Changeset 2267 for LMDZ5/trunk
- Timestamp:
- Apr 23, 2015, 2:07:44 AM (10 years ago)
- Location:
- LMDZ5/trunk/libf/phylmd
- Files:
-
- 2 edited
Legend:
- Unmodified
- Added
- Removed
-
LMDZ5/trunk/libf/phylmd/cloudth.F90
r2140 r2267 5 5 6 6 7 USE IOIPSL, ONLY : getin 7 8 IMPLICIT NONE 8 9 … … 39 40 40 41 41 REAL sigma1(ngrid,klev) 42 REAL sigma1(ngrid,klev) 42 43 REAL sigma2(ngrid,klev) 43 44 REAL qlth(ngrid,klev) … … 48 49 REAL ctot(ngrid,klev) 49 50 REAL rneb(ngrid,klev) 50 REAL t(ngrid,klev) 51 REAL t(ngrid,klev) 51 52 REAL qsatmmussig1,qsatmmussig2,sqrt2pi,pi 52 53 REAL rdd,cppd,Lv … … 62 63 REAL erf 63 64 64 65 66 67 68 ! print*,ngrid,klev,ind1,ind2,ztv(ind1,ind2),po(ind1),zqta(ind1,ind2), & 69 ! & fraca(ind1,ind2),zpspsk(ind1,ind2),paprs(ind1,ind2),ztla(ind1,ind2),zthl(ind1,ind2), & 70 ! & 'verif' 71 72 73 ! LOGICAL active(ngrid) 74 75 !----------------------------------------------------------------------------------------------------------------- 65 REAL, SAVE :: iflag_cloudth_vert, iflag_cloudth_vert_omp=0 66 67 68 LOGICAL, SAVE :: first=.true. 69 70 71 72 73 74 !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! 75 ! Astuce pour gérer deux versions de cloudth en attendant 76 ! de converger sur une version nouvelle 77 !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! 78 IF (first) THEN 79 !$OMP MASTER 80 CALL getin('iflag_cloudth_vert',iflag_cloudth_vert_omp) 81 !$OMP END MASTER 82 !$OMP BARRIER 83 iflag_cloudth_vert=iflag_cloudth_vert_omp 84 first=.false. 85 ENDIF 86 IF (iflag_cloudth_vert==1) THEN 87 CALL cloudth_vert(ngrid,klev,ind2, & 88 & ztv,po,zqta,fraca, & 89 & qcloud,ctot,zpspsk,paprs,ztla,zthl, & 90 & ratqs,zqs,t) 91 RETURN 92 ENDIF 93 !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! 94 95 96 97 !------------------------------------------------------------------------------- 76 98 ! Initialisation des variables r?elles 77 !------------------------------------------------------------------------------- ----------------------------------99 !------------------------------------------------------------------------------- 78 100 sigma1(:,:)=0. 79 101 sigma2(:,:)=0. … … 96 118 97 119 98 !------------------------------------------------------------------------------- -----------------------------------120 !------------------------------------------------------------------------------- 99 121 ! Calcul de la fraction du thermique et des ?cart-types des distributions 100 !------------------------------------------------------------------------------- -----------------------------------122 !------------------------------------------------------------------------------- 101 123 do ind1=1,ngrid 102 124 … … 139 161 140 162 141 !------------------------------------------------------------------------------ -----------------------------------163 !------------------------------------------------------------------------------ 142 164 ! Calcul des ?cart-types pour s 143 !------------------------------------------------------------------------------ -----------------------------------165 !------------------------------------------------------------------------------ 144 166 145 167 ! sigma1s=(1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+ratqs(ind1,ind2)*po(ind1) … … 155 177 ! sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.02)**0.4+0.00003 156 178 157 !