Changeset 2844 for trunk/LMDZ.MARS/libf/dynphy_lonlat
- Timestamp:
- Dec 18, 2022, 11:44:43 PM (2 years ago)
- File:
-
- 1 edited
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trunk/LMDZ.MARS/libf/dynphy_lonlat/phymars/xvik.F
r2824 r2844 10 10 c======================================================================= 11 11 c 12 c Press ion au site Viking12 c Pressure at Insight and Viking sites 13 13 c 14 14 c======================================================================= … … 43 43 c declarations pour les points viking: 44 44 c ------------------------------------ 45 INTEGER i vik(2),jvik(2),ifile(2),iv45 INTEGER isite(3),jsite(3),ifile(3),iv 46 46 47 47 REAL, PARAMETER :: lonvik1 = -47.95 … … 49 49 REAL, PARAMETER :: lonvik2 = 134.29 50 50 REAL, PARAMETER :: latvik2 = 47.67 51 51 REAL, PARAMETER :: loninst = 135.62 52 REAL, PARAMETER :: latinst = 4.502 53 52 54 REAL, PARAMETER :: phivik1 = -3637 53 55 REAL, PARAMETER :: phivik2 = -4505 54 55 56 REAL lonvik(2),latvik(2),phivik(2),phisim(2) 56 REAL, PARAMETER :: phiinst = -2614 57 58 59 REAL lonsite(3),latsite(3),phisite(3),phisim(3) 57 60 REAL unanj 58 61 … … 64 67 real t7(iip1,jjp1) ! temperature in 7th atmospheric layer 65 68 66 REAL zp1,zp2,zp2_sm,zu,zv,zw(0:1,0:1, 2),zalpha,zbeta69 REAL zp1,zp2,zp2_sm,zu,zv,zw(0:1,0:1,3),zalpha,zbeta 67 70 68 71 LOGICAL firstcal … … 85 88 86 89 INTEGER Time_unit 90 91 REAL ls2sol 87 92 88 93 … … 95 100 EXTERNAL SSUM 96 101 REAL SSUM 97 98 102 103 c diurnam: 104 c -------- 105 integer di,di_prev 106 integer k 107 real ps_gcm_diurnal, ps_diurnal 108 integer compt_diurn 109 110 c harmonics: 111 c -------- 112 113 integer, parameter :: nbmax = 999999 114 integer ndata 115 real ls_harm 116 real ls_tab(nbmax) 117 real ps_diurnal_tab(nbmax),ps_gcm_diurnal_tab(nbmax) 118 real a_tab(nbmax),b_tab(nbmax) 119 real a_tab_gcm(nbmax),b_tab_gcm(nbmax) 120 real a,b 121 real ps_harm, ps_gcm_harm 122 integer, parameter :: n_harmo = 6 123 124 99 125 cccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc 100 126 … … 112 138 113 139 c----------------------------------------------------------------------- 114 c Viking Lander coordinates:140 c Viking Lander and Insight coordinates: 115 141 c -------------------------------------------------------------------- 116 142 117 lonvik(1) = lonvik1 118 latvik(1) = latvik1 119 lonvik(2) = lonvik2 120 latvik(2) = latvik2 121 122 phivik(1) = phivik1 123 phivik(2) = phivik2 124 125 WRITE(*,*) 'Viking coordinates:' 126 WRITE(*,*) 'latvik:',latvik,' lonvik:',lonvik 127 WRITE(*,*) 'Phivik:', phivik 128 143 lonsite(1) = lonvik1 144 latsite(1) = latvik1 145 lonsite(2) = lonvik2 146 latsite(2) = latvik2 147 lonsite(3) = loninst 148 latsite(3) = latinst 149 150 phisite(1) = phivik1 151 phisite(2) = phivik2 152 phisite(3) = phiinst 153 154 WRITE(*,*) 'Viking1 coordinates:' 155 WRITE(*,*) 'latvik1:',latvik1,' lonvik1:',lonvik1 156 WRITE(*,*) 'Phivik1:', phivik1 157 158 WRITE(*,*) 'Viking2 coordinates:' 159 WRITE(*,*) 'latvik2:',latvik2,' lonvik2:',lonvik2 160 WRITE(*,*) 'Phivik2:', phivik2 161 162 WRITE(*,*) 'Insight coordinates:' 163 WRITE(*,*) 'latinst:',latinst,' loninst:',loninst 164 WRITE(*,*) 'Phiinst:', phiinst 165 129 166 ! convert coordinates to radians 130 lonvik(1) = lonvik1 * pi/180. 131 latvik(1) = latvik1 * pi/180. 132 lonvik(2) = lonvik2 * pi/180. 133 latvik(2) = latvik2 * pi/180. 