Changeset 3710 for LMDZ6/branches/Optimisation_LMDZ/libf/phylmd
- Timestamp:
- Jun 11, 2020, 11:09:40 AM (4 years ago)
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LMDZ6/branches/Optimisation_LMDZ/libf/phylmd/cv3p_mixing.f90
r3709 r3710 106 106 REAL, DIMENSION(nloc, nd, nd), INTENT(OUT) :: hent 107 107 INTEGER, DIMENSION(nloc, nd), INTENT(OUT) :: nent 108 109 108 109 !local variables: 110 110 INTEGER i, j, k, il, im, jm 111 111 REAL Smid … … 126 126 REAL :: Tm !Mixed draught temperature 127 127 LOGICAL, DIMENSION(nloc) :: lwork 128 128 129 129 REAL amxupcrit, df, ff 130 130 INTEGER nstep 131 131 132 132 INTEGER, SAVE :: igout = 1 133 !$omp THREADPRIVATE(igout)134 135 ! -- Mixing probability distribution functions136 133 !$omp THREADPRIVATE(igout) 134 135 ! -- Mixing probability distribution functions 136 137 137 REAL Qcoef1, Qcoef2, QFF, QFFF, Qmix, Rmix, Qmix1, Rmix1, Qmix2, Rmix2, F 138 138 139 139 Qcoef1(F) = tanh(F/gammas) 140 140 Qcoef2(F) = (tanh(F/gammas) + gammas*log(cosh((1.-F)/gammas)/cosh(F/gammas))) … … 147 147 Qmix(F) = qqa1*Qmix1(F) + qqa2*Qmix2(F) 148 148 Rmix(F) = qqa1*Rmix1(F) + qqa2*Rmix2(F) 149 149 150 150 INTEGER, SAVE :: ifrst = 0 151 !$omp THREADPRIVATE(ifrst)152 153 ! =====================================================================154 ! --- INITIALIZE VARIOUS ARRAYS USED IN THE COMPUTATIONS155 ! =====================================================================156 ! -- Initialize mixing PDF coefficients151 !$omp THREADPRIVATE(ifrst) 152 153 ! ===================================================================== 154 ! --- INITIALIZE VARIOUS ARRAYS USED IN THE COMPUTATIONS 155 ! ===================================================================== 156 ! -- Initialize mixing PDF coefficients 157 157 IF (ifrst == 0) THEN 158 158 ifrst = 1 … … 162 162 fmax, gammas, qqa1, qqa2, Qcoef1max, Qcoef2max 163 163 END IF 164 164 165 165 nent(:ncum, :nl) = 0 166 166 elij(:ncum, :nl, :nl) = 0 167 167 hent(:ncum, :nl, :nl) = 0 168 168 169 169 DO j = 1, nl 170 170 DO k = 1, nl … … 176 176 END DO 177 177 END DO 178 178 179 179 Ment(1:ncum, 1:nd, 1:nd) = 0.0 180 180 Sij(1:ncum, 1:nd, 1:nd) = 0.0 181 181 Sigij(1:ncum, 1:nd, 1:nd) = 0.0 182 183 ! =====================================================================184 ! --- CALCULATE ENTRAINED AIR MASS FLUX (Ment), TOTAL WATER MIXING185 ! --- RATIO (QENT), TOTAL CONDENSED WATER (elij), AND MIXING186 ! --- FRACTION (Sij)187 ! =====================================================================188 182 183 ! ===================================================================== 184 ! --- CALCULATE ENTRAINED AIR MASS FLUX (Ment), TOTAL WATER MIXING 185 ! --- RATIO (QENT), TOTAL CONDENSED WATER (elij), AND