1 | SUBROUTINE DSOLVER(NL,GAMA,CP,CM,CPM1,CMM1,E1,E2,E3,E4,BTOP, |
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2 | * BSURF,RSF,XK1,XK2) |
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3 | |
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4 | C GCM2.0 Feb 2003 |
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5 | C |
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6 | C DOUBLE PRECISION VERSION OF SOLVER |
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7 | |
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8 | PARAMETER (NMAX=201) |
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9 | IMPLICIT REAL*8 (A-H,O-Z) |
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10 | DIMENSION GAMA(NL),CP(NL),CM(NL),CPM1(NL),CMM1(NL),XK1(NL), |
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11 | * XK2(NL),E1(NL),E2(NL),E3(NL),E4(NL) |
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12 | DIMENSION AF(NMAX),BF(NMAX),CF(NMAX),DF(NMAX),XK(NMAX) |
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13 | C********************************************************* |
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14 | C* THIS SUBROUTINE SOLVES FOR THE COEFFICIENTS OF THE * |
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15 | C* TWO STREAM SOLUTION FOR GENERAL BOUNDARY CONDITIONS * |
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16 | C* NO ASSUMPTION OF THE DEPENDENCE ON OPTICAL DEPTH OF * |
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17 | C* C-PLUS OR C-MINUS HAS BEEN MADE. * |
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18 | C* NL = NUMBER OF LAYERS IN THE MODEL * |
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19 | C* CP = C-PLUS EVALUATED AT TAO=0 (TOP) * |
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20 | C* CM = C-MINUS EVALUATED AT TAO=0 (TOP) * |
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21 | C* CPM1 = C-PLUS EVALUATED AT TAOSTAR (BOTTOM) * |
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22 | C* CMM1 = C-MINUS EVALUATED AT TAOSTAR (BOTTOM) * |
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23 | C* EP = EXP(LAMDA*DTAU) * |
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24 | C* EM = 1/EP * |
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25 | C* E1 = EP + GAMA *EM * |
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26 | C* E2 = EP - GAMA *EM * |
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27 | C* E3 = GAMA*EP + EM * |
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28 | C* E4 = GAMA*EP - EM * |
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29 | C* BTOP = THE DIFFUSE RADIATION INTO THE MODEL AT TOP * |
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30 | C* BSURF = THE DIFFUSE RADIATION INTO THE MODEL AT * |
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31 | C* THE BOTTOM: INCLUDES EMMISION AND REFLECTION * |
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32 | C* OF THE UNATTENUATED PORTION OF THE DIRECT * |
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33 | C* BEAM. BSTAR+RSF*FO*EXP(-TAOSTAR/U0) * |
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34 | C* RSF = REFLECTIVITY OF THE SURFACE * |
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35 | C* XK1 = COEFFICIENT OF THE POSITIVE EXP TERM * |
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36 | C* XK2 = COEFFICIENT OF THE NEGATIVE EXP TERM * |
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37 | C********************************************************* |
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38 | |
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39 | C======================================================================C |
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40 | |
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41 | L=2*NL |
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42 | |
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43 | C ************MIXED COEFFICENTS********** |
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44 | C THIS VERSION AVOIDS SINGULARITIES ASSOC. |
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45 | C WITH W0=0 BY SOLVING FOR XK1+XK2, AND XK1-XK2. |
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46 | |
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47 | AF(1) = 0.0 |
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48 | BF(1) = GAMA(1)+1. |
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49 | CF(1) = GAMA(1)-1. |
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50 | DF(1) = BTOP-CMM1(1) |
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51 | N = 0 |
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52 | LM2 = L-2 |
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53 | |
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54 | C EVEN TERMS |
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55 | |
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56 | DO I=2,LM2,2 |
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57 | N = N+1 |
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58 | AF(I) = (E1(N)+E3(N))*(GAMA(N+1)-1.) |
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59 | BF(I) = (E2(N)+E4(N))*(GAMA(N+1)-1.) |
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60 | CF(I) = 2.0*(1.-GAMA(N+1)**2) |
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61 | DF(I) = (GAMA(N+1)-1.) * (CPM1(N+1) - CP(N)) + |
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62 | * (1.-GAMA(N+1))* (CM(N)-CMM1(N+1)) |
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63 | END DO |
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64 | |
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65 | N = 0 |
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66 | LM1 = L-1 |
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67 | DO I=3,LM1,2 |
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68 | N = N+1 |
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69 | AF(I) = 2.0*(1.-GAMA(N)**2) |
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70 | BF(I) = (E1(N)-E3(N))*(1.+GAMA(N+1)) |
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71 | CF(I) = (E1(N)+E3(N))*(GAMA(N+1)-1.) |
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72 | DF(I) = E3(N)*(CPM1(N+1) - CP(N)) + E1(N)*(CM(N) - CMM1(N+1)) |
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73 | END DO |
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74 | |
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75 | AF(L) = E1(NL)-RSF*E3(NL) |
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76 | BF(L) = E2(NL)-RSF*E4(NL) |
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77 | CF(L) = 0.0 |
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78 | DF(L) = BSURF-CP(NL)+RSF*CM(NL) |
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79 | |
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80 | CALL DTRIDGL(L,AF,BF,CF,DF,XK) |
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81 | |
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82 | C ***UNMIX THE COEFFICIENTS**** |
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83 | |
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84 | DO 28 N=1,NL |
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85 | XK1(N) = XK(2*N-1)+XK(2*N) |
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86 | XK2(N) = XK(2*N-1)-XK(2*N) |
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87 | |
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88 | C NOW TEST TO SEE IF XK2 IS REALLY ZERO TO THE LIMIT OF THE |
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89 | C MACHINE ACCURACY = 1 .E -30 |
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90 | C XK2 IS THE COEFFICEINT OF THE GROWING EXPONENTIAL AND MUST |
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91 | C BE TREATED CAREFULLY |
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92 | |
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93 | IF(XK2(N) .EQ. 0.0) GO TO 28 |
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94 | c IF (ABS (XK2(N)/XK(2*N-1)) .LT. 1.E-30) XK2(N)=0.0 |
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95 | |
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96 | IF (ABS (XK2(N)/(XK(2*N-1)+1.e-20)) .LT. 1.E-30) XK2(N)=0.0 ! For debug only (with -Ktrap=fp option) |
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97 | |
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98 | |
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99 | 28 CONTINUE |
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100 | |
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101 | RETURN |
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102 | END |
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