134 135 167 lonsite(1) = lonvik1 * pi/180. 168 latsite(1) = latvik1 * pi/180. 169 lonsite(2) = lonvik2 * pi/180. 170 latsite(2) = latvik2 * pi/180. 171 lonsite(3) = loninst * pi/180. 172 latsite(3) = latinst * pi/180. 173 174 175 136 176 WRITE(*,*) 'Path to the diagfi files directory' 137 177 READ (*,'(a)') pathchmp … … 144 184 145 185 146 write (*,*)'>>>>>>>>>>>>>>>>', phi vik,g147 DO iv=1, 2148 phi vik(iv)=phivik(iv)*3.73186 write (*,*)'>>>>>>>>>>>>>>>>', phisite,g 187 DO iv=1,3 188 phisite(iv)=phisite(iv)*3.73 149 189 END DO 150 190 … … 154 194 ifile(1)=12 155 195 ifile(2)=13 196 ifile(3)=14 197 156 198 kyear=-1 157 199 unitlec=11 … … 171 213 172 214 c---------------------------------------------------------------------- 173 c O uverture des fichiers histoire:215 c Open diagfi files : 174 216 c---------------------------------------------------------------------- 175 217 … … 194 236 195 237 c---------------------------------------------------------------------- 196 c Lecture temps:238 c Read time : 197 239 c---------------------------------------------------------------------- 198 240 … … 221 263 222 264 223 c---------------------------------------------------------------------- 224 c ponderations pour les 4 points autour de Viking 225 c---------------------------------------------------------------------- 226 227 228 DO iv=1,2 265 c------------------------------------------------------ 266 c Weights for 4 near points at Viking and Insight 267 c------------------------------------------------------ 268 269 DO iv=1,3 229 270 ! locate index of GCM grid points near VL 230 271 do i=1,iim 231 272 ! we know longitudes are ordered -180...180 232 if ((lonvik(iv).ge.rlonu(i)).and. 233 & (lonvik(iv).le.rlonu(i+1))) then 234 ivik(iv)=i 273 write(*,*) i, lonsite(iv),rlonu(i),rlonu(i+1) 274 if ((lonsite(iv).ge.rlonu(i)).and. 275 & (lonsite(iv).le.rlonu(i+1))) then 276 isite(iv)=i 235 277 exit 236 278 endif 237 279 enddo 280 238 281 do j=1,jjm-1 239 282 !we know tha latitudes are ordered 90...-90 240 if ((lat vik(iv).le.rlatv(j)).and.241 & (lat vik(iv).ge.rlatv(j+1))) then242 j vik(iv)=j283 if ((latsite(iv).le.rlatv(j)).and. 284 & (latsite(iv).ge.rlatv(j+1))) then 285 jsite(iv)=j 243 286 exit 244 287 endif 245 288 enddo 246 zalpha=(lon vik(iv)-rlonu(ivik(iv)))/247 s (rlonu(i vik(iv)+1)-rlonu(ivik(iv)))248 zbeta=(lat vik(iv)-rlatv(jvik(iv)))/249 s (rlatv(j vik(iv)+1)-rlatv(jvik(iv)))289 zalpha=(lonsite(iv)-rlonu(isite(iv)))/ 290 s (rlonu(isite(iv)+1)-rlonu(isite(iv))) 291 zbeta=(latsite(iv)-rlatv(jsite(iv)))/ 292 s (rlatv(jsite(iv)+1)-rlatv(jsite(iv))) 250 293 zw(0,0,iv)=(1.-zalpha)*(1.-zbeta) 251 294 zw(1,0,iv)=zalpha*(1.-zbeta) … … 255 298 256 299 c---------------------------------------------------------------------- 257 c true and model altitude at Viking locations258 c---------------------------------------------------------------------- 259 260 261 DO iv=1, 2300 c true and model altitude at Viking and Insight locations 301 c---------------------------------------------------------------------- 302 303 304 DO iv=1,3 262 305 phisim(iv)=0. 