------------------------------------------------------------------------------ -----------------------------------179 !------------------------------------------------------------------------------ 158 180 ! Calcul de l'eau condens?e et de la couverture nuageuse 159 !------------------------------------------------------------------------------ -----------------------------------181 !------------------------------------------------------------------------------ 160 182 sqrt2pi=sqrt(2.*pi) 161 183 xth=sth/(sqrt(2.)*sigma2s) … … 176 198 ! print*,senv,sth,sigma1s,sigma2s,fraca(ind1,ind2),'senv et sth et sig1 et sig2 et alpha' 177 199 178 !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!200 !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! 179 201 if (ctot(ind1,ind2).lt.1.e-10) then 180 202 ctot(ind1,ind2)=0. … … 242 264 243 265 244 245 246 247 248 249 250 266 !=========================================================================== 267 SUBROUTINE cloudth_vert(ngrid,klev,ind2, & 268 & ztv,po,zqta,fraca, & 269 & qcloud,ctot,zpspsk,paprs,ztla,zthl, & 270 & ratqs,zqs,t) 271 272 273 IMPLICIT NONE 274 275 276 !=========================================================================== 277 ! Auteur : Arnaud Octavio Jam (LMD/CNRS) 278 ! Date : 25 Mai 2010 279 ! Objet : calcule les valeurs de qc et rneb dans les thermiques 280 !=========================================================================== 281 282 283 #include "YOMCST.h" 284 #include "YOETHF.h" 285 #include "FCTTRE.h" 286 #include "iniprint.h" 287 #include "thermcell.h" 288 289 INTEGER itap,ind1,ind2 290 INTEGER ngrid,klev,klon,l,ig 291 292 REAL ztv(ngrid,klev) 293 REAL po(ngrid) 294 REAL zqenv(ngrid) 295 REAL zqta(ngrid,klev) 296 297 REAL fraca(ngrid,klev+1) 298 REAL zpspsk(ngrid,klev) 299 REAL paprs(ngrid,klev+1) 300 REAL ztla(ngrid,klev) 301 REAL zthl(ngrid,klev) 302 303 REAL zqsatth(ngrid,klev) 304 REAL zqsatenv(ngrid,klev) 305 306 307 REAL sigma1(ngrid,klev) 308 REAL sigma2(ngrid,klev) 309 REAL qlth(ngrid,klev) 310 REAL qlenv(ngrid,klev) 311 REAL qltot(ngrid,klev) 312 REAL cth(ngrid,klev) 313 REAL cenv(ngrid,klev) 314 REAL ctot(ngrid,klev) 315 REAL rneb(ngrid,klev) 316 REAL t(ngrid,klev) 317 REAL qsatmmussig1,qsatmmussig2,sqrt2pi,pi 318 REAL rdd,cppd,Lv,sqrt2,sqrtpi 319 REAL alth,alenv,ath,aenv 320 REAL sth,senv,sigma1s,sigma2s,xth,xenv 321 REAL xth1,xth2,xenv1,xenv2,deltasth, deltasenv 322 REAL IntJ,IntI1,IntI2,IntI3,coeffqlenv,coeffqlth 323 REAL Tbef,zdelta,qsatbef,zcor 324 REAL alpha,qlbef 325 REAL ratqs(ngrid,klev) ! determine la largeur de distribution de vapeur 326 327 REAL zpdf_sig(ngrid),zpdf_k(ngrid),zpdf_delta(ngrid) 328 REAL zpdf_a(ngrid),zpdf_b(ngrid),zpdf_e1(ngrid),zpdf_e2(ngrid) 329 REAL zqs(ngrid), qcloud(ngrid) 330 REAL erf 331 332 333 334 335 336 !------------------------------------------------------------------------------ 337 ! Initialisation des variables r?elles 338 !------------------------------------------------------------------------------ 339 sigma1(:,:)=0. 340 sigma2(:,:)=0. 341 qlth(:,:)=0. 342 qlenv(:,:)=0. 343 qltot(:,:)=0. 344 rneb(:,:)=0. 345 qcloud(:)=0. 