source: LMDZ6/branches/contrails/libf/phylmd/cosp/icarus.f90

Last change on this file was 5263, checked in by abarral, 2 months ago

fix cospv1 compilation

  • Property copyright set to
    Name of program: LMDZ
    Creation date: 1984
    Version: LMDZ5
    License: CeCILL version 2
    Holder: Laboratoire de m\'et\'eorologie dynamique, CNRS, UMR 8539
    See the license file in the root directory
File size: 39.9 KB
Line 
1! $Revision: 88 $, $Date: 2013-11-13 15:08:38 +0100 (mer. 13 nov. 2013) $
2! $URL: http://cfmip-obs-sim.googlecode.com/svn/stable/v1.4.0/icarus-scops-4.1-bsd/icarus.f $
3SUBROUTINE ICARUS( &
4        debug, &
5        debugcol, &
6        npoints, &
7        sunlit, &
8        nlev, &
9        ncol, &
10        pfull, &
11        phalf, &
12        qv, &
13        cc, &
14        conv, &
15        dtau_s, &
16        dtau_c, &
17        top_height, &
18        top_height_direction, &
19        overlap, &
20        frac_out, &
21        skt, &
22        emsfc_lw, &
23        at, &
24        dem_s, &
25        dem_c, &
26        fq_isccp, &
27        totalcldarea, &
28        meanptop, &
29        meantaucld, &
30        meanalbedocld, &
31        meantb, &
32        meantbclr, &
33        boxtau, &
34        boxptop &
35        )
36
37  !$Id: icarus.f,v 4.1 2010/05/27 16:30:18 hadmw Exp $
38
39  ! *****************************COPYRIGHT****************************
40  ! (c) 2009, Lawrence Livermore National Security Limited Liability
41  ! Corporation.
42  ! All rights reserved.
43  !
44  ! Redistribution and use in source and binary forms, with or without
45  ! modification, are permitted provided that the
46  ! following conditions are met:
47  !
48  ! * Redistributions of source code must retain the above
49  !   copyright  notice, this list of conditions and the following
50  !   disclaimer.
51  ! * Redistributions in binary form must reproduce the above
52  !   copyright notice, this list of conditions and the following
53  !   disclaimer in the documentation and/or other materials
54  !   provided with the distribution.
55  ! * Neither the name of the Lawrence Livermore National Security
56  !   Limited Liability Corporation nor the names of its
57  !   contributors may be used to endorse or promote products
58  !   derived from this software without specific prior written
59  !   permission.
60  !
61  ! THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
62  ! "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
63  ! LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
64  ! A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
65  ! OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
66  ! SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
67  ! LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
68  ! DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
69  ! THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
70  ! (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
71  ! OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
72  !
73  ! *****************************COPYRIGHT*******************************
74  ! *****************************COPYRIGHT*******************************
75  ! *****************************COPYRIGHT*******************************
76  ! *****************************COPYRIGHT*******************************
77
78  implicit none
79
80  ! NOTE:   the maximum number of levels and columns is set by
81  !         the following parameter statement
82
83  INTEGER :: ncolprint
84
85  ! -----
86  ! Input
87  ! -----
88
89  INTEGER :: npoints       !  number of model points in the horizontal
90  INTEGER :: nlev          !  number of model levels in column
91  INTEGER :: ncol          !  number of subcolumns
92
93  INTEGER :: sunlit(npoints) !  1 for day points, 0 for night time
94
95  REAL :: pfull(npoints,nlev)
96                   ! !  pressure of full model levels (Pascals)
97              ! !  pfull(npoints,1) is top level of model
98              ! !  pfull(npoints,nlev) is bot of model
99
100  REAL :: phalf(npoints,nlev+1)
101              ! !  pressure of half model levels (Pascals)
102              ! !  phalf(npoints,1) is top of model
103              ! !  phalf(npoints,nlev+1) is the surface pressure
104
105  REAL :: qv(npoints,nlev)
106              ! !  water vapor specific humidity (kg vapor/ kg air)
107              ! !         on full model levels
108
109  REAL :: cc(npoints,nlev)
110              ! !  input cloud cover in each model level (fraction)
111              ! !  NOTE:  This is the HORIZONTAL area of each
112              ! !         grid box covered by clouds
113
114  REAL :: conv(npoints,nlev)
115              ! !  input convective cloud cover in each model
116              ! !   level (fraction)
117              ! !  NOTE:  This is the HORIZONTAL area of each
118              ! !         grid box covered by convective clouds
119
120  REAL :: dtau_s(npoints,nlev)
121              ! !  mean 0.67 micron optical depth of stratiform
122            ! !  clouds in each model level
123            !   !  NOTE:  this the cloud optical depth of only the
124            !   !  cloudy part of the grid box, it is not weighted
125            !   !  with the 0 cloud optical depth of the clear
126            !   !         part of the grid box
127
128  REAL :: dtau_c(npoints,nlev)
129              ! !  mean 0.67 micron optical depth of convective
130            ! !  clouds in each
131            !   !  model level.  Same note applies as in dtau_s.
132
133  INTEGER :: overlap                   !  overlap type
134                          ! !  1=max
135                          ! !  2=rand
136                          ! !  3=max/rand
137
138  INTEGER :: top_height                !  1 = adjust top height using both a computed
139                                    ! !  infrared brightness temperature and the visible
140                          ! !  optical depth to adjust cloud top pressure. Note
141                          ! !  that this calculation is most appropriate to compare
142                          ! !  to ISCCP data during sunlit hours.
143                          !           !  2 = do not adjust top height, that is cloud top
144                          !           !  pressure is the actual cloud top pressure
145                          !           !  in the model
146                          ! !  3 = adjust top height using only the computed
147                          ! !  infrared brightness temperature. Note that this
148                          ! !  calculation is most appropriate to compare to ISCCP
149                          ! !  IR only algortihm (i.e. you can compare to nighttime
150                          ! !  ISCCP data with this option)
151
152  INTEGER :: top_height_direction ! direction for finding atmosphere pressure level
153                             ! ! with interpolated temperature equal to the radiance
154                             ! determined cloud-top temperature
155                             !
156                             ! 1 = find the *lowest* altitude (highest pressure) level
157                             ! with interpolated temperature equal to the radiance
158                             ! determined cloud-top temperature
159                             !
