 8.384298e-01_rb,8.557913e-01_rb,8.686214e-01_rb,8.774605e-01_rb,8.828495e-01_rb,& & 8.853287e-01_rb,8.854393e-01_rb,8.837215e-01_rb,8.807161e-01_rb,8.769639e-01_rb,& & 8.730053e-01_rb,8.693812e-01_rb,8.666321e-01_rb,8.652988e-01_rb,8.659219e-01_rb,& & 8.690419e-01_rb,8.751999e-01_rb,8.849360e-01_rb,8.638013e-01_rb,8.686371e-01_rb,& & 8.726369e-01_rb,8.758605e-01_rb,8.783674e-01_rb,8.802176e-01_rb,8.814705e-01_rb,& & 8.821859e-01_rb,8.824234e-01_rb,8.822429e-01_rb,8.817038e-01_rb,8.808658e-01_rb,& & 8.797887e-01_rb,8.785323e-01_rb,8.771560e-01_rb,8.757196e-01_rb,8.742828e-01_rb,& & 8.729052e-01_rb,8.716467e-01_rb,8.705666e-01_rb,8.697250e-01_rb,8.691812e-01_rb,& & 8.689950e-01_rb,8.692264e-01_rb,8.699346e-01_rb,8.711795e-01_rb,8.730209e-01_rb,& & 8.755181e-01_rb,8.787312e-01_rb,8.8272e-01_rb /) asyliq1(:, 28) = (/ & & 8.452284e-01_rb,8.522700e-01_rb,8.572973e-01_rb,8.607031e-01_rb,8.628802e-01_rb,& & 8.642215e-01_rb,8.651198e-01_rb,8.659679e-01_rb,8.671588e-01_rb,8.690853e-01_rb,& & 8.383803e-01_rb,8.557485e-01_rb,8.685851e-01_rb,8.774303e-01_rb,8.828245e-01_rb,& & 8.853077e-01_rb,8.854207e-01_rb,8.837034e-01_rb,8.806962e-01_rb,8.769398e-01_rb,& & 8.729740e-01_rb,8.693393e-01_rb,8.665761e-01_rb,8.652247e-01_rb,8.658253e-01_rb,& & 8.689182e-01_rb,8.750438e-01_rb,8.847424e-01_rb,8.636140e-01_rb,8.684449e-01_rb,& & 8.724400e-01_rb,8.756589e-01_rb,8.781613e-01_rb,8.800072e-01_rb,8.812559e-01_rb,& & 8.819671e-01_rb,8.822007e-01_rb,8.820165e-01_rb,8.814737e-01_rb,8.806322e-01_rb,& & 8.795518e-01_rb,8.782923e-01_rb,8.769129e-01_rb,8.754737e-01_rb,8.740342e-01_rb,& & 8.726542e-01_rb,8.713934e-01_rb,8.703111e-01_rb,8.694677e-01_rb,8.689222e-01_rb,& & 8.687344e-01_rb,8.689646e-01_rb,8.696715e-01_rb,8.709156e-01_rb,8.727563e-01_rb,& & 8.752531e-01_rb,8.784659e-01_rb,8.8245e-01_rb /) asyliq1(:, 29) = (/ & & 7.800869e-01_rb,8.091120e-01_rb,8.325369e-01_rb,8.466266e-01_rb,8.515495e-01_rb,& & 8.499371e-01_rb,8.456203e-01_rb,8.430521e-01_rb,8.470286e-01_rb,8.625431e-01_rb,& & 8.402261e-01_rb,8.610822e-01_rb,8.776608e-01_rb,8.904485e-01_rb,8.999294e-01_rb,& & 9.065860e-01_rb,9.108995e-01_rb,9.133503e-01_rb,9.144187e-01_rb,9.145855e-01_rb,& & 9.143320e-01_rb,9.141402e-01_rb,9.144933e-01_rb,9.158754e-01_rb,9.187716e-01_rb,& & 9.236677e-01_rb,9.310503e-01_rb,9.414058e-01_rb,9.239108e-01_rb,9.300719e-01_rb,& & 9.353612e-01_rb,9.398378e-01_rb,9.435609e-01_rb,9.465895e-01_rb,9.489829e-01_rb,& & 9.508000e-01_rb,9.521002e-01_rb,9.529424e-01_rb,9.533860e-01_rb,9.534902e-01_rb,& & 9.533143e-01_rb,9.529177e-01_rb,9.523596e-01_rb,9.516997e-01_rb,9.509973e-01_rb,& & 9.503121e-01_rb,9.497037e-01_rb,9.492317e-01_rb,9.489558e-01_rb,9.489356e-01_rb,& & 9.492311e-01_rb,9.499019e-01_rb,9.510077e-01_rb,9.526084e-01_rb,9.547636e-01_rb,& & 9.575331e-01_rb,9.609766e-01_rb,9.6515e-01_rb /) ! Spherical Ice Particle Parameterization ! extinction units (ext coef/iwc): [(m^-1)/(g m^-3)] extice2(:, 16) = (/ & ! band 16 & 4.101824e-01_rb,2.435514e-01_rb,1.713697e-01_rb,1.314865e-01_rb,1.063406e-01_rb,& & 8.910701e-02_rb,7.659480e-02_rb,6.711784e-02_rb,5.970353e-02_rb,5.375249e-02_rb,& & 4.887577e-02_rb,4.481025e-02_rb,4.137171e-02_rb,3.842744e-02_rb,3.587948e-02_rb,& & 3.365396e-02_rb,3.169419e-02_rb,2.995593e-02_rb,2.840419e-02_rb,2.701091e-02_rb,& & 2.575336e-02_rb,2.461293e-02_rb,2.357423e-02_rb,2.262443e-02_rb,2.175276e-02_rb,& & 2.095012e-02_rb,2.020875e-02_rb,1.952199e-02_rb,1.888412e-02_rb,1.829018e-02_rb,& & 1.773586e-02_rb,1.721738e-02_rb,1.673144e-02_rb,1.627510e-02_rb,1.584579e-02_rb,& & 1.544122e-02_rb,1.505934e-02_rb,1.469833e-02_rb,1.435654e-02_rb,1.403251e-02_rb,& & 1.372492e-02_rb,1.343255e-02_rb,1.315433e-02_rb /) extice2(:, 17) = (/ & ! band 17 & 3.836650e-01_rb,2.304055e-01_rb,1.637265e-01_rb,1.266681e-01_rb,1.031602e-01_rb,& & 8.695191e-02_rb,7.511544e-02_rb,6.610009e-02_rb,5.900909e-02_rb,5.328833e-02_rb,& & 4.857728e-02_rb,4.463133e-02_rb,4.127880e-02_rb,3.839567e-02_rb,3.589013e-02_rb,& & 3.369280e-02_rb,3.175027e-02_rb,3.002079e-02_rb,2.847121e-02_rb,2.707493e-02_rb,& & 2.581031e-02_rb,2.465962e-02_rb,2.360815e-02_rb,2.264363e-02_rb,2.175571e-02_rb,& & 2.093563e-02_rb,2.017592e-02_rb,1.947015e-02_rb,1.881278e-02_rb,1.819901e-02_rb,& & 1.762463e-02_rb,1.708598e-02_rb,1.657982e-02_rb,1.610330e-02_rb,1.565390e-02_rb,& & 1.522937e-02_rb,1.482768e-02_rb,1.444706e-02_rb,1.408588e-02_rb,1.374270e-02_rb,& & 1.341619e-02_rb,1.310517e-02_rb,1.280857e-02_rb /) extice2(:, 18) = (/ & ! band 18 & 4.152673e-01_rb,2.436816e-01_rb,1.702243e-01_rb,1.299704e-01_rb,1.047528e-01_rb,& & 8.756039e-02_rb,7.513327e-02_rb,6.575690e-02_rb,5.844616e-02_rb,5.259609e-02_rb,& & 4.781531e-02_rb,4.383980e-02_rb,4.048517e-02_rb,3.761891e-02_rb,3.514342e-02_rb,& & 3.298525e-02_rb,3.108814e-02_rb,2.940825e-02_rb,2.791096e-02_rb,2.656858e-02_rb,& & 2.535869e-02_rb,2.426297e-02_rb,2.326627e-02_rb,2.235602e-02_rb,2.152164e-02_rb,& & 2.075420e-02_rb,2.004613e-02_rb,1.939091e-02_rb,1.878296e-02_rb,1.821744e-02_rb,& & 1.769015e-02_rb,1.719741e-02_rb,1.673600e-02_rb,1.630308e-02_rb,1.589615e-02_rb,& & 1.551298e-02_rb,1.515159e-02_rb,1.481021e-02_rb,1.448726e-02_rb,1.418131e-02_rb,& & 1.389109e-02_rb,1.361544e-02_rb,1.335330e-02_rb /) extice2(:, 19) = (/ & ! band 19 & 3.873250e-01_rb,2.331609e-01_rb,1.655002e-01_rb,1.277753e-01_rb,1.038247e-01_rb,& & 8.731780e-02_rb,7.527638e-02_rb,6.611873e-02_rb,5.892850e-02_rb,5.313885e-02_rb,& & 4.838068e-02_rb,4.440356e-02_rb,4.103167e-02_rb,3.813804e-02_rb,3.562870e-02_rb,& & 3.343269e-02_rb,3.149539e-02_rb,2.977414e-02_rb,2.823510e-02_rb,2.685112e-02_rb,& & 2.560015e-02_rb,2.446411e-02_rb,2.342805e-02_rb,2.247948e-02_rb,2.160789e-02_rb,& & 2.080438e-02_rb,2.006139e-02_rb,1.937238e-02_rb,1.873177e-02_rb,1.813469e-02_rb,& & 1.757689e-02_rb,1.705468e-02_rb,1.656479e-02_rb,1.610435e-02_rb,1.567081e-02_rb,& & 1.526192e-02_rb,1.487565e-02_rb,1.451020e-02_rb,1.416396e-02_rb,1.383546e-02_rb,& & 1.352339e-02_rb,1.322657e-02_rb,1.294392e-02_rb /) extice2(:, 20) = (/ & ! band 20 & 3.784280e-01_rb,2.291396e-01_rb,1.632551e-01_rb,1.263775e-01_rb,1.028944e-01_rb,& & 8.666975e-02_rb,7.480952e-02_rb,6.577335e-02_rb,5.866714e-02_rb,5.293694e-02_rb,& & 4.822153e-02_rb,4.427547e-02_rb,4.092626e-02_rb,3.804918e-02_rb,3.555184e-02_rb,& & 3.336440e-02_rb,3.143307e-02_rb,2.971577e-02_rb,2.817912e-02_rb,2.679632e-02_rb,& & 2.554558e-02_rb,2.440903e-02_rb,2.337187e-02_rb,2.242173e-02_rb,2.154821e-02_rb,& & 2.074249e-02_rb,1.999706e-02_rb,1.930546e-02_rb,1.866212e-02_rb,1.806221e-02_rb,& & 1.750152e-02_rb,1.697637e-02_rb,1.648352e-02_rb,1.602010e-02_rb,1.558358e-02_rb,& & 1.517172e-02_rb,1.478250e-02_rb,1.441413e-02_rb,1.406498e-02_rb,1.373362e-02_rb,& & 1.341872e-02_rb,1.311911e-02_rb,1.283371e-02_rb /) extice2(:, 21) = (/ & ! band 21 & 3.719909e-01_rb,2.259490e-01_rb,1.613144e-01_rb,1.250648e-01_rb,1.019462e-01_rb,& & 8.595358e-02_rb,7.425064e-02_rb,6.532618e-02_rb,5.830218e-02_rb,5.263421e-02_rb,& & 4.796697e-02_rb,4.405891e-02_rb,4.074013e-02_rb,3.788776e-02_rb,3.541071e-02_rb,& & 3.324008e-02_rb,3.132280e-02_rb,2.961733e-02_rb,2.809071e-02_rb,2.671645e-02_rb,& & 2.547302e-02_rb,2.434276e-02_rb,2.331102e-02_rb,2.236558e-02_rb,2.149614e-02_rb,& & 2.069397e-02_rb,1.995163e-02_rb,1.926272e-02_rb,1.862174e-02_rb,1.802389e-02_rb,& & 1.746500e-02_rb,1.694142e-02_rb,1.644994e-02_rb,1.598772e-02_rb,1.555225e-02_rb,& & 1.514129e-02_rb,1.475286e-02_rb,1.438515e-02_rb,1.403659e-02_rb,1.370572e-02_rb,& & 1.339124e-02_rb,1.309197e-02_rb,1.280685e-02_rb /) extice2(:, 22) = (/ & ! band 22 & 3.713158e-01_rb,2.253816e-01_rb,1.608461e-01_rb,1.246718e-01_rb,1.016109e-01_rb,& & 8.566332e-02_rb,7.399666e-02_rb,6.510199e-02_rb,5.810290e-02_rb,5.245608e-02_rb,& & 4.780702e-02_rb,4.391478e-02_rb,4.060989e-02_rb,3.776982e-02_rb,3.530374e-02_rb,& & 3.314296e-02_rb,3.123458e-02_rb,2.953719e-02_rb,2.801794e-02_rb,2.665043e-02_rb,& & 2.541321e-02_rb,2.428868e-02_rb,2.326224e-02_rb,2.232173e-02_rb,2.145688e-02_rb,& & 2.065899e-02_rb,1.992067e-02_rb,1.923552e-02_rb,1.859808e-02_rb,1.800356e-02_rb,& & 1.744782e-02_rb,1.692721e-02_rb,1.643855e-02_rb,1.597900e-02_rb,1.554606e-02_rb,& & 1.513751e-02_rb,1.475137e-02_rb,1.438586e-02_rb,1.403938e-02_rb,1.371050e-02_rb,& & 1.339793e-02_rb,1.310050e-02_rb,1.281713e-02_rb /) extice2(:, 23) = (/ & ! band 23 & 3.605883e-01_rb,2.204388e-01_rb,1.580431e-01_rb,1.229033e-01_rb,1.004203e-01_rb,& & 8.482616e-02_rb,7.338941e-02_rb,6.465105e-02_rb,5.776176e-02_rb,5.219398e-02_rb,& & 4.760288e-02_rb,4.375369e-02_rb,4.048111e-02_rb,3.766539e-02_rb,3.521771e-02_rb,& & 3.307079e-02_rb,3.117277e-02_rb,2.948303e-02_rb,2.796929e-02_rb,2.660560e-02_rb,& & 2.537086e-02_rb,2.424772e-02_rb,2.322182e-02_rb,2.228114e-02_rb,2.141556e-02_rb,& & 2.061649e-02_rb,1.987661e-02_rb,1.918962e-02_rb,1.855009e-02_rb,1.795330e-02_rb,& & 1.739514e-02_rb,1.687199e-02_rb,1.638069e-02_rb,1.591845e-02_rb,1.548276e-02_rb,& & 1.507143e-02_rb,1.468249e-02_rb,1.431416e-02_rb,1.396486e-02_rb,1.363318e-02_rb,& & 1.331781e-02_rb,1.301759e-02_rb,1.273147e-02_rb /) extice2(:, 24) = (/ & ! band 24 & 3.527890e-01_rb,2.168469e-01_rb,1.560090e-01_rb,1.216216e-01_rb,9.955787e-02_rb,& & 8.421942e-02_rb,7.294827e-02_rb,6.432192e-02_rb,5.751081e-02_rb,5.199888e-02_rb,& & 4.744835e-02_rb,4.362899e-02_rb,4.037847e-02_rb,3.757910e-02_rb,3.514351e-02_rb,& & 3.300546e-02_rb,3.111382e-02_rb,2.942853e-02_rb,2.791775e-02_rb,2.655584e-02_rb,& & 2.532195e-02_rb,2.419892e-02_rb,2.317255e-02_rb,2.223092e-02_rb,2.136402e-02_rb,& & 2.056334e-02_rb,1.982160e-02_rb,1.913258e-02_rb,1.849087e-02_rb,1.789178e-02_rb,& & 1.733124e-02_rb,1.680565e-02_rb,1.631187e-02_rb,1.584711e-02_rb,1.540889e-02_rb,& & 1.499502e-02_rb,1.460354e-02_rb,1.423269e-02_rb,1.388088e-02_rb,1.354670e-02_rb,& & 1.322887e-02_rb,1.292620e-02_rb,1.263767e-02_rb /) extice2(:, 25) = (/ & ! band 25 & 3.477874e-01_rb,2.143515e-01_rb,1.544887e-01_rb,1.205942e-01_rb,9.881779e-02_rb,& & 8.366261e-02_rb,7.251586e-02_rb,6.397790e-02_rb,5.723183e-02_rb,5.176908e-02_rb,& & 4.725658e-02_rb,4.346715e-02_rb,4.024055e-02_rb,3.746055e-02_rb,3.504080e-02_rb,& & 3.291583e-02_rb,3.103507e-02_rb,2.935891e-02_rb,2.785582e-02_rb,2.650042e-02_rb,& & 2.527206e-02_rb,2.415376e-02_rb,2.313142e-02_rb,2.219326e-02_rb,2.132934e-02_rb,& & 2.053122e-02_rb,1.979169e-02_rb,1.910456e-02_rb,1.846448e-02_rb,1.786680e-02_rb,& & 1.730745e-02_rb,1.678289e-02_rb,1.628998e-02_rb,1.582595e-02_rb,1.538835e-02_rb,& & 1.497499e-02_rb,1.458393e-02_rb,1.421341e-02_rb,1.386187e-02_rb,1.352788e-02_rb,& & 1.321019e-02_rb,1.290762e-02_rb,1.261913e-02_rb /) extice2(:, 26) = (/ & ! band 26 & 3.453721e-01_rb,2.130744e-01_rb,1.536698e-01_rb,1.200140e-01_rb,9.838078e-02_rb,& & 8.331940e-02_rb,7.223803e-02_rb,6.374775e-02_rb,5.703770e-02_rb,5.160290e-02_rb,& & 4.711259e-02_rb,4.334110e-02_rb,4.012923e-02_rb,3.736150e-02_rb,3.495208e-02_rb,& & 3.283589e-02_rb,3.096267e-02_rb,2.929302e-02_rb,2.779560e-02_rb,2.644517e-02_rb,& & 2.522119e-02_rb,2.410677e-02_rb,2.308788e-02_rb,2.215281e-02_rb,2.129165e-02_rb,& & 2.049602e-02_rb,1.975874e-02_rb,1.907365e-02_rb,1.843542e-02_rb,1.783943e-02_rb,& & 1.728162e-02_rb,1.675847e-02_rb,1.626685e-02_rb,1.580401e-02_rb,1.536750e-02_rb,& & 1.495515e-02_rb,1.456502e-02_rb,1.419537e-02_rb,1.384463e-02_rb,1.351139e-02_rb,& & 1.319438e-02_rb,1.289246e-02_rb,1.260456e-02_rb /) extice2(:, 27) = (/ & ! band 27 & 3.417883e-01_rb,2.113379e-01_rb,1.526395e-01_rb,1.193347e-01_rb,9.790253e-02_rb,& & 8.296715e-02_rb,7.196979e-02_rb,6.353806e-02_rb,5.687024e-02_rb,5.146670e-02_rb,& & 4.700001e-02_rb,4.324667e-02_rb,4.004894e-02_rb,3.729233e-02_rb,3.489172e-02_rb,& & 3.278257e-02_rb,3.091499e-02_rb,2.924987e-02_rb,2.775609e-02_rb,2.640859e-02_rb,& & 2.518695e-02_rb,2.407439e-02_rb,2.305697e-02_rb,2.212303e-02_rb,2.126273e-02_rb,& & 2.046774e-02_rb,1.973090e-02_rb,1.904610e-02_rb,1.840801e-02_rb,1.781204e-02_rb,& & 1.725417e-02_rb,1.673086e-02_rb,1.623902e-02_rb,1.577590e-02_rb,1.533906e-02_rb,& & 1.492634e-02_rb,1.453580e-02_rb,1.416571e-02_rb,1.381450e-02_rb,1.348078e-02_rb,& & 1.316327e-02_rb,1.286082e-02_rb,1.257240e-02_rb /) extice2(:, 28) = (/ & ! band 28 & 3.416111e-01_rb,2.114124e-01_rb,1.527734e-01_rb,1.194809e-01_rb,9.804612e-02_rb,& & 8.310287e-02_rb,7.209595e-02_rb,6.365442e-02_rb,5.697710e-02_rb,5.156460e-02_rb,& & 4.708957e-02_rb,4.332850e-02_rb,4.012361e-02_rb,3.736037e-02_rb,3.495364e-02_rb,& & 3.283879e-02_rb,3.096593e-02_rb,2.929589e-02_rb,2.779751e-02_rb,2.644571e-02_rb,& & 2.522004e-02_rb,2.410369e-02_rb,2.308271e-02_rb,2.214542e-02_rb,2.128195e-02_rb,& & 2.048396e-02_rb,1.974429e-02_rb,1.905679e-02_rb,1.841614e-02_rb,1.781774e-02_rb,& & 1.725754e-02_rb,1.673203e-02_rb,1.623807e-02_rb,1.577293e-02_rb,1.533416e-02_rb,& & 1.491958e-02_rb,1.452727e-02_rb,1.415547e-02_rb,1.380262e-02_rb,1.346732e-02_rb,& & 1.314830e-02_rb,1.284439e-02_rb,1.255456e-02_rb /) extice2(:, 29) = (/ & ! band 29 & 4.196611e-01_rb,2.493642e-01_rb,1.761261e-01_rb,1.357197e-01_rb,1.102161e-01_rb,& & 9.269376e-02_rb,7.992985e-02_rb,7.022538e-02_rb,6.260168e-02_rb,5.645603e-02_rb,& & 5.139732e-02_rb,4.716088e-02_rb,4.356133e-02_rb,4.046498e-02_rb,3.777303e-02_rb,& & 3.541094e-02_rb,3.332137e-02_rb,3.145954e-02_rb,2.978998e-02_rb,2.828419e-02_rb,& & 2.691905e-02_rb,2.567559e-02_rb,2.453811e-02_rb,2.349350e-02_rb,2.253072e-02_rb,& & 2.164042e-02_rb,2.081464e-02_rb,2.004652e-02_rb,1.933015e-02_rb,1.866041e-02_rb,& & 1.803283e-02_rb,1.744348e-02_rb,1.688894e-02_rb,1.636616e-02_rb,1.587244e-02_rb,& & 1.540539e-02_rb,1.496287e-02_rb,1.454295e-02_rb,1.414392e-02_rb,1.376423e-02_rb,& & 1.340247e-02_rb,1.305739e-02_rb,1.272784e-02_rb /) ! single-scattering albedo: unitless ssaice2(:, 16) = (/ & ! band 16 & 6.630615e-01_rb,6.451169e-01_rb,6.333696e-01_rb,6.246927e-01_rb,6.178420e-01_rb,& & 6.121976e-01_rb,6.074069e-01_rb,6.032505e-01_rb,5.995830e-01_rb,5.963030e-01_rb,& & 5.933372e-01_rb,5.906311e-01_rb,5.881427e-01_rb,5.858395e-01_rb,5.836955e-01_rb,& & 5.816896e-01_rb,5.798046e-01_rb,5.780264e-01_rb,5.763429e-01_rb,5.747441e-01_rb,& & 5.732213e-01_rb,5.717672e-01_rb,5.703754e-01_rb,5.690403e-01_rb,5.677571e-01_rb,& & 5.665215e-01_rb,5.653297e-01_rb,5.641782e-01_rb,5.630643e-01_rb,5.619850e-01_rb,& & 5.609381e-01_rb,5.599214e-01_rb,5.589328e-01_rb,5.579707e-01_rb,5.570333e-01_rb,& & 5.561193e-01_rb,5.552272e-01_rb,5.543558e-01_rb,5.535041e-01_rb,5.526708e-01_rb,& & 5.518551e-01_rb,5.510561e-01_rb,5.502729e-01_rb /) ssaice2(:, 17) = (/ & ! band 17 & 7.689749e-01_rb,7.398171e-01_rb,7.205819e-01_rb,7.065690e-01_rb,6.956928e-01_rb,& & 6.868989e-01_rb,6.795813e-01_rb,6.733606e-01_rb,6.679838e-01_rb,6.632742e-01_rb,& & 6.591036e-01_rb,6.553766e-01_rb,6.520197e-01_rb,6.489757e-01_rb,6.461991e-01_rb,& & 6.436531e-01_rb,6.413075e-01_rb,6.391375e-01_rb,6.371221e-01_rb,6.352438e-01_rb,& & 6.334876e-01_rb,6.318406e-01_rb,6.302918e-01_rb,6.288315e-01_rb,6.274512e-01_rb,& & 6.261436e-01_rb,6.249022e-01_rb,6.237211e-01_rb,6.225953e-01_rb,6.215201e-01_rb,& & 6.204914e-01_rb,6.195055e-01_rb,6.185592e-01_rb,6.176492e-01_rb,6.167730e-01_rb,& & 6.159280e-01_rb,6.151120e-01_rb,6.143228e-01_rb,6.135587e-01_rb,6.128177e-01_rb,& & 6.120984e-01_rb,6.113993e-01_rb,6.107189e-01_rb /) ssaice2(:, 18) = (/ & ! band 18 & 9.956167e-01_rb,9.814770e-01_rb,9.716104e-01_rb,9.639746e-01_rb,9.577179e-01_rb,& & 9.524010e-01_rb,9.477672e-01_rb,9.436527e-01_rb,9.399467e-01_rb,9.365708e-01_rb,& & 9.334672e-01_rb,9.305921e-01_rb,9.279118e-01_rb,9.253993e-01_rb,9.230330e-01_rb,& & 9.207954e-01_rb,9.186719e-01_rb,9.166501e-01_rb,9.147199e-01_rb,9.128722e-01_rb,& & 9.110997e-01_rb,9.093956e-01_rb,9.077544e-01_rb,9.061708e-01_rb,9.046406e-01_rb,& & 9.031598e-01_rb,9.017248e-01_rb,9.003326e-01_rb,8.989804e-01_rb,8.976655e-01_rb,& & 8.963857e-01_rb,8.951389e-01_rb,8.939233e-01_rb,8.927370e-01_rb,8.915785e-01_rb,& & 8.904464e-01_rb,8.893392e-01_rb,8.882559e-01_rb,8.871951e-01_rb,8.861559e-01_rb,& & 8.851373e-01_rb,8.841383e-01_rb,8.831581e-01_rb /) ssaice2(:, 19) = (/ & ! band 19 & 9.723177e-01_rb,9.452119e-01_rb,9.267592e-01_rb,9.127393e-01_rb,9.014238e-01_rb,& & 8.919334e-01_rb,8.837584e-01_rb,8.765773e-01_rb,8.701736e-01_rb,8.643950e-01_rb,& & 8.591299e-01_rb,8.542942e-01_rb,8.498230e-01_rb,8.456651e-01_rb,8.417794e-01_rb,& & 8.381324e-01_rb,8.346964e-01_rb,8.314484e-01_rb,8.283687e-01_rb,8.254408e-01_rb,& & 8.226505e-01_rb,8.199854e-01_rb,8.174348e-01_rb,8.149891e-01_rb,8.126403e-01_rb,& & 8.103808e-01_rb,8.082041e-01_rb,8.061044e-01_rb,8.040765e-01_rb,8.021156e-01_rb,& & 8.002174e-01_rb,7.983781e-01_rb,7.965941e-01_rb,7.948622e-01_rb,7.931795e-01_rb,& & 7.915432e-01_rb,7.899508e-01_rb,7.884002e-01_rb,7.868891e-01_rb,7.854156e-01_rb,& & 7.839779e-01_rb,7.825742e-01_rb,7.812031e-01_rb /) ssaice2(:, 20) = (/ & ! band 20 & 9.933294e-01_rb,9.860917e-01_rb,9.811564e-01_rb,9.774008e-01_rb,9.743652e-01_rb,& & 9.718155e-01_rb,9.696159e-01_rb,9.676810e-01_rb,9.659531e-01_rb,9.643915e-01_rb,& & 9.629667e-01_rb,9.616561e-01_rb,9.604426e-01_rb,9.593125e-01_rb,9.582548e-01_rb,& & 9.572607e-01_rb,9.563227e-01_rb,9.554347e-01_rb,9.545915e-01_rb,9.537888e-01_rb,& & 9.530226e-01_rb,9.522898e-01_rb,9.515874e-01_rb,9.509130e-01_rb,9.502643e-01_rb,& & 9.496394e-01_rb,9.490366e-01_rb,9.484542e-01_rb,9.478910e-01_rb,9.473456e-01_rb,& & 9.468169e-01_rb,9.463039e-01_rb,9.458056e-01_rb,9.453212e-01_rb,9.448499e-01_rb,& & 9.443910e-01_rb,9.439438e-01_rb,9.435077e-01_rb,9.430821e-01_rb,9.426666e-01_rb,& & 9.422607e-01_rb,9.418638e-01_rb,9.414756e-01_rb /) ssaice2(:, 21) = (/ & ! band 21 & 9.900787e-01_rb,9.828880e-01_rb,9.779258e-01_rb,9.741173e-01_rb,9.710184e-01_rb,& & 9.684012e-01_rb,9.661332e-01_rb,9.641301e-01_rb,9.623352e-01_rb,9.607083e-01_rb,& & 9.592198e-01_rb,9.578474e-01_rb,9.565739e-01_rb,9.553856e-01_rb,9.542715e-01_rb,& & 9.532226e-01_rb,9.522314e-01_rb,9.512919e-01_rb,9.503986e-01_rb,9.495472e-01_rb,& & 9.487337e-01_rb,9.479549e-01_rb,9.472077e-01_rb,9.464897e-01_rb,9.457985e-01_rb,& & 9.451322e-01_rb,9.444890e-01_rb,9.438673e-01_rb,9.432656e-01_rb,9.426826e-01_rb,& & 9.421173e-01_rb,9.415684e-01_rb,9.410351e-01_rb,9.405164e-01_rb,9.400115e-01_rb,& & 9.395198e-01_rb,9.390404e-01_rb,9.385728e-01_rb,9.381164e-01_rb,9.376707e-01_rb,& & 9.372350e-01_rb,9.368091e-01_rb,9.363923e-01_rb /) ssaice2(:, 22) = (/ & ! band 22 & 9.986793e-01_rb,9.985239e-01_rb,9.983911e-01_rb,9.982715e-01_rb,9.981606e-01_rb,& & 9.980562e-01_rb,9.979567e-01_rb,9.978613e-01_rb,9.977691e-01_rb,9.976798e-01_rb,& & 9.975929e-01_rb,9.975081e-01_rb,9.974251e-01_rb,9.973438e-01_rb,9.972640e-01_rb,& & 9.971855e-01_rb,9.971083e-01_rb,9.970322e-01_rb,9.969571e-01_rb,9.968830e-01_rb,& & 9.968099e-01_rb,9.967375e-01_rb,9.966660e-01_rb,9.965951e-01_rb,9.965250e-01_rb,& & 9.964555e-01_rb,9.963867e-01_rb,9.963185e-01_rb,9.962508e-01_rb,9.961836e-01_rb,& & 9.961170e-01_rb,9.960508e-01_rb,9.959851e-01_rb,9.959198e-01_rb,9.958550e-01_rb,& & 9.957906e-01_rb,9.957266e-01_rb,9.956629e-01_rb,9.955997e-01_rb,9.955367e-01_rb,& & 9.954742e-01_rb,9.954119e-01_rb,9.953500e-01_rb /) ssaice2(:, 23) = (/ & ! band 23 & 9.997944e-01_rb,9.997791e-01_rb,9.997664e-01_rb,9.997547e-01_rb,9.997436e-01_rb,& & 9.997327e-01_rb,9.997219e-01_rb,9.997110e-01_rb,9.996999e-01_rb,9.996886e-01_rb,& & 9.996771e-01_rb,9.996653e-01_rb,9.996533e-01_rb,9.996409e-01_rb,9.996282e-01_rb,& & 9.996152e-01_rb,9.996019e-01_rb,9.995883e-01_rb,9.995743e-01_rb,9.995599e-01_rb,& & 9.995453e-01_rb,9.995302e-01_rb,9.995149e-01_rb,9.994992e-01_rb,9.994831e-01_rb,& & 9.994667e-01_rb,9.994500e-01_rb,9.994329e-01_rb,9.994154e-01_rb,9.993976e-01_rb,& & 9.993795e-01_rb,9.993610e-01_rb,9.993422e-01_rb,9.993230e-01_rb,9.993035e-01_rb,& & 9.992837e-01_rb,9.992635e-01_rb,9.992429e-01_rb,9.992221e-01_rb,9.992008e-01_rb,& & 9.991793e-01_rb,9.991574e-01_rb,9.991352e-01_rb /) ssaice2(:, 24) = (/ & ! band 24 & 9.999949e-01_rb,9.999947e-01_rb,9.999943e-01_rb,9.999939e-01_rb,9.999934e-01_rb,& & 9.999927e-01_rb,9.999920e-01_rb,9.999913e-01_rb,9.999904e-01_rb,9.999895e-01_rb,& & 9.999885e-01_rb,9.999874e-01_rb,9.999863e-01_rb,9.999851e-01_rb,9.999838e-01_rb,& & 9.999824e-01_rb,9.999810e-01_rb,9.999795e-01_rb,9.999780e-01_rb,9.999764e-01_rb,& & 9.999747e-01_rb,9.999729e-01_rb,9.999711e-01_rb,9.999692e-01_rb,9.999673e-01_rb,& & 9.999653e-01_rb,9.999632e-01_rb,9.999611e-01_rb,9.999589e-01_rb,9.999566e-01_rb,& & 9.999543e-01_rb,9.999519e-01_rb,9.999495e-01_rb,9.999470e-01_rb,9.999444e-01_rb,& & 9.999418e-01_rb,9.999392e-01_rb,9.999364e-01_rb,9.999336e-01_rb,9.999308e-01_rb,& & 9.999279e-01_rb,9.999249e-01_rb,9.999219e-01_rb /) ssaice2(:, 25) = (/ & ! band 25 & 9.999997e-01_rb,9.999997e-01_rb,9.999997e-01_rb,9.999996e-01_rb,9.999996e-01_rb,& & 9.999995e-01_rb,9.999994e-01_rb,9.999993e-01_rb,9.999993e-01_rb,9.999992e-01_rb,& & 9.999991e-01_rb,9.999989e-01_rb,9.999988e-01_rb,9.999987e-01_rb,9.999986e-01_rb,& & 9.999984e-01_rb,9.999983e-01_rb,9.999981e-01_rb,9.999980e-01_rb,9.999978e-01_rb,& & 9.999976e-01_rb,9.999974e-01_rb,9.999972e-01_rb,9.999971e-01_rb,9.999969e-01_rb,& & 9.999966e-01_rb,9.999964e-01_rb,9.999962e-01_rb,9.999960e-01_rb,9.999957e-01_rb,& & 9.999955e-01_rb,9.999953e-01_rb,9.999950e-01_rb,9.999947e-01_rb,9.999945e-01_rb,& & 9.999942e-01_rb,9.999939e-01_rb,9.999936e-01_rb,9.999934e-01_rb,9.999931e-01_rb,& & 9.999928e-01_rb,9.999925e-01_rb,9.999921e-01_rb /) ssaice2(:, 26) = (/ & ! band 26 & 9.999997e-01_rb,9.999996e-01_rb,9.999996e-01_rb,9.999995e-01_rb,9.999994e-01_rb,& & 9.999993e-01_rb,9.999992e-01_rb,9.999991e-01_rb,9.999990e-01_rb,9.999989e-01_rb,& & 9.999987e-01_rb,9.999986e-01_rb,9.999984e-01_rb,9.999982e-01_rb,9.999980e-01_rb,& & 9.999978e-01_rb,9.999976e-01_rb,9.999974e-01_rb,9.999972e-01_rb,9.999970e-01_rb,& & 9.999967e-01_rb,9.999965e-01_rb,9.999962e-01_rb,9.999959e-01_rb,9.999956e-01_rb,& & 9.999954e-01_rb,9.999951e-01_rb,9.999947e-01_rb,9.999944e-01_rb,9.999941e-01_rb,& & 9.999938e-01_rb,9.999934e-01_rb,9.999931e-01_rb,9.999927e-01_rb,9.999923e-01_rb,& & 9.999920e-01_rb,9.999916e-01_rb,9.999912e-01_rb,9.999908e-01_rb,9.999904e-01_rb,& & 9.999899e-01_rb,9.999895e-01_rb,9.999891e-01_rb /) ssaice2(:, 27) = (/ & ! band 27 & 9.999987e-01_rb,9.999987e-01_rb,9.999985e-01_rb,9.999984e-01_rb,9.999982e-01_rb,& & 9.999980e-01_rb,9.999978e-01_rb,9.999976e-01_rb,9.999973e-01_rb,9.999970e-01_rb,& & 9.999967e-01_rb,9.999964e-01_rb,9.999960e-01_rb,9.999956e-01_rb,9.999952e-01_rb,& & 9.999948e-01_rb,9.999944e-01_rb,9.999939e-01_rb,9.999934e-01_rb,9.999929e-01_rb,& & 9.999924e-01_rb,9.999918e-01_rb,9.999913e-01_rb,9.999907e-01_rb,9.999901e-01_rb,& & 9.999894e-01_rb,9.999888e-01_rb,9.999881e-01_rb,9.999874e-01_rb,9.999867e-01_rb,& & 9.999860e-01_rb,9.999853e-01_rb,9.999845e-01_rb,9.999837e-01_rb,9.999829e-01_rb,& & 9.999821e-01_rb,9.999813e-01_rb,9.999804e-01_rb,9.999796e-01_rb,9.999787e-01_rb,& & 9.999778e-01_rb,9.999768e-01_rb,9.999759e-01_rb /) ssaice2(:, 28) = (/ & ! band 28 & 9.999989e-01_rb,9.999989e-01_rb,9.999987e-01_rb,9.999986e-01_rb,9.999984e-01_rb,& & 9.999982e-01_rb,9.999980e-01_rb,9.999978e-01_rb,9.999975e-01_rb,9.999972e-01_rb,& & 9.999969e-01_rb,9.999966e-01_rb,9.999962e-01_rb,9.999958e-01_rb,9.999954e-01_rb,& & 9.999950e-01_rb,9.999945e-01_rb,9.999941e-01_rb,9.999936e-01_rb,9.999931e-01_rb,& & 9.999925e-01_rb,9.999920e-01_rb,9.999914e-01_rb,9.999908e-01_rb,9.999902e-01_rb,& & 9.999896e-01_rb,9.999889e-01_rb,9.999883e-01_rb,9.999876e-01_rb,9.999869e-01_rb,& & 9.999861e-01_rb,9.999854e-01_rb,9.999846e-01_rb,9.999838e-01_rb,9.999830e-01_rb,& & 9.999822e-01_rb,9.999814e-01_rb,9.999805e-01_rb,9.999796e-01_rb,9.999787e-01_rb,& & 