263 306 DO jj=0,1 264 j=j vik(iv)+jj307 j=jsite(iv)+jj 265 308 DO ii=0,1 266 i=i vik(iv)+ii309 i=isite(iv)+ii 267 310 phisim(iv)=phisim(iv)+zw(ii,jj,iv)*phis(i,j) 268 311 ENDDO 269 312 ENDDO 270 313 ENDDO 271 PRINT*,'phi vik at Viking locations for outputs:',phivik314 PRINT*,'phisite at Viking locations for outputs:',phisite 272 315 273 316 … … 279 322 280 323 c====================================================================== 281 c debut de la boucle sur les etats dans un fichier histoire:324 c Begin the loop on states in inputs files : 282 325 c====================================================================== 283 326 … … 391 434 IF(iyear.GE.9) WRITE(chr2,'(i2)') iyear+1 392 435 kyear=iyear 393 DO ii=1, 2436 DO ii=1,3 394 437 CLOSE(10+ifile(ii)) 438 CLOSE(20+ifile(ii)) 395 439 CLOSE(2+ifile(ii)) 396 440 CLOSE(4+ifile(ii)) … … 404 448 ENDDO 405 449 CLOSE(5+ifile(1)) 406 OPEN(ifile(1)+10,file='xpsol1'//chr2,form='formatted') 407 OPEN(ifile(2)+10,file='xpsol2'//chr2,form='formatted') 408 OPEN(97,file='xprestot'//chr2,form='formatted') 450 OPEN(ifile(1)+10,file='ps_VL1_year'//chr2,form='formatted') 451 OPEN(ifile(2)+10,file='ps_VL2_year'//chr2,form='formatted') 452 OPEN(ifile(3)+10,file='ps_INS_year'//chr2,form='formatted') 453 OPEN(97,file='prestot_year'//chr2,form='formatted') 454 455 456 c Sol or ls or both 457 c Planetary mean surface pressure (Pa) 458 c Equivalent pressure of CO2 ice at North Polar cap (Pa) 459 c Equivalent pressure of CO2 ice at South Polar cap (Pa) 460 c Total amount of CO2 on the planet (Pa) 461 462 IF (Time_unit == 1) THEN 463 464 WRITE(ifile(1)+10,'(a)') '# Sol , Surface Pressure at VL1 at 465 & true (interpolated) altitude (Pa) , 466 & Surface Pressure at VL1 at GCM altitude (Pa)' 467 468 WRITE(ifile(2)+10,'(a)') '# Sol , Surface Pressure at VL2 at 469 & true (interpolated) altitude (Pa) , 470 & Surface Pressure at VL2 at GCM altitude (Pa)' 471 472 WRITE(ifile(3)+10,'(a)') '# Sol , Surface Pressure at Insight at 473 & true (interpolated) altitude (Pa) , 474 & Surface Pressure at Insight at GCM altitude (Pa)' 475 476 WRITE(97,'(a)') '# Sol , Planetary Mean Surface Pressure (Pa) , 477 & Equivalent pressure of CO2 ice at North Polar cap (Pa) , 478 & Equivalent pressure of CO2 ice at South Polar cap (Pa) , 479 & Total amount of CO2 on the planet (Pa)' 480 481 ELSEIF (Time_unit == 2) THEN 482 483 WRITE(ifile(1)+10,'(a)') '# Ls (deg) , Surface Pressure at VL1 at 484 & true (interpolated) altitude (Pa) , 485 & Surface Pressure at VL1 at GCM altitude (Pa)' 486 487 WRITE(ifile(2)+10,'(a)') '# Ls (deg) , Surface Pressure at VL2 at 488 & true (interpolated) altitude (Pa) , 489 & Surface Pressure at VL2 at GCM altitude (Pa)' 490 491 WRITE(ifile(3)+10,'(a)') '# Ls (deg) , Surface Pressure at Insight at 492 & true (interpolated) altitude (Pa) , 493 & Surface Pressure at Insight at GCM altitude (Pa)' 494 495 WRITE(97,'(a)') '# Ls (deg) , Planetary Mean Surface Pressure (Pa) , 496 & Equivalent pressure of CO2 ice at North Polar cap (Pa) , 497 & Equivalent pressure of CO2 ice at South Polar cap (Pa) , 498 & Total amount of CO2 on the planet (Pa)' 499 500 ELSE 501 502 WRITE(ifile(1)+10,'(a)') '# Sol , Ls (deg) , Surface Pressure at VL1 at 503 & true (interpolated) altitude (Pa) , 504 & Surface Pressure at VL1 at GCM altitude (Pa)' 505 506 WRITE(ifile(2)+10,'(a)') '# Sol , Ls (deg) , Surface Pressure at VL2 at 507 & true (interpolated) altitude (Pa) , 508 & Surface Pressure at VL2 at GCM altitude (Pa)' 509 510 WRITE(ifile(3)+10,'(a)') '# Sol , Ls (deg) , Surface Pressure at Insight at 511 & true (interpolated) altitude (Pa) , 512 & Surface Pressure at Insight at GCM altitude (Pa)' 513 514 