[2696] | 1 | SUBROUTINE INTEGRATE( NSENSIT, Y, TIN, TOUT ) |
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| 2 | |
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| 3 | INCLUDE 'KPP_ROOT_params.h' |
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| 4 | INCLUDE 'KPP_ROOT_global.h' |
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| 5 | |
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| 6 | C TIN - Start Time |
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| 7 | KPP_REAL TIN |
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| 8 | C TOUT - End Time |
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| 9 | KPP_REAL TOUT |
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| 10 | C Y - Concentrations and Sensitivities |
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| 11 | KPP_REAL Y(NVAR*(NSENSIT+1)) |
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| 12 | C --- Note: Y contains: (1:NVAR) concentrations, followed by |
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| 13 | C --- (1:NVAR) sensitivities w.r.t. first parameter, followed by |
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| 14 | C --- etc., followed by |
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| 15 | C --- (1:NVAR) sensitivities w.r.t. NSENSIT's parameter |
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| 16 | |
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| 17 | INTEGER INFO(5) |
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| 18 | |
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| 19 | EXTERNAL FUNC_CHEM, JAC_CHEM |
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| 20 | |
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| 21 | INFO(1) = Autonomous |
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| 22 | |
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| 23 | CALL ROS3_DDM(NVAR,NSENSIT,TIN,TOUT,STEPMIN,STEPMAX, |
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| 24 | + STEPMIN,Y,ATOL,RTOL, |
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| 25 | + Info,FUNC_CHEM,JAC_CHEM) |
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| 26 | |
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| 27 | RETURN |
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| 28 | END |
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| 29 | |
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| 30 | |
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| 31 | SUBROUTINE ROS3_DDM(N,NSENSIT,T,Tnext,Hmin,Hmax,Hstart, |
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| 32 | + y,AbsTol,RelTol, |
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| 33 | + Info,FUNC_CHEM,JAC_CHEM) |
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| 34 | IMPLICIT NONE |
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| 35 | INCLUDE 'KPP_ROOT_params.h' |
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| 36 | INCLUDE 'KPP_ROOT_global.h' |
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| 37 | INCLUDE 'KPP_ROOT_sparse.h' |
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| 38 | |
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| 39 | C L-stable Rosenbrock 3(2), with |
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| 40 | C strongly A-stable embedded formula for error control. |
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| 41 | C |
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| 42 | C Direct decoupled computation of sensitivities. |
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| 43 | C The global variable DDMTYPE distinguishes between: |
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| 44 | C DDMTYPE = 0 : sensitivities w.r.t. initial values |
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| 45 | C DDMTYPE = 1 : sensitivities w.r.t. parameters |
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| 46 | C |
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| 47 | C All the arguments aggree with the KPP syntax. |
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| 48 | C |
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| 49 | C INPUT ARGUMENTS: |
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| 50 | C y = Vector of: (1:NVAR) concentrations, followed by |
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| 51 | C (1:NVAR) sensitivities w.r.t. first parameter, followed by |
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| 52 | C etc., followed by |
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| 53 | C (1:NVAR) sensitivities w.r.t. NSENSIT's parameter |
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| 54 | C (y contains initial values at input, final values at output) |
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| 55 | C [T, Tnext] = the integration interval |
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| 56 | C Hmin, Hmax = lower and upper bounds for the selected step-size. |
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| 57 | C Note that for Step = Hmin the current computed |
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| 58 | C solution is unconditionally accepted by the error |
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| 59 | C control mechanism. |
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| 60 | C AbsTol, RelTol = (NVAR) dimensional vectors of |
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| 61 | C componentwise absolute and relative tolerances. |
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| 62 | C FUNC_CHEM = name of routine of derivatives. KPP syntax. |
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| 63 | C See the header below. |
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| 64 | C JAC_CHEM = name of routine that computes the Jacobian, in |
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| 65 | C sparse format. KPP syntax. See the header below. |
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| 66 | C Info(1) = 1 for Autonomous system |
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| 67 | C = 0 for nonAutonomous system |
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| 68 | C |
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| 69 | C OUTPUT ARGUMENTS: |
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| 70 | C y = the values of concentrations at TEND. |
