Context Navigation

lwu.F @ 1880

Last change on this file since 1880 was 1266, checked in by aslmd, 11 years ago

LMDZ.MARS
IMPORTANT CHANGE

Remove all reference/use of nlayermx and dimphys.h
Made use of automatic arrays whenever arrays are needed with dimension nlayer
Remove lots of obsolete reference to dimensions.h
Converted iono.h and param_v4.h into corresponding modules

(with embedded subroutine to allocate arrays)
(no arrays allocated if thermosphere not used)

Deleted param.h and put contents into module param_v4_h
Adapted testphys1d, newstart, etc...
Made DATA arrays in param_read to be initialized by subroutine

fill_data_thermos in module param_v4_h

Optimized computations in paramfoto_compact (twice less dlog10 calculations)
Checked consistency before/after modification in debug mode
Checked performance is not impacted (same as before)

File size: 7.9 KB

Rev	Line
[38]	1	subroutine lwu (kdlon,kflev
	2	& ,dp,plev,tlay,aerosol
	3	& ,QIRsQREF3d,omegaIR3d,gIR3d
	4	& ,aer_t,co2_u,co2_up
	5	& ,tautotal,omegtotal,gtotal)
	6
	7	c----------------------------------------------------------------------
	8	c LWU computes - co2: longwave effective absorber amounts including
	9	c pressure and temperature effects
	10	c - aerosols: amounts for every band
	11	c transmission for bandes 1 and 2 of co2
	12	c----------------------------------------------------------------------
	13
	14	c-----------------------------------------------------------------------
	15	c ATTENTION AUX UNITES:
	16	c le facteur 10*g fait passer des kg m-2 aux g cm-2
	17	c-----------------------------------------------------------------------
	18	c! modif diffusion
	19	c! on ne change rien a la bande CO2 : les quantites d'absorbant CO2
	20	c! sont multipliees par 1.66
	21	c! pview= 1/cos(teta0)=1.66
	22	c
	23	c Modif J.-B. Madeleine: Computing optical properties of dust and
	24	c water-ice crystals in each gridbox. Optical parameters of
	25	c water-ice clouds are convolved to crystal sizes predicted by
	26	c the microphysical scheme.
	27	c
	28	c MODIF : FF : removing the monster bug on water ice clouds 11/2010
[626]	29	c
	30	c MODIF : TN : corrected bug if very big water ice clouds 04/2012
[38]	31	c-----------------------------------------------------------------------
	32
[1047]	33	use dimradmars_mod, only: ndlo2, nir, nuco2, ndlon, nflev
[1246]	34	use dimradmars_mod, only: naerkind
[1047]	35	use yomlw_h, only: nlaylte, tref, at, bt, cst_voigt
[1226]	36	USE comcstfi_h
[38]	37	implicit none
	38
	39	#include "callkeys.h"
	40
	41	c----------------------------------------------------------------------
	42	c 0.1 arguments
	43	c ---------
	44	c inputs:
	45	c -------
	46	integer kdlon ! part of ngrid
	47	integer kflev ! part of nalyer
	48
	49	real dp (ndlo2,kflev) ! layer pressure thickness (Pa)
	50	real plev (ndlo2,kflev+1) ! level pressure (Pa)
	51	real tlay (ndlo2,kflev) ! layer temperature (K)
	52	real aerosol (ndlo2,kflev,naerkind) ! aerosol extinction optical depth
	53	c at reference wavelength "longrefvis" set
[1047]	54	c in dimradmars_mod , in each layer, for one of
[38]	55	c the "naerkind" kind of aerosol optical properties.
	56	REAL QIRsQREF3d(ndlo2,kflev,nir,naerkind) ! 3d ext. coef.
	57	REAL omegaIR3d(ndlo2,kflev,nir,naerkind) ! 3d ssa
	58	REAL gIR3d(ndlo2,kflev,nir,naerkind) ! 3d assym. param.
	59
	60	c outputs:
	61	c --------
	62	real aer_t (ndlo2,nuco2,kflev+1) ! transmission (aer)
	63	real co2_u (ndlo2,nuco2,kflev+1) ! absorber amounts (co2)
	64	real co2_up (ndlo2,nuco2,kflev+1) ! idem scaled by the pressure (co2)
	65
	66	real tautotal(ndlo2,kflev,nir) ! \ Total single scattering
	67	real omegtotal(ndlo2,kflev,nir) ! > properties (Addition of the
	68	real gtotal(ndlo2,kflev,nir) ! / NAERKIND aerosols properties)
	69
	70	c----------------------------------------------------------------------
	71	c 0.2 local arrays
	72	c ------------
	73
	74	integer jl,jk,jkl,ja,n
	75
	76	real aer_a (ndlon,nir,nflev+1) ! absorber amounts (aer) ABSORPTION
	77	real co2c ! co2 concentration (pa/pa)