9.999778e-01_rb,9.999769e-01_rb,9.999759e-01_rb /) ssaice2(:, 29) = (/ & ! band 29 & 7.042143e-01_rb,6.691161e-01_rb,6.463240e-01_rb,6.296590e-01_rb,6.166381e-01_rb,& & 6.060183e-01_rb,5.970908e-01_rb,5.894144e-01_rb,5.826968e-01_rb,5.767343e-01_rb,& & 5.713804e-01_rb,5.665256e-01_rb,5.620867e-01_rb,5.579987e-01_rb,5.542101e-01_rb,& & 5.506794e-01_rb,5.473727e-01_rb,5.442620e-01_rb,5.413239e-01_rb,5.385389e-01_rb,& & 5.358901e-01_rb,5.333633e-01_rb,5.309460e-01_rb,5.286277e-01_rb,5.263988e-01_rb,& & 5.242512e-01_rb,5.221777e-01_rb,5.201719e-01_rb,5.182280e-01_rb,5.163410e-01_rb,& & 5.145062e-01_rb,5.127197e-01_rb,5.109776e-01_rb,5.092766e-01_rb,5.076137e-01_rb,& & 5.059860e-01_rb,5.043911e-01_rb,5.028266e-01_rb,5.012904e-01_rb,4.997805e-01_rb,& & 4.982951e-01_rb,4.968326e-01_rb,4.953913e-01_rb /) ! asymmetry factor: unitless asyice2(:, 16) = (/ & ! band 16 & 7.946655e-01_rb,8.547685e-01_rb,8.806016e-01_rb,8.949880e-01_rb,9.041676e-01_rb,& & 9.105399e-01_rb,9.152249e-01_rb,9.188160e-01_rb,9.216573e-01_rb,9.239620e-01_rb,& & 9.258695e-01_rb,9.274745e-01_rb,9.288441e-01_rb,9.300267e-01_rb,9.310584e-01_rb,& & 9.319665e-01_rb,9.327721e-01_rb,9.334918e-01_rb,9.341387e-01_rb,9.347236e-01_rb,& & 9.352551e-01_rb,9.357402e-01_rb,9.361850e-01_rb,9.365942e-01_rb,9.369722e-01_rb,& & 9.373225e-01_rb,9.376481e-01_rb,9.379516e-01_rb,9.382352e-01_rb,9.385010e-01_rb,& & 9.387505e-01_rb,9.389854e-01_rb,9.392070e-01_rb,9.394163e-01_rb,9.396145e-01_rb,& & 9.398024e-01_rb,9.399809e-01_rb,9.401508e-01_rb,9.403126e-01_rb,9.404670e-01_rb,& & 9.406144e-01_rb,9.407555e-01_rb,9.408906e-01_rb /) asyice2(:, 17) = (/ & ! band 17 & 9.078091e-01_rb,9.195850e-01_rb,9.267250e-01_rb,9.317083e-01_rb,9.354632e-01_rb,& & 9.384323e-01_rb,9.408597e-01_rb,9.428935e-01_rb,9.446301e-01_rb,9.461351e-01_rb,& & 9.474555e-01_rb,9.486259e-01_rb,9.496722e-01_rb,9.506146e-01_rb,9.514688e-01_rb,& & 9.522476e-01_rb,9.529612e-01_rb,9.536181e-01_rb,9.542251e-01_rb,9.547883e-01_rb,& & 9.553124e-01_rb,9.558019e-01_rb,9.562601e-01_rb,9.566904e-01_rb,9.570953e-01_rb,& & 9.574773e-01_rb,9.578385e-01_rb,9.581806e-01_rb,9.585054e-01_rb,9.588142e-01_rb,& & 9.591083e-01_rb,9.593888e-01_rb,9.596569e-01_rb,9.599135e-01_rb,9.601593e-01_rb,& & 9.603952e-01_rb,9.606219e-01_rb,9.608399e-01_rb,9.610499e-01_rb,9.612523e-01_rb,& & 9.614477e-01_rb,9.616365e-01_rb,9.618192e-01_rb /) asyice2(:, 18) = (/ & ! band 18 & 8.322045e-01_rb,8.528693e-01_rb,8.648167e-01_rb,8.729163e-01_rb,8.789054e-01_rb,& & 8.835845e-01_rb,8.873819e-01_rb,8.905511e-01_rb,8.932532e-01_rb,8.955965e-01_rb,& & 8.976567e-01_rb,8.994887e-01_rb,9.011334e-01_rb,9.026221e-01_rb,9.039791e-01_rb,& & 9.052237e-01_rb,9.063715e-01_rb,9.074349e-01_rb,9.084245e-01_rb,9.093489e-01_rb,& & 9.102154e-01_rb,9.110303e-01_rb,9.117987e-01_rb,9.125253e-01_rb,9.132140e-01_rb,& & 9.138682e-01_rb,9.144910e-01_rb,9.150850e-01_rb,9.156524e-01_rb,9.161955e-01_rb,& & 9.167160e-01_rb,9.172157e-01_rb,9.176959e-01_rb,9.181581e-01_rb,9.186034e-01_rb,& & 9.190330e-01_rb,9.194478e-01_rb,9.198488e-01_rb,9.202368e-01_rb,9.206126e-01_rb,& & 9.209768e-01_rb,9.213301e-01_rb,9.216731e-01_rb /) asyice2(:, 19) = (/ & ! band 19 & 8.116560e-01_rb,8.488278e-01_rb,8.674331e-01_rb,8.788148e-01_rb,8.865810e-01_rb,& & 8.922595e-01_rb,8.966149e-01_rb,9.000747e-01_rb,9.028980e-01_rb,9.052513e-01_rb,& & 9.072468e-01_rb,9.089632e-01_rb,9.104574e-01_rb,9.117713e-01_rb,9.129371e-01_rb,& & 9.139793e-01_rb,9.149174e-01_rb,9.157668e-01_rb,9.165400e-01_rb,9.172473e-01_rb,& & 9.178970e-01_rb,9.184962e-01_rb,9.190508e-01_rb,9.195658e-01_rb,9.200455e-01_rb,& & 9.204935e-01_rb,9.209130e-01_rb,9.213067e-01_rb,9.216771e-01_rb,9.220262e-01_rb,& & 9.223560e-01_rb,9.226680e-01_rb,9.229636e-01_rb,9.232443e-01_rb,9.235112e-01_rb,& & 9.237652e-01_rb,9.240074e-01_rb,9.242385e-01_rb,9.244594e-01_rb,9.246708e-01_rb,& & 9.248733e-01_rb,9.250674e-01_rb,9.252536e-01_rb /) asyice2(:, 20) = (/ & ! band 20 & 8.047113e-01_rb,8.402864e-01_rb,8.570332e-01_rb,8.668455e-01_rb,8.733206e-01_rb,& & 8.779272e-01_rb,8.813796e-01_rb,8.840676e-01_rb,8.862225e-01_rb,8.879904e-01_rb,& & 8.894682e-01_rb,8.907228e-01_rb,8.918019e-01_rb,8.927404e-01_rb,8.935645e-01_rb,& & 8.942943e-01_rb,8.949452e-01_rb,8.955296e-01_rb,8.960574e-01_rb,8.965366e-01_rb,& & 8.969736e-01_rb,8.973740e-01_rb,8.977422e-01_rb,8.980820e-01_rb,8.983966e-01_rb,& & 8.986889e-01_rb,8.989611e-01_rb,8.992153e-01_rb,8.994533e-01_rb,8.996766e-01_rb,& & 8.998865e-01_rb,9.000843e-01_rb,9.002709e-01_rb,9.004474e-01_rb,9.006146e-01_rb,& & 9.007731e-01_rb,9.009237e-01_rb,9.010670e-01_rb,9.012034e-01_rb,9.013336e-01_rb,& & 9.014579e-01_rb,9.015767e-01_rb,9.016904e-01_rb /) asyice2(:, 21) = (/ & ! band 21 & 8.179122e-01_rb,8.480726e-01_rb,8.621945e-01_rb,8.704354e-01_rb,8.758555e-01_rb,& & 8.797007e-01_rb,8.825750e-01_rb,8.848078e-01_rb,8.865939e-01_rb,8.880564e-01_rb,& & 8.892765e-01_rb,8.903105e-01_rb,8.911982e-01_rb,8.919689e-01_rb,8.926446e-01_rb,& & 8.932419e-01_rb,8.937738e-01_rb,8.942506e-01_rb,8.946806e-01_rb,8.950702e-01_rb,& & 8.954251e-01_rb,8.957497e-01_rb,8.960477e-01_rb,8.963223e-01_rb,8.965762e-01_rb,& & 8.968116e-01_rb,8.970306e-01_rb,8.972347e-01_rb,8.974255e-01_rb,8.976042e-01_rb,& & 8.977720e-01_rb,8.979298e-01_rb,8.980784e-01_rb,8.982188e-01_rb,8.983515e-01_rb,& & 8.984771e-01_rb,8.985963e-01_rb,8.987095e-01_rb,8.988171e-01_rb,8.989195e-01_rb,& & 8.990172e-01_rb,8.991104e-01_rb,8.991994e-01_rb /) asyice2(:, 22) = (/ & ! band 22 & 8.169789e-01_rb,8.455024e-01_rb,8.586925e-01_rb,8.663283e-01_rb,8.713217e-01_rb,& & 8.748488e-01_rb,8.774765e-01_rb,8.795122e-01_rb,8.811370e-01_rb,8.824649e-01_rb,& & 8.835711e-01_rb,8.845073e-01_rb,8.853103e-01_rb,8.860068e-01_rb,8.866170e-01_rb,& & 8.871560e-01_rb,8.876358e-01_rb,8.880658e-01_rb,8.884533e-01_rb,8.888044e-01_rb,& & 8.891242e-01_rb,8.894166e-01_rb,8.896851e-01_rb,8.899324e-01_rb,8.901612e-01_rb,& & 8.903733e-01_rb,8.905706e-01_rb,8.907545e-01_rb,8.909265e-01_rb,8.910876e-01_rb,& & 8.912388e-01_rb,8.913812e-01_rb,8.915153e-01_rb,8.916419e-01_rb,8.917617e-01_rb,& & 8.918752e-01_rb,8.919829e-01_rb,8.920851e-01_rb,8.921824e-01_rb,8.922751e-01_rb,& & 8.923635e-01_rb,8.924478e-01_rb,8.925284e-01_rb /) asyice2(:, 23) = (/ & ! band 23 & 8.387642e-01_rb,8.569979e-01_rb,8.658630e-01_rb,8.711825e-01_rb,8.747605e-01_rb,& & 8.773472e-01_rb,8.793129e-01_rb,8.808621e-01_rb,8.821179e-01_rb,8.831583e-01_rb,& & 8.840361e-01_rb,8.847875e-01_rb,8.854388e-01_rb,8.860094e-01_rb,8.865138e-01_rb,& & 8.869634e-01_rb,8.873668e-01_rb,8.877310e-01_rb,8.880617e-01_rb,8.883635e-01_rb,& & 8.886401e-01_rb,8.888947e-01_rb,8.891298e-01_rb,8.893477e-01_rb,8.895504e-01_rb,& & 8.897393e-01_rb,8.899159e-01_rb,8.900815e-01_rb,8.902370e-01_rb,8.903833e-01_rb,& & 8.905214e-01_rb,8.906518e-01_rb,8.907753e-01_rb,8.908924e-01_rb,8.910036e-01_rb,& & 8.911094e-01_rb,8.912101e-01_rb,8.913062e-01_rb,8.913979e-01_rb,8.914856e-01_rb,& & 8.915695e-01_rb,8.916498e-01_rb,8.917269e-01_rb /) asyice2(:, 24) = (/ & ! band 24 & 8.522208e-01_rb,8.648132e-01_rb,8.711224e-01_rb,8.749901e-01_rb,8.776354e-01_rb,& & 8.795743e-01_rb,8.810649e-01_rb,8.822518e-01_rb,8.832225e-01_rb,8.840333e-01_rb,& & 8.847224e-01_rb,8.853162e-01_rb,8.858342e-01_rb,8.862906e-01_rb,8.866962e-01_rb,& & 8.870595e-01_rb,8.873871e-01_rb,8.876842e-01_rb,8.879551e-01_rb,8.882032e-01_rb,& & 8.884316e-01_rb,8.886425e-01_rb,8.888380e-01_rb,8.890199e-01_rb,8.891895e-01_rb,& & 8.893481e-01_rb,8.894968e-01_rb,8.896366e-01_rb,8.897683e-01_rb,8.898926e-01_rb,& & 8.900102e-01_rb,8.901215e-01_rb,8.902272e-01_rb,8.903276e-01_rb,8.904232e-01_rb,& & 8.905144e-01_rb,8.906014e-01_rb,8.906845e-01_rb,8.907640e-01_rb,8.908402e-01_rb,& & 8.909132e-01_rb,8.909834e-01_rb,8.910507e-01_rb /) asyice2(:, 25) = (/ & ! band 25 & 8.578202e-01_rb,8.683033e-01_rb,8.735431e-01_rb,8.767488e-01_rb,8.789378e-01_rb,& & 8.805399e-01_rb,8.817701e-01_rb,8.827485e-01_rb,8.835480e-01_rb,8.842152e-01_rb,& & 8.847817e-01_rb,8.852696e-01_rb,8.856949e-01_rb,8.860694e-01_rb,8.864020e-01_rb,& & 8.866997e-01_rb,8.869681e-01_rb,8.872113e-01_rb,8.874330e-01_rb,8.876360e-01_rb,& & 8.878227e-01_rb,8.879951e-01_rb,8.881548e-01_rb,8.883033e-01_rb,8.884418e-01_rb,& & 8.885712e-01_rb,8.886926e-01_rb,8.888066e-01_rb,8.889139e-01_rb,8.890152e-01_rb,& & 8.891110e-01_rb,8.892017e-01_rb,8.892877e-01_rb,8.893695e-01_rb,8.894473e-01_rb,& & 8.895214e-01_rb,8.895921e-01_rb,8.896597e-01_rb,8.897243e-01_rb,8.897862e-01_rb,& & 8.898456e-01_rb,8.899025e-01_rb,8.899572e-01_rb /) asyice2(:, 26) = (/ & ! band 26 & 8.625615e-01_rb,8.713831e-01_rb,8.755799e-01_rb,8.780560e-01_rb,8.796983e-01_rb,& & 8.808714e-01_rb,8.817534e-01_rb,8.824420e-01_rb,8.829953e-01_rb,8.834501e-01_rb,& & 8.838310e-01_rb,8.841549e-01_rb,8.844338e-01_rb,8.846767e-01_rb,8.848902e-01_rb,& & 8.850795e-01_rb,8.852484e-01_rb,8.854002e-01_rb,8.855374e-01_rb,8.856620e-01_rb,& & 8.857758e-01_rb,8.858800e-01_rb,8.859759e-01_rb,8.860644e-01_rb,8.861464e-01_rb,& & 8.862225e-01_rb,8.862935e-01_rb,8.863598e-01_rb,8.864218e-01_rb,8.864800e-01_rb,& & 8.865347e-01_rb,8.865863e-01_rb,8.866349e-01_rb,8.866809e-01_rb,8.867245e-01_rb,& & 8.867658e-01_rb,8.868050e-01_rb,8.868423e-01_rb,8.868778e-01_rb,8.869117e-01_rb,& & 8.869440e-01_rb,8.869749e-01_rb,8.870044e-01_rb /) asyice2(:, 27) = (/ & ! band 27 & 8.587495e-01_rb,8.684764e-01_rb,8.728189e-01_rb,8.752872e-01_rb,8.768846e-01_rb,& & 8.780060e-01_rb,8.788386e-01_rb,8.794824e-01_rb,8.799960e-01_rb,8.804159e-01_rb,& & 8.807660e-01_rb,8.810626e-01_rb,8.813175e-01_rb,8.815390e-01_rb,8.817335e-01_rb,& & 8.819057e-01_rb,8.820593e-01_rb,8.821973e-01_rb,8.823220e-01_rb,8.824353e-01_rb,& & 8.825387e-01_rb,8.826336e-01_rb,8.827209e-01_rb,8.828016e-01_rb,8.828764e-01_rb,& & 8.829459e-01_rb,8.830108e-01_rb,8.830715e-01_rb,8.831283e-01_rb,8.831817e-01_rb,& & 8.832320e-01_rb,8.832795e-01_rb,8.833244e-01_rb,8.833668e-01_rb,8.834071e-01_rb,& & 8.834454e-01_rb,8.834817e-01_rb,8.835164e-01_rb,8.835495e-01_rb,8.835811e-01_rb,& & 8.836113e-01_rb,8.836402e-01_rb,8.836679e-01_rb /) asyice2(:, 28) = (/ & ! band 28 & 8.561110e-01_rb,8.678583e-01_rb,8.727554e-01_rb,8.753892e-01_rb,8.770154e-01_rb,& & 8.781109e-01_rb,8.788949e-01_rb,8.794812e-01_rb,8.799348e-01_rb,8.802952e-01_rb,& & 8.805880e-01_rb,8.808300e-01_rb,8.810331e-01_rb,8.812058e-01_rb,8.813543e-01_rb,& & 8.814832e-01_rb,8.815960e-01_rb,8.816956e-01_rb,8.817839e-01_rb,8.818629e-01_rb,& & 8.819339e-01_rb,8.819979e-01_rb,8.820560e-01_rb,8.821089e-01_rb,8.821573e-01_rb,& & 8.822016e-01_rb,8.822425e-01_rb,8.822801e-01_rb,8.823150e-01_rb,8.823474e-01_rb,& & 8.823775e-01_rb,8.824056e-01_rb,8.824318e-01_rb,8.824564e-01_rb,8.824795e-01_rb,& & 8.825011e-01_rb,8.825215e-01_rb,8.825408e-01_rb,8.825589e-01_rb,8.825761e-01_rb,& & 8.825924e-01_rb,8.826078e-01_rb,8.826224e-01_rb /) asyice2(:, 29) = (/ & ! band 29 & 8.311124e-01_rb,8.688197e-01_rb,8.900274e-01_rb,9.040696e-01_rb,9.142334e-01_rb,& & 9.220181e-01_rb,9.282195e-01_rb,9.333048e-01_rb,9.375689e-01_rb,9.412085e-01_rb,& & 9.443604e-01_rb,9.471230e-01_rb,9.495694e-01_rb,9.517549e-01_rb,9.537224e-01_rb,& & 9.555057e-01_rb,9.571316e-01_rb,9.586222e-01_rb,9.599952e-01_rb,9.612656e-01_rb,& & 9.624458e-01_rb,9.635461e-01_rb,9.645756e-01_rb,9.655418e-01_rb,9.664513e-01_rb,& & 9.673098e-01_rb,9.681222e-01_rb,9.688928e-01_rb,9.696256e-01_rb,9.703237e-01_rb,& & 9.709903e-01_rb,9.716280e-01_rb,9.722391e-01_rb,9.728258e-01_rb,9.733901e-01_rb,& & 9.739336e-01_rb,9.744579e-01_rb,9.749645e-01_rb,9.754546e-01_rb,9.759294e-01_rb,& & 9.763901e-01_rb,9.768376e-01_rb,9.772727e-01_rb /) ! Hexagonal Ice Particle Parameterization ! extinction units (ext coef/iwc): [(m^-1)/(g m^-3)] extice3(:, 16) = (/ & ! band 16 & 5.194013e-01_rb,3.215089e-01_rb,2.327917e-01_rb,1.824424e-01_rb,1.499977e-01_rb,& & 1.273492e-01_rb,1.106421e-01_rb,9.780982e-02_rb,8.764435e-02_rb,7.939266e-02_rb,& & 7.256081e-02_rb,6.681137e-02_rb,6.190600e-02_rb,5.767154e-02_rb,5.397915e-02_rb,& & 5.073102e-02_rb,4.785151e-02_rb,4.528125e-02_rb,4.297296e-02_rb,4.088853e-02_rb,& & 3.899690e-02_rb,3.727251e-02_rb,3.569411e-02_rb,3.424393e-02_rb,3.290694e-02_rb,& & 3.167040e-02_rb,3.052340e-02_rb,2.945654e-02_rb,2.846172e-02_rb,2.753188e-02_rb,& & 2.666085e-02_rb,2.584322e-02_rb,2.507423e-02_rb,2.434967e-02_rb,2.366579e-02_rb,& & 2.301926e-02_rb,2.240711e-02_rb,2.182666e-02_rb,2.127551e-02_rb,2.075150e-02_rb,& & 2.025267e-02_rb,1.977725e-02_rb,1.932364e-02_rb,1.889035e-02_rb,1.847607e-02_rb,& & 1.807956e-02_rb /) extice3(:, 17) = (/ & ! band 17 & 4.901155e-01_rb,3.065286e-01_rb,2.230800e-01_rb,1.753951e-01_rb,1.445402e-01_rb,& & 1.229417e-01_rb,1.069777e-01_rb,9.469760e-02_rb,8.495824e-02_rb,7.704501e-02_rb,& & 7.048834e-02_rb,6.496693e-02_rb,6.025353e-02_rb,5.618286e-02_rb,5.263186e-02_rb,& & 4.950698e-02_rb,4.673585e-02_rb,4.426164e-02_rb,4.203904e-02_rb,4.003153e-02_rb,& & 3.820932e-02_rb,3.654790e-02_rb,3.502688e-02_rb,3.362919e-02_rb,3.234041e-02_rb,& & 3.114829e-02_rb,3.004234e-02_rb,2.901356e-02_rb,2.805413e-02_rb,2.715727e-02_rb,& & 2.631705e-02_rb,2.552828e-02_rb,2.478637e-02_rb,2.408725e-02_rb,2.342734e-02_rb,& & 2.280343e-02_rb,2.221264e-02_rb,2.165242e-02_rb,2.112043e-02_rb,2.061461e-02_rb,& & 2.013308e-02_rb,1.967411e-02_rb,1.923616e-02_rb,1.881783e-02_rb,1.841781e-02_rb,& & 1.803494e-02_rb /) extice3(:, 18) = (/ & ! band 18 & 5.056264e-01_rb,3.160261e-01_rb,2.298442e-01_rb,1.805973e-01_rb,1.487318e-01_rb,& & 1.264258e-01_rb,1.099389e-01_rb,9.725656e-02_rb,8.719819e-02_rb,7.902576e-02_rb,& & 7.225433e-02_rb,6.655206e-02_rb,6.168427e-02_rb,5.748028e-02_rb,5.381296e-02_rb,& & 5.058572e-02_rb,4.772383e-02_rb,4.516857e-02_rb,4.287317e-02_rb,4.079990e-02_rb,& & 3.891801e-02_rb,3.720217e-02_rb,3.563133e-02_rb,3.418786e-02_rb,3.285686e-02_rb,& & 3.162569e-02_rb,3.048352e-02_rb,2.942104e-02_rb,2.843018e-02_rb,2.750395e-02_rb,& & 2.663621e-02_rb,2.582160e-02_rb,2.505539e-02_rb,2.433337e-02_rb,2.365185e-02_rb,& & 2.300750e-02_rb,2.239736e-02_rb,2.181878e-02_rb,2.126937e-02_rb,2.074699e-02_rb,& & 2.024968e-02_rb,1.977567e-02_rb,1.932338e-02_rb,1.889134e-02_rb,1.847823e-02_rb,& & 1.808281e-02_rb /) extice3(:, 19) = (/ & ! band 19 & 4.881605e-01_rb,3.055237e-01_rb,2.225070e-01_rb,1.750688e-01_rb,1.443736e-01_rb,& & 1.228869e-01_rb,1.070054e-01_rb,9.478893e-02_rb,8.509997e-02_rb,7.722769e-02_rb,& & 7.070495e-02_rb,6.521211e-02_rb,6.052311e-02_rb,5.647351e-02_rb,5.294088e-02_rb,& & 4.983217e-02_rb,4.707539e-02_rb,4.461398e-02_rb,4.240288e-02_rb,4.040575e-02_rb,& & 3.859298e-02_rb,3.694016e-02_rb,3.542701e-02_rb,3.403655e-02_rb,3.275444e-02_rb,& & 3.156849e-02_rb,3.046827e-02_rb,2.944481e-02_rb,2.849034e-02_rb,2.759812e-02_rb,& & 2.676226e-02_rb,2.597757e-02_rb,2.523949e-02_rb,2.454400e-02_rb,2.388750e-02_rb,& & 2.326682e-02_rb,2.267909e-02_rb,2.212176e-02_rb,2.159253e-02_rb,2.108933e-02_rb,& & 2.061028e-02_rb,2.015369e-02_rb,1.971801e-02_rb,1.930184e-02_rb,1.890389e-02_rb,& & 1.852300e-02_rb /) extice3(:, 20) = (/ & ! band 20 & 5.103703e-01_rb,3.188144e-01_rb,2.317435e-01_rb,1.819887e-01_rb,1.497944e-01_rb,& & 1.272584e-01_rb,1.106013e-01_rb,9.778822e-02_rb,8.762610e-02_rb,7.936938e-02_rb,& & 7.252809e-02_rb,6.676701e-02_rb,6.184901e-02_rb,5.760165e-02_rb,5.389651e-02_rb,& & 5.063598e-02_rb,4.774457e-02_rb,4.516295e-02_rb,4.284387e-02_rb,4.074922e-02_rb,& & 3.884792e-02_rb,3.711438e-02_rb,3.552734e-02_rb,3.406898e-02_rb,3.272425e-02_rb,& & 3.148038e-02_rb,3.032643e-02_rb,2.925299e-02_rb,2.825191e-02_rb,2.731612e-02_rb,& & 2.643943e-02_rb,2.561642e-02_rb,2.484230e-02_rb,2.411284e-02_rb,2.342429e-02_rb,& & 2.277329e-02_rb,2.215686e-02_rb,2.157231e-02_rb,2.101724e-02_rb,2.048946e-02_rb,& & 1.998702e-02_rb,1.950813e-02_rb,1.905118e-02_rb,1.861468e-02_rb,1.819730e-02_rb,& & 1.779781e-02_rb /) extice3(:, 21) = (/ & ! band 21 & 5.031161e-01_rb,3.144511e-01_rb,2.286942e-01_rb,1.796903e-01_rb,1.479819e-01_rb,& & 1.257860e-01_rb,1.093803e-01_rb,9.676059e-02_rb,8.675183e-02_rb,7.861971e-02_rb,& & 7.188168e-02_rb,6.620754e-02_rb,6.136376e-02_rb,5.718050e-02_rb,5.353127e-02_rb,& & 5.031995e-02_rb,4.747218e-02_rb,4.492952e-02_rb,4.264544e-02_rb,4.058240e-02_rb,& & 3.870979e-02_rb,3.700242e-02_rb,3.543933e-02_rb,3.400297e-02_rb,3.267854e-02_rb,& & 3.145345e-02_rb,3.031691e-02_rb,2.925967e-02_rb,2.827370e-02_rb,2.735203e-02_rb,& & 2.648858e-02_rb,2.567798e-02_rb,2.491555e-02_rb,2.419710e-02_rb,2.351893e-02_rb,& & 2.287776e-02_rb,2.227063e-02_rb,2.169491e-02_rb,2.114821e-02_rb,2.062840e-02_rb,& & 2.013354e-02_rb,1.966188e-02_rb,1.921182e-02_rb,1.878191e-02_rb,1.837083e-02_rb,& & 1.797737e-02_rb /) extice3(:, 22) = (/ & ! band 22 & 4.949453e-01_rb,3.095918e-01_rb,2.253402e-01_rb,1.771964e-01_rb,1.460446e-01_rb,& & 1.242383e-01_rb,1.081206e-01_rb,9.572235e-02_rb,8.588928e-02_rb,7.789990e-02_rb,& & 7.128013e-02_rb,6.570559e-02_rb,6.094684e-02_rb,5.683701e-02_rb,5.325183e-02_rb,& & 5.009688e-02_rb,4.729909e-02_rb,4.480106e-02_rb,4.255708e-02_rb,4.053025e-02_rb,& & 3.869051e-02_rb,3.701310e-02_rb,3.547745e-02_rb,3.406631e-02_rb,3.276512e-02_rb,& & 3.156153e-02_rb,3.044494e-02_rb,2.940626e-02_rb,2.843759e-02_rb,2.753211e-02_rb,& & 2.668381e-02_rb,2.588744e-02_rb,2.513839e-02_rb,2.443255e-02_rb,2.376629e-02_rb,& & 2.313637e-02_rb,2.253990e-02_rb,2.197428e-02_rb,2.143718e-02_rb,2.092649e-02_rb,& & 2.044032e-02_rb,1.997694e-02_rb,1.953478e-02_rb,1.911241e-02_rb,1.870855e-02_rb,& & 1.832199e-02_rb /) extice3(:, 23) = (/ & ! band 23 & 5.052816e-01_rb,3.157665e-01_rb,2.296233e-01_rb,1.803986e-01_rb,1.485473e-01_rb,& & 1.262514e-01_rb,1.097718e-01_rb,9.709524e-02_rb,8.704139e-02_rb,7.887264e-02_rb,& & 7.210424e-02_rb,6.640454e-02_rb,6.153894e-02_rb,5.733683e-02_rb,5.367116e-02_rb,& & 5.044537e-02_rb,4.758477e-02_rb,4.503066e-02_rb,4.273629e-02_rb,4.066395e-02_rb,& & 3.878291e-02_rb,3.706784e-02_rb,3.549771e-02_rb,3.405488e-02_rb,3.272448e-02_rb,& & 3.149387e-02_rb,3.035221e-02_rb,2.929020e-02_rb,2.829979e-02_rb,2.737397e-02_rb,& & 2.650663e-02_rb,2.569238e-02_rb,2.492651e-02_rb,2.420482e-02_rb,2.352361e-02_rb,& & 2.287954e-02_rb,2.226968e-02_rb,2.169136e-02_rb,2.114220e-02_rb,2.062005e-02_rb,& & 2.012296e-02_rb,1.964917e-02_rb,1.919709e-02_rb,1.876524e-02_rb,1.835231e-02_rb,& & 1.795707e-02_rb /) extice3(:, 24) = (/ & ! band 24 & 5.042067e-01_rb,3.151195e-01_rb,2.291708e-01_rb,1.800573e-01_rb,1.482779e-01_rb,& & 1.260324e-01_rb,1.095900e-01_rb,9.694202e-02_rb,8.691087e-02_rb,7.876056e-02_rb,& & 7.200745e-02_rb,6.632062e-02_rb,6.146600e-02_rb,5.727338e-02_rb,5.361599e-02_rb,& & 5.039749e-02_rb,4.754334e-02_rb,4.499500e-02_rb,4.270580e-02_rb,4.063815e-02_rb,& & 3.876135e-02_rb,3.705016e-02_rb,3.548357e-02_rb,3.404400e-02_rb,3.271661e-02_rb,& & 3.148877e-02_rb,3.034969e-02_rb,2.929008e-02_rb,2.830191e-02_rb,2.737818e-02_rb,& & 2.651279e-02_rb,2.570039e-02_rb,2.493624e-02_rb,2.421618e-02_rb,2.353650e-02_rb,& & 2.289390e-02_rb,2.228541e-02_rb,2.170840e-02_rb,2.116048e-02_rb,2.063950e-02_rb,& & 2.014354e-02_rb,1.967082e-02_rb,1.921975e-02_rb,1.878888e-02_rb,1.837688e-02_rb,& & 1.798254e-02_rb /) extice3(:, 25) = (/ & ! band 25 & 5.022507e-01_rb,3.139246e-01_rb,2.283218e-01_rb,1.794059e-01_rb,1.477544e-01_rb,& & 1.255984e-01_rb,1.092222e-01_rb,9.662516e-02_rb,8.663439e-02_rb,7.851688e-02_rb,& & 7.179095e-02_rb,6.612700e-02_rb,6.129193e-02_rb,5.711618e-02_rb,5.347351e-02_rb,& & 5.026796e-02_rb,4.742530e-02_rb,4.488721e-02_rb,4.260724e-02_rb,4.054790e-02_rb,& & 3.867866e-02_rb,3.697435e-02_rb,3.541407e-02_rb,3.398029e-02_rb,3.265824e-02_rb,& & 3.143535e-02_rb,3.030085e-02_rb,2.924551e-02_rb,2.826131e-02_rb,2.734130e-02_rb,& & 2.647939e-02_rb,2.567026e-02_rb,2.490919e-02_rb,2.419203e-02_rb,2.351509e-02_rb,& & 2.287507e-02_rb,2.226903e-02_rb,2.169434e-02_rb,2.114862e-02_rb,2.062975e-02_rb,& & 2.013578e-02_rb,1.966496e-02_rb,1.921571e-02_rb,1.878658e-02_rb,1.837623e-02_rb,& & 1.798348e-02_rb /) extice3(:, 26) = (/ & ! band 26 & 5.068316e-01_rb,3.166869e-01_rb,2.302576e-01_rb,1.808693e-01_rb,1.489122e-01_rb,& & 1.265423e-01_rb,1.100080e-01_rb,9.728926e-02_rb,8.720201e-02_rb,7.900612e-02_rb,& & 7.221524e-02_rb,6.649660e-02_rb,6.161484e-02_rb,5.739877e-02_rb,5.372093e-02_rb,& & 5.048442e-02_rb,4.761431e-02_rb,4.505172e-02_rb,4.274972e-02_rb,4.067050e-02_rb,& & 3.878321e-02_rb,3.706244e-02_rb,3.548710e-02_rb,3.403948e-02_rb,3.270466e-02_rb,& & 3.146995e-02_rb,3.032450e-02_rb,2.925897e-02_rb,2.826527e-02_rb,2.733638e-02_rb,& & 2.646615e-02_rb,2.564920e-02_rb,2.488078e-02_rb,2.415670e-02_rb,2.347322e-02_rb,& & 2.282702e-02_rb,2.221513e-02_rb,2.163489e-02_rb,2.108390e-02_rb,2.056002e-02_rb,& & 2.006128e-02_rb,1.958591e-02_rb,1.913232e-02_rb,1.869904e-02_rb,1.828474e-02_rb,& & 1.788819e-02_rb /) extice3(:, 27) = (/ & ! band 27 & 5.077707e-01_rb,3.172636e-01_rb,2.306695e-01_rb,1.811871e-01_rb,1.491691e-01_rb,& & 1.267565e-01_rb,1.101907e-01_rb,9.744773e-02_rb,8.734125e-02_rb,7.912973e-02_rb,& & 7.232591e-02_rb,6.659637e-02_rb,6.170530e-02_rb,5.748120e-02_rb,5.379634e-02_rb,& & 5.055367e-02_rb,4.767809e-02_rb,4.511061e-02_rb,4.280423e-02_rb,4.072104e-02_rb,& & 3.883015e-02_rb,3.710611e-02_rb,3.552776e-02_rb,3.407738e-02_rb,3.274002e-02_rb,& & 3.150296e-02_rb,3.035532e-02_rb,2.928776e-02_rb,2.829216e-02_rb,2.736150e-02_rb,& & 2.648961e-02_rb,2.567111e-02_rb,2.490123e-02_rb,2.417576e-02_rb,2.349098e-02_rb,& & 2.284354e-02_rb,2.223049e-02_rb,2.164914e-02_rb,2.109711e-02_rb,2.057222e-02_rb,& & 2.007253e-02_rb,1.959626e-02_rb,1.914181e-02_rb,1.870770e-02_rb,1.829261e-02_rb,& & 1.789531e-02_rb /) extice3(:, 28) = (/ & ! band 28 & 5.062281e-01_rb,3.163402e-01_rb,2.300275e-01_rb,1.807060e-01_rb,1.487921e-01_rb,& & 1.264523e-01_rb,1.099403e-01_rb,9.723879e-02_rb,8.716516e-02_rb,7.898034e-02_rb,& & 7.219863e-02_rb,6.648771e-02_rb,6.161254e-02_rb,5.740217e-02_rb,5.372929e-02_rb,& & 5.049716e-02_rb,4.763092e-02_rb,4.507179e-02_rb,4.277290e-02_rb,4.069649e-02_rb,& & 3.881175e-02_rb,3.709331e-02_rb,3.552008e-02_rb,3.407442e-02_rb,3.274141e-02_rb,& & 3.150837e-02_rb,3.036447e-02_rb,2.930037e-02_rb,2.830801e-02_rb,2.738037e-02_rb,& & 2.651132e-02_rb,2.569547e-02_rb,2.492810e-02_rb,2.420499e-02_rb,2.352243e-02_rb,& & 2.287710e-02_rb,2.226604e-02_rb,2.168658e-02_rb,2.113634e-02_rb,2.061316e-02_rb,& & 2.011510e-02_rb,1.964038e-02_rb,1.918740e-02_rb,1.875471e-02_rb,1.834096e-02_rb,& & 1.794495e-02_rb /) extice3(:, 29) = (/ & ! band 29 & 1.338834e-01_rb,1.924912e-01_rb,1.755523e-01_rb,1.534793e-01_rb,1.343937e-01_rb,& & 1.187883e-01_rb,1.060654e-01_rb,9.559106e-02_rb,8.685880e-02_rb,7.948698e-02_rb,& & 7.319086e-02_rb,6.775669e-02_rb,6.302215e-02_rb,5.886236e-02_rb,5.517996e-02_rb,& & 5.189810e-02_rb,4.895539e-02_rb,4.630225e-02_rb,4.389823e-02_rb,4.171002e-02_rb,& & 3.970998e-02_rb,3.787493e-02_rb,3.618537e-02_rb,3.462471e-02_rb,3.317880e-02_rb,& & 3.183547e-02_rb,3.058421e-02_rb,2.941590e-02_rb,2.832256e-02_rb,2.729724e-02_rb,& & 2.633377e-02_rb,2.542675e-02_rb,2.457136e-02_rb,2.376332e-02_rb,2.299882e-02_rb,& & 2.227443e-02_rb,2.158707e-02_rb,2.093400e-02_rb,2.031270e-02_rb,1.972091e-02_rb,& & 1.915659e-02_rb,1.861787e-02_rb,1.810304e-02_rb,1.761055e-02_rb,1.713899e-02_rb,& & 1.668704e-02_rb /) ! single-scattering albedo: unitless ssaice3(:, 16) = (/ & ! band 16 & 6.749442e-01_rb,6.649947e-01_rb,6.565828e-01_rb,6.489928e-01_rb,6.420046e-01_rb,& & 6.355231e-01_rb,6.294964e-01_rb,6.238901e-01_rb,6.186783e-01_rb,6.138395e-01_rb,& & 6.093543e-01_rb,6.052049e-01_rb,6.013742e-01_rb,5.978457e-01_rb,5.946030e-01_rb,& & 5.916302e-01_rb,5.889115e-01_rb,5.864310e-01_rb,5.841731e-01_rb,5.821221e-01_rb,& & 5.802624e-01_rb,5.785785e-01_rb,5.770549e-01_rb,5.756759e-01_rb,5.744262e-01_rb,& & 