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| 71 | C T = equals TEND on output. |
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| 72 | C Info(2) = # of FUNC_CHEM calls. |
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| 73 | C Info(3) = # of JAC_CHEM calls. |
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| 74 | C Info(4) = # of accepted steps. |
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| 75 | C Info(5) = # of rejected steps. |
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| 76 | C |
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| 77 | C Adrian Sandu, April 1996 |
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| 78 | C The Center for Global and Regional Environmental Research |
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| 79 | INTEGER NSENSIT |
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| 80 | KPP_REAL y(NVAR*(NSENSIT+1)), ynew(NVAR*(NSENSIT+1)) |
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| 81 | KPP_REAL K1(NVAR*(NSENSIT+1)) |
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| 82 | KPP_REAL K2(NVAR*(NSENSIT+1)) |
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| 83 | KPP_REAL K3(NVAR*(NSENSIT+1)) |
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| 84 | KPP_REAL DFDT(NVAR*(NSENSIT+1)) |
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| 85 | KPP_REAL DFDP(NVAR*NSENSIT), DFDPDT(NVAR*NSENSIT) |
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| 86 | KPP_REAL DJDP(NVAR*NSENSIT) |
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| 87 | KPP_REAL JAC(LU_NONZERO), AJAC(LU_NONZERO) |
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| 88 | KPP_REAL DJDT(LU_NONZERO) |
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| 89 | KPP_REAL Fv(NVAR), Hv(NVAR) |
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| 90 | KPP_REAL HESS(NHESS) |
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| 91 | KPP_REAL Hmin,Hmax,Hstart,ghinv,uround |
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| 92 | KPP_REAL AbsTol(NVAR), RelTol(NVAR) |
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| 93 | KPP_REAL T, Tnext, Tplus, H, Hnew, elo |
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| 94 | KPP_REAL ERR, factor, facmax |
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| 95 | INTEGER n,nfcn,njac,Naccept,Nreject,i,j,ier |
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| 96 | INTEGER Info(5) |
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| 97 | LOGICAL IsReject,Autonomous |
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| 98 | EXTERNAL FUNC_CHEM, JAC_CHEM, HESS_CHEM |
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| 99 | |
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| 100 | KPP_REAL gamma, c21, c31,c32,b1,b2,b3,d1,d2,d3,a21,a31,a32 |
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| 101 | KPP_REAL alpha2, alpha3, g1, g2, g3, x1, x2, x3, ytol |
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| 102 | KPP_REAL dround, tau |
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| 103 | |
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| 104 | gamma= .43586652150845899941601945119356d+00 |
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| 105 | c21= -.10156171083877702091975600115545d+01 |
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| 106 | c31= .40759956452537699824805835358067d+01 |
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| 107 | c32= .92076794298330791242156818474003d+01 |
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| 108 | b1= .10000000000000000000000000000000d+01 |
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| 109 | b2= .61697947043828245592553615689730d+01 |
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| 110 | b3= -.42772256543218573326238373806514d+00 |
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| 111 | d1= .50000000000000000000000000000000d+00 |
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| 112 | d2= -.29079558716805469821718236208017d+01 |
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| 113 | d3= .22354069897811569627360909276199d+00 |
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| 114 | a21 = 1.d0 |
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| 115 | a31 = 1.d0 |
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| 116 | a32 = 0.d0 |
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| 117 | alpha2 = gamma |
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| 118 | g1= .43586652150845899941601945119356d+00 |
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| 119 | g2= .24291996454816804366592249683314d+00 |
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| 120 | g3= .21851380027664058511513169485832d+01 |
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| 121 | |
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| 122 | |
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| 123 | c Initialization of counters, etc. |
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| 124 | Autonomous = Info(1) .EQ. 1 |
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| 125 | uround = 1.d-15 |
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| 126 | dround = DSQRT(uround) |
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| 127 | IF (Hmax.le.0.D0) THEN |
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| 128 | Hmax = DABS(Tnext-T) |
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| 129 | END IF |
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| 130 | H = DMAX1(1.d-8, Hstart) |
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| 131 | Tplus = T |
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| 132 | IsReject = .false. |
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| 133 | Naccept = 0 |
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| 134 | Nreject = 0 |
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| 135 | Nfcn = 0 |
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| 136 | Njac = 0 |
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| 137 | |
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| 138 | |
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| 139 | C === Starting the time loop === |
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| 140 | 10 CONTINUE |
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| 141 | |