160                             ! 2 = find the *highest* altitude (lowest pressure) level
161                             ! with interpolated temperature equal to the radiance
162                             ! determined cloud-top temperature
163                             !
164                             ! ONLY APPLICABLE IF top_height EQUALS 1 or 3
165                             !                           !
166                             ! 1 = old setting: matches all versions of
167                             ! ISCCP simulator with versions numbers 3.5.1 and lower
168                             !
169                             ! 2 = default setting: for version numbers 4.0 and higher
170  !
171  ! The following input variables are used only if top_height = 1 or top_height = 3
172  !
173  REAL :: skt(npoints)                 !  skin Temperature (K)
174  REAL :: emsfc_lw                     !  10.5 micron emissivity of surface (fraction)
175  REAL :: at(npoints,nlev)                   !  temperature in each model level (K)
176  REAL :: dem_s(npoints,nlev)                !  10.5 micron longwave emissivity of stratiform
177                          ! !  clouds in each
178                          !           !  model level.  Same note applies as in dtau_s.
179  REAL :: dem_c(npoints,nlev)                  !  10.5 micron longwave emissivity of convective
180                          ! !  clouds in each
181                          !           !  model level.  Same note applies as in dtau_s.
182
183  REAL :: frac_out(npoints,ncol,nlev) ! boxes gridbox divided up into
184                          ! ! Equivalent of BOX in original version, but
185                          ! ! indexed by column then row, rather than
186                          ! ! by row then column
187
188
189
190  ! ------
191  ! Output
192  ! ------
193
194  REAL :: fq_isccp(npoints,7,7)        !  the fraction of the model grid box covered by
195                                    ! !  each of the 49 ISCCP D level cloud types
196
197  REAL :: totalcldarea(npoints)        !  the fraction of model grid box columns
198                                    ! !  with cloud somewhere in them.  NOTE: This diagnostic
199                                    ! does not count model clouds with tau < isccp_taumin
200                          ! ! Thus this diagnostic does not equal the sum over all entries of fq_isccp.
201                          ! However, this diagnostic does equal the sum over entries of fq_isccp with
202                          ! itau = 2:7 (omitting itau = 1)
203
204
205  ! ! The following three means are averages only over the cloudy areas with tau > isccp_taumin.
206  ! ! If no clouds with tau > isccp_taumin are in grid box all three quantities should equal zero.
207
208  REAL :: meanptop(npoints)            !  mean cloud top pressure (mb) - linear averaging
209                                    ! !  in cloud top pressure.
210
211  REAL :: meantaucld(npoints)          !  mean optical thickness
212                                    ! !  linear averaging in albedo performed.
213
214  real :: meanalbedocld(npoints)        ! mean cloud albedo
215                                    ! ! linear averaging in albedo performed
216
217  real :: meantb(npoints)              ! mean all-sky 10.5 micron brightness temperature
218
219  real :: meantbclr(npoints)           ! mean clear-sky 10.5 micron brightness temperature
220
221  REAL :: boxtau(npoints,ncol)         !  optical thickness in each column
222
223  REAL :: boxptop(npoints,ncol)        !  cloud top pressure (mb) in each column
224
225
226  !
227  ! ------
228  ! Working variables added when program updated to mimic Mark Webb's PV-Wave code
229  ! ------
230
231  REAL :: dem(npoints,ncol),bb(npoints)     !  working variables for 10.5 micron longwave
232                          ! !  emissivity in part of
233                          ! !  gridbox under consideration
234
235  REAL :: ptrop(npoints)
236  REAL :: attrop(npoints)
237  REAL :: attropmin (npoints)
238  REAL :: atmax(npoints)
239  REAL :: btcmin(npoints)
240  REAL :: transmax(npoints)
241
242  INTEGER :: i,j,ilev,ibox,itrop(npoints)
243  INTEGER :: ipres(npoints)
244  INTEGER :: itau(npoints),ilev2
245  INTEGER :: acc(nlev,ncol)
246  INTEGER :: match(npoints,nlev-1)
247  INTEGER :: nmatch(npoints)
248  INTEGER :: levmatch(npoints,ncol)
249
250  ! !variables needed for water vapor continuum absorption
251  real :: fluxtop_clrsky(npoints),trans_layers_above_clrsky(npoints)
252  real :: taumin(npoints)
253  real :: dem_wv(npoints,nlev), wtmair, wtmh20, Navo, grav, pstd, t0
254  real :: press(npoints), dpress(npoints), atmden(npoints)
255  real :: rvh20(npoints), wk(npoints), rhoave(npoints)
256  real :: rh20s(npoints), rfrgn(npoints)
257  real :: tmpexp(npoints),tauwv(npoints)
258
259  character(len=1) :: cchar(6),cchar_realtops(6)
260  integer :: icycle
261  REAL :: tau(npoints,ncol)
262  LOGICAL :: box_cloudy(npoints,ncol)
263  REAL :: tb(npoints,ncol)
264  REAL :: ptop(npoints,ncol)
265  REAL :: emcld(npoints,ncol)
266  REAL :: fluxtop(npoints,ncol)
267  REAL :: trans_layers_above(npoints,ncol)
268  real :: isccp_taumin,fluxtopinit(npoints),tauir(npoints)
269  REAL :: albedocld(npoints,ncol)
270  real :: boxarea
271  integer :: debug       ! set to non-zero value to print out inputs
272                ! ! with step debug
273  integer :: debugcol    ! set to non-zero value to print out column
274                ! ! decomposition with step debugcol
275  integer :: rangevec(npoints),rangeerror
276
277  integer :: index1(npoints),num1,jj,k1,k2