MIXING 186 ! --- FRACTION (Sij) 187 ! ===================================================================== 188 189 189 DO i = minorig + 1, nl 190 190 IF (ok_entrain) THEN … … 230 230 nent(il, i) = nent(il, i) + 1 231 231 END IF 232 232 233 233 Sij(il, i, j) = amax1(0.0, Sij(il, i, j)) 234 234 Sij(il, i, j) = amin1(1.0, Sij(il, i, j)) … … 245 245 ENDDO 246 246 ENDIF ! (ok_entrain) 247 247 248 248 IF (prt_level >= 10) THEN 249 249 print *, 'cv3p_mixing i, nent(i), icb, inb ', i, nent(igout, i), icb(igout), inb(igout) … … 252 252 ENDIF 253 253 ENDIF 254 255 ! *** if no air can entrain at level i assume that updraft detrains ***256 ! *** at that level and calculate detrained air flux and properties ***257 254 255 ! *** if no air can entrain at level i assume that updraft detrains *** 256 ! *** at that level and calculate detrained air flux and properties *** 257 258 258 DO il = 1, ncum 259 259 IF ((i >= icb(il)) .AND. (i <= inb(il)) .AND. (nent(il, i) == 0)) THEN … … 270 270 END DO 271 271 END DO ! i = minorig + 1, nl 272 272 273 273 DO j = minorig, nl 274 274 DO i = minorig, nl … … 281 281 END DO 282 282 END DO 283 284 ! =====================================================================285 ! --- NORMALIZE ENTRAINED AIR MASS FLUXES286 ! --- TO REPRESENT EQUAL PROBABILITIES OF MIXING287 ! =====================================================================288 283 284 ! ===================================================================== 285 ! --- NORMALIZE ENTRAINED AIR MASS FLUXES 286 ! --- TO REPRESENT EQUAL PROBABILITIES OF MIXING 287 ! ===================================================================== 288 289 289 CALL zilch(csum, nloc*nd) 290 290 291 291 DO il = 1, ncum 292 292 lwork(il) = .FALSE. 293 293 END DO 294 295 ! ---------------------------------------------------------------294 295 ! --------------------------------------------------------------- 296 296 DO i = minorig + 1, nl !Loop on origin level "i" 297 ! ---------------------------------------------------------------298 297 ! --------------------------------------------------------------- 298 299 299 DO il = 1, ncum 300 300 IF (i >= icb(il) .AND. i <= inb(il)) THEN 301 301 signhpmh(il) = sign(1., hp(il, i) - h(il, i)) 302 303 Sx(il) = max( maxval(Sij(il, i, i + 1:inb(il))), 0., signhpmh(il))304 302 303 Sx(il) = max(maxval(Sij(il, i, i + 1:inb(il))), 0., signhpmh(il)) 304 305 305 lwork(il) = (nent(il, i) /= 0) 306 306 rti = qta(il, i - 1) - ep(il, i)*clw(il, i) … … 319 319 Scrit(il) = min(anum/denom, 1.) 