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| 142 | C ====== Initial Function, Jacobian, and Hessian values =============== |
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| 143 | CALL FUNC_CHEM(NVAR, T, y, Fv) |
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| 144 | Nfcn = Nfcn + 1 |
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| 145 | CALL JAC_CHEM(NVAR, T, y, JAC) |
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| 146 | Njac = Njac + 1 |
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| 147 | CALL HESS_CHEM( NVAR, T, y, HESS ) |
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| 148 | IF (DDMTYPE .EQ. 1) THEN |
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| 149 | CALL DFUNDPAR(NVAR, NSENSIT, T, y, DFDP) |
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| 150 | END IF |
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| 151 | |
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| 152 | C ====== Time derivatives for NONAutonomousous CASE =============== |
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| 153 | IF (.not. Autonomous) THEN |
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| 154 | tau = DSIGN(dround*DMAX1( 1.0d-6, DABS(T) ), T) |
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| 155 | CALL FUNC_CHEM(NVAR, T+tau, y, K2) |
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| 156 | nfcn=nfcn+1 |
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| 157 | DO 20 j = 1,NVAR |
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| 158 | DFDT(j) = ( K2(j)-Fv(j) )/tau |
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| 159 | 20 CONTINUE |
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| 160 | CALL JAC_CHEM(NVAR, T+tau, y, AJAC) |
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| 161 | DO 30 j = 1,LU_NONZERO |
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| 162 | DJDT(j) = ( AJAC(j)-JAC(j) )/tau |
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| 163 | 30 CONTINUE |
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| 164 | DO 40 i=1,NSENSIT |
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| 165 | CALL Jac_SP_Vec (DJDT,y(i*NVAR+1),DFDT(i*NVAR+1)) |
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| 166 | 40 CONTINUE |
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| 167 | END IF |
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| 168 | |
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| 169 | |
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| 170 | Tplus = T + H |
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| 171 | IF ( Tplus .gt. Tnext ) then |
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| 172 | H = Tnext - T |
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| 173 | Tplus = Tnext |
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| 174 | END IF |
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| 175 | |
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| 176 | gHinv = 1.0d0/(gamma*H) |
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| 177 | DO 50 j=1,LU_NONZERO |
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| 178 | AJAC(j) = -JAC(j) |
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| 179 | 50 CONTINUE |
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| 180 | DO 60 j=1,NVAR |
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| 181 | AJAC(LU_DIAG(j)) = AJAC(LU_DIAG(j)) + gHinv |
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| 182 | 60 CONTINUE |
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| 183 | CALL KppDecomp (AJAC, ier) |
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| 184 | |
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| 185 | IF (ier.NE.0) THEN |
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| 186 | IF ( H.GT.Hmin) THEN |
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| 187 | H = 5.0d-1*H |
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| 188 | GO TO 10 |
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| 189 | ELSE |
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| 190 | PRINT *,'IER <> 0, H=',H |
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| 191 | STOP |
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| 192 | END IF |
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| 193 | END IF |
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| 194 | |
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| 195 | Autonomous = .true. |
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| 196 | |
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| 197 | C ------------------------------- STAGE 1 -------------------------------------- |
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| 198 | DO 70 j = 1,NVAR |
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| 199 | K1(j) = Fv(j) |
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| 200 | 70 CONTINUE |
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| 201 | IF (.NOT.Autonomous) THEN |
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| 202 | x1 = gamma*H |
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| 203 | DO 80 j = 1,NVAR |
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| 204 | K1(j) = K1(j) + x1*DFDT(j) |
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| 205 | 80 CONTINUE |
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| 206 | END IF |
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| 207 | CALL KppSolve (AJAC, K1) |
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| 208 | C --- If derivative w.r.t. parameters |
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| 209 | IF (DDMTYPE .EQ. 1) THEN |
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| 210 | CALL DJACDPAR(NVAR, NSENSIT, T, y, K1(1), DJDP) |
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| 211 | END IF |
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| 212 | C --- End of derivative w.r.t. parameters |
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| 213 | |
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| 214 | DO 110 i=1,NSENSIT |
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| 215 | CALL Jac_SP_Vec (JAC,y(i*NVAR+1),K1(i*NVAR+1)) |
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| 216 | CALL Hess_Vec ( HESS, y(i*NVAR+1), K1(1), Hv ) |