5.732901e-01_rb,5.722524e-01_rb,5.712974e-01_rb,5.704097e-01_rb,5.695739e-01_rb,& & 5.687747e-01_rb,5.679964e-01_rb,5.672238e-01_rb,5.664415e-01_rb,5.656340e-01_rb,& & 5.647860e-01_rb,5.638821e-01_rb,5.629070e-01_rb,5.618452e-01_rb,5.606815e-01_rb,& & 5.594006e-01_rb,5.579870e-01_rb,5.564255e-01_rb,5.547008e-01_rb,5.527976e-01_rb,& & 5.507005e-01_rb /) ssaice3(:, 17) = (/ & ! band 17 & 7.628550e-01_rb,7.567297e-01_rb,7.508463e-01_rb,7.451972e-01_rb,7.397745e-01_rb,& & 7.345705e-01_rb,7.295775e-01_rb,7.247881e-01_rb,7.201945e-01_rb,7.157894e-01_rb,& & 7.115652e-01_rb,7.075145e-01_rb,7.036300e-01_rb,6.999044e-01_rb,6.963304e-01_rb,& & 6.929007e-01_rb,6.896083e-01_rb,6.864460e-01_rb,6.834067e-01_rb,6.804833e-01_rb,& & 6.776690e-01_rb,6.749567e-01_rb,6.723397e-01_rb,6.698109e-01_rb,6.673637e-01_rb,& & 6.649913e-01_rb,6.626870e-01_rb,6.604441e-01_rb,6.582561e-01_rb,6.561163e-01_rb,& & 6.540182e-01_rb,6.519554e-01_rb,6.499215e-01_rb,6.479099e-01_rb,6.459145e-01_rb,& & 6.439289e-01_rb,6.419468e-01_rb,6.399621e-01_rb,6.379686e-01_rb,6.359601e-01_rb,& & 6.339306e-01_rb,6.318740e-01_rb,6.297845e-01_rb,6.276559e-01_rb,6.254825e-01_rb,& & 6.232583e-01_rb /) ssaice3(:, 18) = (/ & ! band 18 & 9.924147e-01_rb,9.882792e-01_rb,9.842257e-01_rb,9.802522e-01_rb,9.763566e-01_rb,& & 9.725367e-01_rb,9.687905e-01_rb,9.651157e-01_rb,9.615104e-01_rb,9.579725e-01_rb,& & 9.544997e-01_rb,9.510901e-01_rb,9.477416e-01_rb,9.444520e-01_rb,9.412194e-01_rb,& & 9.380415e-01_rb,9.349165e-01_rb,9.318421e-01_rb,9.288164e-01_rb,9.258373e-01_rb,& & 9.229027e-01_rb,9.200106e-01_rb,9.171589e-01_rb,9.143457e-01_rb,9.115688e-01_rb,& & 9.088263e-01_rb,9.061161e-01_rb,9.034362e-01_rb,9.007846e-01_rb,8.981592e-01_rb,& & 8.955581e-01_rb,8.929792e-01_rb,8.904206e-01_rb,8.878803e-01_rb,8.853562e-01_rb,& & 8.828464e-01_rb,8.803488e-01_rb,8.778616e-01_rb,8.753827e-01_rb,8.729102e-01_rb,& & 8.704421e-01_rb,8.679764e-01_rb,8.655112e-01_rb,8.630445e-01_rb,8.605744e-01_rb,& & 8.580989e-01_rb /) ssaice3(:, 19) = (/ & ! band 19 & 9.629413e-01_rb,9.517182e-01_rb,9.409209e-01_rb,9.305366e-01_rb,9.205529e-01_rb,& & 9.109569e-01_rb,9.017362e-01_rb,8.928780e-01_rb,8.843699e-01_rb,8.761992e-01_rb,& & 8.683536e-01_rb,8.608204e-01_rb,8.535873e-01_rb,8.466417e-01_rb,8.399712e-01_rb,& & 8.335635e-01_rb,8.274062e-01_rb,8.214868e-01_rb,8.157932e-01_rb,8.103129e-01_rb,& & 8.050336e-01_rb,7.999432e-01_rb,7.950294e-01_rb,7.902798e-01_rb,7.856825e-01_rb,& & 7.812250e-01_rb,7.768954e-01_rb,7.726815e-01_rb,7.685711e-01_rb,7.645522e-01_rb,& & 7.606126e-01_rb,7.567404e-01_rb,7.529234e-01_rb,7.491498e-01_rb,7.454074e-01_rb,& & 7.416844e-01_rb,7.379688e-01_rb,7.342485e-01_rb,7.305118e-01_rb,7.267468e-01_rb,& & 7.229415e-01_rb,7.190841e-01_rb,7.151628e-01_rb,7.111657e-01_rb,7.070811e-01_rb,& & 7.028972e-01_rb /) ssaice3(:, 20) = (/ & ! band 20 & 9.942270e-01_rb,9.909206e-01_rb,9.876775e-01_rb,9.844960e-01_rb,9.813746e-01_rb,& & 9.783114e-01_rb,9.753049e-01_rb,9.723535e-01_rb,9.694553e-01_rb,9.666088e-01_rb,& & 9.638123e-01_rb,9.610641e-01_rb,9.583626e-01_rb,9.557060e-01_rb,9.530928e-01_rb,& & 9.505211e-01_rb,9.479895e-01_rb,9.454961e-01_rb,9.430393e-01_rb,9.406174e-01_rb,& & 9.382288e-01_rb,9.358717e-01_rb,9.335446e-01_rb,9.312456e-01_rb,9.289731e-01_rb,& & 9.267255e-01_rb,9.245010e-01_rb,9.222980e-01_rb,9.201147e-01_rb,9.179496e-01_rb,& & 9.158008e-01_rb,9.136667e-01_rb,9.115457e-01_rb,9.094359e-01_rb,9.073358e-01_rb,& & 9.052436e-01_rb,9.031577e-01_rb,9.010763e-01_rb,8.989977e-01_rb,8.969203e-01_rb,& & 8.948423e-01_rb,8.927620e-01_rb,8.906778e-01_rb,8.885879e-01_rb,8.864907e-01_rb,& & 8.843843e-01_rb /) ssaice3(:, 21) = (/ & ! band 21 & 9.934014e-01_rb,9.899331e-01_rb,9.865537e-01_rb,9.832610e-01_rb,9.800523e-01_rb,& & 9.769254e-01_rb,9.738777e-01_rb,9.709069e-01_rb,9.680106e-01_rb,9.651862e-01_rb,& & 9.624315e-01_rb,9.597439e-01_rb,9.571212e-01_rb,9.545608e-01_rb,9.520605e-01_rb,& & 9.496177e-01_rb,9.472301e-01_rb,9.448954e-01_rb,9.426111e-01_rb,9.403749e-01_rb,& & 9.381843e-01_rb,9.360370e-01_rb,9.339307e-01_rb,9.318629e-01_rb,9.298313e-01_rb,& & 9.278336e-01_rb,9.258673e-01_rb,9.239302e-01_rb,9.220198e-01_rb,9.201338e-01_rb,& & 9.182700e-01_rb,9.164258e-01_rb,9.145991e-01_rb,9.127874e-01_rb,9.109884e-01_rb,& & 9.091999e-01_rb,9.074194e-01_rb,9.056447e-01_rb,9.038735e-01_rb,9.021033e-01_rb,& & 9.003320e-01_rb,8.985572e-01_rb,8.967766e-01_rb,8.949879e-01_rb,8.931888e-01_rb,& & 8.913770e-01_rb /) ssaice3(:, 22) = (/ & ! band 22 & 9.994833e-01_rb,9.992055e-01_rb,9.989278e-01_rb,9.986500e-01_rb,9.983724e-01_rb,& & 9.980947e-01_rb,9.978172e-01_rb,9.975397e-01_rb,9.972623e-01_rb,9.969849e-01_rb,& & 9.967077e-01_rb,9.964305e-01_rb,9.961535e-01_rb,9.958765e-01_rb,9.955997e-01_rb,& & 9.953230e-01_rb,9.950464e-01_rb,9.947699e-01_rb,9.944936e-01_rb,9.942174e-01_rb,& & 9.939414e-01_rb,9.936656e-01_rb,9.933899e-01_rb,9.931144e-01_rb,9.928390e-01_rb,& & 9.925639e-01_rb,9.922889e-01_rb,9.920141e-01_rb,9.917396e-01_rb,9.914652e-01_rb,& & 9.911911e-01_rb,9.909171e-01_rb,9.906434e-01_rb,9.903700e-01_rb,9.900967e-01_rb,& & 9.898237e-01_rb,9.895510e-01_rb,9.892784e-01_rb,9.890062e-01_rb,9.887342e-01_rb,& & 9.884625e-01_rb,9.881911e-01_rb,9.879199e-01_rb,9.876490e-01_rb,9.873784e-01_rb,& & 9.871081e-01_rb /) ssaice3(:, 23) = (/ & ! band 23 & 9.999343e-01_rb,9.998917e-01_rb,9.998492e-01_rb,9.998067e-01_rb,9.997642e-01_rb,& & 9.997218e-01_rb,9.996795e-01_rb,9.996372e-01_rb,9.995949e-01_rb,9.995528e-01_rb,& & 9.995106e-01_rb,9.994686e-01_rb,9.994265e-01_rb,9.993845e-01_rb,9.993426e-01_rb,& & 9.993007e-01_rb,9.992589e-01_rb,9.992171e-01_rb,9.991754e-01_rb,9.991337e-01_rb,& & 9.990921e-01_rb,9.990505e-01_rb,9.990089e-01_rb,9.989674e-01_rb,9.989260e-01_rb,& & 9.988846e-01_rb,9.988432e-01_rb,9.988019e-01_rb,9.987606e-01_rb,9.987194e-01_rb,& & 9.986782e-01_rb,9.986370e-01_rb,9.985959e-01_rb,9.985549e-01_rb,9.985139e-01_rb,& & 9.984729e-01_rb,9.984319e-01_rb,9.983910e-01_rb,9.983502e-01_rb,9.983094e-01_rb,& & 9.982686e-01_rb,9.982279e-01_rb,9.981872e-01_rb,9.981465e-01_rb,9.981059e-01_rb,& & 9.980653e-01_rb /) ssaice3(:, 24) = (/ & ! band 24 & 9.999978e-01_rb,9.999965e-01_rb,9.999952e-01_rb,9.999939e-01_rb,9.999926e-01_rb,& & 9.999913e-01_rb,9.999900e-01_rb,9.999887e-01_rb,9.999873e-01_rb,9.999860e-01_rb,& & 9.999847e-01_rb,9.999834e-01_rb,9.999821e-01_rb,9.999808e-01_rb,9.999795e-01_rb,& & 9.999782e-01_rb,9.999769e-01_rb,9.999756e-01_rb,9.999743e-01_rb,9.999730e-01_rb,& & 9.999717e-01_rb,9.999704e-01_rb,9.999691e-01_rb,9.999678e-01_rb,9.999665e-01_rb,& & 9.999652e-01_rb,9.999639e-01_rb,9.999626e-01_rb,9.999613e-01_rb,9.999600e-01_rb,& & 9.999587e-01_rb,9.999574e-01_rb,9.999561e-01_rb,9.999548e-01_rb,9.999535e-01_rb,& & 9.999522e-01_rb,9.999509e-01_rb,9.999496e-01_rb,9.999483e-01_rb,9.999470e-01_rb,& & 9.999457e-01_rb,9.999444e-01_rb,9.999431e-01_rb,9.999418e-01_rb,9.999405e-01_rb,& & 9.999392e-01_rb /) ssaice3(:, 25) = (/ & ! band 25 & 9.999994e-01_rb,9.999993e-01_rb,9.999991e-01_rb,9.999990e-01_rb,9.999989e-01_rb,& & 9.999987e-01_rb,9.999986e-01_rb,9.999984e-01_rb,9.999983e-01_rb,9.999982e-01_rb,& & 9.999980e-01_rb,9.999979e-01_rb,9.999977e-01_rb,9.999976e-01_rb,9.999975e-01_rb,& & 9.999973e-01_rb,9.999972e-01_rb,9.999970e-01_rb,9.999969e-01_rb,9.999967e-01_rb,& & 9.999966e-01_rb,9.999965e-01_rb,9.999963e-01_rb,9.999962e-01_rb,9.999960e-01_rb,& & 9.999959e-01_rb,9.999957e-01_rb,9.999956e-01_rb,9.999954e-01_rb,9.999953e-01_rb,& & 9.999952e-01_rb,9.999950e-01_rb,9.999949e-01_rb,9.999947e-01_rb,9.999946e-01_rb,& & 9.999944e-01_rb,9.999943e-01_rb,9.999941e-01_rb,9.999940e-01_rb,9.999939e-01_rb,& & 9.999937e-01_rb,9.999936e-01_rb,9.999934e-01_rb,9.999933e-01_rb,9.999931e-01_rb,& & 9.999930e-01_rb /) ssaice3(:, 26) = (/ & ! band 26 & 9.999997e-01_rb,9.999995e-01_rb,9.999992e-01_rb,9.999990e-01_rb,9.999987e-01_rb,& & 9.999985e-01_rb,9.999983e-01_rb,9.999980e-01_rb,9.999978e-01_rb,9.999976e-01_rb,& & 9.999973e-01_rb,9.999971e-01_rb,9.999969e-01_rb,9.999967e-01_rb,9.999965e-01_rb,& & 9.999963e-01_rb,9.999960e-01_rb,9.999958e-01_rb,9.999956e-01_rb,9.999954e-01_rb,& & 9.999952e-01_rb,9.999950e-01_rb,9.999948e-01_rb,9.999946e-01_rb,9.999944e-01_rb,& & 9.999942e-01_rb,9.999939e-01_rb,9.999937e-01_rb,9.999935e-01_rb,9.999933e-01_rb,& & 9.999931e-01_rb,9.999929e-01_rb,9.999927e-01_rb,9.999925e-01_rb,9.999923e-01_rb,& & 9.999920e-01_rb,9.999918e-01_rb,9.999916e-01_rb,9.999914e-01_rb,9.999911e-01_rb,& & 9.999909e-01_rb,9.999907e-01_rb,9.999905e-01_rb,9.999902e-01_rb,9.999900e-01_rb,& & 9.999897e-01_rb /) ssaice3(:, 27) = (/ & ! band 27 & 9.999991e-01_rb,9.999985e-01_rb,9.999980e-01_rb,9.999974e-01_rb,9.999968e-01_rb,& & 9.999963e-01_rb,9.999957e-01_rb,9.999951e-01_rb,9.999946e-01_rb,9.999940e-01_rb,& & 9.999934e-01_rb,9.999929e-01_rb,9.999923e-01_rb,9.999918e-01_rb,9.999912e-01_rb,& & 9.999907e-01_rb,9.999901e-01_rb,9.999896e-01_rb,9.999891e-01_rb,9.999885e-01_rb,& & 9.999880e-01_rb,9.999874e-01_rb,9.999869e-01_rb,9.999863e-01_rb,9.999858e-01_rb,& & 9.999853e-01_rb,9.999847e-01_rb,9.999842e-01_rb,9.999836e-01_rb,9.999831e-01_rb,& & 9.999826e-01_rb,9.999820e-01_rb,9.999815e-01_rb,9.999809e-01_rb,9.999804e-01_rb,& & 9.999798e-01_rb,9.999793e-01_rb,9.999787e-01_rb,9.999782e-01_rb,9.999776e-01_rb,& & 9.999770e-01_rb,9.999765e-01_rb,9.999759e-01_rb,9.999754e-01_rb,9.999748e-01_rb,& & 9.999742e-01_rb /) ssaice3(:, 28) = (/ & ! band 28 & 9.999975e-01_rb,9.999961e-01_rb,9.999946e-01_rb,9.999931e-01_rb,9.999917e-01_rb,& & 9.999903e-01_rb,9.999888e-01_rb,9.999874e-01_rb,9.999859e-01_rb,9.999845e-01_rb,& & 9.999831e-01_rb,9.999816e-01_rb,9.999802e-01_rb,9.999788e-01_rb,9.999774e-01_rb,& & 9.999759e-01_rb,9.999745e-01_rb,9.999731e-01_rb,9.999717e-01_rb,9.999702e-01_rb,& & 9.999688e-01_rb,9.999674e-01_rb,9.999660e-01_rb,9.999646e-01_rb,9.999631e-01_rb,& & 9.999617e-01_rb,9.999603e-01_rb,9.999589e-01_rb,9.999574e-01_rb,9.999560e-01_rb,& & 9.999546e-01_rb,9.999532e-01_rb,9.999517e-01_rb,9.999503e-01_rb,9.999489e-01_rb,& & 9.999474e-01_rb,9.999460e-01_rb,9.999446e-01_rb,9.999431e-01_rb,9.999417e-01_rb,& & 9.999403e-01_rb,9.999388e-01_rb,9.999374e-01_rb,9.999359e-01_rb,9.999345e-01_rb,& & 9.999330e-01_rb /) ssaice3(:, 29) = (/ & ! band 29 & 4.526500e-01_rb,5.287890e-01_rb,5.410487e-01_rb,5.459865e-01_rb,5.485149e-01_rb,& & 5.498914e-01_rb,5.505895e-01_rb,5.508310e-01_rb,5.507364e-01_rb,5.503793e-01_rb,& & 5.498090e-01_rb,5.490612e-01_rb,5.481637e-01_rb,5.471395e-01_rb,5.460083e-01_rb,& & 5.447878e-01_rb,5.434946e-01_rb,5.421442e-01_rb,5.407514e-01_rb,5.393309e-01_rb,& & 5.378970e-01_rb,5.364641e-01_rb,5.350464e-01_rb,5.336582e-01_rb,5.323140e-01_rb,& & 5.310283e-01_rb,5.298158e-01_rb,5.286914e-01_rb,5.276704e-01_rb,5.267680e-01_rb,& & 5.260000e-01_rb,5.253823e-01_rb,5.249311e-01_rb,5.246629e-01_rb,5.245946e-01_rb,& & 5.247434e-01_rb,5.251268e-01_rb,5.257626e-01_rb,5.266693e-01_rb,5.278653e-01_rb,& & 5.293698e-01_rb,5.312022e-01_rb,5.333823e-01_rb,5.359305e-01_rb,5.388676e-01_rb,& & 5.422146e-01_rb /) ! asymmetry factor: unitless asyice3(:, 16) = (/ & ! band 16 & 8.340752e-01_rb,8.435170e-01_rb,8.517487e-01_rb,8.592064e-01_rb,8.660387e-01_rb,& & 8.723204e-01_rb,8.780997e-01_rb,8.834137e-01_rb,8.882934e-01_rb,8.927662e-01_rb,& & 8.968577e-01_rb,9.005914e-01_rb,9.039899e-01_rb,9.070745e-01_rb,9.098659e-01_rb,& & 9.123836e-01_rb,9.146466e-01_rb,9.166734e-01_rb,9.184817e-01_rb,9.200886e-01_rb,& & 9.215109e-01_rb,9.227648e-01_rb,9.238661e-01_rb,9.248304e-01_rb,9.256727e-01_rb,& & 9.264078e-01_rb,9.270505e-01_rb,9.276150e-01_rb,9.281156e-01_rb,9.285662e-01_rb,& & 9.289806e-01_rb,9.293726e-01_rb,9.297557e-01_rb,9.301435e-01_rb,9.305491e-01_rb,& & 9.309859e-01_rb,9.314671e-01_rb,9.320055e-01_rb,9.326140e-01_rb,9.333053e-01_rb,& & 9.340919e-01_rb,9.349861e-01_rb,9.360000e-01_rb,9.371451e-01_rb,9.384329e-01_rb,& & 9.398744e-01_rb /) asyice3(:, 17) = (/ & ! band 17 & 8.728160e-01_rb,8.777333e-01_rb,8.823754e-01_rb,8.867535e-01_rb,8.908785e-01_rb,& & 8.947611e-01_rb,8.984118e-01_rb,9.018408e-01_rb,9.050582e-01_rb,9.080739e-01_rb,& & 9.108976e-01_rb,9.135388e-01_rb,9.160068e-01_rb,9.183106e-01_rb,9.204595e-01_rb,& & 9.224620e-01_rb,9.243271e-01_rb,9.260632e-01_rb,9.276788e-01_rb,9.291822e-01_rb,& & 9.305817e-01_rb,9.318853e-01_rb,9.331012e-01_rb,9.342372e-01_rb,9.353013e-01_rb,& & 9.363013e-01_rb,9.372450e-01_rb,9.381400e-01_rb,9.389939e-01_rb,9.398145e-01_rb,& & 9.406092e-01_rb,9.413856e-01_rb,9.421511e-01_rb,9.429131e-01_rb,9.436790e-01_rb,& & 9.444561e-01_rb,9.452517e-01_rb,9.460729e-01_rb,9.469270e-01_rb,9.478209e-01_rb,& & 9.487617e-01_rb,9.497562e-01_rb,9.508112e-01_rb,9.519335e-01_rb,9.531294e-01_rb,& & 9.544055e-01_rb /) asyice3(:, 18) = (/ & ! band 18 & 7.897566e-01_rb,7.948704e-01_rb,7.998041e-01_rb,8.045623e-01_rb,8.091495e-01_rb,& & 8.135702e-01_rb,8.178290e-01_rb,8.219305e-01_rb,8.258790e-01_rb,8.296792e-01_rb,& & 8.333355e-01_rb,8.368524e-01_rb,8.402343e-01_rb,8.434856e-01_rb,8.466108e-01_rb,& & 8.496143e-01_rb,8.525004e-01_rb,8.552737e-01_rb,8.579384e-01_rb,8.604990e-01_rb,& & 8.629597e-01_rb,8.653250e-01_rb,8.675992e-01_rb,8.697867e-01_rb,8.718916e-01_rb,& & 8.739185e-01_rb,8.758715e-01_rb,8.777551e-01_rb,8.795734e-01_rb,8.813308e-01_rb,& & 8.830315e-01_rb,8.846799e-01_rb,8.862802e-01_rb,8.878366e-01_rb,8.893534e-01_rb,& & 8.908350e-01_rb,8.922854e-01_rb,8.937090e-01_rb,8.951099e-01_rb,8.964925e-01_rb,& & 8.978609e-01_rb,8.992192e-01_rb,9.005718e-01_rb,9.019229e-01_rb,9.032765e-01_rb,& & 9.046369e-01_rb /) asyice3(:, 19) = (/ & ! band 19 & 7.812615e-01_rb,7.887764e-01_rb,7.959664e-01_rb,8.028413e-01_rb,8.094109e-01_rb,& & 8.156849e-01_rb,8.216730e-01_rb,8.273846e-01_rb,8.328294e-01_rb,8.380166e-01_rb,& & 8.429556e-01_rb,8.476556e-01_rb,8.521258e-01_rb,8.563753e-01_rb,8.604131e-01_rb,& & 8.642481e-01_rb,8.678893e-01_rb,8.713455e-01_rb,8.746254e-01_rb,8.777378e-01_rb,& & 8.806914e-01_rb,8.834948e-01_rb,8.861566e-01_rb,8.886854e-01_rb,8.910897e-01_rb,& & 8.933779e-01_rb,8.955586e-01_rb,8.976402e-01_rb,8.996311e-01_rb,9.015398e-01_rb,& & 9.033745e-01_rb,9.051436e-01_rb,9.068555e-01_rb,9.085185e-01_rb,9.101410e-01_rb,& & 9.117311e-01_rb,9.132972e-01_rb,9.148476e-01_rb,9.163905e-01_rb,9.179340e-01_rb,& & 9.194864e-01_rb,9.210559e-01_rb,9.226505e-01_rb,9.242784e-01_rb,9.259476e-01_rb,& & 9.276661e-01_rb /) asyice3(:, 20) = (/ & ! band 20 & 7.640720e-01_rb,7.691119e-01_rb,7.739941e-01_rb,7.787222e-01_rb,7.832998e-01_rb,& & 7.877304e-01_rb,7.920177e-01_rb,7.961652e-01_rb,8.001765e-01_rb,8.040551e-01_rb,& & 8.078044e-01_rb,8.114280e-01_rb,8.149294e-01_rb,8.183119e-01_rb,8.215791e-01_rb,& & 8.247344e-01_rb,8.277812e-01_rb,8.307229e-01_rb,8.335629e-01_rb,8.363046e-01_rb,& & 8.389514e-01_rb,8.415067e-01_rb,8.439738e-01_rb,8.463560e-01_rb,8.486568e-01_rb,& & 8.508795e-01_rb,8.530274e-01_rb,8.551039e-01_rb,8.571122e-01_rb,8.590558e-01_rb,& & 8.609378e-01_rb,8.627618e-01_rb,8.645309e-01_rb,8.662485e-01_rb,8.679178e-01_rb,& & 8.695423e-01_rb,8.711251e-01_rb,8.726697e-01_rb,8.741792e-01_rb,8.756571e-01_rb,& & 8.771065e-01_rb,8.785307e-01_rb,8.799331e-01_rb,8.813169e-01_rb,8.826854e-01_rb,& & 8.840419e-01_rb /) asyice3(:, 21) = (/ & ! band 21 & 7.602598e-01_rb,7.651572e-01_rb,7.699014e-01_rb,7.744962e-01_rb,7.789452e-01_rb,& & 7.832522e-01_rb,7.874205e-01_rb,7.914538e-01_rb,7.953555e-01_rb,7.991290e-01_rb,& & 8.027777e-01_rb,8.063049e-01_rb,8.097140e-01_rb,8.130081e-01_rb,8.161906e-01_rb,& & 8.192645e-01_rb,8.222331e-01_rb,8.250993e-01_rb,8.278664e-01_rb,8.305374e-01_rb,& & 8.331153e-01_rb,8.356030e-01_rb,8.380037e-01_rb,8.403201e-01_rb,8.425553e-01_rb,& & 8.447121e-01_rb,8.467935e-01_rb,8.488022e-01_rb,8.507412e-01_rb,8.526132e-01_rb,& & 8.544210e-01_rb,8.561675e-01_rb,8.578554e-01_rb,8.594875e-01_rb,8.610665e-01_rb,& & 8.625951e-01_rb,8.640760e-01_rb,8.655119e-01_rb,8.669055e-01_rb,8.682594e-01_rb,& & 8.695763e-01_rb,8.708587e-01_rb,8.721094e-01_rb,8.733308e-01_rb,8.745255e-01_rb,& & 8.756961e-01_rb /) asyice3(:, 22) = (/ & ! band 22 & 7.568957e-01_rb,7.606995e-01_rb,7.644072e-01_rb,7.680204e-01_rb,7.715402e-01_rb,& & 7.749682e-01_rb,7.783057e-01_rb,7.815541e-01_rb,7.847148e-01_rb,7.877892e-01_rb,& & 7.907786e-01_rb,7.936846e-01_rb,7.965084e-01_rb,7.992515e-01_rb,8.019153e-01_rb,& & 8.045011e-01_rb,8.070103e-01_rb,8.094444e-01_rb,8.118048e-01_rb,8.140927e-01_rb,& & 8.163097e-01_rb,8.184571e-01_rb,8.205364e-01_rb,8.225488e-01_rb,8.244958e-01_rb,& & 8.263789e-01_rb,8.281993e-01_rb,8.299586e-01_rb,8.316580e-01_rb,8.332991e-01_rb,& & 8.348831e-01_rb,8.364115e-01_rb,8.378857e-01_rb,8.393071e-01_rb,8.406770e-01_rb,& & 8.419969e-01_rb,8.432682e-01_rb,8.444923e-01_rb,8.456706e-01_rb,8.468044e-01_rb,& & 8.478952e-01_rb,8.489444e-01_rb,8.499533e-01_rb,8.509234e-01_rb,8.518561e-01_rb,& & 8.527528e-01_rb /) asyice3(:, 23) = (/ & ! band 23 & 7.575066e-01_rb,7.606912e-01_rb,7.638236e-01_rb,7.669035e-01_rb,7.699306e-01_rb,& & 7.729046e-01_rb,7.758254e-01_rb,7.786926e-01_rb,7.815060e-01_rb,7.842654e-01_rb,& & 7.869705e-01_rb,7.896211e-01_rb,7.922168e-01_rb,7.947574e-01_rb,7.972428e-01_rb,& & 7.996726e-01_rb,8.020466e-01_rb,8.043646e-01_rb,8.066262e-01_rb,8.088313e-01_rb,& & 8.109796e-01_rb,8.130709e-01_rb,8.151049e-01_rb,8.170814e-01_rb,8.190001e-01_rb,& & 8.208608e-01_rb,8.226632e-01_rb,8.244071e-01_rb,8.260924e-01_rb,8.277186e-01_rb,& & 8.292856e-01_rb,8.307932e-01_rb,8.322411e-01_rb,8.336291e-01_rb,8.349570e-01_rb,& & 8.362244e-01_rb,8.374312e-01_rb,8.385772e-01_rb,8.396621e-01_rb,8.406856e-01_rb,& & 8.416476e-01_rb,8.425479e-01_rb,8.433861e-01_rb,8.441620e-01_rb,8.448755e-01_rb,& & 8.455263e-01_rb /) asyice3(:, 24) = (/ & ! band 24 & 7.568829e-01_rb,7.597947e-01_rb,7.626745e-01_rb,7.655212e-01_rb,7.683337e-01_rb,& & 7.711111e-01_rb,7.738523e-01_rb,7.765565e-01_rb,7.792225e-01_rb,7.818494e-01_rb,& & 7.844362e-01_rb,7.869819e-01_rb,7.894854e-01_rb,7.919459e-01_rb,7.943623e-01_rb,& & 7.967337e-01_rb,7.990590e-01_rb,8.013373e-01_rb,8.035676e-01_rb,8.057488e-01_rb,& & 8.078802e-01_rb,8.099605e-01_rb,8.119890e-01_rb,8.139645e-01_rb,8.158862e-01_rb,& & 8.177530e-01_rb,8.195641e-01_rb,8.213183e-01_rb,8.230149e-01_rb,8.246527e-01_rb,& & 8.262308e-01_rb,8.277483e-01_rb,8.292042e-01_rb,8.305976e-01_rb,8.319275e-01_rb,& & 8.331929e-01_rb,8.343929e-01_rb,8.355265e-01_rb,8.365928e-01_rb,8.375909e-01_rb,& & 8.385197e-01_rb,8.393784e-01_rb,8.401659e-01_rb,8.408815e-01_rb,8.415240e-01_rb,& & 8.420926e-01_rb /) asyice3(:, 25) = (/ & ! band 25 & 7.548616e-01_rb,7.575454e-01_rb,7.602153e-01_rb,7.628696e-01_rb,7.655067e-01_rb,& & 7.681249e-01_rb,7.707225e-01_rb,7.732978e-01_rb,7.758492e-01_rb,7.783750e-01_rb,& & 7.808735e-01_rb,7.833430e-01_rb,7.857819e-01_rb,7.881886e-01_rb,7.905612e-01_rb,& & 7.928983e-01_rb,7.951980e-01_rb,7.974588e-01_rb,7.996789e-01_rb,8.018567e-01_rb,& & 8.039905e-01_rb,8.060787e-01_rb,8.081196e-01_rb,8.101115e-01_rb,8.120527e-01_rb,& & 8.139416e-01_rb,8.157764e-01_rb,8.175557e-01_rb,8.192776e-01_rb,8.209405e-01_rb,& & 8.225427e-01_rb,8.240826e-01_rb,8.255585e-01_rb,8.269688e-01_rb,8.283117e-01_rb,& & 8.295856e-01_rb,8.307889e-01_rb,8.319198e-01_rb,8.329767e-01_rb,8.339579e-01_rb,& & 8.348619e-01_rb,8.356868e-01_rb,8.364311e-01_rb,8.370930e-01_rb,8.376710e-01_rb,& & 8.381633e-01_rb /) asyice3(:, 26) = (/ & ! band 26 & 7.491854e-01_rb,7.518523e-01_rb,7.545089e-01_rb,7.571534e-01_rb,7.597839e-01_rb,& & 7.623987e-01_rb,7.649959e-01_rb,7.675737e-01_rb,7.701303e-01_rb,7.726639e-01_rb,& & 7.751727e-01_rb,7.776548e-01_rb,7.801084e-01_rb,7.825318e-01_rb,7.849230e-01_rb,& & 7.872804e-01_rb,7.896020e-01_rb,7.918862e-01_rb,7.941309e-01_rb,7.963345e-01_rb,& & 7.984951e-01_rb,8.006109e-01_rb,8.026802e-01_rb,8.047009e-01_rb,8.066715e-01_rb,& & 8.085900e-01_rb,8.104546e-01_rb,8.122636e-01_rb,8.140150e-01_rb,8.157072e-01_rb,& & 8.173382e-01_rb,8.189063e-01_rb,8.204096e-01_rb,8.218464e-01_rb,8.232148e-01_rb,& & 8.245130e-01_rb,8.257391e-01_rb,8.268915e-01_rb,8.279682e-01_rb,8.289675e-01_rb,& & 8.298875e-01_rb,8.307264e-01_rb,8.314824e-01_rb,8.321537e-01_rb,8.327385e-01_rb,& & 8.332350e-01_rb /) asyice3(:, 27) = (/ & ! band 27 & 7.397086e-01_rb,7.424069e-01_rb,7.450955e-01_rb,7.477725e-01_rb,7.504362e-01_rb,& & 7.530846e-01_rb,7.557159e-01_rb,7.583283e-01_rb,7.609199e-01_rb,7.634888e-01_rb,& & 7.660332e-01_rb,7.685512e-01_rb,7.710411e-01_rb,7.735009e-01_rb,7.759288e-01_rb,& & 7.783229e-01_rb,7.806814e-01_rb,7.830024e-01_rb,7.852841e-01_rb,7.875246e-01_rb,& & 7.897221e-01_rb,7.918748e-01_rb,7.939807e-01_rb,7.960380e-01_rb,7.980449e-01_rb,& & 7.999995e-01_rb,8.019000e-01_rb,8.037445e-01_rb,8.055311e-01_rb,8.072581e-01_rb,& & 8.089235e-01_rb,8.105255e-01_rb,8.120623e-01_rb,8.135319e-01_rb,8.149326e-01_rb,& & 8.162626e-01_rb,8.175198e-01_rb,8.187025e-01_rb,8.198089e-01_rb,8.208371e-01_rb,& & 8.217852e-01_rb,8.226514e-01_rb,8.234338e-01_rb,8.241306e-01_rb,8.247399e-01_rb,& & 8.252599e-01_rb /) asyice3(:, 28) = (/ & ! band 28 & 7.224533e-01_rb,7.251681e-01_rb,7.278728e-01_rb,7.305654e-01_rb,7.332444e-01_rb,& & 7.359078e-01_rb,7.385539e-01_rb,7.411808e-01_rb,7.437869e-01_rb,7.463702e-01_rb,& & 7.489291e-01_rb,7.514616e-01_rb,7.539661e-01_rb,7.564408e-01_rb,7.588837e-01_rb,& & 7.612933e-01_rb,7.636676e-01_rb,7.660049e-01_rb,7.683034e-01_rb,7.705612e-01_rb,& & 7.727767e-01_rb,7.749480e-01_rb,7.770733e-01_rb,7.791509e-01_rb,7.811789e-01_rb,& & 7.831556e-01_rb,7.850791e-01_rb,7.869478e-01_rb,7.887597e-01_rb,7.905131e-01_rb,& & 7.922062e-01_rb,7.938372e-01_rb,7.954044e-01_rb,7.969059e-01_rb,7.983399e-01_rb,& & 7.997047e-01_rb,8.009985e-01_rb,8.022195e-01_rb,8.033658e-01_rb,8.044357e-01_rb,& & 8.054275e-01_rb,8.063392e-01_rb,8.071692e-01_rb,8.079157e-01_rb,8.085768e-01_rb,& & 8.091507e-01_rb /) asyice3(:, 29) = (/ & ! band 29 & 8.850026e-01_rb,9.005489e-01_rb,9.069242e-01_rb,9.121799e-01_rb,9.168987e-01_rb,& & 9.212259e-01_rb,9.252176e-01_rb,9.289028e-01_rb,9.323000e-01_rb,9.354235e-01_rb,& & 9.382858e-01_rb,9.408985e-01_rb,9.432734e-01_rb,9.454218e-01_rb,9.473557e-01_rb,& & 9.490871e-01_rb,9.506282e-01_rb,9.519917e-01_rb,9.531904e-01_rb,9.542374e-01_rb,& & 9.551461e-01_rb,9.559298e-01_rb,9.566023e-01_rb,9.571775e-01_rb,9.576692e-01_rb,& & 9.580916e-01_rb,9.584589e-01_rb,9.587853e-01_rb,9.590851e-01_rb,9.593729e-01_rb,& & 9.596632e-01_rb,9.599705e-01_rb,9.603096e-01_rb,9.606954e-01_rb,9.611427e-01_rb,& & 9.616667e-01_rb,9.622826e-01_rb,9.630060e-01_rb,9.638524e-01_rb,9.648379e-01_rb,& & 9.659788e-01_rb,9.672916e-01_rb,9.687933e-01_rb,9.705014e-01_rb,9.724337e-01_rb,& & 9.746084e-01_rb /) ! fdelta: unitless fdlice3(:, 16) = (/ & ! band 16 & 4.959277e-02_rb,4.685292e-02_rb,4.426104e-02_rb,4.181231e-02_rb,3.950191e-02_rb,& & 3.732500e-02_rb,3.527675e-02_rb,3.335235e-02_rb,3.154697e-02_rb,2.985578e-02_rb,& & 2.827395e-02_rb,2.679666e-02_rb,2.541909e-02_rb,2.413640e-02_rb,2.294378e-02_rb,& & 2.183639e-02_rb,2.080940e-02_rb,1.985801e-02_rb,1.897736e-02_rb,1.816265e-02_rb,& & 1.740905e-02_rb,1.671172e-02_rb,1.606585e-02_rb,1.546661e-02_rb,1.490917e-02_rb,& & 1.438870e-02_rb,1.390038e-02_rb,1.343939e-02_rb,1.300089e-02_rb,1.258006e-02_rb,& & 1.217208e-02_rb,1.177212e-02_rb,1.137536e-02_rb,1.097696e-02_rb,1.057210e-02_rb,& & 1.015596e-02_rb,9.723704e-03_rb,9.270516e-03_rb,8.791565e-03_rb,8.282026e-03_rb,& & 7.737072e-03_rb,7.151879e-03_rb,6.521619e-03_rb,5.841467e-03_rb,5.106597e-03_rb,& & 4.312183e-03_rb /) fdlice3(:, 17) = (/ & ! band 17 & 5.071224e-02_rb,5.000217e-02_rb,4.933872e-02_rb,4.871992e-02_rb,4.814380e-02_rb,& & 4.760839e-02_rb,4.711170e-02_rb,4.665177e-02_rb,4.622662e-02_rb,4.583426e-02_rb,& & 4.547274e-02_rb,4.514007e-02_rb,4.483428e-02_rb,4.455340e-02_rb,4.429544e-02_rb,& & 