320 320 alt = rti - rs(il, i) + Scrit(il)*(rr(il, i) - rti) 321 321 322 322 ! Find new critical value Scrit2 323 323 ! such that : Sij > Scrit2 => mixed draught will detrain at J<I … … 326 326 Scrit(il)*max(0., signhpmh(il)) 327 327 Scrit(il) = Scrit2 328 328 329 329 ! Correction pour la nouvelle logique; la correction pour ALT 330 330 ! est un peu au hazard 331 331 IF (Scrit(il) <= 0.0) Scrit(il) = 0.0 332 332 IF (alt <= 0.0) Scrit(il) = 1.0 333 333 334 334 smax(il) = 0.0 335 335 ASij(il) = 0.0 336 336 sup(il) = 0. ! upper S-value reached by descending draughts 337 338 if ( i < inb(il)) then337 338 if (i < inb(il)) then 339 339 Sbef(il) = Sij(il, i, inb(il)) 340 340 else … … 343 343 END IF 344 344 END DO 345 346 ! --------------------------------------------------------------- 347 DO j = minorig, nl !Loop on destination level "j" 348 ! --------------------------------------------------------------- 349 ! ----------------------------------------------- 350 IF (j > i) THEN 351 ! ----------------------------------------------- 352 DO il = 1, ncum 353 IF (i >= icb(il) .AND. i <= inb(il) .AND. & 354 j >= (icb(il) - 1) .AND. j <= inb(il) .AND. & 355 lwork(il)) THEN 356 IF (Sij(il, i, j) > 0.0) THEN 357 Smid = min(Sij(il, i, j), Scrit(il)) 358 Sjmax(il) = Smid 359 Sjmin(il) = Smid 360 IF (Smid < smin(il) .AND. Sij(il, i, j + 1) < Smid) THEN 361 smin(il) = min( smin(il), Smid ) 362 Sjmax(il) = min((Sij(il, i, j + 1) + Sij(il, i, j))/2., Sij(il, i, j), Scrit(il)) 363 Sjmin(il) = max((Sbef(il) + Sij(il, i, j))/2., Sij(il, i, j)) 364 Sjmin(il) = min(Sjmin(il), Scrit(il)) 365 Sbef(il) = Sij(il, i, j) 366 END IF 367 END IF 368 END IF 369 END DO 370 ! ----------------------------------------------- 371 ELSE IF (j == i) THEN 372 ! ----------------------------------------------- 373 DO il = 1, ncum 374 IF (i >= icb(il) .AND. i <= inb(il) .AND. & 375 j >= (icb(il) - 1) .AND. j <= inb(il) .AND. & 376 lwork(il)) THEN 377 IF (Sij(il, i, j) > 0.0) THEN 378 Smid = 1. 379 Sjmin(il) = max((Sij(il, i, j - 1) + Smid)/2., Scrit(il))*max(0., -signhpmh(il)) + & 380 min((Sij(il, i, j + 1) + Smid)/2., Scrit(il))*max(0., signhpmh(il)) 381 Sjmin(il) = max(Sjmin(il), sup(il)) 382 Sjmax(il) = 1. 383 ! - preparation des variables Scrit, Smin et Sbef pour la partie j>i 384 Scrit(il) = min(Sjmin(il), Sjmax(il), Scrit(il)) 385 386 smin(il) = 1. 387 Sbef(il) = max(0., signhpmh(il)) 388 supmax(il, i) = sign(Scrit(il), -signhpmh(il)) 389 END IF 390 END IF 391 END DO 392 ! ----------------------------------------------- 393 ELSE IF (j < i) THEN 394 ! ----------------------------------------------- 395 DO il = 1, ncum 396 IF (i >= icb(il) .AND. i <= inb(il) .AND. & 397 j >= (icb(il) - 1) .AND. j <= inb(il) .AND. & 398 lwork(il)) THEN 399 IF (Sij(il, i, j) > 0.0) THEN 400 Smid = max(Sij(il, i, j), Scrit(il)) 401 Sjmax(il) = Smid 402 Sjmin(il) = Smid 403 IF (Smid > smax(il) .AND. Sij(il, i, j + 1) > Smid) THEN 