	78	real pview ! cosecant of viewing angle
	79	real pref ! reference pressure (1013 mb = 101325 Pa)
	80	real tx,tx2
	81	real phi (ndlon,nuco2)
	82	real psi (ndlon,nuco2)
	83	real plev2 (ndlon,nflev+1)
	84	real zzz
	85
	86	real ray,coefsize,coefsizew,coefsizeg
	87
	88	c************************************************************************
	89	c----------------------------------------------------------------------
	90	c 0.3 Initialisation
	91	c -------------
	92
	93	pview = 1.66
	94	co2c = 0.95
	95	pref = 101325.
	96
	97	do jk=1,nlaylte+1
	98	do jl=1,kdlon
	99	plev2(jl,jk)=plev(jl,jk)*plev(jl,jk)
	100	enddo
	101	enddo
	102
	103	c----------------------------------------------------------------------
	104	c Computing TOTAL single scattering parameters by adding properties of
	105	c all the NAERKIND kind of aerosols in each IR band
	106
	107	call zerophys(ndlonkflevnir,tautotal)
	108	call zerophys(ndlonkflevnir,omegtotal)
	109	call zerophys(ndlonkflevnir,gtotal)
	110
	111	do n=1,naerkind
	112	do ja=1,nir
	113	do jk=1,nlaylte
	114	do jl = 1,kdlon
	115	tautotal(jl,jk,ja)=tautotal(jl,jk,ja) +
	116	& QIRsQREF3d(jl,jk,ja,n)*aerosol(jl,jk,n)
	117	omegtotal(jl,jk,ja) = omegtotal(jl,jk,ja) +
	118	& QIRsQREF3d(jl,jk,ja,n)aerosol(jl,jk,n)
	119	& omegaIR3d(jl,jk,ja,n)
	120	gtotal(jl,jk,ja) = gtotal(jl,jk,ja) +
	121	& QIRsQREF3d(jl,jk,ja,n)aerosol(jl,jk,n)
	122	& omegaIR3d(jl,jk,ja,n)*gIR3d(jl,jk,ja,n)
	123	enddo
	124	enddo
	125	enddo
	126	enddo
	127	do ja=1,nir
	128	do jk=1,nlaylte
	129	do jl = 1,kdlon
	130	gtotal(jl,jk,ja)=gtotal(jl,jk,ja)/omegtotal(jl,jk,ja)
	131	omegtotal(jl,jk,ja)=omegtotal(jl,jk,ja)/tautotal(jl,jk,ja)
	132	enddo
	133	enddo
	134	enddo
	135
	136	c----------------------------------------------------------------------
	137	c 1.0 cumulative (aerosol) amounts (for every band)
	138	c ----------------------------
	139
	140	jk=nlaylte+1
	141	do ja=1,nir
	142	do jl = 1 , kdlon
	143	aer_a(jl,ja,jk)=0.
	144	enddo
	145	enddo
	146
	147	do jk=1,nlaylte
	148	jkl=nlaylte+1-jk
	149	do ja=1,nir
	150	do jl=1,kdlon
	151	aer_a(jl,ja,jkl)=aer_a(jl,ja,jkl+1)+
	152	& tautotal(jl,jkl,ja)*(1.-omegtotal(jl,jkl,ja))
	153	enddo
	154	enddo
	155	enddo
	156
	157	c----------------------------------------------------------------------
	158	c 1.0 bands 1 and 2 of co2
	159	c --------------------
	160
	161	jk=nlaylte+1
	162	do ja=1,nuco2
	163	do jl = 1 , kdlon
	164	co2_u(jl,ja,jk)=0.
	165	co2_up(jl,ja,jk)=0.
	166	aer_t(jl,ja,jk)=1.
	167	enddo
	168	enddo
	169
	170	do jk=1,nlaylte
	171	jkl=nlaylte+1-jk
	172	do ja=1,nuco2
	173	do jl=1,kdlon
	174
	175	c introduces temperature effects on absorber(co2) amounts
	176	c -------------------------------------------------------
	177	tx = sign(min(abs(tlay(jl,jkl)-tref),70.)
	178	. ,tlay(jl,jkl)-tref)
	179	tx2=tx*tx
	180	phi(jl,ja)=at(1,ja)tx+bt(1,ja)tx2
	181	psi(jl,ja)=at(2,ja)tx+bt(2,ja)tx2
	182	phi(jl,ja)=exp(phi(jl,ja)/cst_voigt(2,ja))
	183	psi(jl,ja)=exp(2.*psi(jl,ja))
	184
	185	c cumulative absorber(co2) amounts
	186	c --------------------------------
	187	co2_u(jl,ja,jkl)=co2_u(jl,ja,jkl+1)
	188	. + pview/(10g)phi(jl,ja)dp(jl,jkl)co2c
	189
	190	co2_up(jl,ja,jkl)=co2_up(jl,ja,jkl+1)
	191	. + pview/(10g2pref)psi(jl,ja)
	192	. * (plev2(jl,jkl)-plev2(jl,jkl+1))*co2c
	193
	194
	195	c (aerosol) transmission
	196	c ----------------------
	197	c on calcule directement les transmissions pour les aerosols.
	198	c on multiplie le Qext par 1-omega dans la bande du CO2.
	199	c et pourquoi pas d'abord? hourdin@lmd.ens.fr
	200
[626]	201	c TN 04/12 : if very big water ice clouds, aer_t is strictly rounded
	202	c to zero in lower levels, which is a source of NaN
	203	!aer_t(jl,ja,jkl)=exp(-pview*aer_a(jl,ja,jkl))
	204	aer_t(jl,ja,jkl)=max(exp(-pview*aer_a(jl,ja,jkl)),1e-30)
	205
[38]	206
	207	enddo
	208	enddo
[626]	209	enddo
	210
[38]	211	c----------------------------------------------------------------------
	212	return
	213	end

Note: See TracBrowser for help on using the repository browser.

Download in other formats:

Original Format