278  real :: rec2p13,tauchk,logp,logp1,logp2,atd
279  real :: output_missing_value
280
281  character(len=10) :: ftn09
282
283  DATA isccp_taumin / 0.3 /
284  DATA output_missing_value / -1.E+30 /
285  DATA cchar / ' ','-','1','+','I','+'/
286  DATA cchar_realtops / ' ',' ','1','1','I','I'/
287
288  ! ------ End duplicate definitions common to wrapper routine
289
290  tauchk = -1.*log(0.9999999)
291  rec2p13=1./2.13
292
293  ncolprint=0
294
295  if ( debug.ne.0 ) then
296      j=1
297      write(6,'(a10)') 'j='
298      write(6,'(8I10)') j
299      write(6,'(a10)') 'debug='
300      write(6,'(8I10)') debug
301      write(6,'(a10)') 'debugcol='
302      write(6,'(8I10)') debugcol
303      write(6,'(a10)') 'npoints='
304      write(6,'(8I10)') npoints
305      write(6,'(a10)') 'nlev='
306      write(6,'(8I10)') nlev
307      write(6,'(a10)') 'ncol='
308      write(6,'(8I10)') ncol
309      write(6,'(a11)') 'top_height='
310      write(6,'(8I10)') top_height
311      write(6,'(a21)') 'top_height_direction='
312      write(6,'(8I10)') top_height_direction
313      write(6,'(a10)') 'overlap='
314      write(6,'(8I10)') overlap
315      write(6,'(a10)') 'emsfc_lw='
316      write(6,'(8f10.2)') emsfc_lw
317    do j=1,npoints,debug
318      write(6,'(a10)') 'j='
319      write(6,'(8I10)') j
320      write(6,'(a10)') 'sunlit='
321      write(6,'(8I10)') sunlit(j)
322      write(6,'(a10)') 'pfull='
323      write(6,'(8f10.2)') (pfull(j,i),i=1,nlev)
324      write(6,'(a10)') 'phalf='
325      write(6,'(8f10.2)') (phalf(j,i),i=1,nlev+1)
326      write(6,'(a10)') 'qv='
327      write(6,'(8f10.3)') (qv(j,i),i=1,nlev)
328      write(6,'(a10)') 'cc='
329      write(6,'(8f10.3)') (cc(j,i),i=1,nlev)
330      write(6,'(a10)') 'conv='
331      write(6,'(8f10.2)') (conv(j,i),i=1,nlev)
332      write(6,'(a10)') 'dtau_s='
333      write(6,'(8g12.5)') (dtau_s(j,i),i=1,nlev)
334      write(6,'(a10)') 'dtau_c='
335      write(6,'(8f10.2)') (dtau_c(j,i),i=1,nlev)
336      write(6,'(a10)') 'skt='
337      write(6,'(8f10.2)') skt(j)
338      write(6,'(a10)') 'at='
339      write(6,'(8f10.2)') (at(j,i),i=1,nlev)
340      write(6,'(a10)') 'dem_s='
341      write(6,'(8f10.3)') (dem_s(j,i),i=1,nlev)
342      write(6,'(a10)') 'dem_c='
343      write(6,'(8f10.3)') (dem_c(j,i),i=1,nlev)
344    enddo
345  endif
346
347  ! ---------------------------------------------------!
348
349  if (ncolprint.ne.0) then
350  do j=1,npoints,1000
351    write(6,'(a10)') 'j='
352    write(6,'(8I10)') j
353  enddo
354  endif
355
356  if (top_height .eq. 1 .or. top_height .eq. 3) then
357
358  do j=1,npoints
359      ptrop(j)=5000.
360      attropmin(j) = 400.
361      atmax(j) = 0.
362      attrop(j) = 120.
363      itrop(j) = 1
364  enddo
365
366  do ilev=1,nlev
367    do j=1,npoints
368     if (pfull(j,ilev) .lt. 40000. .and. &
369           pfull(j,ilev) .gt.  5000. .and. &
370           at(j,ilev) .lt. attropmin(j)) then
371            ptrop(j) = pfull(j,ilev)
372            attropmin(j) = at(j,ilev)
373            attrop(j) = attropmin(j)
374            itrop(j)=ilev
375       end if
376    enddo
377  end do
378
379  do ilev=1,nlev
380    do j=1,npoints
381       if (at(j,ilev) .gt. atmax(j) .and. &
382             ilev  .ge. itrop(j)) atmax(j)=at(j,ilev)
383    enddo
384  end do
385
386  end if
387
388
389  if (top_height .eq. 1 .or. top_height .eq. 3) then
390      do j=1,npoints
391          meantb(j) = 0.
392          meantbclr(j) = 0.
393      end do
394  else
395      do j=1,npoints
396          meantb(j) = output_missing_value
397          meantbclr(j) = output_missing_value
398      end do
399  end if
400
401  ! -----------------------------------------------------!
402
403  ! ---------------------------------------------------!
404
405  do ilev=1,nlev
406    do j=1,npoints
407
408      rangevec(j)=0
409
410      if (cc(j,ilev) .lt. 0. .or. cc(j,ilev) .gt. 1.) then
411        ! error = cloud fraction less than zero
412        ! error = cloud fraction greater than 1
413        rangevec(j)=rangevec(j)+1
414      endif
415
416      if (conv(j,ilev) .lt. 0. .or. conv(j,ilev) .gt. 1.) then
417        ! ' error = convective cloud fraction less than zero'
418        ! ' error = convective cloud fraction greater than 1'
419        rangevec(j)=rangevec(j)+2
420      endif
421
422      if (dtau_s(j,ilev) .lt. 0.) then
423        ! ' error = stratiform cloud opt. depth less than zero'
424        rangevec(j)=rangevec(j)+4
425      endif
426
427      if (dtau_c(j,ilev) .lt. 0.) then
428        ! ' error = convective cloud opt. depth less than zero'
429        rangevec(j)=rangevec(j)+8
430      endif
431
432      if (dem_s(j,ilev) .lt. 0. .or. dem_s(j,ilev) .gt. 1.) then
433          ! ' error = stratiform cloud emissivity less than zero'
434          ! ' error = stratiform cloud emissivity greater than 1'
435        rangevec(j)=rangevec(j)+16
436      endif
437
438      if (dem_c(j,ilev) .lt. 0. .or. dem_c(j,ilev) .gt. 1.) then
439          ! ' error = convective cloud emissivity less than zero'
440          ! ' error = convective cloud emissivity greater than 1'
441          rangevec(j)=rangevec(j)+32
442      endif
443    enddo
444
445    rangeerror=0
446    do j=1,npoints
447        rangeerror=rangeerror+rangevec(j)
448    enddo
449
450    if (rangeerror.ne.0) then
451          write (6,*) 'Input variable out of range'
452          write (6,*) 'rangevec:'
453          write (6,*) rangevec
454          STOP
455    endif
456  enddo
457
458  !
459  ! ---------------------------------------------------!
460
461
462  !
463  ! ---------------------------------------------------!