404 smax(il) = Smid 405 Sjmax(il) = max((Sij(il, i, j + 1) + Sij(il, i, j))/2., Sij(il, i, j)) 406 Sjmax(il) = max(Sjmax(il), Scrit(il)) 407 Sjmin(il) = min((Sbef(il) + Sij(il, i, j))/2., Sij(il, i, j)) 408 Sjmin(il) = max(Sjmin(il), Scrit(il)) 409 Sbef(il) = Sij(il, i, j) 410 END IF 411 IF (abs(Sjmin(il) - Sjmax(il)) > 1.E-10) & 412 sup(il) = max(Sjmin(il), Sjmax(il), sup(il)) 413 END IF 414 END IF 415 END DO 416 ! ----------------------------------------------- 417 END IF 418 ! ----------------------------------------------- 419 420 DO il = 1, ncum 345 346 DO il = 1, ncum 347 DO j = minorig, nl !Loop on destination level "j" 421 348 IF (i >= icb(il) .AND. i <= inb(il) .AND. & 422 349 j >= (icb(il) - 1) .AND. j <= inb(il) .AND. & 423 lwork(il)) THEN 424 IF (Sij(il, i, j) > 0.0) THEN 350 lwork(il) .AND. Sij(il, i, j) > 0.0) THEN 351 ! ----------------------------------------------- 352 IF (j > i) THEN 353 Smid = min(Sij(il, i, j), Scrit(il)) 354 Sjmax(il) = Smid 355 Sjmin(il) = Smid 356 IF (Smid < smin(il) .AND. Sij(il, i, j + 1) < Smid) THEN 357 smin(il) = min(smin(il), Smid) 358 Sjmax(il) = min((Sij(il, i, j + 1) + Sij(il, i, j))/2., Sij(il, i, j), Scrit(il)) 359 Sjmin(il) = max((Sbef(il) + Sij(il, i, j))/2., Sij(il, i, j)) 360 Sjmin(il) = min(Sjmin(il), Scrit(il)) 361 Sbef(il) = Sij(il, i, j) 362 END IF 363 ELSE IF (j == i) THEN 364 Smid = 1. 365 Sjmin(il) = max((Sij(il, i, j - 1) + Smid)/2., Scrit(il))*max(0., -signhpmh(il)) + & 366 min((Sij(il, i, j + 1) + Smid)/2., Scrit(il))*max(0., signhpmh(il)) 367 Sjmin(il) = max(Sjmin(il), sup(il)) 368 Sjmax(il) = 1. 369 ! preparation des variables Scrit, Smin et Sbef pour la partie j>i 370 Scrit(il) = min(Sjmin(il), Sjmax(il), Scrit(il)) 371 372 smin(il) = 1. 373 Sbef(il) = max(0., signhpmh(il)) 374 supmax(il, i) = sign(Scrit(il), -signhpmh(il)) 375 ELSE IF (j < i) THEN 376 Smid = max(Sij(il, i, j), Scrit(il)) 377 Sjmax(il) = Smid 378 Sjmin(il) = Smid 379 IF (Smid > smax(il) .AND. Sij(il, i, j + 1) > Smid) THEN 380 smax(il) = Smid 381 Sjmax(il) = max((Sij(il, i, j + 1) + Sij(il, i, j))/2., Sij(il, i, j)) 382 Sjmax(il) = max(Sjmax(il), Scrit(il)) 383 Sjmin(il) = min((Sbef(il) + Sij(il, i, j))/2., Sij(il, i, j)) 384 Sjmin(il) = max(Sjmin(il), Scrit(il)) 385 Sbef(il) = Sij(il, i, j) 386 END IF 387 IF (abs(Sjmin(il) - Sjmax(il)) > 1.E-10) & 388 sup(il) = max(Sjmin(il), Sjmax(il), sup(il)) 389 END IF 390 ! ----------------------------------------------- 391 392 rti = qta(il, i - 1) - ep(il, i)*clw(il, i) 393 Qmixmax(il) = Qmix(Sjmax(il)) 394 Qmixmin(il) = Qmix(Sjmin(il)) 395 Rmixmax(il) = Rmix(Sjmax(il)) 396 Rmixmin(il) = Rmix(Sjmin(il)) 397 sqmrmax(il) = Sjmax(il)*Qmix(Sjmax(il)) - Rmix(Sjmax(il)) 398 sqmrmin(il) = Sjmin(il)*Qmix(Sjmin(il)) - Rmix(Sjmin(il)) 399 400 Ment(il, i, j) = abs(Qmixmax(il) - Qmixmin(il))*Ment(il, i, j) 401 IF (abs(Qmixmax(il) - Qmixmin(il)) > 1.E-10) THEN 402 Sigij(il, i, j) = (sqmrmax(il) - sqmrmin(il))/(Qmixmax(il) - Qmixmin(il)) 403 ELSE 404 Sigij(il, i, j) = 0. 