346 cth(:,:)=0. 347 cenv(:,:)=0. 348 ctot(:,:)=0. 349 qsatmmussig1=0. 350 qsatmmussig2=0. 351 rdd=287.04 352 cppd=1005.7 353 pi=3.14159 354 Lv=2.5e6 355 sqrt2pi=sqrt(2.*pi) 356 sqrt2=sqrt(2.) 357 sqrtpi=sqrt(pi) 358 359 360 361 !------------------------------------------------------------------------------- 362 ! Calcul de la fraction du thermique et des ?cart-types des distributions 363 !------------------------------------------------------------------------------- 364 do ind1=1,ngrid 365 366 if ((ztv(ind1,1).gt.ztv(ind1,2)).and.(fraca(ind1,ind2).gt.1.e-10)) then 367 368 zqenv(ind1)=(po(ind1)-fraca(ind1,ind2)*zqta(ind1,ind2))/(1.-fraca(ind1,ind2)) 369 370 371 ! zqenv(ind1)=po(ind1) 372 Tbef=zthl(ind1,ind2)*zpspsk(ind1,ind2) 373 zdelta=MAX(0.,SIGN(1.,RTT-Tbef)) 374 qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2) 375 qsatbef=MIN(0.5,qsatbef) 376 zcor=1./(1.-retv*qsatbef) 377 qsatbef=qsatbef*zcor 378 zqsatenv(ind1,ind2)=qsatbef 379 380 381 382 383 alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2) 384 aenv=1./(1.+(alenv*Lv/cppd)) 385 senv=aenv*(po(ind1)-zqsatenv(ind1,ind2)) 386 387 388 389 390 Tbef=ztla(ind1,ind2)*zpspsk(ind1,ind2) 391 zdelta=MAX(0.,SIGN(1.,RTT-Tbef)) 392 qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2) 393 qsatbef=MIN(0.5,qsatbef) 394 zcor=1./(1.-retv*qsatbef) 395 qsatbef=qsatbef*zcor 396 zqsatth(ind1,ind2)=qsatbef 397 398 alth=(0.622*Lv*zqsatth(ind1,ind2))/(rdd*ztla(ind1,ind2)**2) 399 ath=1./(1.+(alth*Lv/cppd)) 400 sth=ath*(zqta(ind1,ind2)-zqsatth(ind1,ind2)) 401 402 403 404 !------------------------------------------------------------------------------ 405 ! Calcul des ?cart-types pour s 406 !------------------------------------------------------------------------------ 407 408 sigma1s=(0.92**0.5)*(fraca(ind1,ind2)**0.5)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+ratqs(ind1,ind2)*po(ind1) 409 sigma2s=0.09*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.02)**0.5+0.002*zqta(ind1,ind2) 410 ! if (paprs(ind1,ind2).gt.90000) then 411 ! ratqs(ind1,ind2)=0.002 412 ! else 413 ! ratqs(ind1,ind2)=0.002+0.0*(90000-paprs(ind1,ind2))/20000 414 ! endif 415 ! sigma1s=(1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+0.002*po(ind1) 416 ! sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.01)**0.4+0.002*zqta(ind1,ind2) 417 ! sigma1s=ratqs(ind1,ind2)*po(ind1) 418 ! sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.02)**0.4+0.00003 419 420 !------------------------------------------------------------------------------ 421 ! Calcul de l'eau condens?e et de la couverture nuageuse 422 !------------------------------------------------------------------------------ 423 sqrt2pi=sqrt(2.*pi) 424 xth=sth/(sqrt(2.)*sigma2s) 425 xenv=senv/(sqrt(2.)*sigma1s) 426 cth(ind1,ind2)=0.5*(1.+1.*erf(xth)) 427 cenv(ind1,ind2)=0.5*(1.+1.*erf(xenv)) 428 ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2) 429 ! ctot(ind1,ind2)=alpha*cth(ind1,ind2)+(1.-1.*alpha)*cenv(ind1,ind2) 430 431 432 433 qlth(ind1,ind2)=sigma2s*((exp(-1.*xth**2)/sqrt2pi)+xth*sqrt(2.)*cth(ind1,ind2)) 434 qlenv(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt(2.)*cenv(ind1,ind2)) 435 qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2) 436 ! qltot(ind1,ind2)=alpha*qlth(ind1,ind2)+(1.