WRITE(97,'(a)') '# Sol , Ls (deg) , Planetary Mean Surface Pressure (Pa) , 515 & Equivalent pressure of CO2 ice at North Polar cap (Pa) , 516 & Equivalent pressure of CO2 ice at South Polar cap (Pa) , 517 & Total amount of CO2 on the planet (Pa)' 518 519 ENDIF 520 409 521 410 522 ENDIF … … 442 554 443 555 444 c --------------Write output file xprestot----------------------- 445 c Sol ou ls ou les deux 446 c Ps_moy_planetaire (Pa) 447 c Pequivalente de glace de CO2 au Nord (si entierement sublimee) (Pa) 448 c Pequivalente de glace de CO2 au Sud (si entierement sublimee) (Pa) 556 c --------------Write output file prestot----------------------- 557 c Sol or ls or both 558 c Planetary mean surface pressure (Pa) 559 c Equivalent pressure of CO2 ice at North Polar cap (Pa) 560 c Equivalent pressure of CO2 ice at South Polar cap (Pa) 561 c Total amount of CO2 on the planet (Pa) 449 562 450 563 451 564 IF(Time_unit == 1) THEN 452 WRITE(97,'(4e16.6)') dayw,pstot*airtot1 453 & , captotN*g*airtot1, captotS*g*airtot1 565 WRITE(97,'(5e16.6)') dayw,pstot*airtot1 566 & , captotN*g*airtot1, captotS*g*airtot1, 567 & pstot*airtot1+captotN*g*airtot1+captotS*g*airtot1 454 568 455 569 ELSEIF (Time_unit == 2) THEN 456 WRITE(97,'(4e16.6)') dayw_ls,pstot*airtot1 457 & , captotN*g*airtot1, captotS*g*airtot1 570 WRITE(97,'(5e16.6)') dayw_ls,pstot*airtot1 571 & , captotN*g*airtot1, captotS*g*airtot1, 572 & pstot*airtot1+captotN*g*airtot1+captotS*g*airtot1 458 573 459 574 ELSE 460 WRITE(97,'(5e16.6)') dayw,dayw_ls,pstot*airtot1 461 & , captotN*g*airtot1,captotS*g*airtot1 575 WRITE(97,'(6e16.6)') dayw,dayw_ls,pstot*airtot1 576 & , captotN*g*airtot1,captotS*g*airtot1, 577 & pstot*airtot1+captotN*g*airtot1+captotS*g*airtot1 462 578 463 579 … … 465 581 466 582 c---------------------------------------------------------------------- 467 c Loop on Vikingsites:583 c Loop on sites: 468 584 c---------------------------------------------------------------------- 469 585 … … 474 590 IF(.NOT.firstcal) THEN 475 591 476 DO iv=1, 2592 DO iv=1,3 477 593 478 594 zp1=0. … … 483 599 DO jj=0,1 484 600 485 j=j vik(iv)+jj601 j=jsite(iv)+jj 486 602 487 603 DO ii=0,1 488 604 489 i=i vik(iv)+ii605 i=isite(iv)+ii 490 606 zt=zt+zw(ii,jj,iv)*t7(i,j) 491 607 zp1=zp1+zw(ii,jj,iv)*log(ps(i,j)) ! interpolate in log(P) … … 506 622 if (gh.eq.0) then ! if we don't have temperature values 507 623 ! assume a scale height of 10km 508 zp2=zp1*exp(-(phi vik(iv)-phisim(iv))/(3.73*1.e4))624 zp2=zp1*exp(-(phisite(iv)-phisim(iv))/(3.73*1.e4)) 509 625 else 510 zp2=zp1*exp(-(phi vik(iv)-phisim(iv))/gh)626 zp2=zp1*exp(-(phisite(iv)-phisim(iv))/gh) 511 627 endif 512 628 513 WRITE (*,*) 'iv,pstot,zp2, zp1, phi vik(iv),phisim(iv),gh'514 WRITE (*,*) iv,pstot*airtot1,zp2,zp1,phi vik(iv),phisim(iv),gh629 WRITE (*,*) 'iv,pstot,zp2, zp1, phisite(iv),phisim(iv),gh' 630 WRITE (*,*) iv,pstot*airtot1,zp2,zp1,phisite(iv),phisim(iv),gh 515 631 WRITE(*,*) "------" 516 632 517 633 518 c ------Write 2 files (1 for Vl1, 1 for VL2) xpsol------634 c ------Write 3 files (for Vl1, VL2, Insight) -------- 519 635 c Sol or ls or both 520 c Ps site VLi (i=1,2) at GCM altitude (Pa)521 c Ps site VLi (i=1,2) at true (interpolated) altitude (Pa)636 c Ps site VLi (i=1,2) or Inisght at true (interpolated) altitude (Pa) (zp2) 637 c Ps site VLi (i=1,2) or Insight at GCM altitude (Pa) (zp1) 522 638 523 639 IF(Time_unit == 1) THEN … … 