464  ! COMPUTE CLOUD OPTICAL DEPTH FOR EACH COLUMN and
465  ! put into vector tau
466
467  ! !initialize tau and albedocld to zero
468  do ibox=1,ncol
469    do j=1,npoints
470        tau(j,ibox)=0.
471      albedocld(j,ibox)=0.
472      boxtau(j,ibox)=output_missing_value
473      boxptop(j,ibox)=output_missing_value
474      box_cloudy(j,ibox)=.false.
475    enddo
476  end do
477
478  ! !compute total cloud optical depth for each column
479  do ilev=1,nlev
480        ! !increment tau for each of the boxes
481        do ibox=1,ncol
482          do j=1,npoints
483             if (frac_out(j,ibox,ilev).eq.1) then
484                    tau(j,ibox)=tau(j,ibox) &
485                          + dtau_s(j,ilev)
486             endif
487             if (frac_out(j,ibox,ilev).eq.2) then
488                    tau(j,ibox)=tau(j,ibox) &
489                          + dtau_c(j,ilev)
490             end if
491          enddo
492        enddo ! ibox
493  enddo ! ilev
494      if (ncolprint.ne.0) then
495
496          do j=1,npoints ,1000
497            write(6,'(a10)') 'j='
498            write(6,'(8I10)') j
499            write(6,'(i2,1X,8(f7.2,1X))') &
500                  ilev, &
501                  (tau(j,ibox),ibox=1,ncolprint)
502          enddo
503      endif
504  !
505  ! ---------------------------------------------------!
506
507
508
509  !
510  ! ---------------------------------------------------!
511  ! COMPUTE INFRARED BRIGHTNESS TEMPERUATRES
512  ! AND CLOUD TOP TEMPERATURE SATELLITE SHOULD SEE
513  !
514  ! again this is only done if top_height = 1 or 3
515  !
516  ! fluxtop is the 10.5 micron radiance at the top of the
517  !          atmosphere
518  ! trans_layers_above is the total transmissivity in the layers
519  !         above the current layer
520  ! fluxtop_clrsky(j) and trans_layers_above_clrsky(j) are the clear
521  !         sky versions of these quantities.
522
523  if (top_height .eq. 1 .or. top_height .eq. 3) then
524
525
526    ! !----------------------------------------------------------------------
527    ! !
528    ! !             DO CLEAR SKY RADIANCE CALCULATION FIRST
529    ! !
530    ! !compute water vapor continuum emissivity
531    ! !this treatment follows Schwarkzopf and Ramasamy
532    ! !JGR 1999,vol 104, pages 9467-9499.
533    ! !the emissivity is calculated at a wavenumber of 955 cm-1,
534    ! !or 10.47 microns
535    wtmair = 28.9644
536    wtmh20 = 18.01534
537    Navo = 6.023E+23
538    grav = 9.806650E+02
539    pstd = 1.013250E+06
540    t0 = 296.
541    if (ncolprint .ne. 0) &
542          write(6,*)  'ilev   pw (kg/m2)   tauwv(j)      dem_wv'
543    do ilev=1,nlev
544      do j=1,npoints
545           ! !press and dpress are dyne/cm2 = Pascals *10
546           press(j) = pfull(j,ilev)*10.
547           dpress(j) = (phalf(j,ilev+1)-phalf(j,ilev))*10
548           ! !atmden = g/cm2 = kg/m2 / 10
549           atmden(j) = dpress(j)/grav
550           rvh20(j) = qv(j,ilev)*wtmair/wtmh20
551           wk(j) = rvh20(j)*Navo*atmden(j)/wtmair
552           rhoave(j) = (press(j)/pstd)*(t0/at(j,ilev))
553           rh20s(j) = rvh20(j)*rhoave(j)
554           rfrgn(j) = rhoave(j)-rh20s(j)
555           tmpexp(j) = exp(-0.02*(at(j,ilev)-t0))
556           tauwv(j) = wk(j)*1.e-20*( &
557                 (0.0224697*rh20s(j)*tmpexp(j)) + &
558                 (3.41817e-7*rfrgn(j)) )*0.98
559           dem_wv(j,ilev) = 1. - exp( -1. * tauwv(j))
560      enddo
561           if (ncolprint .ne. 0) then
562           do j=1,npoints ,1000
563           write(6,'(a10)') 'j='
564           write(6,'(8I10)') j
565           write(6,'(i2,1X,3(f8.3,3X))') ilev, &
566                 qv(j,ilev)*(phalf(j,ilev+1)-phalf(j,ilev))/(grav/100.), &
567                 tauwv(j),dem_wv(j,ilev)
568           enddo
569         endif
570    end do
571
572    ! !initialize variables
573    do j=1,npoints
574      fluxtop_clrsky(j) = 0.
575      trans_layers_above_clrsky(j)=1.
576    enddo
577
578    do ilev=1,nlev
579      do j=1,npoints
580
581        ! ! Black body emission at temperature of the layer
582
583          bb(j)=1 / ( exp(1307.27/at(j,ilev)) - 1. )
584          ! !bb(j)= 5.67e-8*at(j,ilev)**4
585
586          ! ! increase TOA flux by flux emitted from layer
587          ! ! times total transmittance in layers above
588
589            fluxtop_clrsky(j) = fluxtop_clrsky(j) &
590                  + dem_wv(j,ilev)*bb(j)*trans_layers_above_clrsky(j)
591
592            ! ! update trans_layers_above with transmissivity
593          ! ! from this layer for next time around loop
594
595            trans_layers_above_clrsky(j)= &
596                  trans_layers_above_clrsky(j)*(1.-dem_wv(j,ilev))
597
598
599      enddo
600        if (ncolprint.ne.0) then
601         do j=1,npoints ,1000
602          write(6,'(a10)') 'j='
603          write(6,'(8I10)') j
604          write (6,'(a)') 'ilev:'
605          write (6,'(I2)') ilev
606
607          write (6,'(a)') &
608                'emiss_layer,100.*bb(j),100.*f,total_trans:'
609          write (6,'(4(f7.2,1X))') dem_wv(j,ilev),100.*bb(j), &
610                100.*fluxtop_clrsky(j),trans_layers_above_clrsky(j)
611         enddo
612        endif
613
614    enddo   !loop over level
615
616    do j=1,npoints
617      ! !add in surface emission
618      bb(j)=1/( exp(1307.27/skt(j)) - 1. )
619      ! !bb(j)=5.67e-8*skt(j)**4
620
621      fluxtop_clrsky(j) = fluxtop_clrsky(j) + emsfc_lw * bb(j) &
622            * trans_layers_above_clrsky(j)
623
624      ! !clear sky brightness temperature
625      meantbclr(j) = 1307.27/(log(1.+(1./fluxtop_clrsky(j))))
626
627    enddo
628
629    if (ncolprint.ne.0) then
630    do j=1,npoints ,1000
631      write(6,'(a10)') 'j='
632      write(6,'(8I10)') j
633      write (6,'(a)') 'id:'
634      write (6,'(a)') 'surface'
635
636      write (6,'(a)') 'emsfc,100.*bb(j),100.*f,total_trans:'
637      write (6,'(5(f7.2,1X))') emsfc_lw,100.*bb(j), &
638            100.*fluxtop_clrsky(j), &
639            trans_layers_above_clrsky(j), meantbclr(j)
640    enddo
641  endif
642
643
644    ! !