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| 217 | DO 90 j=1,NVAR |
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| 218 | K1(i*NVAR+j) = K1(i*NVAR+j) + Hv(j) |
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| 219 | 90 CONTINUE |
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| 220 | IF (.NOT. Autonomous) THEN |
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| 221 | DO 100 j=1,NVAR |
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| 222 | K1(i*NVAR+j) = K1(i*NVAR+j) + x1*DFDT(i*NVAR+j) |
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| 223 | 100 CONTINUE |
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| 224 | END IF |
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| 225 | C --- If derivative w.r.t. parameters |
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| 226 | IF (DDMTYPE .EQ. 1) THEN |
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| 227 | DO 44 j = 1,NVAR |
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| 228 | K1(i*NVAR+j) = K1(i*NVAR+j) + DFDP((i-1)*NVAR+j) |
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| 229 | & + DJDP((i-1)*NVAR+j) |
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| 230 | 44 CONTINUE |
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| 231 | END IF |
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| 232 | C --- End of derivative w.r.t. parameters |
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| 233 | CALL KppSolve (AJAC, K1(i*NVAR+1)) |
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| 234 | 110 CONTINUE |
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| 235 | |
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| 236 | C ------------------------------- STAGE 2 -------------------------------------- |
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| 237 | DO 120 j = 1,NVAR*(NSENSIT+1) |
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| 238 | ynew(j) = y(j) + a21*K1(j) |
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| 239 | 120 CONTINUE |
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| 240 | CALL FUNC_CHEM(NVAR, T + alpha2*H, ynew, Fv) |
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| 241 | IF (DDMTYPE .EQ. 1) THEN |
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| 242 | CALL DFUNDPAR(NVAR, NSENSIT, T+alpha3*H, ynew, DFDP) |
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| 243 | END IF |
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| 244 | nfcn=nfcn+1 |
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| 245 | x1 = c21/H |
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| 246 | DO 130 j = 1,NVAR |
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| 247 | K2(j) = Fv(j) + x1*K1(j) |
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| 248 | 130 CONTINUE |
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| 249 | IF (.NOT.Autonomous) THEN |
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| 250 | x2 = g2*H |
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| 251 | DO 140 j = 1,NVAR |
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| 252 | K2(j) = K2(j) + x2*DFDT(j) |
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| 253 | 140 CONTINUE |
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| 254 | END IF |
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| 255 | CALL KppSolve (AJAC, K2) |
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| 256 | C --- If derivative w.r.t. parameters |
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| 257 | IF (DDMTYPE .EQ. 1) THEN |
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| 258 | CALL DJACDPAR(NVAR, NSENSIT, T, y, K2(1), DJDP) |
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| 259 | END IF |
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| 260 | C --- End of derivative w.r.t. parameters |
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| 261 | |
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| 262 | CALL JAC_CHEM(NVAR, T+alpha2*H, ynew, JAC) |
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| 263 | njac=njac+1 |
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| 264 | DO 170 i=1,NSENSIT |
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| 265 | CALL Jac_SP_Vec (JAC,ynew(i*NVAR+1),K2(i*NVAR+1)) |
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| 266 | CALL Hess_Vec ( HESS, y(i*NVAR+1), K2(1), Hv ) |
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| 267 | DO 150 j = 1,NVAR |
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| 268 | K2(i*NVAR+j) = K2(i*NVAR+j) + x1*K1(i*NVAR+j) |
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| 269 | & + Hv(j) |
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| 270 | 150 CONTINUE |
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| 271 | IF (.NOT. Autonomous) THEN |
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| 272 | DO 160 j=1,NVAR |
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| 273 | K2(i*NVAR+j) = K2(i*NVAR+j) + x2*DFDT(i*NVAR+j) |
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| 274 | 160 CONTINUE |
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| 275 | END IF |
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| 276 | C --- If derivative w.r.t. parameters |
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| 277 | IF (DDMTYPE .EQ. 1) THEN |
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| 278 | DO 165 j = 1,NVAR |
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| 279 | K2(i*NVAR+j) = K2(i*NVAR+j) + DFDP((i-1)*NVAR+j) |
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| 280 | & + DJDP((i-1)*NVAR+j) |
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| 281 | 165 CONTINUE |
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| 282 | END IF |
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| 283 | C --- End of derivative w.r.t. parameters |
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| 284 | CALL KppSolve (AJAC, K2(i*NVAR+1)) |
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| 285 | 170 CONTINUE |
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| 286 | |
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| 287 | C ------------------------------- STAGE 3 -------------------------------------- |
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| 288 | x1 = c31/H |
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| 289 | x2 = c32/H |