405 END IF 406 407 ! Compute Qent, uent, vent according to the true mixing fraction 408 Qent(il, i, j) = (1.-Sigij(il, i, j))*rti + Sigij(il, i, j)*rr(il, i) 409 uent(il, i, j) = (1.-Sigij(il, i, j))*unk(il) + Sigij(il, i, j)*u(il, i) 410 vent(il, i, j) = (1.-Sigij(il, i, j))*vnk(il) + Sigij(il, i, j)*v(il, i) 411 412 ! Compute liquid water static energy of mixed draughts 413 hent(il, i, j) = (1.-Sigij(il, i, j))*hp(il, i) + Sigij(il, i, j)*h(il, i) 414 ! Heat capacity of mixed draught 415 cpm = cpd + Qent(il, i, j)*(cpv - cpd) 416 IF (cvflag_ice .and. frac(il, j) .gt. 0.) THEN 417 elij(il, i, j) = Qent(il, i, j) - rs(il, j) 418 elij(il, i, j) = elij(il, i, j) + & 419 (h(il, j) - hent(il, i, j) + (cpv - cpd)*(Qent(il, i, j) - rr(il, j))*t(il, j))* & 420 rs(il, j)*lv(il, j)/(cpm*rrv*t(il, j)*t(il, j)) 421 elij(il, i, j) = elij(il, i, j)/ & 422 (1.+(lv(il, j) + frac(il, j)*lf(il, j))*lv(il, j)*rs(il, j)/ & 423 (cpm*rrv*t(il, j)*t(il, j))) 424 ELSE 425 elij(il, i, j) = Qent(il, i, j) - rs(il, j) 426 elij(il, i, j) = elij(il, i, j) + & 427 (h(il, j) - hent(il, i, j) + (cpv - cpd)*(Qent(il, i, j) - rr(il, j))*t(il, j))* & 428 rs(il, j)*lv(il, j)/(cpm*rrv*t(il, j)*t(il, j)) 429 elij(il, i, j) = elij(il, i, j)/ & 430 (1.+lv(il, j)*lv(il, j)*rs(il, j)/ & 431 (cpm*rrv*t(il, j)*t(il, j))) 432 ENDIF 433 elij(il, i, j) = max(elij(il, i, j), 0.) 434 435 elij(il, i, j) = min(elij(il, i, j), Qent(il, i, j)) 436 437 IF (j > i) THEN 438 awat = elij(il, i, j) - (1.-ep(il, j))*clw(il, j) 439 awat = amax1(awat, 0.0) 440 ELSE 441 awat = 0. 442 END IF 443 444 ! Mixed draught temperature at level j 445 IF (cvflag_ice .and. frac(il, j) .gt. 0.) THEN 446 Tm = t(il, j) + (Qent(il, i, j) - elij(il, i, j) - rs(il, j))*rrv*t(il, j)*t(il, j)/(lv(il, j)*rs(il, j)) 447 hent(il, i, j) = hent(il, i, j) + (lv(il, j) + frac(il, j)*lf(il, j) + (cpd - cpv)*Tm)*awat 448 ELSE 449 Tm = t(il, j) + (Qent(il, i, j) - elij(il, i, j) - rs(il, j))*rrv*t(il, j)*t(il, j)/(lv(il, j)*rs(il, j)) 450 hent(il, i, j) = hent(il, i, j) + (lv(il, j) + (cpd - cpv)*Tm)*awat 451 ENDIF 452 453 ! ASij is the integral of P(F) over the relevant F interval 454 ASij(il) = ASij(il) + abs(Qmixmax(il)*(1.-Sjmax(il)) + Rmixmax(il) - & 455 Qmixmin(il)*(1.