4.405844e-02_rb,4.384041e-02_rb,4.363939e-02_rb,4.345340e-02_rb,4.328047e-02_rb,& & 4.311861e-02_rb,4.296586e-02_rb,4.282024e-02_rb,4.267977e-02_rb,4.254248e-02_rb,& & 4.240640e-02_rb,4.226955e-02_rb,4.212995e-02_rb,4.198564e-02_rb,4.183462e-02_rb,& & 4.167494e-02_rb,4.150462e-02_rb,4.132167e-02_rb,4.112413e-02_rb,4.091003e-02_rb,& & 4.067737e-02_rb,4.042420e-02_rb,4.014854e-02_rb,3.984840e-02_rb,3.952183e-02_rb,& & 3.916683e-02_rb,3.878144e-02_rb,3.836368e-02_rb,3.791158e-02_rb,3.742316e-02_rb,& & 3.689645e-02_rb /) fdlice3(:, 18) = (/ & ! band 18 & 1.062938e-01_rb,1.065234e-01_rb,1.067822e-01_rb,1.070682e-01_rb,1.073793e-01_rb,& & 1.077137e-01_rb,1.080693e-01_rb,1.084442e-01_rb,1.088364e-01_rb,1.092439e-01_rb,& & 1.096647e-01_rb,1.100970e-01_rb,1.105387e-01_rb,1.109878e-01_rb,1.114423e-01_rb,& & 1.119004e-01_rb,1.123599e-01_rb,1.128190e-01_rb,1.132757e-01_rb,1.137279e-01_rb,& & 1.141738e-01_rb,1.146113e-01_rb,1.150385e-01_rb,1.154534e-01_rb,1.158540e-01_rb,& & 1.162383e-01_rb,1.166045e-01_rb,1.169504e-01_rb,1.172741e-01_rb,1.175738e-01_rb,& & 1.178472e-01_rb,1.180926e-01_rb,1.183080e-01_rb,1.184913e-01_rb,1.186405e-01_rb,& & 1.187538e-01_rb,1.188291e-01_rb,1.188645e-01_rb,1.188580e-01_rb,1.188076e-01_rb,& & 1.187113e-01_rb,1.185672e-01_rb,1.183733e-01_rb,1.181277e-01_rb,1.178282e-01_rb,& & 1.174731e-01_rb /) fdlice3(:, 19) = (/ & ! band 19 & 1.076195e-01_rb,1.065195e-01_rb,1.054696e-01_rb,1.044673e-01_rb,1.035099e-01_rb,& & 1.025951e-01_rb,1.017203e-01_rb,1.008831e-01_rb,1.000808e-01_rb,9.931116e-02_rb,& & 9.857151e-02_rb,9.785939e-02_rb,9.717230e-02_rb,9.650774e-02_rb,9.586322e-02_rb,& & 9.523623e-02_rb,9.462427e-02_rb,9.402484e-02_rb,9.343544e-02_rb,9.285358e-02_rb,& & 9.227675e-02_rb,9.170245e-02_rb,9.112818e-02_rb,9.055144e-02_rb,8.996974e-02_rb,& & 8.938056e-02_rb,8.878142e-02_rb,8.816981e-02_rb,8.754323e-02_rb,8.689919e-02_rb,& & 8.623517e-02_rb,8.554869e-02_rb,8.483724e-02_rb,8.409832e-02_rb,8.332943e-02_rb,& & 8.252807e-02_rb,8.169175e-02_rb,8.081795e-02_rb,7.990419e-02_rb,7.894796e-02_rb,& & 7.794676e-02_rb,7.689809e-02_rb,7.579945e-02_rb,7.464834e-02_rb,7.344227e-02_rb,& & 7.217872e-02_rb /) fdlice3(:, 20) = (/ & ! band 20 & 1.119014e-01_rb,1.122706e-01_rb,1.126690e-01_rb,1.130947e-01_rb,1.135456e-01_rb,& & 1.140199e-01_rb,1.145154e-01_rb,1.150302e-01_rb,1.155623e-01_rb,1.161096e-01_rb,& & 1.166703e-01_rb,1.172422e-01_rb,1.178233e-01_rb,1.184118e-01_rb,1.190055e-01_rb,& & 1.196025e-01_rb,1.202008e-01_rb,1.207983e-01_rb,1.213931e-01_rb,1.219832e-01_rb,& & 1.225665e-01_rb,1.231411e-01_rb,1.237050e-01_rb,1.242561e-01_rb,1.247926e-01_rb,& & 1.253122e-01_rb,1.258132e-01_rb,1.262934e-01_rb,1.267509e-01_rb,1.271836e-01_rb,& & 1.275896e-01_rb,1.279669e-01_rb,1.283134e-01_rb,1.286272e-01_rb,1.289063e-01_rb,& & 1.291486e-01_rb,1.293522e-01_rb,1.295150e-01_rb,1.296351e-01_rb,1.297104e-01_rb,& & 1.297390e-01_rb,1.297189e-01_rb,1.296480e-01_rb,1.295244e-01_rb,1.293460e-01_rb,& & 1.291109e-01_rb /) fdlice3(:, 21) = (/ & ! band 21 & 1.133298e-01_rb,1.136777e-01_rb,1.140556e-01_rb,1.144615e-01_rb,1.148934e-01_rb,& & 1.153492e-01_rb,1.158269e-01_rb,1.163243e-01_rb,1.168396e-01_rb,1.173706e-01_rb,& & 1.179152e-01_rb,1.184715e-01_rb,1.190374e-01_rb,1.196108e-01_rb,1.201897e-01_rb,& & 1.207720e-01_rb,1.213558e-01_rb,1.219389e-01_rb,1.225194e-01_rb,1.230951e-01_rb,& & 1.236640e-01_rb,1.242241e-01_rb,1.247733e-01_rb,1.253096e-01_rb,1.258309e-01_rb,& & 1.263352e-01_rb,1.268205e-01_rb,1.272847e-01_rb,1.277257e-01_rb,1.281415e-01_rb,& & 1.285300e-01_rb,1.288893e-01_rb,1.292173e-01_rb,1.295118e-01_rb,1.297710e-01_rb,& & 1.299927e-01_rb,1.301748e-01_rb,1.303154e-01_rb,1.304124e-01_rb,1.304637e-01_rb,& & 1.304673e-01_rb,1.304212e-01_rb,1.303233e-01_rb,1.301715e-01_rb,1.299638e-01_rb,& & 1.296983e-01_rb /) fdlice3(:, 22) = (/ & ! band 22 & 1.145360e-01_rb,1.153256e-01_rb,1.161453e-01_rb,1.169929e-01_rb,1.178666e-01_rb,& & 1.187641e-01_rb,1.196835e-01_rb,1.206227e-01_rb,1.215796e-01_rb,1.225522e-01_rb,& & 1.235383e-01_rb,1.245361e-01_rb,1.255433e-01_rb,1.265579e-01_rb,1.275779e-01_rb,& & 1.286011e-01_rb,1.296257e-01_rb,1.306494e-01_rb,1.316703e-01_rb,1.326862e-01_rb,& & 1.336951e-01_rb,1.346950e-01_rb,1.356838e-01_rb,1.366594e-01_rb,1.376198e-01_rb,& & 1.385629e-01_rb,1.394866e-01_rb,1.403889e-01_rb,1.412678e-01_rb,1.421212e-01_rb,& & 1.429469e-01_rb,1.437430e-01_rb,1.445074e-01_rb,1.452381e-01_rb,1.459329e-01_rb,& & 1.465899e-01_rb,1.472069e-01_rb,1.477819e-01_rb,1.483128e-01_rb,1.487976e-01_rb,& & 1.492343e-01_rb,1.496207e-01_rb,1.499548e-01_rb,1.502346e-01_rb,1.504579e-01_rb,& & 1.506227e-01_rb /) fdlice3(:, 23) = (/ & ! band 23 & 1.153263e-01_rb,1.161445e-01_rb,1.169932e-01_rb,1.178703e-01_rb,1.187738e-01_rb,& & 1.197016e-01_rb,1.206516e-01_rb,1.216217e-01_rb,1.226099e-01_rb,1.236141e-01_rb,& & 1.246322e-01_rb,1.256621e-01_rb,1.267017e-01_rb,1.277491e-01_rb,1.288020e-01_rb,& & 1.298584e-01_rb,1.309163e-01_rb,1.319736e-01_rb,1.330281e-01_rb,1.340778e-01_rb,& & 1.351207e-01_rb,1.361546e-01_rb,1.371775e-01_rb,1.381873e-01_rb,1.391820e-01_rb,& & 1.401593e-01_rb,1.411174e-01_rb,1.420540e-01_rb,1.429671e-01_rb,1.438547e-01_rb,& & 1.447146e-01_rb,1.455449e-01_rb,1.463433e-01_rb,1.471078e-01_rb,1.478364e-01_rb,& & 1.485270e-01_rb,1.491774e-01_rb,1.497857e-01_rb,1.503497e-01_rb,1.508674e-01_rb,& & 1.513367e-01_rb,1.517554e-01_rb,1.521216e-01_rb,1.524332e-01_rb,1.526880e-01_rb,& & 1.528840e-01_rb /) fdlice3(:, 24) = (/ & ! band 24 & 1.160842e-01_rb,1.169118e-01_rb,1.177697e-01_rb,1.186556e-01_rb,1.195676e-01_rb,& & 1.205036e-01_rb,1.214616e-01_rb,1.224394e-01_rb,1.234349e-01_rb,1.244463e-01_rb,& & 1.254712e-01_rb,1.265078e-01_rb,1.275539e-01_rb,1.286075e-01_rb,1.296664e-01_rb,& & 1.307287e-01_rb,1.317923e-01_rb,1.328550e-01_rb,1.339149e-01_rb,1.349699e-01_rb,& & 1.360179e-01_rb,1.370567e-01_rb,1.380845e-01_rb,1.390991e-01_rb,1.400984e-01_rb,& & 1.410803e-01_rb,1.420429e-01_rb,1.429840e-01_rb,1.439016e-01_rb,1.447936e-01_rb,& & 1.456579e-01_rb,1.464925e-01_rb,1.472953e-01_rb,1.480642e-01_rb,1.487972e-01_rb,& & 1.494923e-01_rb,1.501472e-01_rb,1.507601e-01_rb,1.513287e-01_rb,1.518511e-01_rb,& & 1.523252e-01_rb,1.527489e-01_rb,1.531201e-01_rb,1.534368e-01_rb,1.536969e-01_rb,& & 1.538984e-01_rb /) fdlice3(:, 25) = (/ & ! band 25 & 1.168725e-01_rb,1.177088e-01_rb,1.185747e-01_rb,1.194680e-01_rb,1.203867e-01_rb,& & 1.213288e-01_rb,1.222923e-01_rb,1.232750e-01_rb,1.242750e-01_rb,1.252903e-01_rb,& & 1.263187e-01_rb,1.273583e-01_rb,1.284069e-01_rb,1.294626e-01_rb,1.305233e-01_rb,& & 1.315870e-01_rb,1.326517e-01_rb,1.337152e-01_rb,1.347756e-01_rb,1.358308e-01_rb,& & 1.368788e-01_rb,1.379175e-01_rb,1.389449e-01_rb,1.399590e-01_rb,1.409577e-01_rb,& & 1.419389e-01_rb,1.429007e-01_rb,1.438410e-01_rb,1.447577e-01_rb,1.456488e-01_rb,& & 1.465123e-01_rb,1.473461e-01_rb,1.481483e-01_rb,1.489166e-01_rb,1.496492e-01_rb,& & 1.503439e-01_rb,1.509988e-01_rb,1.516118e-01_rb,1.521808e-01_rb,1.527038e-01_rb,& & 1.531788e-01_rb,1.536037e-01_rb,1.539764e-01_rb,1.542951e-01_rb,1.545575e-01_rb,& & 1.547617e-01_rb /) fdlice3(:, 26) = (/ & !band 26 & 1.180509e-01_rb,1.189025e-01_rb,1.197820e-01_rb,1.206875e-01_rb,1.216171e-01_rb,& & 1.225687e-01_rb,1.235404e-01_rb,1.245303e-01_rb,1.255363e-01_rb,1.265564e-01_rb,& & 1.275888e-01_rb,1.286313e-01_rb,1.296821e-01_rb,1.307392e-01_rb,1.318006e-01_rb,& & 1.328643e-01_rb,1.339284e-01_rb,1.349908e-01_rb,1.360497e-01_rb,1.371029e-01_rb,& & 1.381486e-01_rb,1.391848e-01_rb,1.402095e-01_rb,1.412208e-01_rb,1.422165e-01_rb,& & 1.431949e-01_rb,1.441539e-01_rb,1.450915e-01_rb,1.460058e-01_rb,1.468947e-01_rb,& & 1.477564e-01_rb,1.485888e-01_rb,1.493900e-01_rb,1.501580e-01_rb,1.508907e-01_rb,& & 1.515864e-01_rb,1.522428e-01_rb,1.528582e-01_rb,1.534305e-01_rb,1.539578e-01_rb,& & 1.544380e-01_rb,1.548692e-01_rb,1.552494e-01_rb,1.555767e-01_rb,1.558490e-01_rb,& & 1.560645e-01_rb /) fdlice3(:, 27) = (/ & ! band 27 & 1.200480e-01_rb,1.209267e-01_rb,1.218304e-01_rb,1.227575e-01_rb,1.237059e-01_rb,& & 1.246739e-01_rb,1.256595e-01_rb,1.266610e-01_rb,1.276765e-01_rb,1.287041e-01_rb,& & 1.297420e-01_rb,1.307883e-01_rb,1.318412e-01_rb,1.328988e-01_rb,1.339593e-01_rb,& & 1.350207e-01_rb,1.360813e-01_rb,1.371393e-01_rb,1.381926e-01_rb,1.392396e-01_rb,& & 1.402783e-01_rb,1.413069e-01_rb,1.423235e-01_rb,1.433263e-01_rb,1.443134e-01_rb,& & 1.452830e-01_rb,1.462332e-01_rb,1.471622e-01_rb,1.480681e-01_rb,1.489490e-01_rb,& & 1.498032e-01_rb,1.506286e-01_rb,1.514236e-01_rb,1.521863e-01_rb,1.529147e-01_rb,& & 1.536070e-01_rb,1.542614e-01_rb,1.548761e-01_rb,1.554491e-01_rb,1.559787e-01_rb,& & 1.564629e-01_rb,1.568999e-01_rb,1.572879e-01_rb,1.576249e-01_rb,1.579093e-01_rb,& & 1.581390e-01_rb /) fdlice3(:, 28) = (/ & ! band 28 & 1.247813e-01_rb,1.256496e-01_rb,1.265417e-01_rb,1.274560e-01_rb,1.283905e-01_rb,& & 1.293436e-01_rb,1.303135e-01_rb,1.312983e-01_rb,1.322964e-01_rb,1.333060e-01_rb,& & 1.343252e-01_rb,1.353523e-01_rb,1.363855e-01_rb,1.374231e-01_rb,1.384632e-01_rb,& & 1.395042e-01_rb,1.405441e-01_rb,1.415813e-01_rb,1.426140e-01_rb,1.436404e-01_rb,& & 1.446587e-01_rb,1.456672e-01_rb,1.466640e-01_rb,1.476475e-01_rb,1.486157e-01_rb,& & 1.495671e-01_rb,1.504997e-01_rb,1.514117e-01_rb,1.523016e-01_rb,1.531673e-01_rb,& & 1.540073e-01_rb,1.548197e-01_rb,1.556026e-01_rb,1.563545e-01_rb,1.570734e-01_rb,& & 1.577576e-01_rb,1.584054e-01_rb,1.590149e-01_rb,1.595843e-01_rb,1.601120e-01_rb,& & 1.605962e-01_rb,1.610349e-01_rb,1.614266e-01_rb,1.617693e-01_rb,1.620614e-01_rb,& & 1.623011e-01_rb /) fdlice3(:, 29) = (/ & ! band 29 & 1.006055e-01_rb,9.549582e-02_rb,9.063960e-02_rb,8.602900e-02_rb,8.165612e-02_rb,& & 7.751308e-02_rb,7.359199e-02_rb,6.988496e-02_rb,6.638412e-02_rb,6.308156e-02_rb,& & 5.996942e-02_rb,5.703979e-02_rb,5.428481e-02_rb,5.169657e-02_rb,4.926719e-02_rb,& & 4.698880e-02_rb,4.485349e-02_rb,4.285339e-02_rb,4.098061e-02_rb,3.922727e-02_rb,& & 3.758547e-02_rb,3.604733e-02_rb,3.460497e-02_rb,3.325051e-02_rb,3.197604e-02_rb,& & 3.077369e-02_rb,2.963558e-02_rb,2.855381e-02_rb,2.752050e-02_rb,2.652776e-02_rb,& & 2.556772e-02_rb,2.463247e-02_rb,2.371415e-02_rb,2.280485e-02_rb,2.189670e-02_rb,& & 2.098180e-02_rb,2.005228e-02_rb,1.910024e-02_rb,1.811781e-02_rb,1.709709e-02_rb,& & 1.603020e-02_rb,1.490925e-02_rb,1.372635e-02_rb,1.247363e-02_rb,1.114319e-02_rb,& & 9.727157e-03_rb /) end subroutine swcldpr end module rrtmg_sw_init ! path: $Source: /cvsroot/NWP/WRFV3/phys/module_ra_rrtmg_sw.F,v $ ! author: $Author: trn $ ! revision: $Revision: 1.3 $ ! created: $Date: 2009/04/16 19:54:22 $ ! module rrtmg_sw_vrtqdr ! -------------------------------------------------------------------------- ! | | ! | Copyright 2002-2008, Atmospheric & Environmental Research, Inc. (AER). | ! | This software may be used, copied, or redistributed as long as it is | ! | not sold and this copyright notice is reproduced on each copy made. | ! | This model is provided as is without any express or implied warranties. | ! | (http://www.rtweb.aer.com/) | ! | | ! -------------------------------------------------------------------------- ! ------- Modules ------- use parkind, only: im => kind_im, rb => kind_rb ! use parrrsw, only: ngptsw implicit none contains ! -------------------------------------------------------------------------- subroutine vrtqdr_sw(klev, kw, & pref, prefd, ptra, ptrad, & pdbt, prdnd, prup, prupd, ptdbt, & pfd, pfu) ! -------------------------------------------------------------------------- ! Purpose: This routine performs the vertical quadrature integration ! ! Interface: *vrtqdr_sw* is called from *spcvrt_sw* and *spcvmc_sw* ! ! Modifications. ! ! Original: H. Barker ! Revision: Integrated with rrtmg_sw, J.-J. Morcrette, ECMWF, Oct 2002 ! Revision: Reformatted for consistency with rrtmg_lw: MJIacono, AER, Jul 2006 ! !----------------------------------------------------------------------- ! ------- Declarations ------- ! Input integer(kind=im), intent (in) :: klev ! number of model layers integer(kind=im), intent (in) :: kw ! g-point index real(kind=rb), intent(in) :: pref(:) ! direct beam reflectivity ! Dimensions: (nlayers+1) real(kind=rb), intent(in) :: prefd(:) ! diffuse beam reflectivity ! Dimensions: (nlayers+1) real(kind=rb), intent(in) :: ptra(:) ! direct beam transmissivity ! Dimensions: (nlayers+1) real(kind=rb), intent(in) :: ptrad(:) ! diffuse beam transmissivity ! Dimensions: (nlayers+1) real(kind=rb), intent(in) :: pdbt(:) ! Dimensions: (nlayers+1) real(kind=rb), intent(in) :: ptdbt(:) ! Dimensions: (nlayers+1) real(kind=rb), intent(inout) :: prdnd(:) ! Dimensions: (nlayers+1) real(kind=rb), intent(inout) :: prup(:) ! Dimensions: (nlayers+1) real(kind=rb), intent(inout) :: prupd(:) ! Dimensions: (nlayers+1) ! Output real(kind=rb), intent(out) :: pfd(:,:) ! downwelling flux (W/m2) ! Dimensions: (nlayers+1,ngptsw) ! unadjusted for earth/sun distance or zenith angle real(kind=rb), intent(out) :: pfu(:,:) ! upwelling flux (W/m2) ! Dimensions: (nlayers+1,ngptsw) ! unadjusted for earth/sun distance or zenith angle ! Local integer(kind=im) :: ikp, ikx, jk real(kind=rb) :: zreflect real(kind=rb) :: ztdn(klev+1) ! Definitions ! ! pref(jk) direct reflectance ! prefd(jk) diffuse reflectance ! ptra(jk) direct transmittance ! ptrad(jk) diffuse transmittance ! ! pdbt(jk) layer mean direct beam transmittance ! ptdbt(jk) total direct beam transmittance at levels ! !----------------------------------------------------------------------------- ! Link lowest layer with surface zreflect = 1._rb / (1._rb - prefd(klev+1) * prefd(klev)) prup(klev) = pref(klev) + (ptrad(klev) * & ((ptra(klev) - pdbt(klev)) * prefd(klev+1) + & pdbt(klev) * pref(klev+1))) * zreflect prupd(klev) = prefd(klev) + ptrad(klev) * ptrad(klev) * & prefd(klev+1) * zreflect ! Pass from bottom to top do jk = 1,klev-1 ikp = klev+1-jk ikx = ikp-1 zreflect = 1._rb / (1._rb -prupd(ikp) * prefd(ikx)) prup(ikx) = pref(ikx) + (ptrad(ikx) * & ((ptra(ikx) - pdbt(ikx)) * prupd(ikp) + & pdbt(ikx) * prup(ikp))) * zreflect prupd(ikx) = prefd(ikx) + ptrad(ikx) * ptrad(ikx) * & prupd(ikp) * zreflect enddo ! Upper boundary conditions ztdn(1) = 1._rb prdnd(1) = 0._rb ztdn(2) = ptra(1) prdnd(2) = prefd(1) ! Pass from top to bottom do jk = 2,klev ikp = jk+1 zreflect = 1._rb / (1._rb - prefd(jk) * prdnd(jk)) ztdn(ikp) = ptdbt(jk) * ptra(jk) + & (ptrad(jk) * ((ztdn(jk) - ptdbt(jk)) + & ptdbt(jk) * pref(jk) * prdnd(jk))) * zreflect prdnd(ikp) = prefd(jk) + ptrad(jk) * ptrad(jk) * & prdnd(jk) * zreflect enddo ! Up and down-welling fluxes at levels do jk = 1,klev+1 zreflect = 1._rb / (1._rb - prdnd(jk) * prupd(jk)) pfu(jk,kw) = (ptdbt(jk) * prup(jk) + & (ztdn(jk) - ptdbt(jk)) * prupd(jk)) * zreflect pfd(jk,kw) = ptdbt(jk) + (ztdn(jk) - ptdbt(jk)+ & ptdbt(jk) * prup(jk) * prdnd(jk)) * zreflect enddo end subroutine vrtqdr_sw end module rrtmg_sw_vrtqdr ! path: $Source: /cvsroot/NWP/WRFV3/phys/module_ra_rrtmg_sw.F,v $ ! author: $Author: trn $ ! revision: $Revision: 1.3 $ ! created: $Date: 2009/04/16 19:54:22 $ module rrtmg_sw_spcvmc ! -------------------------------------------------------------------------- ! | | ! | Copyright 2002-2008, Atmospheric & Environmental Research, Inc. (AER). | ! | This software may be used, copied, or redistributed as long as it is | ! | not sold and this copyright notice is reproduced on each copy made. | ! | This model is provided as is without any express or implied warranties. | ! | (http://www.rtweb.aer.com/) | ! | | ! -------------------------------------------------------------------------- ! ------- Modules ------- use parkind, only : im => kind_im, rb => kind_rb use parrrsw, only : nbndsw, ngptsw, mxmol, jpband use rrsw_tbl, only : tblint, bpade, od_lo, exp_tbl use rrsw_vsn, only : hvrspc, hnamspc use rrsw_wvn, only : ngc, ngs use rrtmg_sw_reftra, only: reftra_sw use rrtmg_sw_taumol, only: taumol_sw use rrtmg_sw_vrtqdr, only: vrtqdr_sw implicit none contains ! --------------------------------------------------------------------------- subroutine spcvmc_sw & (nlayers, istart, iend, icpr, iout, & pavel, tavel, pz, tz, tbound, palbd, palbp, & pcldfmc, ptaucmc, pasycmc, pomgcmc, ptaormc, & ptaua, pasya, pomga, prmu0, coldry, wkl, adjflux, & laytrop, layswtch, laylow, jp, jt, jt1, & co2mult, colch4, colco2, colh2o, colmol, coln2o, colo2, colo3, & fac00, fac01, fac10, fac11, & selffac, selffrac, indself, forfac, forfrac, indfor, & pbbfd, pbbfu, pbbcd, pbbcu, puvfd, puvcd, pnifd, pnicd, & pbbfddir, pbbcddir, puvfddir, puvcddir, pnifddir, pnicddir) ! --------------------------------------------------------------------------- ! ! Purpose: Contains spectral loop to compute the shortwave radiative fluxes, ! using the two-stream method of H. Barker and McICA, the Monte-Carlo ! Independent Column Approximation, for the representation of ! sub-grid cloud variability (i.e. cloud overlap). ! ! Interface: *spcvmc_sw* is called from *rrtmg_sw.F90* or rrtmg_sw.1col.F90* ! ! Method: ! Adapted from two-stream model of H. Barker; ! Two-stream model options (selected with kmodts in rrtmg_sw_reftra.F90): ! 1: Eddington, 2: PIFM, Zdunkowski et al., 3: discret ordinates ! ! Modifications: ! ! Original: H. Barker ! Revision: Merge with RRTMG_SW: J.-J.Morcrette, ECMWF, Feb 2003 ! Revision: Add adjustment for Earth/Sun distance : MJIacono, AER, Oct 2003 ! Revision: Bug fix for use of PALBP and PALBD: MJIacono, AER, Nov 2003 ! Revision: Bug fix to apply delta scaling to clear sky: AER, Dec 2004 ! Revision: Code modified so that delta scaling is not done in cloudy profiles ! if routine cldprop is used; delta scaling can be applied by swithcing ! code below if cldprop is not used to get cloud properties. ! AER, Jan 2005 ! Revision: Modified to use McICA: MJIacono, AER, Nov 2005 ! Revision: Uniform formatting for RRTMG: MJIacono, AER, Jul 2006 ! Revision: Use exponential lookup table for transmittance: MJIacono, AER, ! Aug 2007 ! ! ------------------------------------------------------------------ ! ------- Declarations ------ ! ------- Input ------- integer(kind=im), intent(in) :: nlayers integer(kind=im), intent(in) :: istart integer(kind=im), intent(in) :: iend integer(kind=im), intent(in) :: icpr integer(kind=im), intent(in) :: iout integer(kind=im), intent(in) :: laytrop integer(kind=im), intent(in) :: layswtch integer(kind=im), intent(in) :: laylow integer(kind=im), intent(in) :: indfor(:) ! Dimensions: (nlayers) integer(kind=im), intent(in) :: indself(:) ! Dimensions: (nlayers) integer(kind=im), intent(in) :: jp(:) ! Dimensions: (nlayers) integer(kind=im), intent(in) :: jt(:) ! Dimensions: (nlayers) integer(kind=im), intent(in) :: jt1(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: pavel(:) ! layer pressure (hPa, mb) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: tavel(:) ! layer temperature (K) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: pz(0:) ! level (interface) pressure (hPa, mb) ! Dimensions: (0:nlayers) real(kind=rb), intent(in) :: tz(0:) ! level temperatures (hPa, mb) ! Dimensions: (0:nlayers) real(kind=rb), intent(in) :: tbound ! surface temperature (K) real(kind=rb), intent(in) :: wkl(:,:) ! molecular amounts (mol/cm2) ! Dimensions: (mxmol,nlayers) real(kind=rb), intent(in) :: coldry(:) ! dry air column density (mol/cm2) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colmol(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: adjflux(:) ! Earth/Sun distance adjustment ! Dimensions: (jpband) real(kind=rb), intent(in) :: palbd(:) ! surface albedo (diffuse) ! Dimensions: (nbndsw) real(kind=rb), intent(in) :: palbp(:) ! surface albedo (direct) ! Dimensions: (nbndsw) real(kind=rb), intent(in) :: prmu0 ! cosine of solar zenith angle real(kind=rb), intent(in) :: pcldfmc(:,:) ! cloud fraction [mcica] ! Dimensions: (nlayers,ngptsw) real(kind=rb), intent(in) :: ptaucmc(:,:) ! cloud optical depth [mcica] ! Dimensions: (nlayers,ngptsw) real(kind=rb), intent(in) :: pasycmc(:,:) ! cloud asymmetry parameter [mcica] ! Dimensions: (nlayers,ngptsw) real(kind=rb), intent(in) :: pomgcmc(:,:) ! cloud single scattering albedo [mcica] ! Dimensions: (nlayers,ngptsw) real(kind=rb), intent(in) :: ptaormc(:,:) ! cloud optical depth, non-delta scaled [mcica] ! Dimensions: (nlayers,ngptsw) real(kind=rb), intent(in) :: ptaua(:,:) ! aerosol optical depth ! Dimensions: (nlayers,nbndsw) real(kind=rb), intent(in) :: pasya(:,:) ! aerosol asymmetry parameter ! Dimensions: (nlayers,nbndsw) real(kind=rb), intent(in) :: pomga(:,:) ! aerosol single scattering albedo ! Dimensions: (nlayers,nbndsw) real(kind=rb), intent(in) :: colh2o(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colco2(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colch4(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: co2mult(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colo3(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: colo2(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: coln2o(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: forfac(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: forfrac(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: selffac(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: selffrac(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: fac00(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: fac01(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: fac10(:) ! Dimensions: (nlayers) real(kind=rb), intent(in) :: fac11(:) ! Dimensions: (nlayers) ! ------- Output ------- ! All Dimensions: (nlayers+1) real(kind=rb), intent(out) :: pbbcd(:) real(kind=rb), intent(out) :: pbbcu(:) real(kind=rb), intent(out) :: pbbfd(:) real(kind=rb), intent(out) :: pbbfu(:) real(kind=rb), intent(out) :: pbbfddir(:) real(kind=rb), intent(out) :: pbbcddir(:) real(kind=rb), intent(out) :: puvcd(:) real(kind=rb), intent(out) :: puvfd(:) real(kind=rb), intent(out) :: puvcddir(:) real(kind=rb), intent(out) :: puvfddir(:) real(kind=rb), intent(out) :: pnicd(:) real(kind=rb), intent(out) :: pnifd(:) real(kind=rb), intent(out) :: pnicddir(:) real(kind=rb), intent(out) :: pnifddir(:) ! Output - inactive ! All Dimensions: (nlayers+1) ! real(kind=rb), intent(out) :: puvcu(:) ! real(kind=rb), intent(out) :: puvfu(:) ! real(kind=rb), intent(out) :: pnicu(:) ! real(kind=rb), intent(out) :: pnifu(:) ! real(kind=rb), intent(out) :: pvscd(:) ! real(kind=rb), intent(out) :: pvscu(:) ! real(kind=rb), intent(out) :: pvsfd(:) ! real(kind=rb), intent(out) :: pvsfu(:) ! ------- Local ------- logical :: lrtchkclr(nlayers),lrtchkcld(nlayers) integer(kind=im) :: klev integer(kind=im) :: ib1, ib2, ibm, igt, ikl, ikp, ikx integer(kind=im) :: iw, jb, jg, jl, jk ! integer(kind=im), parameter :: nuv = ?? ! integer(kind=im), parameter :: nvs = ?? integer(kind=im) :: itind real(kind=rb) :: tblind, ze1 real(kind=rb) :: zclear, zcloud real(kind=rb) :: zdbt(nlayers+1), zdbt_nodel(nlayers+1) real(kind=rb) :: zgc(nlayers), zgcc(nlayers), zgco(nlayers) real(kind=rb) :: zomc(nlayers), zomcc(nlayers), zomco(nlayers) real(kind=rb) :: zrdnd(nlayers+1), zrdndc(nlayers+1) real(kind=rb) :: zref(nlayers+1), zrefc(nlayers+1), zrefo(nlayers+1) real(kind=rb) :: zrefd(nlayers+1), zrefdc(nlayers+1), zrefdo(nlayers+1) real(kind=rb) :: zrup(nlayers+1), zrupd(nlayers+1) real(kind=rb) :: zrupc(nlayers+1), zrupdc(nlayers+1) real(kind=rb) :: zs1(nlayers+1) real(kind=rb) :: ztauc(nlayers), ztauo(nlayers) real(kind=rb) :: ztdn(nlayers+1), ztdnd(nlayers+1), ztdbt(nlayers+1) real(kind=rb) :: ztoc(nlayers), ztor(nlayers) real(kind=rb) :: ztra(nlayers+1), ztrac(nlayers+1), ztrao(nlayers+1) real(kind=rb) :: ztrad(nlayers+1), ztradc(nlayers+1), ztrado(nlayers+1) real(kind=rb) :: zdbtc(nlayers+1), ztdbtc(nlayers+1) real(kind=rb) :: zincflx(ngptsw), zdbtc_nodel(nlayers+1) real(kind=rb) :: ztdbt_nodel(nlayers+1), ztdbtc_nodel(nlayers+1) real(kind=rb) :: zdbtmc, zdbtmo, zf, zgw, zreflect