527 643 ELSE 528 644 WRITE(ifile(iv)+10,'(4e15.5)') dayw,dayw_ls,zp2,zp1 529 ENDIF 530 645 ENDIF 646 647 531 648 ENDDO 532 649 533 650 ENDIF 651 534 652 535 653 firstcal=.false. … … 556 674 557 675 676 558 677 c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 559 678 c End of loop on the diagfi files … … 562 681 ENDDO 563 682 564 PRINT*,'altitude of VL1',.001*phis(ivik(1),jvik(1))/g 565 PRINT*,'altitude of VL2',.001*phis(ivik(2),jvik(2))/g 566 DO iv=1,2 567 PRINT*,'Viking',iv,' i=',ivik(iv),'j =',jvik(iv) 683 PRINT*,'altitude of VL1',.001*phis(isite(1),jsite(1))/g 684 PRINT*,'altitude of VL2',.001*phis(isite(2),jsite(2))/g 685 PRINT*,'altitude of Ins',.001*phis(isite(3),jsite(3))/g 686 687 DO iv=1,3 688 PRINT*,'Site',iv,' i=',isite(iv),'j =',jsite(iv) 568 689 WRITE(6,7777) 569 s (rlonv(i)*180./pi,i=i vik(iv)-1,ivik(iv)+2)690 s (rlonv(i)*180./pi,i=isite(iv)-1,isite(iv)+2) 570 691 print* 571 DO j=j vik(iv)-1,jvik(iv)+2692 DO j=jsite(iv)-1,jsite(iv)+2 572 693 WRITE(6,'(f8.1,10x,5f7.1)') 573 s rlatu(j)*180./pi,(phis(i,j)/(g*1000.),i=ivik(iv)-1,ivik(iv)+2) 694 s rlatu(j)*180./pi,(phis(i,j)/(g*1000.),i=isite(iv)-1, 695 & isite(iv)+2) 574 696 ENDDO 575 697 print* … … 583 705 7777 FORMAT ('latitude/longitude',4f7.1) 584 706 585 586 707 c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 708 c Diurnal Average 709 c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 710 711 write(*,*) 'ici' 712 DO i=1,kyear+1 713 WRITE(chr2(1:1),'(i1)') i 714 IF(i.GE.9) WRITE(chr2,'(i2)') i 715 DO iv=1,3 716 if (iv==1) then 717 718 open(ifile(iv), file = 'ps_VL1_year'//trim(trim(chr2))) 719 open(ifile(iv)+20, file = 'ps_VL1_year'//trim(chr2)//'_diurnal') 720 IF(Time_unit == 1) THEN 721 write(ifile(iv)+20,'(a)') '# Sol , PS at VL1 at true 722 & (interpolated) altitude (diurnal mean) , PS at VL1 at 723 & GCM altitude (diurnal mean)' 724 ELSEIF (Time_unit == 2) THEN 725 write(ifile(iv)+20,'(a)') '# Ls (deg) , PS at VL1 at 726 & true (interpolated) altitude (diurnal mean) , PS at VL1 727 & at GCM altitude (diurnal mean)' 728 ELSE 729 write(ifile(iv)+20,'(a)') '# Sol , Ls (deg) , PS at VL1 730 & at true (interpolated) altitude (diurnal mean) , PS at VL1 731 & at GCM altitude (diurnal mean)' 732 ENDIF 733 734 elseif (iv==2) then 735 736 open(ifile(iv), file = 'ps_VL2_year'//trim(chr2)) 737 open(ifile(iv)+20, file = 'ps_VL2_year'//trim(chr2)//'_diurnal') 738 IF(Time_unit == 1) THEN 739 write(ifile(iv)+20,'(a)') '# Sol , PS at VL2 at true 740 & (interpolated) altitude (diurnal mean) , PS at VL1 at 741 & GCM altitude (diurnal mean)' 742 ELSEIF (Time_unit == 2) THEN 743 write(ifile(iv)+20,'(a)') '# Ls (deg) , PS at VL2 744 & at true (interpolated) altitude (diurnal mean) , PS at VL1 745 & at GCM altitude (diurnal mean)' 746 ELSE 747 write(ifile(iv)+20,'(a)') '# Sol , Ls (deg) , PS at VL2 748 & at true (interpolated) altitude (diurnal mean) , PS at VL1 749 & at GCM altitude (diurnal mean)' 750 ENDIF 751 752 else 753 open(ifile(iv), file = 'ps_INS_year'//trim(chr2)) 754 open(ifile(iv)+20, file = 'ps_INS_year'//trim(chr2)//'_diurnal') 755 IF(Time_unit == 1) THEN 756 write(ifile(iv)+20,'(a)') '# Sol , PS at Insight at true 757 & (interpolated) altitude (diurnal mean) , PS at VL1 758 & at GCM altitude (diurnal mean)' 759 ELSEIF (Time_unit == 2) THEN 760 write(ifile(iv)+20,'(a)') '# Ls (deg) , PS at Insight at true 761 & (interpolated) altitude (diurnal