-Sjmin(il)) - Rmixmin(il)) 456 457 ! If I=J (detrainement and entrainement at the same level), then only the 458 ! adiabatic ascent part of the mixture is considered 459 IF (i == j) THEN 425 460 rti = qta(il, i - 1) - ep(il, i)*clw(il, i) 426 Qmixmax(il) = Qmix(Sjmax(il)) 427 Qmixmin(il) = Qmix(Sjmin(il)) 428 Rmixmax(il) = Rmix(Sjmax(il)) 429 Rmixmin(il) = Rmix(Sjmin(il)) 430 sqmrmax(il) = Sjmax(il)*Qmix(Sjmax(il)) - Rmix(Sjmax(il)) 431 sqmrmin(il) = Sjmin(il)*Qmix(Sjmin(il)) - Rmix(Sjmin(il)) 432 433 Ment(il, i, j) = abs(Qmixmax(il) - Qmixmin(il))*Ment(il, i, j) 434 IF (abs(Qmixmax(il) - Qmixmin(il)) > 1.E-10) THEN 435 Sigij(il, i, j) = (sqmrmax(il) - sqmrmin(il))/(Qmixmax(il) - Qmixmin(il)) 436 ELSE 437 Sigij(il, i, j) = 0. 438 END IF 439 440 ! -- Compute Qent, uent, vent according to the true mixing fraction 441 Qent(il, i, j) = (1.-Sigij(il, i, j))*rti + Sigij(il, i, j)*rr(il, i) 442 uent(il, i, j) = (1.-Sigij(il, i, j))*unk(il) + Sigij(il, i, j)*u(il, i) 443 vent(il, i, j) = (1.-Sigij(il, i, j))*vnk(il) + Sigij(il, i, j)*v(il, i) 444 445 ! -- Compute liquid water static energy of mixed draughts 446 hent(il, i, j) = (1.-Sigij(il, i, j))*hp(il, i) + Sigij(il, i, j)*h(il, i) 447 ! Heat capacity of mixed draught 448 cpm = cpd + Qent(il, i, j)*(cpv - cpd) 449 IF (cvflag_ice .and. frac(il, j) .gt. 0.) THEN 450 elij(il, i, j) = Qent(il, i, j) - rs(il, j) 451 elij(il, i, j) = elij(il, i, j) + & 452 (h(il, j) - hent(il, i, j) + (cpv - cpd)*(Qent(il, i, j) - rr(il, j))*t(il, j))* & 453 rs(il, j)*lv(il, j)/(cpm*rrv*t(il, j)*t(il, j)) 454 elij(il, i, j) = elij(il, i, j)/ & 455 (1.+(lv(il, j) + frac(il, j)*lf(il, j))*lv(il, j)*rs(il, j)/ & 456 (cpm*rrv*t(il, j)*t(il, j))) 457 ELSE 458 elij(il, i, j) = Qent(il, i, j) - rs(il, j) 459 elij(il, i, j) = elij(il, i, j) + & 460 (h(il, j) - hent(il, i, j) + (cpv - cpd)*(Qent(il, i, j) - rr(il, j))*t(il, j))* & 461 rs(il, j)*lv(il, j)/(cpm*rrv*t(il, j)*t(il, j)) 462 elij(il, i, j) = elij(il, i, j)/ & 463 (1.+lv(il, j)*lv(il, j)*rs(il, j)/ & 464 (cpm*rrv*t(il, j)*t(il, j))) 465 ENDIF 466 elij(il, i, j) = max(elij(il, i, j), 0.) 467 468 elij(il, i, j) = min(elij(il, i, j), Qent(il, i, j)) 469 470 IF (j > i) THEN 471 awat = elij(il, i, j) - (1.-ep(il, j))*clw(il, j) 472 awat = amax1(awat, 0.0) 473 ELSE 474 awat = 0. 475 END IF 476 477 ! Mixed draught temperature at level j 478 IF (cvflag_ice .and. frac(il, j) .gt. 0.) THEN 479 Tm = t(il, j) + (Qent(il, i, j) - elij(il, i, j) - rs(il, j))*rrv*t(il, j)*t(il, j)/(lv(il, j)*rs(il, j)) 480 hent(il, i, j) = hent(il, i, j) + (lv(il, j) + frac(il, j)*lf(il, j) + (cpd - cpv)*Tm)*awat 481 ELSE 482 Tm = t(il, j) + (Qent(il, i, j) - elij(il, i, j) - rs(il, j))*rrv*t(il, j)*t(il, j)/(lv(il, j)*rs(il, j)) 483 hent(il, i, j) = hent(il, i, j) + (lv(il, j) + (cpd - cpv)*Tm)*awat 484 ENDIF 485 486 ! -- ASij is the integral of P(F) over the relevant F interval 487 ASij(il) = ASij(il) + abs(Qmixmax(il)*(1.-Sjmax(il)) + Rmixmax(il) - & 488 Qmixmin(il)*(1.