real(kind=rb) :: zwf, tauorig, repclc ! real(kind=rb) :: zincflux ! inactive ! Arrays from rrtmg_sw_taumoln routines ! real(kind=rb) :: ztaug(nlayers,16), ztaur(nlayers,16) ! real(kind=rb) :: zsflxzen(16) real(kind=rb) :: ztaug(nlayers,ngptsw), ztaur(nlayers,ngptsw) real(kind=rb) :: zsflxzen(ngptsw) ! Arrays from rrtmg_sw_vrtqdr routine real(kind=rb) :: zcd(nlayers+1,ngptsw), zcu(nlayers+1,ngptsw) real(kind=rb) :: zfd(nlayers+1,ngptsw), zfu(nlayers+1,ngptsw) ! Inactive arrays ! real(kind=rb) :: zbbcd(nlayers+1), zbbcu(nlayers+1) ! real(kind=rb) :: zbbfd(nlayers+1), zbbfu(nlayers+1) ! real(kind=rb) :: zbbfddir(nlayers+1), zbbcddir(nlayers+1) ! ------------------------------------------------------------------ ! Initializations ib1 = istart ib2 = iend klev = nlayers iw = 0 repclc = 1.e-12_rb ! zincflux = 0.0_rb do jk=1,klev+1 pbbcd(jk)=0._rb pbbcu(jk)=0._rb pbbfd(jk)=0._rb pbbfu(jk)=0._rb pbbcddir(jk)=0._rb pbbfddir(jk)=0._rb puvcd(jk)=0._rb puvfd(jk)=0._rb puvcddir(jk)=0._rb puvfddir(jk)=0._rb pnicd(jk)=0._rb pnifd(jk)=0._rb pnicddir(jk)=0._rb pnifddir(jk)=0._rb enddo ! Calculate the optical depths for gaseous absorption and Rayleigh scattering call taumol_sw(klev, & colh2o, colco2, colch4, colo2, colo3, colmol, & laytrop, jp, jt, jt1, & fac00, fac01, fac10, fac11, & selffac, selffrac, indself, forfac, forfrac, indfor, & zsflxzen, ztaug, ztaur) ! Top of shortwave spectral band loop, jb = 16 -> 29; ibm = 1 -> 14 do jb = ib1, ib2 ibm = jb-15 igt = ngc(ibm) ! Reinitialize g-point counter for each band if output for each band is requested. if (iout.gt.0.and.ibm.ge.2) iw = ngs(ibm-1) ! do jk=1,klev+1 ! zbbcd(jk)=0.0_rb ! zbbcu(jk)=0.0_rb ! zbbfd(jk)=0.0_rb ! zbbfu(jk)=0.0_rb ! enddo ! Top of g-point interval loop within each band (iw is cumulative counter) do jg = 1,igt iw = iw+1 ! Apply adjustment for correct Earth/Sun distance and zenith angle to incoming solar flux zincflx(iw) = adjflux(jb) * zsflxzen(iw) * prmu0 ! zincflux = zincflux + adjflux(jb) * zsflxzen(iw) * prmu0 ! inactive ! Compute layer reflectances and transmittances for direct and diffuse sources, ! first clear then cloudy ! zrefc(jk) direct albedo for clear ! zrefo(jk) direct albedo for cloud ! zrefdc(jk) diffuse albedo for clear ! zrefdo(jk) diffuse albedo for cloud ! ztrac(jk) direct transmittance for clear ! ztrao(jk) direct transmittance for cloudy ! ztradc(jk) diffuse transmittance for clear ! ztrado(jk) diffuse transmittance for cloudy ! ! zref(jk) direct reflectance ! zrefd(jk) diffuse reflectance ! ztra(jk) direct transmittance ! ztrad(jk) diffuse transmittance ! ! zdbtc(jk) clear direct beam transmittance ! zdbto(jk) cloudy direct beam transmittance ! zdbt(jk) layer mean direct beam transmittance ! ztdbt(jk) total direct beam transmittance at levels ! Clear-sky ! TOA direct beam ztdbtc(1)=1.0_rb ztdbtc_nodel(1)=1.0_rb ! Surface values zdbtc(klev+1) =0.0_rb ztrac(klev+1) =0.0_rb ztradc(klev+1)=0.0_rb zrefc(klev+1) =palbp(ibm) zrefdc(klev+1)=palbd(ibm) zrupc(klev+1) =palbp(ibm) zrupdc(klev+1)=palbd(ibm) ! Total sky ! TOA direct beam ztdbt(1)=1.0_rb ztdbt_nodel(1)=1.0_rb ! Surface values zdbt(klev+1) =0.0_rb ztra(klev+1) =0.0_rb ztrad(klev+1)=0.0_rb zref(klev+1) =palbp(ibm) zrefd(klev+1)=palbd(ibm) zrup(klev+1) =palbp(ibm) zrupd(klev+1)=palbd(ibm) ! Top of layer loop do jk=1,klev ! Note: two-stream calculations proceed from top to bottom; ! RRTMG_SW quantities are given bottom to top and are reversed here ikl=klev+1-jk ! Set logical flag to do REFTRA calculation ! Do REFTRA for all clear layers lrtchkclr(jk)=.true. ! Do REFTRA only for cloudy layers in profile, since already done for clear layers lrtchkcld(jk)=.false. lrtchkcld(jk)=(pcldfmc(ikl,iw) > repclc) ! Clear-sky optical parameters - this section inactive ! Original ! ztauc(jk) = ztaur(ikl,iw) + ztaug(ikl,iw) ! zomcc(jk) = ztaur(ikl,iw) / ztauc(jk) ! zgcc(jk) = 0.0001_rb ! Total sky optical parameters ! ztauo(jk) = ztaur(ikl,iw) + ztaug(ikl,iw) + ptaucmc(ikl,iw) ! zomco(jk) = ptaucmc(ikl,iw) * pomgcmc(ikl,iw) + ztaur(ikl,iw) ! zgco (jk) = (ptaucmc(ikl,iw) * pomgcmc(ikl,iw) * pasycmc(ikl,iw) + & ! ztaur(ikl,iw) * 0.0001_rb) / zomco(jk) ! zomco(jk) = zomco(jk) / ztauo(jk) ! Clear-sky optical parameters including aerosols ztauc(jk) = ztaur(ikl,iw) + ztaug(ikl,iw) + ptaua(ikl,ibm) zomcc(jk) = ztaur(ikl,iw) * 1.0_rb + ptaua(ikl,ibm) * pomga(ikl,ibm) zgcc(jk) = pasya(ikl,ibm) * pomga(ikl,ibm) * ptaua(ikl,ibm) / zomcc(jk) zomcc(jk) = zomcc(jk) / ztauc(jk) ! Pre-delta-scaling clear and cloudy direct beam transmittance (must use 'orig', unscaled cloud OD) ! \/\/\/ This block of code is only needed for direct beam calculation ! zclear = 1.0_rb - pcldfmc(ikl,iw) zcloud = pcldfmc(ikl,iw) ! Clear ! zdbtmc = exp(-ztauc(jk) / prmu0) ! Use exponential lookup table for transmittance, or expansion of ! exponential for low tau ze1 = ztauc(jk) / prmu0 if (ze1 .le. od_lo) then zdbtmc = 1._rb - ze1 + 0.5_rb * ze1 * ze1 else tblind = ze1 / (bpade + ze1) itind = tblint * tblind + 0.5_rb zdbtmc = exp_tbl(itind) endif zdbtc_nodel(jk) = zdbtmc ztdbtc_nodel(jk+1) = zdbtc_nodel(jk) * ztdbtc_nodel(jk) ! Clear + Cloud tauorig = ztauc(jk) + ptaormc(ikl,iw) ! zdbtmo = exp(-tauorig / prmu0) ! Use exponential lookup table for transmittance, or expansion of ! exponential for low tau ze1 = tauorig / prmu0 if (ze1 .le. od_lo) then zdbtmo = 1._rb - ze1 + 0.5_rb * ze1 * ze1 else tblind = ze1 / (bpade + ze1) itind = tblint * tblind + 0.5_rb zdbtmo = exp_tbl(itind) endif zdbt_nodel(jk) = zclear*zdbtmc + zcloud*zdbtmo ztdbt_nodel(jk+1) = zdbt_nodel(jk) * ztdbt_nodel(jk) ! /\/\/\ Above code only needed for direct beam calculation ! Delta scaling - clear zf = zgcc(jk) * zgcc(jk) zwf = zomcc(jk) * zf ztauc(jk) = (1.0_rb - zwf) * ztauc(jk) zomcc(jk) = (zomcc(jk) - zwf) / (1.0_rb - zwf) zgcc (jk) = (zgcc(jk) - zf) / (1.0_rb - zf) ! Total sky optical parameters (cloud properties already delta-scaled) ! Use this code if cloud properties are derived in rrtmg_sw_cldprop if (icpr .ge. 1) then ztauo(jk) = ztauc(jk) + ptaucmc(ikl,iw) zomco(jk) = ztauc(jk) * zomcc(jk) + ptaucmc(ikl,iw) * pomgcmc(ikl,iw) zgco (jk) = (ptaucmc(ikl,iw) * pomgcmc(ikl,iw) * pasycmc(ikl,iw) + & ztauc(jk) * zomcc(jk) * zgcc(jk)) / zomco(jk) zomco(jk) = zomco(jk) / ztauo(jk) ! Total sky optical parameters (if cloud properties not delta scaled) ! Use this code if cloud properties are not derived in rrtmg_sw_cldprop elseif (icpr .eq. 0) then ztauo(jk) = ztaur(ikl,iw) + ztaug(ikl,iw) + ptaua(ikl,ibm) + ptaucmc(ikl,iw) zomco(jk) = ptaua(ikl,ibm) * pomga(ikl,ibm) + ptaucmc(ikl,iw) * pomgcmc(ikl,iw) + & ztaur(ikl,iw) * 1.0_rb zgco (jk) = (ptaucmc(ikl,iw) * pomgcmc(ikl,iw) * pasycmc(ikl,iw) + & ptaua(ikl,ibm)*pomga(ikl,ibm)*pasya(ikl,ibm)) / zomco(jk) zomco(jk) = zomco(jk) / ztauo(jk) ! Delta scaling - clouds ! Use only if subroutine rrtmg_sw_cldprop is not used to get cloud properties and to apply delta scaling zf = zgco(jk) * zgco(jk) zwf = zomco(jk) * zf ztauo(jk) = (1._rb - zwf) * ztauo(jk) zomco(jk) = (zomco(jk) - zwf) / (1.0_rb - zwf) zgco (jk) = (zgco(jk) - zf) / (1.0_rb - zf) endif ! End of layer loop enddo ! Clear sky reflectivities call reftra_sw (klev, & lrtchkclr, zgcc, prmu0, ztauc, zomcc, & zrefc, zrefdc, ztrac, ztradc) ! Total sky reflectivities call reftra_sw (klev, & lrtchkcld, zgco, prmu0, ztauo, zomco, & zrefo, zrefdo, ztrao, ztrado) do jk=1,klev ! Combine clear and cloudy contributions for total sky ikl = klev+1-jk zclear = 1.0_rb - pcldfmc(ikl,iw) zcloud = pcldfmc(ikl,iw) zref(jk) = zclear*zrefc(jk) + zcloud*zrefo(jk) zrefd(jk)= zclear*zrefdc(jk) + zcloud*zrefdo(jk) ztra(jk) = zclear*ztrac(jk) + zcloud*ztrao(jk) ztrad(jk)= zclear*ztradc(jk) + zcloud*ztrado(jk) ! Direct beam transmittance ! Clear ! zdbtmc = exp(-ztauc(jk) / prmu0) ! Use exponential lookup table for transmittance, or expansion of ! exponential for low tau ze1 = ztauc(jk) / prmu0 if (ze1 .le. od_lo) then zdbtmc = 1._rb - ze1 + 0.5_rb * ze1 * ze1 else tblind = ze1 / (bpade + ze1) itind = tblint * tblind + 0.5_rb zdbtmc = exp_tbl(itind) endif zdbtc(jk) = zdbtmc ztdbtc(jk+1) = zdbtc(jk)*ztdbtc(jk) ! Clear + Cloud ! zdbtmo = exp(-ztauo(jk) / prmu0) ! Use exponential lookup table for transmittance, or expansion of ! exponential for low tau ze1 = ztauo(jk) / prmu0 if (ze1 .le. od_lo) then zdbtmo = 1._rb - ze1 + 0.5_rb * ze1 * ze1 else tblind = ze1 / (bpade + ze1) itind = tblint * tblind + 0.5_rb zdbtmo = exp_tbl(itind) endif zdbt(jk) = zclear*zdbtmc + zcloud*zdbtmo ztdbt(jk+1) = zdbt(jk)*ztdbt(jk) enddo ! Vertical quadrature for clear-sky fluxes call vrtqdr_sw(klev, iw, & zrefc, zrefdc, ztrac, ztradc, & zdbtc, zrdndc, zrupc, zrupdc, ztdbtc, & zcd, zcu) ! Vertical quadrature for cloudy fluxes call vrtqdr_sw(klev, iw, & zref, zrefd, ztra, ztrad, & zdbt, zrdnd, zrup, zrupd, ztdbt, & zfd, zfu) ! Upwelling and downwelling fluxes at levels ! Two-stream calculations go from top to bottom; ! layer indexing is reversed to go bottom to top for output arrays do jk=1,klev+1 ikl=klev+2-jk ! Accumulate spectral fluxes over bands - inactive ! zbbfu(ikl) = zbbfu(ikl) + zincflx(iw)*zfu(jk,iw) ! zbbfd(ikl) = zbbfd(ikl) + zincflx(iw)*zfd(jk,iw) ! zbbcu(ikl) = zbbcu(ikl) + zincflx(iw)*zcu(jk,iw) ! zbbcd(ikl) = zbbcd(ikl) + zincflx(iw)*zcd(jk,iw) ! zbbfddir(ikl) = zbbfddir(ikl) + zincflx(iw)*ztdbt_nodel(jk) ! zbbcddir(ikl) = zbbcddir(ikl) + zincflx(iw)*ztdbtc_nodel(jk) ! Accumulate spectral fluxes over whole spectrum pbbfu(ikl) = pbbfu(ikl) + zincflx(iw)*zfu(jk,iw) pbbfd(ikl) = pbbfd(ikl) + zincflx(iw)*zfd(jk,iw) pbbcu(ikl) = pbbcu(ikl) + zincflx(iw)*zcu(jk,iw) pbbcd(ikl) = pbbcd(ikl) + zincflx(iw)*zcd(jk,iw) pbbfddir(ikl) = pbbfddir(ikl) + zincflx(iw)*ztdbt_nodel(jk) pbbcddir(ikl) = pbbcddir(ikl) + zincflx(iw)*ztdbtc_nodel(jk) ! Accumulate direct fluxes for UV/visible bands if (ibm >= 10 .and. ibm <= 13) then puvcd(ikl) = puvcd(ikl) + zincflx(iw)*zcd(jk,iw) puvfd(ikl) = puvfd(ikl) + zincflx(iw)*zfd(jk,iw) puvcddir(ikl) = puvcddir(ikl) + zincflx(iw)*ztdbtc_nodel(jk) puvfddir(ikl) = puvfddir(ikl) + zincflx(iw)*ztdbt_nodel(jk) ! Accumulate direct fluxes for near-IR bands else if (ibm == 14 .or. ibm <= 9) then pnicd(ikl) = pnicd(ikl) + zincflx(iw)*zcd(jk,iw) pnifd(ikl) = pnifd(ikl) + zincflx(iw)*zfd(jk,iw) pnicddir(ikl) = pnicddir(ikl) + zincflx(iw)*ztdbtc_nodel(jk) pnifddir(ikl) = pnifddir(ikl) + zincflx(iw)*ztdbt_nodel(jk) endif enddo ! End loop on jg, g-point interval enddo ! End loop on jb, spectral band enddo end subroutine spcvmc_sw end module rrtmg_sw_spcvmc ! path: $Source: /cvsroot/NWP/WRFV3/phys/module_ra_rrtmg_sw.F,v $ ! author: $Author: trn $ ! revision: $Revision: 1.3 $ ! created: $Date: 2009/04/16 19:54:22 $ ! module rrtmg_sw_rad ! -------------------------------------------------------------------------- ! | | ! | Copyright 2002-2008, Atmospheric & Environmental Research, Inc. (AER). | ! | This software may be used, copied, or redistributed as long as it is | ! | not sold and this copyright notice is reproduced on each copy made. | ! | This model is provided as is without any express or implied warranties. | ! | (http://www.rtweb.aer.com/) | ! | | ! -------------------------------------------------------------------------- ! ! **************************************************************************** ! * * ! * RRTMG_SW * ! * * ! * * ! * * ! * a rapid radiative transfer model * ! * for the solar spectral region * ! * for application to general circulation models * ! * * ! * * ! * Atmospheric and Environmental Research, Inc. * ! * 131 Hartwell Avenue * ! * Lexington, MA 02421 * ! * * ! * * ! * Eli J. Mlawer * ! * Jennifer S. Delamere * ! * Michael J. Iacono * ! * Shepard A. Clough * ! * * ! * * ! * * ! * * ! * * ! * * ! * email: miacono@aer.com * ! * email: emlawer@aer.com * ! * email: jdelamer@aer.com * ! * * ! * The authors wish to acknowledge the contributions of the * ! * following people: Steven J. Taubman, Patrick D. Brown, * ! * Ronald E. Farren, Luke Chen, Robert Bergstrom. * ! * * ! **************************************************************************** ! --------- Modules --------- use parkind, only : im => kind_im, rb => kind_rb use rrsw_vsn use mcica_subcol_gen_sw, only: mcica_subcol_sw use rrtmg_sw_cldprmc, only: cldprmc_sw ! *** Move the required call to rrtmg_sw_ini below and the following ! use association to GCM initialization area *** ! use rrtmg_sw_init, only: rrtmg_sw_ini use rrtmg_sw_setcoef, only: setcoef_sw use rrtmg_sw_spcvmc, only: spcvmc_sw implicit none ! public interfaces/functions/subroutines public :: rrtmg_sw, inatm_sw, earth_sun !------------------------------------------------------------------ contains !------------------------------------------------------------------ !------------------------------------------------------------------ ! Public subroutines !------------------------------------------------------------------ subroutine rrtmg_sw & (ncol ,nlay ,icld , & play ,plev ,tlay ,tlev ,tsfc , & h2ovmr , o3vmr ,co2vmr ,ch4vmr ,n2ovmr ,o2vmr , & asdir ,asdif ,aldir ,aldif , & coszen ,adjes ,dyofyr ,scon , & inflgsw ,iceflgsw,liqflgsw,cldfmcl , & taucmcl ,ssacmcl ,asmcmcl ,fsfcmcl , & ciwpmcl ,clwpmcl ,reicmcl ,relqmcl , & tauaer ,ssaaer ,asmaer ,ecaer , & swuflx ,swdflx ,swhr ,swuflxc ,swdflxc ,swhrc) ! ------- Description ------- ! This program is the driver for RRTMG_SW, the AER SW radiation model for ! application to GCMs, that has been adapted from RRTM_SW for improved ! efficiency and to provide fractional cloudiness and cloud overlap ! capability using McICA. ! ! Note: The call to RRTMG_SW_INI should be moved to the GCM initialization ! area, since this has to be called only once. ! ! This routine ! b) calls INATM_SW to read in the atmospheric profile; ! all layering in RRTMG is ordered from surface to toa. ! c) calls CLDPRMC_SW to set cloud optical depth for McICA based ! on input cloud properties ! d) calls SETCOEF_SW to calculate various quantities needed for ! the radiative transfer algorithm ! e) calls SPCVMC to call the two-stream model that in turn ! calls TAUMOL to calculate gaseous optical depths for each ! of the 16 spectral bands and to perform the radiative transfer ! using McICA, the Monte-Carlo Independent Column Approximation, ! to represent sub-grid scale cloud variability ! f) passes the calculated fluxes and cooling rates back to GCM ! ! Two modes of operation are possible: ! The mode is chosen by using either rrtmg_sw.nomcica.f90 (to not use ! McICA) or rrtmg_sw.f90 (to use McICA) to interface with a GCM. ! ! 1) Standard, single forward model calculation (imca = 0); this is ! valid only for clear sky or fully overcast clouds ! 2) Monte Carlo Independent Column Approximation (McICA, Pincus et al., ! JC, 2003) method is applied to the forward model calculation (imca = 1) ! This method is valid for clear sky or partial cloud conditions. ! ! This call to RRTMG_SW must be preceeded by a call to the module ! mcica_subcol_gen_sw.f90 to run the McICA sub-column cloud generator, ! which will provide the cloud physical or cloud optical properties ! on the RRTMG quadrature point (ngptsw) dimension. ! ! Two methods of cloud property input are possible: ! Cloud properties can be input in one of two ways (controlled by input ! flags inflag, iceflag and liqflag; see text file rrtmg_sw_instructions ! and subroutine rrtmg_sw_cldprop.f90 for further details): ! ! 1) Input cloud fraction, cloud optical depth, single scattering albedo ! and asymmetry parameter directly (inflgsw = 0) ! 2) Input cloud fraction and cloud physical properties: ice fracion, ! ice and liquid particle sizes (inflgsw = 1 or 2); ! cloud optical properties are calculated by cldprop or cldprmc based ! on input settings of iceflgsw and liqflgsw ! ! Two methods of aerosol property input are possible: ! Aerosol properties can be input in one of two ways (controlled by input ! flag iaer, see text file rrtmg_sw_instructions for further details): ! ! 1) Input aerosol optical depth, single scattering albedo and asymmetry ! parameter directly by layer and spectral band (iaer=10) ! 2) Input aerosol optical depth and 0.55 micron directly by layer and use ! one or more of six ECMWF aerosol types (iaer=6) ! ! ! ------- Modifications ------- ! ! This version of RRTMG_SW has been modified from RRTM_SW to use a reduced ! set of g-point intervals and a two-stream model for application to GCMs. ! !-- Original version (derived from RRTM_SW) ! 2002: AER. Inc. !-- Conversion to F90 formatting; addition of 2-stream radiative transfer ! Feb 2003: J.-J. Morcrette, ECMWF !-- Additional modifications for GCM application ! Aug 2003: M. J. Iacono, AER Inc. !-- Total number of g-points reduced from 224 to 112. Original ! set of 224 can be restored by exchanging code in module parrrsw.f90 ! and in file rrtmg_sw_init.f90. ! Apr 2004: M. J. Iacono, AER, Inc. !-- Modifications to include output for direct and diffuse ! downward fluxes. There are output as "true" fluxes without ! any delta scaling applied. Code can be commented to exclude ! this calculation in source file rrtmg_sw_spcvrt.f90. ! Jan 2005: E. J. Mlawer, M. J. Iacono, AER, Inc. !-- Revised to add McICA capability. ! Nov 2005: M. J. Iacono, AER, Inc. !-- Reformatted for consistency with rrtmg_lw. ! Feb 2007: M. J. Iacono, AER, Inc. !-- Modifications to formatting to use assumed-shape arrays. ! Aug 2007: M. J. Iacono, AER, Inc. ! --------- Modules --------- use parrrsw, only : nbndsw, ngptsw, naerec, nstr, nmol, mxmol, & jpband, jpb1, jpb2 use rrsw_aer, only : rsrtaua, rsrpiza, rsrasya use rrsw_con, only : heatfac, oneminus, pi use rrsw_wvn, only : wavenum1, wavenum2 ! ------- Declarations ! ----- Input ----- integer(kind=im), intent(in) :: ncol ! Number of horizontal columns integer(kind=im), intent(in) :: nlay ! Number of model layers integer(kind=im), intent(inout) :: icld ! Cloud overlap method ! 0: Clear only ! 1: Random ! 2: Maximum/random ! 3: Maximum real(kind=rb), intent(in) :: play(:,:) ! Layer pressures (hPa, mb) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: plev(:,:) ! Interface pressures (hPa, mb) ! Dimensions: (ncol,nlay+1) real(kind=rb), intent(in) :: tlay(:,:) ! Layer temperatures (K) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: tlev(:,:) ! Interface temperatures (K) ! Dimensions: (ncol,nlay+1) real(kind=rb), intent(in) :: tsfc(:) ! Surface temperature (K) ! Dimensions: (ncol) real(kind=rb), intent(in) :: h2ovmr(:,:) ! H2O volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: o3vmr(:,:) ! O3 volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: co2vmr(:,:) ! CO2 volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: ch4vmr(:,:) ! Methane volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: n2ovmr(:,:) ! Nitrous oxide volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: o2vmr(:,:) ! Oxygen volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: asdir(:) ! UV/vis surface albedo direct rad ! Dimensions: (ncol) real(kind=rb), intent(in) :: aldir(:) ! Near-IR surface albedo direct rad ! Dimensions: (ncol) real(kind=rb), intent(in) :: asdif(:) ! UV/vis surface albedo: diffuse rad ! Dimensions: (ncol) real(kind=rb), intent(in) :: aldif(:) ! Near-IR surface albedo: diffuse rad ! Dimensions: (ncol) integer(kind=im), intent(in) :: dyofyr ! Day of the year (used to get Earth/Sun ! distance if adjflx not provided) real(kind=rb), intent(in) :: adjes ! Flux adjustment for Earth/Sun distance real(kind=rb), intent(in) :: coszen(:) ! Cosine of solar zenith angle ! Dimensions: (ncol) real(kind=rb), intent(in) :: scon ! Solar constant (W/m2) integer(kind=im), intent(in) :: inflgsw ! Flag for cloud optical properties integer(kind=im), intent(in) :: iceflgsw ! Flag for ice particle specification integer(kind=im), intent(in) :: liqflgsw ! Flag for liquid droplet specification real(kind=rb), intent(in) :: cldfmcl(:,:,:) ! Cloud fraction ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: taucmcl(:,:,:) ! In-cloud optical depth ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: ssacmcl(:,:,:) ! In-cloud single scattering albedo ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: asmcmcl(:,:,:) ! In-cloud asymmetry parameter ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: fsfcmcl(:,:,:) ! In-cloud forward scattering fraction ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: ciwpmcl(:,:,:) ! In-cloud ice water path (g/m2) ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: clwpmcl(:,:,:) ! In-cloud liquid water path (g/m2) ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: reicmcl(:,:) ! Cloud ice effective radius (microns) ! Dimensions: (ncol,nlay) ! specific definition of reicmcl depends on setting of iceflglw: ! iceflglw = 0: ice effective radius, r_ec, (Ebert and Curry, 1992), ! r_ec must be >= 10.0 microns ! iceflglw = 1: ice effective radius, r_ec, (Ebert and Curry, 1992), ! r_ec range is limited to 13.0 to 130.0 microns ! iceflglw = 2: ice effective radius, r_k, (Key, Streamer Ref. Manual, 1996) ! r_k range is limited to 5.0 to 131.0 microns ! iceflglw = 3: generalized effective size, dge, (Fu, 1996), ! dge range is limited to 5.0 to 140.0 microns ! [dge = 1.0315 * r_ec] real(kind=rb), intent(in) :: relqmcl(:,:) ! Cloud water drop effective radius (microns) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: tauaer(:,:,:) ! Aerosol optical depth (iaer=10 only) ! Dimensions: (ncol,nlay,nbndsw) ! (non-delta scaled) real(kind=rb), intent(in) :: ssaaer(:,:,:) ! Aerosol single scattering albedo (iaer=10 only) ! Dimensions: (ncol,nlay,nbndsw) ! (non-delta scaled) real(kind=rb), intent(in) :: asmaer(:,:,:) ! Aerosol asymmetry parameter (iaer=10 only) ! Dimensions: (ncol,nlay,nbndsw) ! (non-delta scaled) real(kind=rb), intent(in) :: ecaer(:,:,:) ! Aerosol optical depth at 0.55 micron (iaer=6 only) ! Dimensions: (ncol,nlay,naerec) ! (non-delta scaled) ! ----- Output ----- real(kind=rb), intent(out) :: swuflx(:,:) ! Total sky shortwave upward flux (W/m2) ! Dimensions: (ncol,nlay+1) real(kind=rb), intent(out) :: swdflx(:,:) ! Total sky shortwave downward flux (W/m2) ! Dimensions: (ncol,nlay+1) real(kind=rb), intent(out) :: swhr(:,:) ! Total sky shortwave radiative heating rate (K/d) ! Dimensions: (ncol,nlay) real(kind=rb), intent(out) :: swuflxc(:,:) ! Clear sky shortwave upward flux (W/m2) ! Dimensions: (ncol,nlay+1) real(kind=rb), intent(out) :: swdflxc(:,:) ! Clear sky shortwave downward flux (W/m2) ! Dimensions: (ncol,nlay+1) real(kind=rb), intent(out) :: swhrc(:,:) ! Clear sky shortwave radiative heating rate (K/d) ! Dimensions: (ncol,nlay) ! ----- Local ----- ! Control integer(kind=im) :: nlayers ! total number of layers integer(kind=im) :: istart ! beginning band of calculation integer(kind=im) :: iend ! ending band of calculation integer(kind=im) :: icpr ! cldprop/cldprmc use flag integer(kind=im) :: iout ! output option flag (inactive) integer(kind=im) :: iaer ! aerosol option flag integer(kind=im) :: idelm ! delta-m scaling flag (inactive) integer(kind=im) :: isccos ! instrumental cosine response flag (inactive) integer(kind=im) :: iplon ! column loop index integer(kind=im) :: i ! layer loop index ! jk integer(kind=im) :: ib ! band loop index ! jsw integer(kind=im) :: ia, ig ! indices integer(kind=im) :: k ! layer loop index integer(kind=im) :: ims ! value for changing mcica permute seed integer(kind=im) :: imca ! flag for mcica [0=off, 1=on] real(kind=rb) :: zepsec, zepzen ! epsilon real(kind=rb) :: zdpgcp ! flux to heating conversion ratio ! Atmosphere real(kind=rb) :: pavel(nlay+1) ! layer pressures (mb) real(kind=rb) :: tavel(nlay+1) ! layer temperatures (K) real(kind=rb) :: pz(0:nlay+1) ! level (interface) pressures (hPa, mb) real(kind=rb) :: tz(0:nlay+1) ! level (interface) temperatures (K) real(kind=rb) :: tbound ! surface temperature (K) real(kind=rb) :: pdp(nlay+1) ! layer pressure thickness (hPa, mb) real(kind=rb) :: coldry(nlay+1) ! dry air column amount real(kind=rb) :: wkl(mxmol,nlay+1) ! molecular amounts (mol/cm-2) ! real(kind=rb) :: earth_sun ! function for Earth/Sun distance factor real(kind=rb) :: cossza ! Cosine of solar zenith angle real(kind=rb) :: adjflux(jpband) ! adjustment for current Earth/Sun distance real(kind=rb) :: solvar(jpband) ! solar constant scaling factor from rrtmg_sw ! default value of 1368.22 Wm-2 at 1 AU real(kind=rb) :: albdir(nbndsw) ! surface albedo, direct ! zalbp real(kind=rb) :: albdif(nbndsw) ! surface albedo, diffuse ! zalbd real(kind=rb) :: taua(nlay+1,nbndsw) ! Aerosol optical depth real(kind=rb) :: ssaa(nlay+1,nbndsw) ! Aerosol single scattering albedo real(kind=rb) :: asma(nlay+1,nbndsw) ! Aerosol asymmetry parameter ! Atmosphere - setcoef integer(kind=im) :: laytrop ! tropopause layer index integer(kind=im) :: layswtch ! tropopause layer index integer(kind=im) :: laylow ! tropopause layer index integer(kind=im) :: jp(nlay+1) ! integer(kind=im) :: jt(nlay+1) ! integer(kind=im) :: jt1(nlay+1) ! real(kind=rb) :: colh2o(nlay+1) ! column amount (h2o) real(kind=rb) :: colco2(nlay+1) ! column amount (co2) real(kind=rb) :: colo3(nlay+1) ! column amount (o3) real(kind=rb) :: coln2o(nlay+1) ! column amount (n2o) real(kind=rb) :: colch4(nlay+1) ! column amount (ch4) real(kind=rb) :: colo2(nlay+1) ! column amount (o2) real(kind=rb) :: colmol(nlay+1) ! column amount real(kind=rb) :: co2mult(nlay+1) ! column amount integer(kind=im) :: indself(nlay+1) integer(kind=im) :: indfor(nlay+1) real(kind=rb) :: selffac(nlay+1) real(kind=rb) :: selffrac(nlay+1) real(kind=rb) :: forfac(nlay+1) real(kind=rb) :: forfrac(nlay+1) real(kind=rb) :: & ! fac00(nlay+1), fac01(nlay+1), & fac10(nlay+1), fac11(nlay+1) ! Atmosphere/clouds - cldprop integer(kind=im) :: ncbands ! number of cloud spectral bands integer(kind=im) :: inflag ! flag for cloud property method integer(kind=im) :: iceflag ! flag for ice cloud properties integer(kind=im) :: liqflag ! flag for liquid cloud properties ! real(kind=rb) :: cldfrac(nlay+1) ! layer cloud fraction ! real(kind=rb) :: tauc(nlay+1) ! in-cloud optical depth (non-delta scaled) ! real(kind=rb) :: ssac(nlay+1) ! in-cloud single scattering albedo (non-delta scaled) ! real(kind=rb) :: asmc(nlay+1) ! in-cloud asymmetry parameter (non-delta scaled) ! real(kind=rb) :: fsfc(nlay+1) ! in-cloud forward scattering fraction (non-delta scaled) ! real(kind=rb) :: ciwp(nlay+1) ! in-cloud ice water path ! real(kind=rb) :: clwp(nlay+1) ! in-cloud liquid water path ! real(kind=rb) :: rei(nlay+1) ! cloud ice particle size ! real(kind=rb) :: rel(nlay+1) ! cloud liquid particle size ! real(kind=rb) :: taucloud(nlay+1,jpband) ! in-cloud optical depth ! real(kind=rb) :: taucldorig(nlay+1,jpband)! in-cloud optical depth (non-delta scaled) ! real(kind=rb) :: ssacloud(nlay+1,jpband) ! in-cloud single scattering albedo ! real(kind=rb) :: asmcloud(nlay+1,jpband) ! in-cloud asymmetry parameter ! Atmosphere/clouds - cldprmc [mcica] real(kind=rb) :: cldfmc(ngptsw,nlay+1) ! cloud fraction [mcica] real(kind=rb) :: ciwpmc(ngptsw,nlay+1) ! in-cloud ice water path [mcica] real(kind=rb) :: clwpmc(ngptsw,nlay+1) ! in-cloud liquid water path [mcica] real(kind=rb) :: relqmc(nlay+1) ! liquid particle effective radius (microns) real(kind=rb) :: reicmc(nlay+1) ! ice particle effective size (microns) real(kind=rb) :: taucmc(ngptsw,nlay+1) ! in-cloud optical depth [mcica] real(kind=rb) :: taormc(ngptsw,nlay+1) ! unscaled in-cloud optical depth [mcica] real(kind=rb) :: ssacmc(ngptsw,nlay+1) ! in-cloud single scattering albedo [mcica] real(kind=rb) :: asmcmc(ngptsw,nlay+1) ! in-cloud asymmetry parameter [mcica] real(kind=rb) :: fsfcmc(ngptsw,nlay+1) ! in-cloud forward scattering fraction [mcica] ! Atmosphere/clouds/aerosol - spcvrt,spcvmc real(kind=rb) :: ztauc(nlay+1,nbndsw) ! cloud optical depth real(kind=rb) :: ztaucorig(nlay+1,nbndsw) ! unscaled cloud optical depth real(kind=rb) :: zasyc(nlay+1,nbndsw) ! cloud asymmetry parameter ! (first moment of phase function) real(kind=rb) :: zomgc(nlay+1,nbndsw) ! cloud single scattering albedo real(kind=rb) :: ztaua(nlay+1,nbndsw) ! total aerosol optical depth real(kind=rb) :: zasya(nlay+1,nbndsw) ! total aerosol asymmetry parameter real(kind=rb) :: zomga(nlay+1,nbndsw) ! total aerosol single scattering albedo real(kind=rb) :: zcldfmc(nlay+1,ngptsw) ! cloud fraction [mcica] real(kind=rb) :: ztaucmc(nlay+1,ngptsw) ! cloud optical depth [mcica] real(kind=rb) :: ztaormc(nlay+1,ngptsw) ! unscaled cloud optical depth [mcica] real(kind=rb) :: zasycmc(nlay+1,ngptsw) ! cloud asymmetry parameter [mcica] real(kind=rb) :: zomgcmc(nlay+1,ngptsw) ! cloud single scattering albedo [mcica] real(kind=rb) :: zbbfu(nlay+2) ! temporary upward shortwave flux (w/m2) real(kind=rb) :: zbbfd(nlay+2) ! temporary downward shortwave flux (w/m2) real(kind=rb) :: zbbcu(nlay+2) ! temporary clear sky upward shortwave flux (w/m2) real(kind=rb) :: zbbcd(nlay+2) ! temporary clear sky downward shortwave flux (w/m2) real(kind=rb) :: zbbfddir(nlay+2) ! temporary downward direct shortwave flux (w/m2) real(kind=rb) :: zbbcddir(nlay+2) ! temporary clear sky downward direct shortwave flux (w/m2) real(kind=rb) :: zuvfd(nlay+2) ! temporary UV downward shortwave flux (w/m2) real(kind=rb) :: zuvcd(nlay+2) ! temporary clear sky UV downward shortwave flux (w/m2) real(kind=rb) :: zuvfddir(nlay+2) ! temporary UV downward direct shortwave flux (w/m2) real(kind=rb) :: zuvcddir(nlay+2) ! temporary clear sky UV downward direct shortwave flux (w/m2) real(kind=rb) :: znifd(nlay+2) ! temporary near-IR downward shortwave flux (w/m2) real(kind=rb) :: znicd(nlay+2) ! temporary clear sky near-IR downward shortwave flux (w/m2) real(kind=rb) :: znifddir(nlay+2) ! temporary near-IR downward direct shortwave flux (w/m2) real(kind=rb) :: znicddir(nlay+2) ! temporary clear sky near-IR downward direct shortwave flux (w/m2) ! Optional output fields real(kind=rb) :: swnflx(nlay+2) ! Total sky shortwave net flux (W/m2) real(kind=rb) :: swnflxc(nlay+2) ! Clear sky shortwave net flux (W/m2) real(kind=rb) :: dirdflux(nlay+2) ! Direct downward shortwave surface flux real(kind=rb) :: difdflux(nlay+2) ! Diffuse downward shortwave surface flux real(kind=rb) :: uvdflx(nlay+2) ! Total sky downward shortwave flux, UV/vis real(kind=rb) :: nidflx(nlay+2) ! Total sky downward shortwave flux, near-IR real(kind=rb) :: dirdnuv(nlay+2) ! Direct downward shortwave flux, UV/vis real(kind=rb) :: difdnuv(nlay+2) ! Diffuse downward shortwave flux, UV/vis real(kind=rb) :: dirdnir(nlay+2) ! Direct downward shortwave flux, near-IR real(kind=rb) :: difdnir(nlay+2) ! Diffuse downward shortwave flux, near-IR ! Output - inactive ! real(kind=rb) :: zuvfu(nlay+2) ! temporary upward UV shortwave flux (w/m2) ! real(kind=rb) :: zuvfd(nlay+2) ! temporary downward UV shortwave flux (w/m2) ! real(kind=rb) :: zuvcu(nlay+2) ! temporary clear sky upward UV shortwave flux (w/m2) ! real(kind=rb) :: zuvcd(nlay+2) ! temporary clear sky downward UV shortwave flux (w/m2) ! real(kind=rb) :: zvsfu(nlay+2) ! temporary upward visible shortwave flux (w/m2) ! real(kind=rb) :: zvsfd(nlay+2) ! temporary downward visible shortwave flux (w/m2) ! real(kind=rb) :: zvscu(nlay+2) ! temporary clear sky upward visible shortwave flux (w/m2) ! real(kind=rb) :: zvscd(nlay+2) ! temporary clear sky downward visible shortwave flux (w/m2) ! real(kind=rb) :: znifu(nlay+2) ! temporary upward near-IR shortwave flux (w/m2) ! real(kind=rb) :: znifd(nlay+2) ! temporary downward near-IR shortwave flux (w/m2) ! real(kind=rb) :: znicu(nlay+2) ! temporary clear sky upward near-IR shortwave flux (w/m2) ! real(kind=rb) :: znicd(nlay+2) ! temporary clear sky downward near-IR shortwave flux (w/m2) ! Initializations zepsec = 1.e-06_rb zepzen = 1.e-10_rb oneminus = 1.0_rb - zepsec pi = 2._rb * asin(1._rb) istart = jpb1 iend = jpb2 icpr = 0 ims = 2 ! In a GCM with or without McICA, set nlon to the longitude dimension ! ! Set imca to select calculation type: ! imca = 0, use standard forward model calculation (clear and overcast only) ! imca = 1, use McICA for Monte Carlo treatment of sub-grid cloud variability ! (clear, overcast or partial cloud conditions) ! *** This version uses McICA (imca = 1) *** ! Set icld to select of clear or cloud calculation and cloud ! overlap method (read by subroutine readprof from input file INPUT_RRTM): ! icld = 0, clear only ! icld = 1, with clouds using random cloud overlap (McICA only) ! icld = 2, with clouds using maximum/random cloud overlap (McICA only) ! icld = 3, with clouds using maximum cloud overlap (McICA only) if (icld.lt.0.or.icld.gt.3) icld = 2 ! Set iaer to select aerosol option ! iaer = 0, no aerosols ! iaer = 6, use six ECMWF aerosol types ! input aerosol optical depth at 0.55 microns for each aerosol type (ecaer) ! iaer = 10, input total aerosol optical depth, single scattering albedo ! and asymmetry parameter (tauaer, ssaaer, asmaer) directly iaer = 10 ! Call model and data initialization, compute lookup tables, perform ! reduction of g-points from 224 to 112 for input absorption ! coefficient data and other arrays. ! ! In a GCM this call should be placed in the model initialization ! area, since this has to be called only once. ! call rrtmg_sw_ini(cpdair) ! This is the main longitude/column loop in RRTMG. ! Modify to loop over all columns (nlon) or over daylight columns do iplon = 1, ncol ! Prepare atmosphere profile from GCM for use in RRTMG, and define ! other input parameters call inatm_sw (iplon, nlay, icld, iaer, & play, plev, tlay, tlev, tsfc, h2ovmr, & o3vmr, co2vmr, ch4vmr, n2ovmr, o2vmr, & adjes, dyofyr, scon, inflgsw, iceflgsw, liqflgsw, & cldfmcl, taucmcl, ssacmcl, asmcmcl, fsfcmcl, ciwpmcl, clwpmcl, & reicmcl, relqmcl, tauaer, ssaaer, asmaer, & nlayers, pavel, pz, pdp, tavel, tz, tbound, coldry, wkl, & adjflux, solvar, inflag, iceflag, liqflag, cldfmc, taucmc, & ssacmc, asmcmc, fsfcmc, ciwpmc, clwpmc, reicmc, relqmc, & taua, ssaa, asma) ! For cloudy atmosphere, use cldprop to set cloud optical properties based on ! input cloud physical properties. Select method based on choices described ! in cldprop. Cloud fraction, water path, liquid droplet and ice particle ! effective radius must be passed in cldprop. Cloud fraction and cloud ! optical properties are transferred to rrtmg_sw arrays in cldprop. call cldprmc_sw(nlayers, inflag, iceflag, liqflag, cldfmc, & ciwpmc, clwpmc, reicmc, relqmc, & taormc, taucmc, ssacmc, asmcmc, fsfcmc) icpr = 1 ! Calculate coefficients for the temperature and pressure dependence of the ! molecular absorption coefficients by interpolating data from stored ! reference atmospheres. call setcoef_sw(nlayers, pavel, tavel, pz, tz, tbound, coldry, wkl, & laytrop, layswtch, laylow, jp, jt, jt1, & co2mult, colch4, colco2, colh2o, colmol, coln2o, & colo2, colo3, fac00, fac01, fac10, fac11, & selffac, selffrac, indself, forfac, forfrac, indfor) ! Cosine of the solar zenith angle ! Prevent using value of zero; ideally, SW model is not called from host model when sun ! is below horizon cossza = coszen(iplon) if (cossza .le. zepzen) cossza = zepzen ! Transfer albedo, cloud and aerosol properties into arrays for 2-stream radiative transfer ! Surface albedo ! Near-IR bands 16-24 and 29 (1-9 and 14), 820-16000 cm-1, 0.625-12.195 microns do ib=1,9 albdir(ib) = aldir(iplon) albdif(ib) = aldif(iplon) enddo albdir(nbndsw) = aldir(iplon) albdif(nbndsw) = aldif(iplon) ! UV/visible bands 25-28 (10-13), 16000-50000 cm-1, 0.200-0.625 micron do ib=10,13 albdir(ib) = asdir(iplon) albdif(ib) = asdif(iplon) enddo ! Clouds if (icld.eq.0) then zcldfmc(:,:) = 0._rb ztaucmc(:,:) = 0._rb ztaormc(:,:) = 0._rb zasycmc(:,:) = 0._rb zomgcmc(:,:) = 1._rb elseif (icld.ge.1) then do i=1,nlayers do ig=1,ngptsw zcldfmc(i,ig) = cldfmc(ig,i) ztaucmc(i,ig) = taucmc(ig,i) ztaormc(i,ig) = taormc(ig,i) zasycmc(i,ig) = asmcmc(ig,i) zomgcmc(i,ig) = ssacmc(ig,i) enddo enddo endif ! Aerosol ! IAER = 0: no aerosols if (iaer.eq.0) then ztaua(:,:) = 0._rb zasya(:,:) = 0._rb zomga(:,:) = 1._rb ! IAER = 6: Use ECMWF six aerosol types. See rrsw_aer.f90 for details. ! Input aerosol optical thickness at 0.55 micron for each aerosol type (ecaer), ! or set manually here for each aerosol and layer. elseif (iaer.eq.6) then ! do i = 1, nlayers ! do ia = 1, naerec ! ecaer(iplon,i,ia) = 1.0e-15_rb ! enddo ! enddo do i = 1, nlayers do ib = 1, nbndsw ztaua(i,ib) = 0._rb zasya(i,ib) = 0._rb zomga(i,ib) = 1._rb do ia = 1, naerec ztaua(i,ib) = ztaua(i,ib) + rsrtaua(ib,ia) * ecaer(iplon,i,ia) zomga(i,ib) = zomga(i,ib) + rsrtaua(ib,ia) * ecaer(iplon,i,ia) * & rsrpiza(ib,ia) zasya(i,ib) = zasya(i,ib) + rsrtaua(ib,ia) * ecaer(iplon,i,ia) * & rsrpiza(ib,ia) * rsrasya(ib,ia) enddo if (zomga(i,ib) /= 0._rb) then zasya(i,ib) = zasya(i,ib) / zomga(i,ib) endif if (ztaua(i,ib) /= 0._rb) then zomga(i,ib) = zomga(i,ib) / ztaua(i,ib) endif enddo enddo ! IAER=10: Direct specification of aerosol optical properties from GCM elseif (iaer.eq.10) then do i = 1 ,nlayers do ib = 1 ,nbndsw ztaua(i,ib) = taua(i,ib) zasya(i,ib) = asma(i,ib) zomga(i,ib) = ssaa(i,ib) enddo enddo endif ! Call the 2-stream radiation transfer model do i=1,nlayers+1 zbbcu(i) = 0._rb zbbcd(i) = 0._rb zbbfu(i) = 0._rb zbbfd(i) = 0._rb zbbcddir(i) = 0._rb zbbfddir(i) = 0._rb zuvcd(i) = 0._rb zuvfd(i) = 0._rb zuvcddir(i) = 0._rb zuvfddir(i) = 0._rb znicd(i) = 0._rb znifd(i) = 0._rb znicddir(i) = 0._rb znifddir(i) = 0._rb enddo call spcvmc_sw & (nlayers, istart, iend, icpr, iout, & pavel, tavel, pz, tz, tbound, albdif, albdir, & zcldfmc, ztaucmc, zasycmc, zomgcmc, ztaormc, & ztaua, zasya, zomga, cossza, coldry, wkl, adjflux, & laytrop, layswtch, laylow, jp, jt, jt1, & co2mult, colch4, colco2, colh2o, colmol, coln2o, colo2, colo3, & fac00, fac01, fac10, fac11, & selffac, selffrac, indself, forfac, forfrac, indfor, & zbbfd, zbbfu, zbbcd, zbbcu, zuvfd, zuvcd, znifd, znicd, & zbbfddir, zbbcddir, zuvfddir, zuvcddir, znifddir, znicddir) ! Transfer up and down, clear and total sky fluxes to output arrays. ! Vertical indexing goes from bottom to top; reverse here for GCM if necessary. do i = 1, nlayers+1 swuflxc(iplon,i) = zbbcu(i) swdflxc(iplon,i) = zbbcd(i) swuflx(iplon,i) = zbbfu(i) swdflx(iplon,i) = zbbfd(i) uvdflx(i) = zuvfd(i) nidflx(i) = znifd(i) ! Direct/diffuse fluxes dirdflux(i) = zbbfddir(i) difdflux(i) = swdflx(iplon,i) - dirdflux(i) ! UV/visible direct/diffuse fluxes dirdnuv(i) = zuvfddir(i) difdnuv(i) = zuvfd(i) - dirdnuv(i) ! Near-IR direct/diffuse fluxes dirdnir(i) = znifddir(i) difdnir(i) = znifd(i) - dirdnir(i) enddo ! Total and clear sky net fluxes do i = 1, nlayers+1 swnflxc(i) = swdflxc(iplon,i) - swuflxc(iplon,i) swnflx(i) = swdflx(iplon,i) - swuflx(iplon,i) enddo ! Total and clear sky heating rates do i = 1, nlayers zdpgcp = heatfac / pdp(i) swhrc(iplon,i) = (swnflxc(i+1) - swnflxc(i)) * zdpgcp swhr(iplon,i) = (swnflx(i+1) - swnflx(i)) * zdpgcp enddo swhrc(iplon,nlayers) = 0._rb swhr(iplon,nlayers) = 0._rb ! End longitude loop enddo end subroutine rrtmg_sw !************************************************************************* real(kind=rb) function earth_sun(idn) !************************************************************************* ! ! Purpose: Function to calculate the correction factor of Earth's orbit ! for current day of the year ! idn : Day of the year ! earth_sun : square of the ratio of mean to actual Earth-Sun distance ! ------- Modules ------- use rrsw_con, only : pi integer(kind=im), intent(in) :: idn real(kind=rb) :: gamma gamma = 2._rb*pi*(idn-1)/365._rb ! Use Iqbal's equation 1.2.1 earth_sun = 1.000110_rb + .034221_rb * cos(gamma) + .001289_rb * sin(gamma) + & .000719_rb * cos(2._rb*gamma) + .000077_rb * sin(2._rb*gamma) end function earth_sun !*************************************************************************** subroutine inatm_sw (iplon, nlay, icld, iaer, & play, plev, tlay, tlev, tsfc, h2ovmr, & o3vmr, co2vmr, ch4vmr, n2ovmr, o2vmr, & adjes, dyofyr, scon, inflgsw, iceflgsw, liqflgsw, & cldfmcl, taucmcl, ssacmcl, asmcmcl, fsfcmcl, ciwpmcl, clwpmcl, & reicmcl, relqmcl, tauaer, ssaaer, asmaer, & nlayers, pavel, pz, pdp, tavel, tz, tbound, coldry, wkl, & adjflux, solvar, inflag, iceflag, liqflag, cldfmc, taucmc, & ssacmc, asmcmc, fsfcmc, ciwpmc, clwpmc, reicmc, relqmc, & taua, ssaa, asma) !*************************************************************************** ! ! Input atmospheric profile from GCM, and prepare it for use in RRTMG_SW. ! Set other RRTMG_SW input parameters. ! !*************************************************************************** ! --------- Modules ---------- use parrrsw, only : nbndsw, ngptsw, nstr, nmol, mxmol, & jpband, jpb1, jpb2, rrsw_scon use rrsw_con, only : heatfac, oneminus, pi, grav, avogad use rrsw_wvn, only : ng, nspa, nspb, wavenum1, wavenum2, delwave ! ------- Declarations ------- ! ----- Input ----- integer(kind=im), intent(in) :: iplon ! column loop index integer(kind=im), intent(in) :: nlay ! number of model layers integer(kind=im), intent(in) :: icld ! clear/cloud and cloud overlap flag integer(kind=im), intent(in) :: iaer ! aerosol option flag real(kind=rb), intent(in) :: play(:,:) ! Layer pressures (hPa, mb) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: plev(:,:) ! Interface pressures (hPa, mb) ! Dimensions: (ncol,nlay+1) real(kind=rb), intent(in) :: tlay(:,:) ! Layer temperatures (K) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: tlev(:,:) ! Interface temperatures (K) ! Dimensions: (ncol,nlay+1) real(kind=rb), intent(in) :: tsfc(:) ! Surface temperature (K) ! Dimensions: (ncol) real(kind=rb), intent(in) :: h2ovmr(:,:) ! H2O volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: o3vmr(:,:) ! O3 volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: co2vmr(:,:) ! CO2 volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: ch4vmr(:,:) ! Methane volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: n2ovmr(:,:) ! Nitrous oxide volume mixing ratio ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: o2vmr(:,:) ! Oxygen volume mixing ratio ! Dimensions: (ncol,nlay) integer(kind=im), intent(in) :: dyofyr ! Day of the year (used to get Earth/Sun ! distance if adjflx not provided) real(kind=rb), intent(in) :: adjes ! Flux adjustment for Earth/Sun distance real(kind=rb), intent(in) :: scon ! Solar constant (W/m2) integer(kind=im), intent(in) :: inflgsw ! Flag for cloud optical properties integer(kind=im), intent(in) :: iceflgsw ! Flag for ice particle specification integer(kind=im), intent(in) :: liqflgsw ! Flag for liquid droplet specification real(kind=rb), intent(in) :: cldfmcl(:,:,:) ! Cloud fraction ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: taucmcl(:,:,:) ! In-cloud optical depth (optional) ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: ssacmcl(:,:,:) ! In-cloud single scattering albedo ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: asmcmcl(:,:,:) ! In-cloud asymmetry parameter ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: fsfcmcl(:,:,:) ! In-cloud forward scattering fraction ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: ciwpmcl(:,:,:) ! In-cloud ice water path (g/m2) ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: clwpmcl(:,:,:) ! In-cloud liquid water path (g/m2) ! Dimensions: (ngptsw,ncol,nlay) real(kind=rb), intent(in) :: reicmcl(:,:) ! Cloud ice effective size (microns) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: relqmcl(:,:) ! Cloud water drop effective radius (microns) ! Dimensions: (ncol,nlay) real(kind=rb), intent(in) :: tauaer(:,:,:) ! Aerosol optical depth ! Dimensions: (ncol,nlay,nbndsw) real(kind=rb), intent(in) :: ssaaer(:,:,:) ! Aerosol single scattering albedo ! Dimensions: (ncol,nlay,nbndsw) real(kind=rb), intent(in) :: asmaer(:,:,:) ! Aerosol asymmetry parameter ! Dimensions: (ncol,nlay,nbndsw) ! Atmosphere integer(kind=im), intent(out) :: nlayers ! number of layers real(kind=rb), intent(out) :: pavel(:) ! layer pressures (mb) ! Dimensions: (nlay) real(kind=rb), intent(out) :: tavel(:) ! layer temperatures (K) ! Dimensions: (nlay) real(kind=rb), intent(out) :: pz(0:) ! level (interface) pressures (hPa, mb) ! Dimensions: (0:nlay) real(kind=rb), intent(out) :: tz(0:) ! level (interface) temperatures (K) ! Dimensions: (0:nlay) real(kind=rb), intent(out) :: tbound ! surface temperature (K) real(kind=rb), intent(out) :: pdp(:) ! layer pressure thickness (hPa, mb) ! Dimensions: (nlay) real(kind=rb), intent(out) :: coldry(:) ! dry air column density (mol/cm2) ! Dimensions: (nlay) real(kind=rb), intent(out) :: wkl(:,:) ! molecular amounts (mol/cm-2) ! Dimensions: (mxmol,nlay) real(kind=rb), intent(out) :: adjflux(:) ! adjustment for current Earth/Sun distance ! Dimensions: (jpband) real(kind=rb), intent(out) :: solvar(:) ! solar constant scaling factor from rrtmg_sw ! Dimensions: (jpband) ! default value of 1368.22 Wm-2 at 1 AU real(kind=rb), intent(out) :: taua(:,:) ! Aerosol optical depth ! Dimensions: (nlay,nbndsw) real(kind=rb), intent(out) :: ssaa(:,:) ! Aerosol single scattering albedo ! Dimensions: (nlay,nbndsw) real(kind=rb), intent(out) :: asma(:,:) ! Aerosol asymmetry parameter ! Dimensions: (nlay,nbndsw) ! Atmosphere/clouds - cldprop integer(kind=im), intent(out) :: inflag ! flag for cloud property method integer(kind=im), intent(out) :: iceflag ! flag for ice cloud properties integer(kind=im), intent(out) :: liqflag ! flag for liquid cloud properties real(kind=rb), intent(out) :: cldfmc(:,:) ! layer cloud fraction ! Dimensions: (ngptsw,nlay) real(kind=rb), intent(out) :: taucmc(:,:) ! in-cloud optical depth (non-delta scaled) ! Dimensions: (ngptsw,nlay) real(kind=rb), intent(out) :: ssacmc(:,:) ! in-cloud single scattering albedo (non-delta-scaled) ! Dimensions: (ngptsw,nlay) real(kind=rb), intent(out) :: asmcmc(:,:) ! in-cloud asymmetry parameter (non-delta scaled) ! Dimensions: (ngptsw,nlay) real(kind=rb), intent(out) :: fsfcmc(:,:) ! in-cloud forward scattering fraction (non-delta scaled) ! Dimensions: (ngptsw,nlay) real(kind=rb), intent(out) :: ciwpmc(:,:) ! in-cloud ice water path ! Dimensions: (ngptsw,nlay) real(kind=rb), intent(out) :: clwpmc(:,:) ! in-cloud liquid water path ! Dimensions: (ngptsw,nlay) real(kind=rb), intent(out) :: relqmc(:) ! liquid particle effective radius (microns) ! Dimensions: (nlay) real(kind=rb), intent(out) :: reicmc(:) ! ice particle effective size (microns) ! Dimensions: (nlay) ! ----- Local ----- real(kind=rb), parameter :: amd = 28.9660_rb ! Effective molecular weight of dry air (g/mol) real(kind=rb), parameter :: amw = 18.0160_rb ! Molecular weight of water vapor (g/mol) ! real(kind=rb), parameter :: amc = 44.0098_rb ! Molecular weight of carbon dioxide (g/mol) ! real(kind=rb), parameter :: amo = 47.9998_rb ! Molecular weight of ozone (g/mol) ! real(kind=rb), parameter :: amo2 = 31.9999_rb ! Molecular weight of oxygen (g/mol) ! real(kind=rb), parameter :: amch4 = 16.0430_rb ! Molecular weight of methane (g/mol) ! real(kind=rb), parameter :: amn2o = 44.0128_rb ! Molecular weight of nitrous oxide (g/mol) ! Set molecular weight ratios (for converting mmr to vmr) ! e.g. h2ovmr = h2ommr * amdw) real(kind=rb), parameter :: amdw = 1.607793_rb ! Molecular weight of dry air / water vapor real(kind=rb), parameter :: amdc = 0.658114_rb ! Molecular weight of dry air / carbon dioxide real(kind=rb), parameter :: amdo = 0.603428_rb ! Molecular weight of dry air / ozone real(kind=rb), parameter :: amdm = 1.805423_rb ! Molecular weight of dry air / methane real(kind=rb), parameter :: amdn = 0.658090_rb ! Molecular weight of dry air / nitrous oxide real(kind=rb), parameter :: amdo2 = 0.905140_rb ! Molecular weight of dry air / oxygen real(kind=rb), parameter :: sbc = 5.67e-08_rb ! Stefan-Boltzmann constant (W/m2K4) integer(kind=im) :: isp, l, ix, n, imol, ib, ig ! Loop indices real(kind=rb) :: amm, summol ! real(kind=rb) :: adjflx ! flux adjustment for Earth/Sun distance ! real(kind=rb) :: earth_sun ! function for Earth/Sun distance adjustment nlayers = nlay ! Initialize all molecular amounts to zero here, then pass input amounts ! into RRTM array WKL below. wkl(:,:) = 0.0_rb cldfmc(:,:) = 0.0_rb taucmc(:,:) = 0.0_rb ssacmc(:,:) = 1.0_rb asmcmc(:,:) = 0.0_rb fsfcmc(:,:) = 0.0_rb ciwpmc(:,:) = 0.0_rb clwpmc(:,:) = 0.0_rb reicmc(:) = 0.0_rb relqmc(:) = 0.0_rb taua(:,:) = 0.0_rb ssaa(:,:) = 1.0_rb asma(:,:) = 0.0_rb ! Set flux adjustment for current Earth/Sun distance (two options). ! 