mean) , PS at VL1 762 & at GCM altitude (diurnal mean)' 763 ELSE 764 write(ifile(iv)+20,'(a)') '# Sol , Ls (deg) , PS at Insight 765 & at true (interpolated) altitude (diurnal mean) , PS at VL1 766 & at GCM altitude (diurnal mean)' 767 ENDIF 768 endif 769 770 READ(ifile(iv),*) 771 IF(Time_unit == 1) THEN 772 READ(ifile(iv),*) dayw,zp2,zp1 773 ELSEIF (Time_unit == 2) THEN 774 READ(ifile(iv),*) dayw_ls,zp2,zp1 775 dayw = ls2sol(dayw_ls) 776 ELSE 777 READ(ifile(iv),*) dayw,dayw_ls,zp2,zp1 778 ENDIF 779 780 di=floor(dayw) 781 di_prev = floor(dayw) 782 783 DO k=1,nbmax 784 ps_gcm_diurnal = 0. 785 ps_diurnal = 0. 786 compt_diurn = 0 787 788 DO WHILE (di==di_prev) 789 790 ps_gcm_diurnal = ps_gcm_diurnal + zp1 791 ps_diurnal = ps_diurnal + zp2 792 compt_diurn = compt_diurn + 1 793 IF(Time_unit == 1) THEN 794 READ(ifile(iv),*,end=777) dayw,zp2,zp1 795 ELSEIF (Time_unit == 2) THEN 796 READ(ifile(iv),*,end=777) dayw_ls,zp2,zp1 797 dayw=ls2sol(dayw_ls) 798 ELSE 799 READ(ifile(iv),*,end=777) dayw,dayw_ls,zp2,zp1 800 ENDIF 801 di=floor(dayw) 802 803 ENDDO 804 805 ps_gcm_diurnal = ps_gcm_diurnal/compt_diurn 806 ps_diurnal = ps_diurnal/compt_diurn 807 808 IF(Time_unit == 1) THEN 809 810 write(ifile(iv)+20,'(i4,2e15.5)') di_prev, ps_diurnal, 811 & ps_gcm_diurnal 812 813 ELSEIF (Time_unit == 2) THEN 814 815 write(ifile(iv)+20,'(3e15.5)') dayw_ls, ps_diurnal, 816 & ps_gcm_diurnal 817 818 ELSE 819 820 write(ifile(iv)+20,'(i4,3e15.5)') di_prev, dayw_ls, 821 & ps_diurnal, ps_gcm_diurnal 822 823 ENDIF 824 825 826 di_prev = di 827 828 ENDDO 829 close(ifile(iv)+20) 830 close(ifile(iv)) 831 777 ENDDO 832 ENDDO 833 834 835 836 c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 837 c Harmonics 838 c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 839 840 841 DO i=1,kyear+1 842 WRITE(chr2(1:1),'(i1)') i 843 IF(i.GE.9) WRITE(chr2,'(i2)') i 844 DO iv=1,3 845 846 if (iv==1) then 847 open(ifile(iv), file = 'ps_VL1_year'//trim(chr2)//'_diurnal') 848 open(ifile(iv)+20, file = 'ps_VL1_year'//trim(chr2)//'_harmonics') 849 850 IF(Time_unit == 1) THEN 851 write(ifile(iv)+20,'(a)') '# Sol , PS at VL1 at true 852 & (interpolated) altitude (harmonics fit) , PS at VL1 at 853 & GCM altitude (harmonics fit)' 854 ELSEIF (Time_unit == 2) THEN 855 write(ifile(iv)+20,'(a)') '# Ls (deg) , PS at VL1 at 856 & true (interpolated) altitude (harmonics fit) , PS at VL1 857 & at GCM altitude (harmonics fit)' 858 ELSE 859 write(ifile(iv)+20,'(a)') '# Sol , Ls (deg) , PS at VL1 860 & at true (interpolated) altitude (harmonics fit) , PS at VL1 861 & at GCM altitude (harmonics fit)' 862 ENDIF 863 864 elseif (iv==2) then 865 open(ifile(iv), file = 'ps_VL2_year'//trim(chr2)//'_diurnal') 866 open(ifile(iv)+20, file = 'ps_VL2_year'//trim(chr2)//'_harmonics') 867 868 IF(Time_unit == 1) THEN 869 write(ifile(iv)+20,'(a)') '# Sol , PS at VL2 at true 870 & (interpolated) altitude (harmonics fit) , PS at VL2 at 871 & GCM altitude (harmonics fit)' 872 ELSEIF (Time_unit == 2) THEN 873 write(ifile(iv)+20,'(a)') '# Ls (deg) , PS at VL2 at 874 & true (interpolated) altitude (harmonics fit) , PS at VL2 875 & at GCM altitude (harmonics fit)' 876 ELSE 877 write(ifile(iv)+20,'(a)') '# Sol , Ls (deg) , PS at VL2 878 & at true (interpolated) altitude (harmonics fit) , PS at VL2 879 & at GCM altitude (harmonics fit)' 880 ENDIF 881 882 else 883 open(ifile(iv), file = 'ps_INS_year'//trim(chr2)//'_diurnal') 