-Sjmin(il)) - Rmixmin(il)) 489 461 Ment(il, i, i) = abs(Qmixmax(il)*(1.-Sjmax(il)) + Rmixmax(il) - & 462 Qmixmin(il)*(1.-Sjmin(il)) - Rmixmin(il)) 463 Qent(il, i, i) = rti 464 uent(il, i, i) = unk(il) 465 vent(il, i, i) = vnk(il) 466 hent(il, i, i) = hp(il, i) 467 elij(il, i, i) = clw(il, i)*(1.-ep(il, i)) 468 Sigij(il, i, i) = 0. 490 469 END IF 491 470 END IF 492 END DO 493 494 ! -- If I=J (detrainement and entrainement at the same level), then only the 495 ! -- adiabatic ascent part of the mixture is considered 496 IF (i == j) THEN 497 DO il = 1, ncum 498 IF (i >= icb(il) .AND. i <= inb(il) .AND. & 499 j >= (icb(il) - 1) .AND. j <= inb(il) .AND. & 500 lwork(il)) THEN 501 IF (Sij(il, i, j) > 0.0) THEN 502 rti = qta(il, i - 1) - ep(il, i)*clw(il, i) 503 Ment(il, i, i) = abs(Qmixmax(il)*(1.-Sjmax(il)) + Rmixmax(il) - & 504 Qmixmin(il)*(1.-Sjmin(il)) - Rmixmin(il)) 505 Qent(il, i, i) = rti 506 uent(il, i, i) = unk(il) 507 vent(il, i, i) = vnk(il) 508 hent(il, i, i) = hp(il, i) 509 elij(il, i, i) = clw(il, i)*(1.-ep(il, i)) 510 Sigij(il, i, i) = 0. 511 END IF 512 END IF 513 END DO 514 END IF 515 516 ! --------------------------------------------------------------- 517 175 END DO ! End loop on destination level "j" 518 ! --------------------------------------------------------------- 519 471 END DO ! End loop on destination level "j" 472 ! --------------------------------------------------------------- 473 END DO 474 520 475 DO il = 1, ncum 521 476 IF (i >= icb(il) .AND. i <= inb(il) .AND. lwork(il)) THEN 522 477 ASij(il) = amax1(1.0E-16, ASij(il)) 523 478 ASij_inv(il) = 1.0/ASij(il) 524 ! IF the F-interval spanned by possible mixtures is less than 0.01, no mixing occurs479 ! IF the F-interval spanned by possible mixtures is less than 0.01, no mixing occurs 525 480 IF (ASij_inv(il) > 100.) ASij_inv(il) = 0. 526 481 csum(il, i) = 0.0 527 482 END IF 528 483 END DO 529 484 530 485 DO j = minorig, nl 531 486 DO il = 1, ncum … … 536 491 END DO 537 492 END DO 538 493 539 494 DO j = minorig, nl 540 495 DO il = 1, ncum … … 545 500 END DO 546 501 END DO 547 502 548 503 DO il = 1, ncum 549 504 IF (i >= icb(il) .AND. i <= inb(il) .AND. lwork(il) .AND. csum(il, i) < 1.) THEN … … 562 517 END IF 563 518 END DO ! il 564 565 ! ---------------------------------------------------------------566 789END DO ! End loop on origin level "i"567 ! ---------------------------------------------------------------519 520 ! --------------------------------------------------------------- 521 END DO ! End loop on origin level "i" 522 ! --------------------------------------------------------------- 568 523 RETURN 569 524 END SUBROUTINE
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