1) Use Earth/Sun distance flux adjustment provided by GCM (input as adjes); adjflx = adjes ! ! 2) Calculate Earth/Sun distance from DYOFYR, the cumulative day of the year. ! (Set adjflx to 1. to use constant Earth/Sun distance of 1 AU). if (dyofyr .gt. 0) then adjflx = earth_sun(dyofyr) endif ! Set incoming solar flux adjustment to include adjustment for ! current Earth/Sun distance (ADJFLX) and scaling of default internal ! solar constant (rrsw_scon = 1368.22 Wm-2) by band (SOLVAR). SOLVAR can be set ! to a single scaling factor as needed, or to a different value in each ! band, which may be necessary for paleoclimate simulations. ! do ib = jpb1,jpb2 ! solvar(ib) = 1._rb solvar(ib) = scon / rrsw_scon adjflux(ib) = adjflx * solvar(ib) enddo ! Set surface temperature. tbound = tsfc(iplon) ! Install input GCM arrays into RRTMG_SW arrays for pressure, temperature, ! and molecular amounts. ! Pressures are input in mb, or are converted to mb here. ! Molecular amounts are input in volume mixing ratio, or are converted from ! mass mixing ratio (or specific humidity for h2o) to volume mixing ratio ! here. These are then converted to molecular amount (molec/cm2) below. ! The dry air column COLDRY (in molec/cm2) is calculated from the level ! pressures, pz (in mb), based on the hydrostatic equation and includes a ! correction to account for h2o in the layer. The molecular weight of moist ! air (amm) is calculated for each layer. ! Note: In RRTMG, layer indexing goes from bottom to top, and coding below ! assumes GCM input fields are also bottom to top. Input layer indexing ! from GCM fields should be reversed here if necessary. pz(0) = plev(iplon,1) tz(0) = tlev(iplon,1) do l = 1, nlayers pavel(l) = play(iplon,l) tavel(l) = tlay(iplon,l) pz(l) = plev(iplon,l+1) tz(l) = tlev(iplon,l+1) pdp(l) = pz(l-1) - pz(l) ! For h2o input in vmr: wkl(1,l) = h2ovmr(iplon,l) ! For h2o input in mmr: ! wkl(1,l) = h2o(iplon,l)*amdw ! For h2o input in specific humidity; ! wkl(1,l) = (h2o(iplon,l)/(1._rb - h2o(iplon,l)))*amdw wkl(2,l) = co2vmr(iplon,l) wkl(3,l) = o3vmr(iplon,l) wkl(4,l) = n2ovmr(iplon,l) wkl(6,l) = ch4vmr(iplon,l) wkl(7,l) = o2vmr(iplon,l) amm = (1._rb - wkl(1,l)) * amd + wkl(1,l) * amw coldry(l) = (pz(l-1)-pz(l)) * 1.e3_rb * avogad / & (1.e2_rb * grav * amm * (1._rb + wkl(1,l))) enddo ! The following section can be used to set values for an additional layer (from ! the GCM top level to 1.e-4 mb) for improved calculation of TOA fluxes. ! Temperature and molecular amounts in the extra model layer are set to ! their values in the top GCM model layer, though these can be modified ! here if necessary. ! If this feature is utilized, increase nlayers by one above, limit the two ! loops above to (nlayers-1), and set the top most (nlayers) layer values here. ! pavel(nlayers) = 0.5_rb * pz(nlayers-1) ! tavel(nlayers) = tavel(nlayers-1) ! pz(nlayers) = 1.e-4_rb ! tz(nlayers-1) = 0.5_rb * (tavel(nlayers)+tavel(nlayers-1)) ! tz(nlayers) = tz(nlayers-1) ! pdp(nlayers) = pz(nlayers-1) - pz(nlayers) ! wkl(1,nlayers) = wkl(1,nlayers-1) ! wkl(2,nlayers) = wkl(2,nlayers-1) ! wkl(3,nlayers) = wkl(3,nlayers-1) ! wkl(4,nlayers) = wkl(4,nlayers-1) ! wkl(6,nlayers) = wkl(6,nlayers-1) ! wkl(7,nlayers) = wkl(7,nlayers-1) ! amm = (1._rb - wkl(1,nlayers-1)) * amd + wkl(1,nlayers-1) * amw ! coldry(nlayers) = (pz(nlayers-1)) * 1.e3_rb * avogad / & ! (1.e2_rb * grav * amm * (1._rb + wkl(1,nlayers-1))) ! At this point all molecular amounts in wkl are in volume mixing ratio; ! convert to molec/cm2 based on coldry for use in rrtm. do l = 1, nlayers do imol = 1, nmol wkl(imol,l) = coldry(l) * wkl(imol,l) enddo enddo ! Transfer aerosol optical properties to RRTM variables; ! modify to reverse layer indexing here if necessary. if (iaer .ge. 1) then do l = 1, nlayers do ib = 1, nbndsw taua(l,ib) = tauaer(iplon,l,ib) ssaa(l,ib) = ssaaer(iplon,l,ib) asma(l,ib) = asmaer(iplon,l,ib) enddo enddo endif ! Transfer cloud fraction and cloud optical properties to RRTM variables; ! modify to reverse layer indexing here if necessary. if (icld .ge. 1) then inflag = inflgsw iceflag = iceflgsw liqflag = liqflgsw ! Move incoming GCM cloud arrays to RRTMG cloud arrays. ! For GCM input, incoming reicmcl is defined based on selected ice parameterization (inflgsw) do l = 1, nlayers do ig = 1, ngptsw cldfmc(ig,l) = cldfmcl(ig,iplon,l) taucmc(ig,l) = taucmcl(ig,iplon,l) ssacmc(ig,l) = ssacmcl(ig,iplon,l) asmcmc(ig,l) = asmcmcl(ig,iplon,l) fsfcmc(ig,l) = fsfcmcl(ig,iplon,l) ciwpmc(ig,l) = ciwpmcl(ig,iplon,l) clwpmc(ig,l) = clwpmcl(ig,iplon,l) enddo reicmc(l) = reicmcl(iplon,l) relqmc(l) = relqmcl(iplon,l) enddo ! If an extra layer is being used in RRTMG, set all cloud properties to zero in the extra layer. ! cldfmc(:,nlayers) = 0.0_rb ! taucmc(:,nlayers) = 0.0_rb ! ssacmc(:,nlayers) = 1.0_rb ! asmcmc(:,nlayers) = 0.0_rb ! fsfcmc(:,nlayers) = 0.0_rb ! ciwpmc(:,nlayers) = 0.0_rb ! clwpmc(:,nlayers) = 0.0_rb ! reicmc(nlayers) = 0.0_rb ! relqmc(nlayers) = 0.0_rb endif end subroutine inatm_sw end module rrtmg_sw_rad !------------------------------------------------------------------ MODULE module_ra_rrtmg_sw use module_model_constants, only : cp USE module_wrf_error !USE module_dm use parrrsw, only : nbndsw, ngptsw, naerec use rrtmg_sw_init, only: rrtmg_sw_ini use rrtmg_sw_rad, only: rrtmg_sw use mcica_subcol_gen_sw, only: mcica_subcol_sw use module_ra_rrtmg_lw, only : inirad, o3data, relcalc, reicalc ! mcica_random_numbers, randomNumberSequence, & ! new_RandomNumberSequence, getRandomReal CONTAINS !------------------------------------------------------------------ SUBROUTINE RRTMG_SWRAD( & rthratensw, & swupt, swuptc, swdnt, swdntc, & swupb, swupbc, swdnb, swdnbc, & ! swupflx, swupflxc, swdnflx, swdnflxc, & swcf, gsw, & xtime, gmt, xlat, xlong, & radt, degrad, declin, & coszr, julday, solcon, & albedo, t3d, t8w, tsk, & p3d, p8w, pi3d, rho3d, & dz8w, cldfra3d, r, g, & icloud, warm_rain, & f_ice_phy, f_rain_phy, & xland, xice, snow, & qv3d, qc3d, qr3d, & qi3d, qs3d, qg3d, & f_qv, f_qc, f_qr, f_qi, f_qs, f_qg, & tauaer300,tauaer400,tauaer600,tauaer999, & ! czhao gaer300,gaer400,gaer600,gaer999, & ! czhao waer300,waer400,waer600,waer999, & ! czhao aer_ra_feedback, & !jdfcz progn,prescribe, & progn, & qndrop3d,f_qndrop, & !czhao ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte, & swupflx, swupflxc, swdnflx, swdnflxc & ) !------------------------------------------------------------------ IMPLICIT NONE !------------------------------------------------------------------ LOGICAL, INTENT(IN ) :: warm_rain ! INTEGER, INTENT(IN ) :: ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte INTEGER, INTENT(IN ) :: ICLOUD ! REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) , & INTENT(IN ) :: dz8w, & t3d, & t8w, & p3d, & p8w, & pi3d, & rho3d REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) , & INTENT(INOUT) :: RTHRATENSW REAL, DIMENSION( ims:ime, jms:jme ) , & INTENT(INOUT) :: GSW, & SWCF, & COSZR INTEGER, INTENT(IN ) :: JULDAY REAL, INTENT(IN ) :: RADT,DEGRAD, & XTIME,DECLIN,SOLCON,GMT REAL, DIMENSION( ims:ime, jms:jme ) , & INTENT(IN ) :: XLAT, & XLONG, & XLAND, & XICE, & SNOW, & TSK, & ALBEDO ! REAL, INTENT(IN ) :: R,G ! ! Optional ! REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) , & OPTIONAL , & INTENT(IN ) :: & CLDFRA3D, & QV3D, & QC3D, & QR3D, & QI3D, & QS3D, & QG3D, & QNDROP3D real pi,third,relconst,lwpmin,rhoh2o REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) , & OPTIONAL , & INTENT(IN ) :: & F_ICE_PHY, & F_RAIN_PHY LOGICAL, OPTIONAL, INTENT(IN) :: & F_QV,F_QC,F_QR,F_QI,F_QS,F_QG,F_QNDROP ! Optional REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), OPTIONAL , & INTENT(IN ) :: tauaer300,tauaer400,tauaer600,tauaer999, & ! czhao gaer300,gaer400,gaer600,gaer999, & ! czhao waer300,waer400,waer600,waer999 ! czhao INTEGER, INTENT(IN ), OPTIONAL :: aer_ra_feedback !jdfcz INTEGER, INTENT(IN ), OPTIONAL :: progn,prescribe INTEGER, INTENT(IN ), OPTIONAL :: progn !wavelength corresponding to wavenum1 and wavenum2 (cm-1) real, save :: wavemin(nbndsw) ! Min wavelength (um) of 14 intervals data wavemin /3.077,2.500,2.150,1.942,1.626,1.299, & 1.242,0.778,0.625,0.442,0.345,0.263,0.200,3.846/ real, save :: wavemax(nbndsw) ! Max wavelength (um) of interval data wavemax/3.846,3.077,2.500,2.150,1.942,1.626, & 1.299,1.242,0.778,0.625,0.442,0.345,0.263,12.195/ real wavemid(nbndsw) ! Mid wavelength (um) of interval real, parameter :: thresh=1.e-9 real ang,slope character(len=200) :: msg ! Top of atmosphere and surface shortwave fluxes (W m-2) REAL, DIMENSION( ims:ime, jms:jme ), & OPTIONAL, INTENT(INOUT) :: & SWUPT,SWUPTC,SWDNT,SWDNTC, & SWUPB,SWUPBC,SWDNB,SWDNBC ! Layer shortwave fluxes (including extra layer above model top) ! Vertical ordering is from bottom to top (W m-2) REAL, DIMENSION( ims:ime, kms:kme+2, jms:jme ), & OPTIONAL, INTENT(OUT) :: & SWUPFLX,SWUPFLXC,SWDNFLX,SWDNFLXC ! LOCAL VARS REAL, DIMENSION( kts:kte+1 ) :: Pw1D, & Tw1D REAL, DIMENSION( kts:kte ) :: TTEN1D, & CLDFRA1D, & DZ1D, & P1D, & T1D, & QV1D, & QC1D, & QR1D, & QI1D, & QS1D, & QG1D, & qndrop1d ! Added local arrays for RRTMG integer :: ncol, & nlay, & icld, & inflgsw, & iceflgsw, & liqflgsw ! Dimension with extra layer from model top to TOA real, dimension( 1, kts:kte+2 ) :: plev, & tlev real, dimension( 1, kts:kte+1 ) :: play, & tlay, & h2ovmr, & o3vmr, & co2vmr, & o2vmr, & ch4vmr, & n2ovmr real, dimension( kts:kte+1 ) :: o3mmr ! Surface albedo (for UV/visible and near-IR spectral regions, ! and for direct and diffuse radiation) real, dimension( 1 ) :: asdir, & asdif, & aldir, & aldif ! Dimension with extra layer from model top to TOA, ! though no clouds are allowed in extra layer real, dimension( 1, kts:kte+1 ) :: clwpth, & ciwpth, & rel, & rei, & cldfrac, & relqmcl, & reicmcl real, dimension( nbndsw, 1, kts:kte+1 ) :: taucld, & ssacld, & asmcld, & fsfcld real, dimension( ngptsw, 1, kts:kte+1 ) :: cldfmcl, & clwpmcl, & ciwpmcl, & taucmcl, & ssacmcl, & asmcmcl, & fsfcmcl real, dimension( 1, kts:kte+1, nbndsw ) :: tauaer, & ssaaer, & asmaer real, dimension( 1, kts:kte+1, naerec ) :: ecaer ! Output arrays contain extra layer from model top to TOA real, dimension( 1, kts:kte+2 ) :: swuflx, & swdflx, & swuflxc, & swdflxc real, dimension( 1, kts:kte+1 ) :: swhr, & swhrc real, dimension ( 1 ) :: tsfc, & ps, & coszen real :: ro, & dz, & adjes, & scon integer :: dyofyr ! Set trace gas volume mixing ratios, 2005 values, IPCC (2007) ! carbon dioxide (379 ppmv) real :: co2 data co2 / 379.e-6 / ! methane (1774 ppbv) real :: ch4 data ch4 / 1774.e-9 / ! nitrous oxide (319 ppbv) real :: n2o data n2o / 319.e-9 / ! Set oxygen volume mixing ratio (for o2mmr=0.23143) real :: o2 data o2 / 0.209488 / integer :: iplon, irng, permuteseed integer :: nb ! For old lw cloud property specification ! Cloud and precipitation absorption coefficients ! real :: abcw,abice,abrn,absn ! data abcw /0.144/ ! data abice /0.0735/ ! data abrn /0.330e-3/ ! data absn /2.34e-3/ ! Molecular weights and ratios for converting mmr to vmr units ! real :: amd ! Effective molecular weight of dry air (g/mol) ! real :: amw ! Molecular weight of water vapor (g/mol) ! real :: amo ! Molecular weight of ozone (g/mol) ! real :: amo2 ! Molecular weight of oxygen (g/mol) ! Atomic weights for conversion from mass to volume mixing ratios ! data amd / 28.9660 / ! data amw / 18.0160 / ! data amo / 47.9998 / ! data amo2 / 31.9999 / real :: amdw ! Molecular weight of dry air / water vapor real :: amdo ! Molecular weight of dry air / ozone real :: amdo2 ! Molecular weight of dry air / oxygen data amdw / 1.607793 / data amdo / 0.603461 / data amdo2 / 0.905190 / !! real, dimension(1, 1:kte-kts+1 ) :: pdel ! Layer pressure thickness (mb) real, dimension(1, 1:kte-kts+1) :: cicewp, & ! in-cloud cloud ice water path cliqwp, & ! in-cloud cloud liquid water path reliq, & ! effective drop radius (microns) reice ! ice effective drop size (microns) real :: gliqwp, gicewp, gravmks ! ! REAL :: TSFC,GLW0,OLR0,EMISS0,FP REAL :: FP ! real, dimension(1:ite-its+1 ) :: clat ! latitude in radians for columns real :: coszrs ! Cosine of solar zenith angle for present latitude logical :: dorrsw ! Flag to allow shortwave calculation real, dimension (1) :: landfrac, landm, snowh, icefrac integer :: pcols, pver REAL :: XT24, TLOCTM, HRANG, XXLAT INTEGER :: i,j,K, na LOGICAL :: predicate !------------------------------------------------------------------ #ifdef WRF_CHEM IF ( aer_ra_feedback == 1) then IF ( .NOT. & ( PRESENT(tauaer300) .AND. & PRESENT(tauaer400) .AND. & PRESENT(tauaer600) .AND. & PRESENT(tauaer999) .AND. & PRESENT(gaer300) .AND. & PRESENT(gaer400) .AND. & PRESENT(gaer600) .AND. & PRESENT(gaer999) .AND. & PRESENT(waer300) .AND. & PRESENT(waer400) .AND. & PRESENT(waer600) .AND. & PRESENT(waer999) ) ) THEN CALL wrf_error_fatal & ('Warning: missing fields required for aerosol radiation' ) ENDIF ENDIF #endif !-----CALCULATE SHORT WAVE RADIATION ! ! All fields are ordered vertically from bottom to top ! Pressures are in mb ! latitude loop j_loop: do j = jts,jte ! longitude loop i_loop: do i = its,ite ! ! Do shortwave by default, deactivate below if sun below horizon dorrsw = .true. ! Cosine solar zenith angle for current time step ! ! xt24 is the fractional part of simulation days plus half of radt expressed in ! units of minutes ! julian is in days ! radt is in minutes xt24 = mod(xtime+radt*0.5,1440.) tloctm = gmt + xt24/60. + xlong(i,j)/15. hrang = 15. * (tloctm-12.) * degrad xxlat = xlat(i,j) * degrad ! clat(i) = xxlat coszrs = sin(xxlat) * sin(declin) + cos(xxlat) * cos(declin) * cos(hrang) coszr(i,j) = coszrs ! Set flag to prevent shortwave calculation when sun below horizon if (coszrs.le.0.0) dorrsw = .false. ! Perform shortwave calculation if sun above horizon if (dorrsw) then do k=kts,kte+1 Pw1D(K) = p8w(I,K,J)/100. Tw1D(K) = t8w(I,K,J) enddo DO K=kts,kte QV1D(K)=0. QC1D(K)=0. QR1D(K)=0. QI1D(K)=0. QS1D(K)=0. CLDFRA1D(k)=0. QNDROP1D(k)=0. ENDDO DO K=kts,kte QV1D(K)=QV3D(I,K,J) QV1D(K)=max(0.,QV1D(K)) ENDDO DO K=kts,kte TTEN1D(K)=0. T1D(K)=t3d(I,K,J) P1D(K)=p3d(I,K,J)/100. DZ1D(K)=dz8w(I,K,J) ENDDO ! moist variables IF (ICLOUD .ne. 0) THEN IF ( PRESENT( CLDFRA3D ) ) THEN DO K=kts,kte CLDFRA1D(k)=CLDFRA3D(I,K,J) ENDDO ENDIF IF (PRESENT(F_QC) .AND. PRESENT(QC3D)) THEN IF ( F_QC) THEN DO K=kts,kte QC1D(K)=QC3D(I,K,J) QC1D(K)=max(0.,QC1D(K)) ENDDO ENDIF ENDIF IF (PRESENT(F_QR) .AND. PRESENT(QR3D)) THEN IF ( F_QR) THEN DO K=kts,kte QR1D(K)=QR3D(I,K,J) QR1D(K)=max(0.,QR1D(K)) ENDDO ENDIF ENDIF IF ( PRESENT(F_QNDROP).AND.PRESENT(QNDROP3D)) THEN IF (F_QNDROP) THEN DO K=kts,kte qndrop1d(K)=qndrop3d(I,K,J) ENDDO ENDIF ENDIF ! This logic is tortured because cannot test F_QI unless ! it is present, and order of evaluation of expressions ! is not specified in Fortran IF ( PRESENT ( F_QI ) ) THEN predicate = F_QI ELSE predicate = .FALSE. ENDIF ! For MP option 3 IF (.NOT. predicate .and. .not. warm_rain) THEN DO K=kts,kte IF (T1D(K) .lt. 273.15) THEN QI1D(K)=QC1D(K) QS1D(K)=QR1D(K) QC1D(K)=0. QR1D(K)=0. ENDIF ENDDO ENDIF IF (PRESENT(F_QI) .AND. PRESENT(QI3D)) THEN IF (F_QI) THEN DO K=kts,kte QI1D(K)=QI3D(I,K,J) QI1D(K)=max(0.,QI1D(K)) ENDDO ENDIF ENDIF IF (PRESENT(F_QS) .AND. PRESENT(QS3D)) THEN IF (F_QS) THEN DO K=kts,kte QS1D(K)=QS3D(I,K,J) QS1D(K)=max(0.,QS1D(K)) ENDDO ENDIF ENDIF IF (PRESENT(F_QG) .AND. PRESENT(QG3D)) THEN IF (F_QG) THEN DO K=kts,kte QG1D(K)=QG3D(I,K,J) QG1D(K)=max(0.,QG1D(K)) ENDDO ENDIF ENDIF ! mji - For MP option 5 IF ( PRESENT(F_QI) .and. PRESENT(F_QC) .and. PRESENT(F_QS) .and. PRESENT(F_ICE_PHY) ) THEN IF ( F_QC .and. .not. F_QI .and. F_QS ) THEN DO K=kts,kte qi1d(k) = qs3d(i,k,j) qc1d(k) = qc3d(i,k,j) qi1d(k) = max(0.,qi1d(k)) qc1d(k) = max(0.,qc1d(k)) ENDDO ENDIF ENDIF ENDIF ! EMISS0=EMISS(I,J) ! GLW0=0. ! OLR0=0. ! TSFC=TSK(I,J) DO K=kts,kte QV1D(K)=AMAX1(QV1D(K),1.E-12) ENDDO ! Set up input for shortwave ncol = 1 ! Add extra layer from top of model to top of atmosphere nlay = (kte - kts + 1) + 1 ! Select cloud liquid and ice optics parameterization options ! For passing in cloud optical properties directly: ! icld = 2 ! inflgsw = 0 ! iceflgsw = 0 ! liqflgsw = 0 ! For passing in cloud physical properties; cloud optics parameterized in RRTMG: icld = 2 inflgsw = 2 iceflgsw = 3 liqflgsw = 1 ! Set cosine of solar zenith angle coszen(ncol) = coszrs ! Set solar constant scon = solcon ! For Earth/Sun distance adjustment in RRTMG ! dyofyr = julday ! adjes = 0.0 ! For WRF, solar constant is already provided with eccentricity adjustment, ! so do not do this in RRTMG dyofyr = 0 adjes = 1.0 ! Layer indexing goes bottom to top here for all fields. ! Water vapor and ozone are converted from mmr to vmr. ! Pressures are in units of mb here. plev(ncol,1) = pw1d(1) tlev(ncol,1) = tw1d(1) tsfc(ncol) = tsk(i,j) do k = kts, kte play(ncol,k) = p1d(k) plev(ncol,k+1) = pw1d(k+1) pdel(ncol,k) = plev(ncol,k) - plev(ncol,k+1) tlay(ncol,k) = t1d(k) tlev(ncol,k+1) = tw1d(k+1) h2ovmr(ncol,k) = qv1d(k) * amdw co2vmr(ncol,k) = co2 o2vmr(ncol,k) = o2 ch4vmr(ncol,k) = ch4 n2ovmr(ncol,k) = n2o enddo ! Define profile values for extra layer from model top to top of atmosphere. ! The top layer temperature for all gridpoints is set to the top layer-1 ! temperature plus a constant (0 K) that represents an isothermal layer ! above ptop. Top layer interface temperatures are linearly interpolated ! from the layer temperatures. play(ncol,kte+1) = 0.5 * plev(ncol,kte+1) tlay(ncol,kte+1) = tlev(ncol,kte+1) + 0.0 plev(ncol,kte+2) = 1.0e-5 tlev(ncol,kte+2) = tlev(ncol,kte+1) + 0.0 tlev(ncol,kte+2) = tlev(ncol,kte+1) + 0.0 h2ovmr(ncol,kte+1) = h2ovmr(ncol,kte) co2vmr(ncol,kte+1) = co2vmr(ncol,kte) o2vmr(ncol,kte+1) = o2vmr(ncol,kte) ch4vmr(ncol,kte+1) = ch4vmr(ncol,kte) n2ovmr(ncol,kte+1) = n2ovmr(ncol,kte) ! Get ozone profile including amount in extra layer above model top call inirad (o3mmr,plev,kts,kte) do k = kts, kte+1 o3vmr(ncol,k) = o3mmr(k) * amdo enddo ! Set surface albedo for direct and diffuse radiation in UV/visible and ! near-IR spectral regions asdir(ncol) = albedo(i,j) asdif(ncol) = albedo(i,j) aldir(ncol) = albedo(i,j) aldif(ncol) = albedo(i,j) ! Define cloud optical properties for radiation (inflgsw = 0) ! This option is not currently active ! Cloud and precipitation paths in g/m2 ! qi=0 if no ice phase ! qs=0 if no ice phase if (inflgsw .eq. 0) then ! Set cloud fraction and cloud optical properties here; not yet active do k = kts, kte cldfrac(ncol,k) = cldfra1d(k) do nb = 1, nbndsw taucld(nb,ncol,k) = 0.0 ssacld(nb,ncol,k) = 1.0 asmcld(nb,ncol,k) = 0.0 fsfcld(nb,ncol,k) = 0.0 enddo enddo ! Zero out cloud physical property arrays; not used when passing optical properties ! into radiation do k = kts, kte clwpth(ncol,k) = 0.0 ciwpth(ncol,k) = 0.0 rel(ncol,k) = 10.0 rei(ncol,k) = 10. enddo endif ! Define cloud physical properties for radiation (inflgsw = 1 or 2) ! Cloud fraction ! Set cloud arrays if passing cloud physical properties into radiation if (inflgsw .gt. 0) then do k = kts, kte cldfrac(ncol,k) = cldfra1d(k) enddo ! Compute cloud water/ice paths and particle sizes for input to radiation (CAM method) pcols = ncol pver = kte - kts + 1 gravmks = g landfrac(ncol) = 2.-XLAND(I,J) landm(ncol) = landfrac(ncol) snowh(ncol) = 0.001*SNOW(I,J) icefrac(ncol) = XICE(I,J) ! From module_ra_cam: Convert liquid and ice mixing ratios to water paths; ! pdel is in mb here; convert back to Pa (*100.) ! Water paths are in units of g/m2 ! snow added as ice cloud (JD 091022) do k = kts, kte gicewp = (qi1d(k)+qs1d(k)) * pdel(ncol,k)*100.0 / gravmks * 1000.0 ! Grid box ice water path. gliqwp = qc1d(k) * pdel(ncol,k)*100.0 / gravmks * 1000.0 ! Grid box liquid water path. cicewp(ncol,k) = gicewp / max(0.01,cldfrac(ncol,k)) ! In-cloud ice water path. cliqwp(ncol,k) = gliqwp / max(0.01,cldfrac(ncol,k)) ! In-cloud liquid water path. end do !link the aerosol feedback to cloud -czhao if( PRESENT( progn ) ) then if (progn == 1) then !jdfcz if(prescribe==0) then pi = 4.*atan(1.0) third=1./3. rhoh2o=1.e3 relconst=3/(4.*pi*rhoh2o) ! minimun liquid water path to calculate rel ! corresponds to optical depth of 1.e-3 for radius 4 microns. lwpmin=3.e-5 do k = kts, kte reliq(ncol,k) = 10. if( PRESENT( F_QNDROP ) ) then if( F_QNDROP ) then if ( qc1d(k)*pdel(ncol,k).gt.lwpmin.and. & qndrop1d(k).gt.1000. ) then reliq(ncol,k)=(relconst*qc1d(k)/qndrop1d(k))**third ! effective radius in m ! apply scaling from Martin et al., JAS 51, 1830. reliq(ncol,k)=1.1*reliq(ncol,k) reliq(ncol,k)=reliq(ncol,k)*1.e6 ! convert from m to microns reliq(ncol,k)=max(reliq(ncol,k),4.) reliq(ncol,k)=min(reliq(ncol,k),20.) end if end if end if end do !jdfcz else ! prescribe ! following Kiehl call relcalc(ncol, pcols, pver, tlay, landfrac, landm, icefrac, reliq, snowh) ! write(0,*) 'sw prescribe aerosol',maxval(qndrop3d) !jdfcz endif else ! progn call relcalc(ncol, pcols, pver, tlay, landfrac, landm, icefrac, reliq, snowh) endif else !progn call relcalc(ncol, pcols, pver, tlay, landfrac, landm, icefrac, reliq, snowh) endif ! following Kristjansson and Mitchell call reicalc(ncol, pcols, pver, tlay, reice) if (i==80.and.j==30) then #if defined( DM_PARALLEL ) && ! defined( STUBMPI) if( PRESENT( progn ) ) write(0,*) 'aerosol indirect',progn write(0,*)'sw water eff radius',reliq(ncol,10),reliq(ncol,20),reliq(ncol,25) write(0,*)'sw ice eff radius',reice(ncol,10),reice(ncol,20),reice(ncol,25) #endif endif ! Limit upper bound of reice for Fu ice parameterization and convert ! from effective radius to generalized effective size (*1.0315; Fu, 1996) if (iceflgsw .eq. 3) then do k = kts, kte reice(ncol,k) = reice(ncol,k) * 1.0315 reice(ncol,k) = min(140.0,reice(ncol,k)) end do endif ! Set cloud physical property arrays do k = kts, kte clwpth(ncol,k) = cliqwp(ncol,k) ciwpth(ncol,k) = cicewp(ncol,k) rel(ncol,k) = reliq(ncol,k) rei(ncol,k) = reice(ncol,k) enddo ! Zero out cloud optical properties here, calculated in radiation do k = kts, kte do nb = 1, nbndsw taucld(nb,ncol,k) = 0.0 ssacld(nb,ncol,k) = 1.0 asmcld(nb,ncol,k) = 0.0 fsfcld(nb,ncol,k) = 0.0 enddo enddo endif ! No clouds are allowed in the extra layer from model top to TOA clwpth(ncol,kte+1) = 0. ciwpth(ncol,kte+1) = 0. rel(ncol,kte+1) = 10. rei(ncol,kte+1) = 10. cldfrac(ncol,kte+1) = 0. do nb = 1, nbndsw taucld(nb,ncol,kte+1) = 0. ssacld(nb,ncol,kte+1) = 1. asmcld(nb,ncol,kte+1) = 0. fsfcld(nb,ncol,kte+1) = 0. enddo iplon = 1 irng = 0 permuteseed = 1 ! Sub-column generator for McICA call mcica_subcol_sw(iplon, ncol, nlay, icld, permuteseed, irng, play, & cldfrac, ciwpth, clwpth, rei, rel, taucld, ssacld, asmcld, fsfcld, & cldfmcl, ciwpmcl, clwpmcl, reicmcl, relqmcl, & taucmcl, ssacmcl, asmcmcl, fsfcmcl) !