884 open(ifile(iv)+20, file = 'ps_INS_year'//trim(chr2)//'_harmonics') 885 886 IF(Time_unit == 1) THEN 887 write(ifile(iv)+20,'(a)') '# Sol , PS at Insight at true 888 & (interpolated) altitude (harmonics fit) , PS at Insight at 889 & GCM altitude (harmonics fit)' 890 ELSEIF (Time_unit == 2) THEN 891 write(ifile(iv)+20,'(a)') '# Ls (deg) , PS at Insight at 892 & true (interpolated) altitude (harmonics fit) , PS at Insight 893 & at GCM altitude (harmonics fit)' 894 ELSE 895 write(ifile(iv)+20,'(a)') '# Sol , Ls (deg) , PS at Insight 896 & at true (interpolated) altitude (harmonics fit) , PS at Insight 897 & at GCM altitude (harmonics fit)' 898 ENDIF 899 900 endif 901 902 READ(ifile(iv),*) 903 904 DO k = 1,nbmax 905 IF (Time_unit == 1) THEN 906 READ(ifile(iv),*,end=99) di_prev, ps_diurnal_tab(k), 907 & ps_gcm_diurnal_tab(k) 908 call sol2ls(real(di_prev),ls_tab(k)) 909 ELSEIF (Time_unit == 2) THEN 910 READ(ifile(iv),*,end=99) ls_tab(k), ps_diurnal_tab(k), 911 & ps_gcm_diurnal_tab(k) 912 ELSE 913 READ(ifile(iv),*,end=99) di_prev, ls_tab(k), 914 & ps_diurnal_tab(k), ps_gcm_diurnal_tab(k) 915 ENDIF 916 917 ENDDO 918 919 920 99 ndata=k-1 921 922 if(ls_tab(ndata).gt.350.) then 923 924 do k = 0,n_harmo 925 926 call DiscreetFourierHn(ndata,ls_tab,ps_diurnal_tab,k,a,b) 927 if(modulo(k,2)==0) then 928 a_tab(k+1)= a 929 b_tab(k+1)= b 930 else 931 a_tab(k+1)= -a 932 b_tab(k+1)= -b 933 endif 934 935 call DiscreetFourierHn(ndata,ls_tab,ps_gcm_diurnal_tab,k,a,b) 936 if(modulo(k,2)==0) then 937 a_tab_gcm(k+1)= a 938 b_tab_gcm(k+1)= b 939 else 940 a_tab_gcm(k+1)= -a 941 b_tab_gcm(k+1)= -b 942 endif 943 944 enddo 945 946 write(ifile(iv)+20,'(a)') 'Fourrier coefficients ak/bk 947 &(interpolated altitude)' 948 write(ifile(iv)+20,'(a,7f)') '#',(a_tab(k),k=1,n_harmo+1) 949 write(ifile(iv)+20,'(a,7f)') '#',(b_tab(k),k=1,n_harmo+1) 950 write(ifile(iv)+20,'(a)') 'Fourrier coefficients ak/bk 951 &(GCM altitude)' 952 write(ifile(iv)+20,'(a,7f)') '#',(a_tab_gcm(k),k=1,n_harmo+1) 953 write(ifile(iv)+20,'(a,7f)') '#',(b_tab_gcm(k),k=1,n_harmo+1) 954 955 956 do l = 1,669 957 958 call sol2ls(real(l),ls_harm) 959 ps_harm = a_tab(1) 960 ps_gcm_harm = a_tab_gcm(1) 961 962 do k = 1,n_harmo 963 964 ps_harm = ps_harm + a_tab(k+1)* 965 &cos((pi/180.)*k*(ls_harm)) 966 &+ b_tab(k+1)*sin((pi/180.)*k*(ls_harm)) 967 968 ps_gcm_harm = ps_gcm_harm + a_tab_gcm(k+1)* 969 &cos((pi/180.)*k*(ls_harm)) 970 &+ b_tab_gcm(k+1)*sin((pi/180.)*k*(ls_harm)) 971 972 enddo 973 974 975 IF(Time_unit == 1) THEN 976 977 write(ifile(iv)+20,'(i4,2e15.5)') l, ps_harm, 978 & ps_gcm_harm 979 980 ELSEIF (Time_unit == 2) THEN 981 982 write(ifile(iv)+20,'(3e15.5)') ls_harm, ps_harm, 983 & ps_gcm_harm 984 985 ELSE 986 987 write(ifile(iv)+20,'(i4,3e15.5)') l,ls_harm, ps_harm, 988 & ps_gcm_harm 989 990 ENDIF 991 992 enddo 993 close(ifile(iv)) 994 close(ifile(iv)+20) 995 996 else 997 write(ifile(iv)+20,'(a)') 'not computed because 998 & year is not complete' 999 endif ! (ls.gt.350) 1000 1001 ENDDO 1002 ENDDO 1003 1004 1005 587 1006 END 588 1007 … … 679 1098 680 1099 end subroutine sol2ls 1100 1101 1102 !cccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc 1103 real function ls2sol(ls) 1104 1105 ! Returns solar longitude, Ls (in deg.), from day number (in sol), 1106 ! where sol=0=Ls=0 at the northern hemisphere spring equinox 1107 1108 implicit none 1109 1110 ! Arguments: 