-1.*alpha)*qlenv(ind1,ind2) 437 438 439 ! print*,senv,sth,sigma1s,sigma2s,fraca(ind1,ind2),'senv et sth et sig1 et sig2 et alpha' 440 441 442 !------------------------------------------------------------------------------- 443 ! Version 2: Modification selon J.-Louis. On condense ?? partir de qsat-ratqs 444 !------------------------------------------------------------------------------- 445 ! deltasenv=aenv*ratqs(ind1,ind2)*po(ind1) 446 ! deltasth=ath*ratqs(ind1,ind2)*zqta(ind1,ind2) 447 deltasenv=aenv*ratqs(ind1,ind2)*zqsatenv(ind1,ind2) 448 deltasth=ath*ratqs(ind1,ind2)*zqsatth(ind1,ind2) 449 ! deltasenv=aenv*0.01*po(ind1) 450 ! deltasth=ath*0.01*zqta(ind1,ind2) 451 xenv1=(senv-deltasenv)/(sqrt(2.)*sigma1s) 452 xenv2=(senv+deltasenv)/(sqrt(2.)*sigma1s) 453 xth1=(sth-deltasth)/(sqrt(2.)*sigma2s) 454 xth2=(sth+deltasth)/(sqrt(2.)*sigma2s) 455 coeffqlenv=(sigma1s)**2/(2*sqrtpi*deltasenv) 456 coeffqlth=(sigma2s)**2/(2*sqrtpi*deltasth) 457 458 cth(ind1,ind2)=0.5*(1.+1.*erf(xth2)) 459 cenv(ind1,ind2)=0.5*(1.+1.*erf(xenv2)) 460 ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2) 461 462 IntJ=sigma1s*(exp(-1.*xenv1**2)/sqrt2pi)+0.5*senv*(1+erf(xenv1)) 463 IntI1=coeffqlenv*0.5*(0.5*sqrtpi*(erf(xenv2)-erf(xenv1))+xenv1*exp(-1.*xenv1**2)-xenv2*exp(-1.*xenv2**2)) 464 IntI2=coeffqlenv*xenv2*(exp(-1.*xenv2**2)-exp(-1.*xenv1**2)) 465 IntI3=coeffqlenv*0.5*sqrtpi*xenv2**2*(erf(xenv2)-erf(xenv1)) 466 467 qlenv(ind1,ind2)=IntJ+IntI1+IntI2+IntI3 468 ! qlenv(ind1,ind2)=IntJ 469 ! print*, qlenv(ind1,ind2),'VERIF EAU' 470 471 472 IntJ=sigma2s*(exp(-1.*xth1**2)/sqrt2pi)+0.5*sth*(1+erf(xth1)) 473 ! IntI1=coeffqlth*((0.5*xth1-xth2)*exp(-1.*xth1**2)+0.5*xth2*exp(-1.*xth2**2)) 474 ! IntI2=coeffqlth*0.5*sqrtpi*(0.5+xth2**2)*(erf(xth2)-erf(xth1)) 475 IntI1=coeffqlth*0.5*(0.5*sqrtpi*(erf(xth2)-erf(xth1))+xth1*exp(-1.*xth1**2)-xth2*exp(-1.*xth2**2)) 476 IntI2=coeffqlth*xth2*(exp(-1.*xth2**2)-exp(-1.*xth1**2)) 477 IntI3=coeffqlth*0.5*sqrtpi*xth2**2*(erf(xth2)-erf(xth1)) 478 qlth(ind1,ind2)=IntJ+IntI1+IntI2+IntI3 479 ! qlth(ind1,ind2)=IntJ 480 ! print*, IntJ,IntI1,IntI2,IntI3,qlth(ind1,ind2),'VERIF EAU2' 481 qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2) 482 483 !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! 484 if (cenv(ind1,ind2).lt.1.e-10.or.cth(ind1,ind2).lt.1.e-10) then 485 ctot(ind1,ind2)=0. 486 qcloud(ind1)=zqsatenv(ind1,ind2) 487 488 else 489 490 ctot(ind1,ind2)=ctot(ind1,ind2) 491 qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqs(ind1) 492 ! qcloud(ind1)=fraca(ind1,ind2)*qlth(ind1,ind2)/cth(ind1,ind2) & 493 ! & +(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)/cenv(ind1,ind2)+zqs(ind1) 494 495 endif 496 497 498 499 ! print*,sth,sigma2s,qlth(ind1,ind2),ctot(ind1,ind2),qltot(ind1,ind2),'verif' 500 501 502 else ! gaussienne environnement seule 503 504 zqenv(ind1)=po(ind1) 505 Tbef=t(ind1,ind2) 506 zdelta=MAX(0.,SIGN(1.,RTT-Tbef)) 507 qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2) 508 qsatbef=MIN(0.5,qsatbef) 509 zcor=1./(1.-retv*qsatbef) 510 qsatbef=qsatbef*zcor 511 zqsatenv(ind1,ind2)=qsatbef 512 513 514 ! qlbef=Max(po(ind1)-zqsatenv(ind1,ind2),0.) 