-------------------------------------------------------------------------- ! Aerosol optical depth, single scattering albedo and asymmetry parameter -czhao 03/2010 !-------------------------------------------------------------------------- ! by layer for each RRTMG shortwave band ! No aerosols in top layer above model top (kte+1). !cz do nb = 1, nbndsw !cz do k = kts, kte+1 !cz tauaer(ncol,k,nb) = 0. !cz ssaaer(ncol,k,nb) = 1. !cz asmaer(ncol,k,nb) = 0. !cz enddo !cz enddo ! ... Aerosol effects. Added aerosol feedbacks from Chem , 03/2010 -czhao ! do nb = 1, nbndsw do k = kts,kte+1 tauaer(ncol,k,nb) = 0. ssaaer(ncol,k,nb) = 1. asmaer(ncol,k,nb) = 0. end do end do #ifdef WRF_CHEM IF ( AER_RA_FEEDBACK == 1) then do nb = 1, nbndsw wavemid(nb)=0.5*(wavemin(nb)+wavemax(nb)) ! um do k = kts,kte !wig ! convert optical properties at 300,400,600, and 999 to conform to the band wavelengths ! tauaer - use angstrom exponent if(tauaer300(i,k,j).gt.thresh .and. tauaer999(i,k,j).gt.thresh) then ang=alog(tauaer300(i,k,j)/tauaer999(i,k,j))/alog(999./300.) tauaer(ncol,k,nb)=tauaer400(i,k,j)*(0.4/wavemid(nb))**ang !tauaer(ncol,k,nb)=tauaer600(i,k,j)*(0.6/wavemid(nb))**ang if (i==30.and.j==49.and.k==2.and.nb==12) then write(0,*) 'TAU from 600 vs 400 in RRTMG',tauaer600(i,k,j),tauaer400(i,k,j) print*, 'TAU from 600 vs 400 in RRTMG',tauaer600(i,k,j),tauaer400(i,k,j) write(0,*) tauaer600(i,k,j)*(0.6/wavemid(nb))**ang,tauaer400(i,k,j)*(0.4/wavemid(nb))**ang print*, tauaer600(i,k,j)*(0.6/wavemid(nb))**ang,tauaer400(i,k,j)*(0.4/wavemid(nb))**ang endif ! ssa - linear interpolation; extrapolation slope=(waer600(i,k,j)-waer400(i,k,j))/.2 ssaaer(ncol,k,nb) = slope*(wavemid(nb)-.6)+waer600(i,k,j) if(ssaaer(ncol,k,nb).lt.0.4) ssaaer(ncol,k,nb)=0.4 if(ssaaer(ncol,k,nb).ge.1.0) ssaaer(ncol,k,nb)=1.0 ! g - linear interpolation;extrapolation slope=(gaer600(i,k,j)-gaer400(i,k,j))/.2 asmaer(ncol,k,nb) = slope*(wavemid(nb)-.6)+gaer600(i,k,j) ! notice reversed varaibles if(asmaer(ncol,k,nb).lt.0.5) asmaer(ncol,k,nb)=0.5 if(asmaer(ncol,k,nb).ge.1.0) asmaer(ncol,k,nb)=1.0 endif end do ! k end do ! nb !wig beg do nb = 1, nbndsw slope = 0. !use slope as a sum holder do k = kts,kte slope = slope + tauaer(ncol,k,nb) end do if( slope < 0. ) then write(msg,'("ERROR: Negative total optical depth of ",f8.2," at point i,j,nb=",3i5)') slope,i,j,nb call wrf_error_fatal(msg) else if( slope > 6. ) then call wrf_message("-------------------------") write(msg,'("WARNING: Large total sw optical depth of ",f8.2," at point i,j,nb=",3i5)') slope,i,j,nb call wrf_message(msg) call wrf_message("Diagnostics 1: k, tauaer300, tauaer400, tauaer600, tauaer999, tauaer") do k=kts,kte write(msg,'(i4,5f8.2)') k, tauaer300(i,k,j), tauaer400(i,k,j), & tauaer600(i,k,j), tauaer999(i,k,j),tauaer(ncol,k,nb) call wrf_message(msg) !czhao set an up-limit here to avoid segmentation fault !from extreme AOD tauaer(ncol,k,nb)=tauaer(ncol,k,nb)*6.0/slope end do call wrf_message("Diagnostics 2: k, gaer300, gaer400, gaer600, gaer999") do k=kts,kte write(msg,'(i4,4f8.2)') k, gaer300(i,k,j), gaer400(i,k,j), & gaer600(i,k,j), gaer999(i,k,j) call wrf_message(msg) end do call wrf_message("Diagnostics 3: k, waer300, waer400, waer600, waer999") do k=kts,kte write(msg,'(i4,4f8.2)') k, waer300(i,k,j), waer400(i,k,j), & waer600(i,k,j), waer999(i,k,j) call wrf_message(msg) end do call wrf_message("Diagnostics 4: k, ssaal, asyal, taual") do k=kts-1,kte write(msg,'(i4,3f8.2)') k, ssaaer(i,k,nb), asmaer(i,k,nb), tauaer(i,k,nb) call wrf_message(msg) end do call wrf_message("-------------------------") endif enddo ! nb endif ! aer_ra_feedback #endif ! Zero array for input of aerosol optical thickness for use with ! ECMWF aerosol types (not used) do na = 1, naerec do k = kts, kte+1 ecaer(ncol,k,na) = 0. enddo enddo ! Call RRTMG shortwave radiation model call rrtmg_sw & (ncol ,nlay ,icld , & play ,plev ,tlay ,tlev ,tsfc , & h2ovmr , o3vmr ,co2vmr ,ch4vmr ,n2ovmr ,o2vmr , & asdir ,asdif ,aldir ,aldif , & coszen ,adjes ,dyofyr ,scon , & inflgsw ,iceflgsw,liqflgsw,cldfmcl , & taucmcl ,ssacmcl ,asmcmcl ,fsfcmcl , & ciwpmcl ,clwpmcl ,reicmcl ,relqmcl , & tauaer ,ssaaer ,asmaer ,ecaer , & swuflx ,swdflx ,swhr ,swuflxc ,swdflxc ,swhrc) ! Output net absorbed shortwave surface flux and shortwave cloud forcing ! at the top of atmosphere (W/m2) gsw(i,j) = swdflx(1,1) - swuflx(1,1) swcf(i,j) = (swdflx(1,kte+2) - swuflx(1,kte+2)) - (swdflxc(1,kte+2) - swuflxc(1,kte+2)) if (present(swupt)) then ! Output up and down toa fluxes for total and clear sky swupt(i,j) = swuflx(1,kte+2) swuptc(i,j) = swuflxc(1,kte+2) swdnt(i,j) = swdflx(1,kte+2) swdntc(i,j) = swdflxc(1,kte+2) ! Output up and down surface fluxes for total and clear sky swupb(i,j) = swuflx(1,1) swupbc(i,j) = swuflxc(1,1) swdnb(i,j) = swdflx(1,1) swdnbc(i,j) = swdflxc(1,1) endif ! Output up and down layer fluxes for total and clear sky. ! Vertical ordering is from bottom to top in units of W m-2. if ( present (swupflx) ) then do k=kts,kte+2 swupflx(i,k,j) = swuflx(1,k) swupflxc(i,k,j) = swuflxc(1,k) swdnflx(i,k,j) = swdflx(1,k) swdnflxc(i,k,j) = swdflxc(1,k) enddo endif ! Output heating rate tendency; convert heating rate from K/d to K/s ! Heating rate arrays are ordered vertically from bottom to top here. do k=kts,kte tten1d(k) = swhr(ncol,k)/86400. rthratensw(i,k,j) = tten1d(k)/pi3d(i,k,j) enddo else if (present(swupt)) then ! Output up and down toa fluxes for total and clear sky swupt(i,j) = 0. swuptc(i,j) = 0. swdnt(i,j) = 0. swdntc(i,j) = 0. ! Output up and down surface fluxes for total and clear sky swupb(i,j) = 0. swupbc(i,j) = 0. swdnb(i,j) = 0. swdnbc(i,j) = 0. endif endif ! end do i_loop end do j_loop !------------------------------------------------------------------- END SUBROUTINE RRTMG_SWRAD !==================================================================== SUBROUTINE rrtmg_swinit( & allowed_to_read , & ids, ide, jds, jde, kds, kde, & ims, ime, jms, jme, kms, kme, & its, ite, jts, jte, kts, kte ) !-------------------------------------------------------------------- IMPLICIT NONE !-------------------------------------------------------------------- LOGICAL , INTENT(IN) :: allowed_to_read INTEGER , INTENT(IN) :: ids, ide, jds, jde, kds, kde, & ims, ime, jms, jme, kms, kme, & its, ite, jts, jte, kts, kte ! Read in absorption coefficients and other data IF ( allowed_to_read ) THEN CALL rrtmg_swlookuptable ENDIF ! Perform g-point reduction and other initializations ! Specific heat of dry air (cp) used in flux to heating rate conversion factor. call rrtmg_sw_ini(cp) END SUBROUTINE rrtmg_swinit ! ************************************************************************** SUBROUTINE rrtmg_swlookuptable ! ************************************************************************** IMPLICIT NONE ! Local INTEGER :: i LOGICAL :: opened LOGICAL , EXTERNAL :: wrf_dm_on_monitor CHARACTER*80 errmess INTEGER rrtmg_unit IF ( wrf_dm_on_monitor() ) THEN DO i = 10,99 INQUIRE ( i , OPENED = opened ) IF ( .NOT. opened ) THEN rrtmg_unit = i GOTO 2010 ENDIF ENDDO rrtmg_unit = -1 2010 CONTINUE ENDIF CALL wrf_dm_bcast_bytes ( rrtmg_unit , IWORDSIZE ) IF ( rrtmg_unit < 0 ) THEN CALL wrf_error_fatal ( 'module_ra_rrtmg_sw: rrtm_swlookuptable: Can not '// & 'find unused fortran unit to read in lookup table.' ) ENDIF IF ( wrf_dm_on_monitor() ) THEN OPEN(rrtmg_unit,FILE='RRTMG_SW_DATA', & FORM='UNFORMATTED',STATUS='OLD',ERR=9009) ENDIF call sw_kgb16(rrtmg_unit) call sw_kgb17(rrtmg_unit) call sw_kgb18(rrtmg_unit) call sw_kgb19(rrtmg_unit) call sw_kgb20(rrtmg_unit) call sw_kgb21(rrtmg_unit) call sw_kgb22(rrtmg_unit) call sw_kgb23(rrtmg_unit) call sw_kgb24(rrtmg_unit) call sw_kgb25(rrtmg_unit) call sw_kgb26(rrtmg_unit) call sw_kgb27(rrtmg_unit) call sw_kgb28(rrtmg_unit) call sw_kgb29(rrtmg_unit) IF ( wrf_dm_on_monitor() ) CLOSE (rrtmg_unit) RETURN 9009 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error opening RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) END SUBROUTINE rrtmg_swlookuptable ! ************************************************************************** ! RRTMG Shortwave Radiative Transfer Model ! Atmospheric and Environmental Research, Inc., Cambridge, MA ! ! Original by J.Delamere, Atmospheric & Environmental Research. ! Reformatted for F90: JJMorcrette, ECMWF ! Revision for GCMs: Michael J. Iacono, AER, July 2002 ! Further F90 reformatting: Michael J. Iacono, AER, June 2006 ! ! This file contains 14 READ statements that include the ! absorption coefficients and other data for each of the 14 shortwave ! spectral bands used in RRTMG_SW. Here, the data are defined for 16 ! g-points, or sub-intervals, per band. These data are combined and ! weighted using a mapping procedure in module RRTMG_SW_INIT to reduce ! the total number of g-points from 224 to 112 for use in the GCM. ! ************************************************************************** ! ************************************************************************** subroutine sw_kgb16(rrtmg_unit) ! ************************************************************************** use rrsw_kg16, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & rayl, strrat1, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array rayl contains the Rayleigh extinction coefficient at v = 2925 cm-1. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296,260,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & rayl, strrat1, layreffr, kao, kbo, selfrefo, forrefo, sfluxrefo DM_BCAST_REAL(rayl) DM_BCAST_REAL(strrat1) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb16 ! ************************************************************************** subroutine sw_kgb17(rrtmg_unit) ! ************************************************************************** use rrsw_kg17, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & rayl, strrat, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array rayl contains the Rayleigh extinction coefficient at v = 3625 cm-1. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296,260,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & rayl, strrat, layreffr, kao, kbo, selfrefo, forrefo, sfluxrefo DM_BCAST_REAL(rayl) DM_BCAST_REAL(strrat) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb17 ! ************************************************************************** subroutine sw_kgb18(rrtmg_unit) ! ************************************************************************** use rrsw_kg18, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & rayl, strrat, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array rayl contains the Rayleigh extinction coefficient at v = 4325 cm-1. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296,260,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & rayl, strrat, layreffr, kao, kbo, selfrefo, forrefo, sfluxrefo DM_BCAST_REAL(rayl) DM_BCAST_REAL(strrat) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb18 ! ************************************************************************** subroutine sw_kgb19(rrtmg_unit) ! ************************************************************************** use rrsw_kg19, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & rayl, strrat, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array rayl contains the Rayleigh extinction coefficient at v = 4900 cm-1. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296,260,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & rayl, strrat, layreffr, kao, kbo, selfrefo, forrefo, sfluxrefo DM_BCAST_REAL(rayl) DM_BCAST_REAL(strrat) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb19 ! ************************************************************************** subroutine sw_kgb20(rrtmg_unit) ! ************************************************************************** use rrsw_kg20, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & absch4o, rayl, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array rayl contains the Rayleigh extinction coefficient at v = 5670 cm-1. ! Array absch4o contains the absorption coefficients for methane. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296,260,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & rayl, layreffr, absch4o, kao, kbo, selfrefo, forrefo, sfluxrefo DM_BCAST_REAL(rayl) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(absch4o) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb20 ! ************************************************************************** subroutine sw_kgb21(rrtmg_unit) ! ************************************************************************** use rrsw_kg21, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & rayl, strrat, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array rayl contains the Rayleigh extinction coefficient at v = 6925 cm-1. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296,260,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & rayl, strrat, layreffr, kao, kbo, selfrefo, forrefo, sfluxrefo DM_BCAST_REAL(rayl) DM_BCAST_REAL(strrat) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb21 ! ************************************************************************** subroutine sw_kgb22(rrtmg_unit) ! ************************************************************************** use rrsw_kg22, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & rayl, strrat, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array rayl contains the Rayleigh extinction coefficient at v = 8000 cm-1. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296_rb,260_rb,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & rayl, strrat, layreffr, kao, kbo, selfrefo, forrefo, sfluxrefo DM_BCAST_REAL(rayl) DM_BCAST_REAL(strrat) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb22 ! ************************************************************************** subroutine sw_kgb23(rrtmg_unit) ! ************************************************************************** use rrsw_kg23, only : kao, selfrefo, forrefo, sfluxrefo, & raylo, givfac, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array raylo contains the Rayleigh extinction coefficient at all v for this band ! Array givfac is the average Giver et al. correction factor for this band. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296,260,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & raylo, givfac, layreffr, kao, selfrefo, forrefo, sfluxrefo DM_BCAST_MACRO(raylo) DM_BCAST_REAL(givfac) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb23 ! ************************************************************************** subroutine sw_kgb24(rrtmg_unit) ! ************************************************************************** use rrsw_kg24, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & raylao, raylbo, abso3ao, abso3bo, strrat, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Arrays raylao and raylbo contain the Rayleigh extinction coefficient at ! all v for this band for the upper and lower atmosphere. ! Arrays abso3ao and abso3bo contain the ozone absorption coefficient at ! all v for this band for the upper and lower atmosphere. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296,260,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & raylao, raylbo, strrat, layreffr, abso3ao, abso3bo, kao, kbo, selfrefo, & forrefo, sfluxrefo DM_BCAST_MACRO(raylao) DM_BCAST_MACRO(raylbo) DM_BCAST_REAL(strrat) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(abso3ao) DM_BCAST_MACRO(abso3bo) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb24 ! ************************************************************************** subroutine sw_kgb25(rrtmg_unit) ! ************************************************************************** use rrsw_kg25, only : kao, sfluxrefo, & raylo, abso3ao, abso3bo, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array raylo contains the Rayleigh extinction coefficient at all v = 2925 cm-1. ! Arrays abso3ao and abso3bo contain the ozone absorption coefficient at ! all v for this band for the upper and lower atmosphere. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & raylo, layreffr, abso3ao, abso3bo, kao, sfluxrefo DM_BCAST_MACRO(raylo) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(abso3ao) DM_BCAST_MACRO(abso3bo) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb25 ! ************************************************************************** subroutine sw_kgb26(rrtmg_unit) ! ************************************************************************** use rrsw_kg26, only : sfluxrefo, raylo implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array raylo contains the Rayleigh extinction coefficient at all v for this band. #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & raylo, sfluxrefo DM_BCAST_MACRO(raylo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb26 ! ************************************************************************** subroutine sw_kgb27(rrtmg_unit) ! ************************************************************************** use rrsw_kg27, only : kao, kbo, sfluxrefo, raylo, & scalekur, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! The values in array sfluxrefo were obtained using the "low resolution" ! version of the Kurucz solar source function. For unknown reasons, ! the total irradiance in this band differs from the corresponding ! total in the "high-resolution" version of the Kurucz function. ! Therefore, these values are scaled by the factor SCALEKUR. ! Array raylo contains the Rayleigh extinction coefficient at all v = 2925 cm-1. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & raylo, scalekur, layreffr, kao, kbo, sfluxrefo DM_BCAST_MACRO(raylo) DM_BCAST_REAL(scalekur) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb27 ! ************************************************************************** subroutine sw_kgb28(rrtmg_unit) ! ************************************************************************** use rrsw_kg28, only : kao, kbo, sfluxrefo, & rayl, strrat, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array raylo contains the Rayleigh extinction coefficient at all v = ???? cm-1. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & rayl, strrat, layreffr, kao, kbo, sfluxrefo DM_BCAST_REAL(rayl) DM_BCAST_REAL(strrat) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb28 ! ************************************************************************** subroutine sw_kgb29(rrtmg_unit) ! ************************************************************************** use rrsw_kg29, only : kao, kbo, selfrefo, forrefo, sfluxrefo, & absh2oo, absco2o, rayl, layreffr implicit none save ! Input integer, intent(in) :: rrtmg_unit ! Local character*80 errmess logical, external :: wrf_dm_on_monitor ! Array sfluxrefo contains the Kurucz solar source function for this band. ! Array rayl contains the Rayleigh extinction coefficient at all v = 2200 cm-1. ! Array absh2oo contains the water vapor absorption coefficient for this band. ! Array absco2o contains the carbon dioxide absorption coefficient for this band. ! The array KAO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels> ~100mb, temperatures, and binary ! species parameters (see taumol.f for definition). The first ! index in the array, JS, runs from 1 to 9, and corresponds to ! different values of the binary species parameter. For instance, ! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, ! JS = 3 corresponds to the parameter value 2/8, etc. The second index ! in the array, JT, which runs from 1 to 5, corresponds to different ! temperatures. More specifically, JT = 3 means that the data are for ! the reference temperature TREF for this pressure level, JT = 2 refers ! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5 ! is for TREF+30. The third index, JP, runs from 1 to 13 and refers ! to the JPth reference pressure level (see taumol.f for these levels ! in mb). The fourth index, IG, goes from 1 to 16, and indicates ! which g-interval the absorption coefficients are for. ! The array KBO contains absorption coefs at the 16 chosen g-values ! for a range of pressure levels < ~100mb and temperatures. The first ! index in the array, JT, which runs from 1 to 5, corresponds to ! different temperatures. More specifically, JT = 3 means that the ! data are for the reference temperature TREF for this pressure ! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for ! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. ! The second index, JP, runs from 13 to 59 and refers to the JPth ! reference pressure level (see taumol.f for the value of these ! pressure levels in mb). The third index, IG, goes from 1 to 16, ! and tells us which g-interval the absorption coefficients are for. ! The array FORREFO contains the coefficient of the water vapor ! foreign-continuum (including the energy term). The first ! index refers to reference temperature (296,260,224,260) and ! pressure (970,475,219,3 mbar) levels. The second index ! runs over the g-channel (1 to 16). ! The array SELFREFO contains the coefficient of the water vapor ! self-continuum (including the energy term). The first index ! refers to temperature in 7.2 degree increments. For instance, ! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, ! etc. The second index runs over the g-channel (1 to 16). #define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE ) #define DM_BCAST_REAL(A) CALL wrf_dm_bcast_real ( A , 1 ) #define DM_BCAST_INTEGER(A) CALL wrf_dm_bcast_integer ( A , 1 ) IF ( wrf_dm_on_monitor() ) READ (rrtmg_unit,ERR=9010) & rayl, layreffr, absh2oo, absco2o, kao, kbo, selfrefo, forrefo, sfluxrefo DM_BCAST_REAL(rayl) DM_BCAST_INTEGER(layreffr) DM_BCAST_MACRO(absh2oo) DM_BCAST_MACRO(absco2o) DM_BCAST_MACRO(kao) DM_BCAST_MACRO(kbo) DM_BCAST_MACRO(selfrefo) DM_BCAST_MACRO(forrefo) DM_BCAST_MACRO(sfluxrefo) RETURN 9010 CONTINUE WRITE( errmess , '(A,I4)' ) 'module_ra_rrtmg_sw: error reading RRTMG_SW_DATA on unit ',rrtmg_unit CALL wrf_error_fatal(errmess) end subroutine sw_kgb29 !------------------------------------------------------------------ END MODULE module_ra_rrtmg_sw