645    ! !           END OF CLEAR SKY CALCULATION
646    ! !
647    ! !----------------------------------------------------------------
648
649
650
651    if (ncolprint.ne.0) then
652
653    do j=1,npoints ,1000
654        write(6,'(a10)') 'j='
655        write(6,'(8I10)') j
656        write (6,'(a)') 'ts:'
657        write (6,'(8f7.2)') (skt(j),ibox=1,ncolprint)
658
659        write (6,'(a)') 'ta_rev:'
660        write (6,'(8f7.2)') &
661              ((at(j,ilev2),ibox=1,ncolprint),ilev2=1,nlev)
662
663    enddo
664    endif
665    ! !loop over columns
666    do ibox=1,ncol
667      do j=1,npoints
668        fluxtop(j,ibox)=0.
669        trans_layers_above(j,ibox)=1.
670      enddo
671    enddo
672
673    do ilev=1,nlev
674          do j=1,npoints
675            ! ! Black body emission at temperature of the layer
676
677          bb(j)=1 / ( exp(1307.27/at(j,ilev)) - 1. )
678          ! !bb(j)= 5.67e-8*at(j,ilev)**4
679          enddo
680
681        do ibox=1,ncol
682          do j=1,npoints
683
684          ! ! emissivity for point in this layer
685            if (frac_out(j,ibox,ilev).eq.1) then
686            dem(j,ibox)= 1. - &
687                  ( (1. - dem_wv(j,ilev)) * (1. -  dem_s(j,ilev)) )
688            else if (frac_out(j,ibox,ilev).eq.2) then
689            dem(j,ibox)= 1. - &
690                  ( (1. - dem_wv(j,ilev)) * (1. -  dem_c(j,ilev)) )
691            else
692            dem(j,ibox)=  dem_wv(j,ilev)
693            end if
694
695
696            ! ! increase TOA flux by flux emitted from layer
697          ! ! times total transmittance in layers above
698
699            fluxtop(j,ibox) = fluxtop(j,ibox) &
700                  + dem(j,ibox) * bb(j) &
701                  * trans_layers_above(j,ibox)
702
703            ! ! update trans_layers_above with transmissivity
704          ! ! from this layer for next time around loop
705
706            trans_layers_above(j,ibox)= &
707                  trans_layers_above(j,ibox)*(1.-dem(j,ibox))
708
709          enddo ! j
710        enddo ! ibox
711
712        if (ncolprint.ne.0) then
713          do j=1,npoints,1000
714          write (6,'(a)') 'ilev:'
715          write (6,'(I2)') ilev
716
717          write(6,'(a10)') 'j='
718          write(6,'(8I10)') j
719          write (6,'(a)') 'emiss_layer:'
720          write (6,'(8f7.2)') (dem(j,ibox),ibox=1,ncolprint)
721
722          write (6,'(a)') '100.*bb(j):'
723          write (6,'(8f7.2)') (100.*bb(j),ibox=1,ncolprint)
724
725          write (6,'(a)') '100.*f:'
726          write (6,'(8f7.2)') &
727                (100.*fluxtop(j,ibox),ibox=1,ncolprint)
728
729          write (6,'(a)') 'total_trans:'
730          write (6,'(8f7.2)') &
731                (trans_layers_above(j,ibox),ibox=1,ncolprint)
732        enddo
733      endif
734
735    enddo ! ilev
736
737
738      do j=1,npoints
739        ! !add in surface emission
740        bb(j)=1/( exp(1307.27/skt(j)) - 1. )
741        ! !bb(j)=5.67e-8*skt(j)**4
742      end do
743
744    do ibox=1,ncol
745      do j=1,npoints
746
747        ! !add in surface emission
748
749        fluxtop(j,ibox) = fluxtop(j,ibox) &
750              + emsfc_lw * bb(j) &
751              * trans_layers_above(j,ibox)
752
753      end do
754    end do
755
756    ! !calculate mean infrared brightness temperature
757    do ibox=1,ncol
758      do j=1,npoints
759        meantb(j) = meantb(j)+1307.27/(log(1.+(1./fluxtop(j,ibox))))
760      end do
761    end do
762      do j=1, npoints
763        meantb(j) = meantb(j) / real(ncol)
764      end do
765
766    if (ncolprint.ne.0) then
767
768      do j=1,npoints ,1000
769      write(6,'(a10)') 'j='
770      write(6,'(8I10)') j
771      write (6,'(a)') 'id:'
772      write (6,'(a)') 'surface'
773
774      write (6,'(a)') 'emiss_layer:'
775      write (6,'(8f7.2)') (dem(1,ibox),ibox=1,ncolprint)
776
777      write (6,'(a)') '100.*bb(j):'
778      write (6,'(8f7.2)') (100.*bb(j),ibox=1,ncolprint)
779
780      write (6,'(a)') '100.*f:'
781      write (6,'(8f7.2)') (100.*fluxtop(j,ibox),ibox=1,ncolprint)
782
783      write (6,'(a)') 'meantb(j):'
784      write (6,'(8f7.2)') (meantb(j),ibox=1,ncolprint)
785
786      end do
787  endif
788
789    ! !now that you have the top of atmosphere radiance account
790    ! !for ISCCP procedures to determine cloud top temperature
791
792    ! !account for partially transmitting cloud recompute flux
793    ! !ISCCP would see assuming a single layer cloud
794    ! !note choice here of 2.13, as it is primarily ice
795    ! !clouds which have partial emissivity and need the
796    ! !adjustment performed in this section
797    ! !