515 zthl(ind1,ind2)=t(ind1,ind2)*(101325/paprs(ind1,ind2))**(rdd/cppd) 516 alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2) 517 aenv=1./(1.+(alenv*Lv/cppd)) 518 senv=aenv*(po(ind1)-zqsatenv(ind1,ind2)) 519 520 521 sigma1s=ratqs(ind1,ind2)*zqenv(ind1) 522 523 sqrt2pi=sqrt(2.*pi) 524 xenv=senv/(sqrt(2.)*sigma1s) 525 ctot(ind1,ind2)=0.5*(1.+1.*erf(xenv)) 526 qltot(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt(2.)*cenv(ind1,ind2)) 527 528 if (ctot(ind1,ind2).lt.1.e-3) then 529 ctot(ind1,ind2)=0. 530 qcloud(ind1)=zqsatenv(ind1,ind2) 531 532 else 533 534 ctot(ind1,ind2)=ctot(ind1,ind2) 535 qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqsatenv(ind1,ind2) 536 537 endif 538 539 540 541 542 543 544 endif 545 enddo 546 547 return 548 end -
LMDZ5/trunk/libf/phylmd/thermcell_plume.F90
r2189 r2267 6 6 & lalim,f0,detr_star,entr_star,f_star,csc,ztva, & 7 7 & ztla,zqla,zqta,zha,zw2,w_est,ztva_est,zqsatth,lmix,lmix_bis,linter & 8 9 ! & ,lev_out,lunout1,igout,zbuoy,zbuoyjam)8 & ,lev_out,lunout1,igout) 9 ! & ,lev_out,lunout1,igout,zbuoy,zbuoyjam) 10 10 !-------------------------------------------------------------------------- 11 11 !thermcell_plume: calcule les valeurs de qt, thetal et w dans l ascendance … … 87 87 real ztv_est1,ztv_est2 88 88 real zcor,zdelta,zcvm5,qlbef 89 real zbetalpha 89 real zbetalpha, coefzlmel 90 90 real eps 91 91 REAL REPS,RLvCp,DDT0 … … 396 396 else ! if (iflag_thermals_ed.lt.8) then 397 397 lt=l+1 398 zlt=zlev(ig,lt) 398 399 zdz2=zlev(ig,lt)-zlev(ig,l) 399 400 … … 405 406 zdz3=zlev(ig,lt+1)-zlt 406 407 zltdwn=zlev(ig,lt)-zdz3/2 407 408 zbuoyjam(ig,l)=1.*RG*(((lmel+zdz3-zdz2)/zdz3)*(ztva_est(ig,l)- & 409 & ztv(ig,lt))/ztv(ig,lt)+((zdz2-lmel)/zdz3)*(ztva_est(ig,l)- & 408 zlmelup=zlmel+(zdz/2) 409 coefzlmel=Min(1.,(zlmelup-zltdwn)/zdz) 410 zbuoyjam(ig,l)=1.*RG*(coefzlmel*(ztva_est(ig,l)- & 411 & ztv(ig,lt))/ztv(ig,lt)+(1.-coefzlmel)*(ztva_est(ig,l)- & 410 412 & ztv(ig,lt-1))/ztv(ig,lt-1))+0.*zbuoy(ig,l) 411 413 endif ! if (iflag_thermals_ed.lt.8) then … … 422 424 zdw2=afact*zbuoy(ig,l)/fact_epsilon 423 425 zdw2bis=afact*zbuoy(ig,l-1)/fact_epsilon 426 ! zdw2bis=0.5*(zdw2+zdw2bis) 424 427 lm=Max(1,l-2) 425 428 ! zdw2=(afact/fact_epsilon)*((zdz/zdzbis)*zbuoy(ig,l) & … … 442 445 ! & (exp(-zw2factbis)*(w_est(ig,l-1)-zdw2bis)+zdw2)) 443 446 444 w_est(ig,l+1)=Max(0.0001,exp(-zw2fact)*(w_est(ig,l)-zdw2 bis)+zdw2)447 w_est(ig,l+1)=Max(0.0001,exp(-zw2fact)*(w_est(ig,l)-zdw2)+zdw2) 445 448 446 449 ! Nouvelle version Arnaud … … 556 559 & mix0 * 0.1 / (zalpha+0.001) & 557 560 & + zbetalpha*MAX(entr_min, & 558 & afact*zbuoyjam(ig,l)/zw2m - fact_epsilon 561 & afact*zbuoyjam(ig,l)/zw2m - fact_epsilon)) 559 562 560 563 … … 645 648 ! & (zw2(ig,l)-zdw2)+zdw2)+(zdzbis-zdz)/zdzbis* & 646 649 ! & (exp(-zw2factbis)*(zw2(ig,l-1)-zdw2bis)+zdw2)) 650 if (iflag_thermals_ed==8) then 651 zw2(ig,l+1)=Max(0.0001,exp(-zw2fact)*(zw2(ig,l)-zdw2)+zdw2) 652 else 647 653 zw2(ig,l+1)=Max(0.0001,exp(-zw2fact)*(zw2(ig,l)-zdw2bis)+zdw2) 654 endif 648 655 ! zw2(ig,l+1)=Max(0.0001,(zdz/(zdz+zdzbis))*(exp(-zw2fact)* & 649 ! & (zw2(ig,l)-zdw2 bis)+zdw2)+(zdzbis/(zdz+zdzbis))* &656 ! & (zw2(ig,l)-zdw2)+zdw2bis)+(zdzbis/(zdz+zdzbis))* & 650 657 ! & (exp(-zw2factbis)*(zw2(ig,l-1)-zdw2bis)+zdw2bis)) 651 658
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