1111 real, intent(in) :: ls 1112 1113 ! Local: 1114 double precision xref,zx0,zteta,zz 1115 ! xref: mean anomaly, zteta: true anomaly, zx0: eccentric anomaly 1116 double precision year_day 1117 double precision peri_day,timeperi,e_elips 1118 double precision pi,degrad 1119 parameter (year_day=668.6d0) ! number of sols in a amartian year 1120 ! data peri_day /485.0/ 1121 parameter (peri_day=485.35d0) ! date (in sols) of perihelion 1122 ! timeperi: 2*pi*( 1 - Ls(perihelion)/ 360 ); Ls(perihelion)=250.99 1123 parameter (timeperi=1.90258341759902d0) 1124 parameter (e_elips=0.0934d0) ! eccentricity of orbit 1125 parameter (pi=3.14159265358979d0) 1126 parameter (degrad=57.2957795130823d0) 1127 1128 if (abs(ls).lt.1.0e-5) then 1129 if (ls.ge.0.0) then 1130 ls2sol = 0.0 1131 else 1132 ls2sol = real(year_day) 1133 end if 1134 return 1135 end if 1136 1137 zteta = ls/degrad + timeperi 1138 zx0 = 2.0*datan(dtan(0.5*zteta)/dsqrt((1.+e_elips)/(1.-e_elips))) 1139 xref = zx0-e_elips*dsin(zx0) 1140 zz = xref/(2.*pi) 1141 ls2sol = real(zz*year_day + peri_day) 1142 if (ls2sol.lt.0.0) ls2sol = ls2sol + real(year_day) 1143 if (ls2sol.ge.year_day) ls2sol = ls2sol - real(year_day) 1144 1145 return 1146 end 1147 1148 !ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc 1149 1150 1151 !**************************************************************** 1152 !* Calculate the Fourier harmonic #n of a periodic discreet * 1153 !* function F(x) defined by ndata points. * 1154 !* ------------------------------------------------------------ * 1155 !* Inputs: * 1156 !* ndata: number of points of discreet function. * 1157 !* X : pointer to table storing xi abscissas. * 1158 !* Y : pointer to table storing yi ordinates. * 1159 !* * 1160 !* Outputs: * 1161 !* a : coefficient an of the Fourier series. * 1162 !* b: : coefficient bn of the Fourier series. * 1163 !* ------------------------------------------------------------ * 1164 !* Reference: "Mathematiques en Turbo-Pascal By Marc Ducamp and * 1165 !* Alain Reverchon, 1. Analyse, Editions Eyrolles, * 1166 !* Paris, 1991" [BIBLI 03]. * 1167 !* * 1168 !* F90 Version By J-P Moreau, Paris. * 1169 !* (www.jpmoreau.fr) * 1170 !**************************************************************** 1171 ! Note: The Fourier series of a periodic discreet function F(x) 1172 ! can be written under the form: 1173 ! n=inf. 1174 ! F(x) = a0 + Sum ( an cos(2 n pi/T x) + bn sin(2 n pi/T x) 1175 ! n=1 1176 ! ---------------------------------------------------------------- 1177 1178 Subroutine DiscreetFourierHn(ndata, X, Y, n, a, b) 1179 real X(1:ndata), Y(1:ndata), a, b 1180 integer ndata,n,i 1181 real xi,T,om,wa,wb,wc,wd,wg,wh,wi,wl,wm,wn,wp 1182 real PI 1183 PI=4.d0*datan(1.d0) 1184 T=X(ndata)-X(1); xi=(X(ndata)+X(1))/2.d0 1185 om = 2*PI*n/T; a=0.d0; b=0.d0 1186 do i=1, ndata-1 1187 wa=X(i); wb=X(i+1) 1188 wc=Y(i); wd=Y(i+1) 1189 if (wa.ne.wb) then 1190 wg = (wd-wc)/(wb-wa) 1191 wh = om*(wa-xi); wi=om*(wb-xi) 1192 if (n==0) then 1193 a = a + (wb-wa)*(wc+wg/2.d0*(wb-wa)) 1194 else 1195 wl = cos(wh); wm = sin(wh) 1196 wn = cos(wi); wp = sin(wi) 1197 a = a + wg/om*(wn-wl) + wd*wp - wc*wm 1198 b = b + wg/om*(wp-wm) - wd*wn + wc*wl 1199 end if 1200 end if 1201 end do 1202 a = a/T; b = b/T 1203 if (n.ne.0) then 1204 a = a*2.d0/om; b = b*2.d0/om 1205 end if 1206 return 1207 End
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