798  ! !If it turns out that the cloud brightness temperature
799  ! !is greater than 260K, then the liquid cloud conversion
800  !   !factor of 2.56 is used.
801  ! !
802  !   !Note that this is discussed on pages 85-87 of
803  !   !the ISCCP D level documentation (Rossow et al. 1996)
804
805      do j=1,npoints
806        ! !compute minimum brightness temperature and optical depth
807        btcmin(j) = 1. /  ( exp(1307.27/(attrop(j)-5.)) - 1. )
808      enddo
809    do ibox=1,ncol
810      do j=1,npoints
811        transmax(j) = (fluxtop(j,ibox)-btcmin(j)) &
812              /(fluxtop_clrsky(j)-btcmin(j))
813      ! !note that the initial setting of tauir(j) is needed so that
814      ! !tauir(j) has a realistic value should the next if block be
815      ! !bypassed
816        tauir(j) = tau(j,ibox) * rec2p13
817        taumin(j) = -1. * log(max(min(transmax(j),0.9999999),0.001))
818
819      enddo
820
821      if (top_height .eq. 1) then
822        do j=1,npoints
823          if (transmax(j) .gt. 0.001 .and. &
824                transmax(j) .le. 0.9999999) then
825            fluxtopinit(j) = fluxtop(j,ibox)
826          tauir(j) = tau(j,ibox) *rec2p13
827          endif
828        enddo
829        do icycle=1,2
830          do j=1,npoints
831            if (tau(j,ibox) .gt. (tauchk            )) then
832            if (transmax(j) .gt. 0.001 .and. &
833                  transmax(j) .le. 0.9999999) then
834              emcld(j,ibox) = 1. - exp(-1. * tauir(j)  )
835              fluxtop(j,ibox) = fluxtopinit(j) - &
836                    ((1.-emcld(j,ibox))*fluxtop_clrsky(j))
837              fluxtop(j,ibox)=max(1.E-06, &
838                    (fluxtop(j,ibox)/emcld(j,ibox)))
839              tb(j,ibox)= 1307.27 &
840                    / (log(1. + (1./fluxtop(j,ibox))))
841              if (tb(j,ibox) .gt. 260.) then
842              tauir(j) = tau(j,ibox) / 2.56
843              end if
844            end if
845            end if
846          enddo
847        enddo
848
849      endif
850
851      do j=1,npoints
852        if (tau(j,ibox) .gt. (tauchk            )) then
853            ! !cloudy box
854            !NOTE: tb is the cloud-top temperature not infrared brightness temperature
855            !at this point in the code
856            tb(j,ibox)= 1307.27/ (log(1. + (1./fluxtop(j,ibox))))
857            if (top_height.eq.1.and.tauir(j).lt.taumin(j)) then
858                     tb(j,ibox) = attrop(j) - 5.
859               tau(j,ibox) = 2.13*taumin(j)
860            end if
861        else
862            ! !clear sky brightness temperature
863            tb(j,ibox) = meantbclr(j)
864        end if
865      enddo ! j
866    enddo ! ibox
867
868    if (ncolprint.ne.0) then
869
870      do j=1,npoints,1000
871      write(6,'(a10)') 'j='
872      write(6,'(8I10)') j
873
874      write (6,'(a)') 'attrop:'
875      write (6,'(8f7.2)') (attrop(j))
876
877      write (6,'(a)') 'btcmin:'
878      write (6,'(8f7.2)') (btcmin(j))
879
880      write (6,'(a)') 'fluxtop_clrsky*100:'
881      write (6,'(8f7.2)') &
882            (100.*fluxtop_clrsky(j))
883
884      write (6,'(a)') '100.*f_adj:'
885      write (6,'(8f7.2)') (100.*fluxtop(j,ibox),ibox=1,ncolprint)
886
887      write (6,'(a)') 'transmax:'
888      write (6,'(8f7.2)') (transmax(ibox),ibox=1,ncolprint)
889
890      write (6,'(a)') 'tau:'
891      write (6,'(8f7.2)') (tau(j,ibox),ibox=1,ncolprint)
892
893      write (6,'(a)') 'emcld:'
894      write (6,'(8f7.2)') (emcld(j,ibox),ibox=1,ncolprint)
895
896      write (6,'(a)') 'total_trans:'
897      write (6,'(8f7.2)') &
898            (trans_layers_above(j,ibox),ibox=1,ncolprint)
899
900      write (6,'(a)') 'total_emiss:'
901      write (6,'(8f7.2)') &
902            (1.0-trans_layers_above(j,ibox),ibox=1,ncolprint)
903
904      write (6,'(a)') 'total_trans:'
905      write (6,'(8f7.2)') &
906            (trans_layers_above(j,ibox),ibox=1,ncolprint)
907
908      write (6,'(a)') 'ppout:'
909      write (6,'(8f7.2)') (tb(j,ibox),ibox=1,ncolprint)
910      enddo ! j
911  endif
912
913  end if
914
915  ! ---------------------------------------------------!
916
917  !
918  ! ---------------------------------------------------!
919  ! DETERMINE CLOUD TOP PRESSURE
920  !
921  ! again the 2 methods differ according to whether
922  ! or not you use the physical cloud top pressure (top_height = 2)
923  ! or the radiatively determined cloud top pressure (top_height = 1 or 3)
924  !
925
926  ! !compute cloud top pressure
927  do ibox=1,ncol
928    ! !segregate according to optical thickness
929    if (top_height .eq. 1 .or. top_height .eq. 3) then
930      ! !find level whose temperature
931      ! !most closely matches brightness temperature
932      do j=1,npoints
933        nmatch(j)=0
934      enddo
935      do k1=1,nlev-1
936        if (top_height_direction .eq. 2) then
937          ilev = nlev - k1
938        else
939          ilev = k1
940        end if
941        ! !cdir nodep
942        do j=1,npoints
943         if (ilev .ge. itrop(j)) then
944          if ((at(j,ilev)   .ge. tb(j,ibox) .and. &
945                at(j,ilev+1) .le. tb(j,ibox)) .or. &
946                (at(j,ilev) .le. tb(j,ibox) .and. &
947                at(j,ilev+1) .ge. tb(j,ibox))) then
948            nmatch(j)=nmatch(j)+1
949            match(j,nmatch(j))=ilev
950          end if
951         end if
952        enddo
953      end do
954
955      do j=1,npoints
956        if (nmatch(j) .ge. 1) then
957          k1 = match(j,nmatch(j))
958          k2 = k1 + 1
959          logp1 = log(pfull(j,k1))
960          logp2 = log(pfull(j,k2))
961          atd = max(tauchk,abs(at(j,k2) - at(j,k1)))
962          logp=logp1+(logp2-logp1)*abs(tb(j,ibox)-at(j,k1))/atd
963          ptop(j,ibox) = exp(logp)
964          if(abs(pfull(j,k1)-ptop(j,ibox)) .lt. &
965                abs(pfull(j,k2)-ptop(j,ibox))) then
966             levmatch(j,ibox)=k1
967          else
968             levmatch(j,ibox)=k2
969          end if
970        else
971          if (tb(j,ibox) .le. attrop(j)) then
972            ptop(j,ibox)=ptrop(j)
973            levmatch(j,ibox)=itrop(j)
974          end if
975          if (tb(j,ibox) .ge. atmax(j)) then
976            ptop(j,ibox)=pfull(j,nlev)
977            levmatch(j,ibox)=nlev
978          end if
979        end if
980      enddo ! j
981
982    else ! if (top_height .eq. 1 .or. top_height .eq. 3)
983
984      do j=1,npoints
985        ptop(j,ibox)=0.
986      enddo
987      do ilev=1,nlev
988        do j=1,npoints
989          if ((ptop(j,ibox) .eq. 0. ) &
990                .and.(frac_out(j,ibox,ilev) .ne. 0)) then
991            ptop(j,ibox)=phalf(j,ilev)
992          levmatch(j,ibox)=ilev
993          end if
994        end do
995      end do
996    end if
997
998    do j=1,npoints
999      if (tau(j,ibox) .le. (tauchk            )) then
1000        ptop(j,ibox)=0.
1001        levmatch(j,ibox)=0
1002      endif
1003    enddo
1004
1005  end do
1006
1007  !
1008  !
1009  ! ---------------------------------------------------!
1010
1011
1012  !
1013  ! ---------------------------------------------------!
1014  ! DETERMINE ISCCP CLOUD TYPE FREQUENCIES
1015  !
1016  ! Now that ptop and tau have been determined,
1017  ! determine amount of each of the 49 ISCCP cloud
1018  ! types
1019  !
1020  ! Also compute grid box mean cloud top pressure and
1021  ! optical thickness.  The mean cloud top pressure and
1022  ! optical thickness are averages over the cloudy
1023  ! area only. The mean cloud top pressure is a linear
1024  ! average of the cloud top pressures.  The mean cloud
1025  ! optical thickness is computed by converting optical
1026  ! thickness to an albedo, averaging in albedo units,
1027  ! then converting the average albedo back to a mean
1028  ! optical thickness.
1029  !
1030
1031  ! !compute isccp frequencies
1032
1033  ! !reset frequencies
1034  do ilev=1,7
1035  do ilev2=1,7
1036    do j=1,npoints !
1037         if (sunlit(j).eq.1 .or. top_height .eq. 3) then
1038            fq_isccp(j,ilev,ilev2)= 0.
1039         else
1040            fq_isccp(j,ilev,ilev2)= output_missing_value
1041         end if
1042    enddo
1043  end do
1044  end do
1045
1046  ! !reset variables need for averaging cloud properties
1047  do j=1,npoints
1048    if (sunlit(j).eq.1 .or. top_height .eq. 3) then
1049         totalcldarea(j) = 0.
1050         meanalbedocld(j) = 0.
1051         meanptop(j) = 0.
1052         meantaucld(j) = 0.
1053    else
1054         totalcldarea(j) = output_missing_value
1055         meanalbedocld(j) = output_missing_value
1056         meanptop(j) = output_missing_value
1057         meantaucld(j) = output_missing_value
1058    end if
1059  enddo ! j
1060
1061  boxarea = 1./real(ncol)
1062
1063  do ibox=1,ncol
1064    do j=1,npoints
1065
1066      if (tau(j,ibox) .gt. (tauchk            ) &
1067            .and. ptop(j,ibox) .gt. 0.) then
1068          box_cloudy(j,ibox)=.true.
1069      endif
1070
1071      if (box_cloudy(j,ibox)) then
1072
1073          if (sunlit(j).eq.1 .or. top_height .eq. 3) then
1074
1075            boxtau(j,ibox) = tau(j,ibox)
1076
1077            if (tau(j,ibox) .ge. isccp_taumin) then
1078               totalcldarea(j) = totalcldarea(j) + boxarea
1079
1080               ! !convert optical thickness to albedo
1081               albedocld(j,ibox) &
1082                     = (tau(j,ibox)**0.895)/((tau(j,ibox)**0.895)+6.82)
1083
1084               ! !contribute to averaging
1085               meanalbedocld(j) = meanalbedocld(j) &
1086                     +albedocld(j,ibox)*boxarea
1087
1088            end if
1089
1090        endif
1091
1092      endif
1093
1094      if (sunlit(j).eq.1 .or. top_height .eq. 3) then
1095
1096       if (box_cloudy(j,ibox)) then
1097
1098          ! !convert ptop to millibars
1099          ptop(j,ibox)=ptop(j,ibox) / 100.
1100
1101          ! !save for output cloud top pressure and optical thickness
1102          boxptop(j,ibox) = ptop(j,ibox)
1103
1104          if (tau(j,ibox) .ge. isccp_taumin) then
1105            meanptop(j) = meanptop(j) + ptop(j,ibox)*boxarea
1106          end if
1107
1108          ! !reset itau(j), ipres(j)
1109          itau(j) = 0
1110          ipres(j) = 0
1111
1112          ! !determine optical depth category
1113          if (tau(j,ibox) .lt. isccp_taumin) then
1114              itau(j)=1
1115          else if (tau(j,ibox) .ge. isccp_taumin &
1116                .and. tau(j,ibox) .lt. 1.3) then
1117            itau(j)=2
1118          else if (tau(j,ibox) .ge. 1.3 &
1119                .and. tau(j,ibox) .lt. 3.6) then
1120            itau(j)=3
1121          else if (tau(j,ibox) .ge. 3.6 &
1122                .and. tau(j,ibox) .lt. 9.4) then
1123              itau(j)=4
1124          else if (tau(j,ibox) .ge. 9.4 &
1125                .and. tau(j,ibox) .lt. 23.) then
1126              itau(j)=5
1127          else if (tau(j,ibox) .ge. 23. &
1128                .and. tau(j,ibox) .lt. 60.) then
1129              itau(j)=6
1130          else if (tau(j,ibox) .ge. 60.) then
1131              itau(j)=7
1132          end if
1133
1134          ! !determine cloud top pressure category
1135          if (    ptop(j,ibox) .gt. 0. &
1136                .and.ptop(j,ibox) .lt. 180.) then
1137              ipres(j)=1
1138          else if(ptop(j,ibox) .ge. 180. &
1139                .and.ptop(j,ibox) .lt. 310.) then
1140              ipres(j)=2
1141          else if(ptop(j,ibox) .ge. 310. &
1142                .and.ptop(j,ibox) .lt. 440.) then
1143              ipres(j)=3
1144          else if(ptop(j,ibox) .ge. 440. &
1145                .and.ptop(j,ibox) .lt. 560.) then
1146              ipres(j)=4
1147          else if(ptop(j,ibox) .ge. 560. &
1148                .and.ptop(j,ibox) .lt. 680.) then
1149              ipres(j)=5
1150          else if(ptop(j,ibox) .ge. 680. &
1151                .and.ptop(j,ibox) .lt. 800.) then
1152              ipres(j)=6
1153          else if(ptop(j,ibox) .ge. 800.) then
1154              ipres(j)=7
1155          end if
1156
1157          ! !update frequencies
1158          if(ipres(j) .gt. 0.and.itau(j) .gt. 0) then
1159          fq_isccp(j,itau(j),ipres(j))= &
1160                fq_isccp(j,itau(j),ipres(j))+ boxarea
1161          end if
1162
1163        end if
1164
1165      end if
1166
1167    enddo ! j
1168  end do
1169
1170  ! !compute mean cloud properties
1171  do j=1,npoints
1172    if (totalcldarea(j) .gt. 0.) then
1173      ! code above guarantees that totalcldarea > 0
1174      ! only if sunlit .eq. 1 .or. top_height = 3
1175      ! and applies only to clouds with tau > isccp_taumin
1176      meanptop(j) = meanptop(j) / totalcldarea(j)
1177      meanalbedocld(j) = meanalbedocld(j) / totalcldarea(j)
1178      meantaucld(j) = (6.82/((1./meanalbedocld(j))-1.))**(1./0.895)
1179    else
1180      ! this code is necessary so that in the case that totalcldarea = 0.,
1181      ! that these variables, which are in-cloud averages, are set to missing
1182      ! note that totalcldarea will be 0. if all the clouds in the grid box have
1183      ! tau < isccp_taumin
1184      meanptop(j) = output_missing_value
1185      meanalbedocld(j) = output_missing_value
1186      meantaucld(j) = output_missing_value
1187    end if
1188  enddo ! j
1189  !
1190  ! ---------------------------------------------------!
1191
1192  ! ---------------------------------------------------!
1193  ! OPTIONAL PRINTOUT OF DATA TO CHECK PROGRAM
1194  !
1195  if (debugcol.ne.0) then
1196  !
1197     do j=1,npoints,debugcol
1198
1199        ! !produce character output
1200        do ilev=1,nlev
1201          do ibox=1,ncol
1202               acc(ilev,ibox)=0
1203          enddo
1204        enddo
1205
1206        do ilev=1,nlev
1207          do ibox=1,ncol
1208               acc(ilev,ibox)=frac_out(j,ibox,ilev)*2
1209               if (levmatch(j,ibox) .eq. ilev) &
1210                     acc(ilev,ibox)=acc(ilev,ibox)+1
1211          enddo
1212        enddo
1213
1214         ! !print test
1215
1216      write(ftn09,11) j
121711     format('ftn09.',i4.4)
1218      open(9, FILE=ftn09, FORM='FORMATTED')
1219
1220         write(9,'(a1)') ' '
1221         write(9,'(10i5)') &
1222               (ilev,ilev=5,nlev,5)
1223         write(9,'(a1)') ' '
1224
1225         do ibox=1,ncol
1226           write(9,'(40(a1),1x,40(a1))') &
1227                 (cchar_realtops(acc(ilev,ibox)+1),ilev=1,nlev) &
1228                 ,(cchar(acc(ilev,ibox)+1),ilev=1,nlev)
1229         end do
1230         close(9)
1231
1232         if (ncolprint.ne.0) then
1233           write(6,'(a1)') ' '
1234                write(6,'(a2,1X,5(a7,1X),a50)') &
1235                      'ilev', &
1236                      'pfull','at', &
1237                      'cc*100','dem_s','dtau_s', &
1238                      'cchar'
1239
1240            ! do 4012 ilev=1,nlev
1241            !      write(6,'(60i2)') (box(i,ilev),i=1,ncolprint)
1242            !     write(6,'(i2,1X,5(f7.2,1X),50(a1))')
1243  ! &                  ilev,
1244  ! &                  pfull(j,ilev)/100.,at(j,ilev),
1245  ! &                  cc(j,ilev)*100.0,dem_s(j,ilev),dtau_s(j,ilev)
1246  ! &                  ,(cchar(acc(ilev,ibox)+1),ibox=1,ncolprint)
1247  !4012           continue
1248           write (6,'(a)') 'skt(j):'
1249           write (6,'(8f7.2)') skt(j)
1250
1251           write (6,'(8I7)') (ibox,ibox=1,ncolprint)
1252
1253           write (6,'(a)') 'tau:'
1254           write (6,'(8f7.2)') (tau(j,ibox),ibox=1,ncolprint)
1255
1256           write (6,'(a)') 'tb:'
1257           write (6,'(8f7.2)') (tb(j,ibox),ibox=1,ncolprint)
1258
1259           write (6,'(a)') 'ptop:'
1260           write (6,'(8f7.2)') (ptop(j,ibox),ibox=1,ncolprint)
1261         endif
1262
1263    enddo
1264
1265  end if
1266
1267  return
1268end subroutine icarus
1269
1270
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