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| 290 | DO 180 j = 1,NVAR |
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| 291 | K3(j) = Fv(j) + x1*K1(j) + x2*K2(j) |
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| 292 | 180 CONTINUE |
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| 293 | IF (.NOT.Autonomous) THEN |
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| 294 | x3 = g3*H |
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| 295 | DO 190 j = 1,NVAR |
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| 296 | K3(j) = K3(j) + x3*DFDT(j) |
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| 297 | 190 CONTINUE |
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| 298 | END IF |
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| 299 | CALL KppSolve (AJAC, K3) |
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| 300 | C --- If derivative w.r.t. parameters |
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| 301 | IF (DDMTYPE .EQ. 1) THEN |
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| 302 | CALL DJACDPAR(NVAR, NSENSIT, T, y, K3(1), DJDP) |
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| 303 | END IF |
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| 304 | C --- End of derivative w.r.t. parameters |
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| 305 | |
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| 306 | DO 220 i=1,NSENSIT |
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| 307 | CALL Jac_SP_Vec (JAC,ynew(i*NVAR+1),K3(i*NVAR+1)) |
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| 308 | CALL Hess_Vec ( HESS, y(i*NVAR+1), K3(1), Hv ) |
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| 309 | DO 200 j = 1,NVAR |
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| 310 | K3(i*NVAR+j) = K3(i*NVAR+j) +x1*K1(i*NVAR+j) |
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| 311 | & + x2*K2(i*NVAR+j) + Hv(j) |
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| 312 | 200 CONTINUE |
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| 313 | IF (.NOT. Autonomous) THEN |
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| 314 | DO 210 j=1,NVAR |
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| 315 | K3(i*NVAR+j) = K3(i*NVAR+j) + x3*DFDT(i*NVAR+j) |
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| 316 | 210 CONTINUE |
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| 317 | END IF |
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| 318 | C --- If derivative w.r.t. parameters |
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| 319 | IF (DDMTYPE .EQ. 1) THEN |
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| 320 | DO 215 j = 1,NVAR |
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| 321 | K3(i*NVAR+j) = K3(i*NVAR+j) + DFDP((i-1)*NVAR+j) |
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| 322 | & + DJDP((i-1)*NVAR+j) |
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| 323 | 215 CONTINUE |
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| 324 | END IF |
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| 325 | C --- End of derivative w.r.t. parameters |
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| 326 | CALL KppSolve (AJAC, K3(i*NVAR+1)) |
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| 327 | 220 CONTINUE |
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| 328 | |
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| 329 | C ------------------------------ The Solution --- |
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| 330 | |
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| 331 | DO 230 j = 1,NVAR*(NSENSIT+1) |
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| 332 | ynew(j) = y(j) + b1*K1(j) + b2*K2(j) + b3*K3(j) |
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| 333 | 230 CONTINUE |
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| 334 | |
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| 335 | |
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| 336 | C ====== Error estimation ======== |
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| 337 | |
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| 338 | ERR=0.d0 |
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| 339 | DO 240 i=1,NVAR |
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| 340 | ytol = AbsTol(i) + RelTol(i)*DABS(ynew(i)) |
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| 341 | ERR=ERR+((d1*K1(i)+d2*K2(i)+d3*K3(i))/ytol)**2 |
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| 342 | 240 CONTINUE |
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| 343 | ERR = DMAX1( uround, DSQRT( ERR/NVAR ) ) |
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| 344 | |
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| 345 | C ======= Choose the stepsize =============================== |
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| 346 | |
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| 347 | elo = 3.0D0 ! estimator local order |
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| 348 | factor = DMAX1(2.0D-1,DMIN1(6.0D0,ERR**(1.0D0/elo)/.9D0)) |
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| 349 | Hnew = DMIN1(Hmax,DMAX1(Hmin, H/factor)) |
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| 350 | |
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| 351 | C ======= Rejected/Accepted Step ============================ |
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| 352 | |
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| 353 | IF ( (ERR.gt.1).and.(H.gt.Hmin) ) THEN |
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| 354 | IsReject = .true. |
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| 355 | H = DMIN1(H/10,Hnew) |
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| 356 | Nreject = Nreject+1 |
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| 357 | GO TO 10 |
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| 358 | ELSE |
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| 359 | DO 250 j=1,NVAR*(NSENSIT+1) |
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| 360 | y(j) = ynew(j) |
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| 361 | 250 CONTINUE |
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| 362 | T = Tplus |
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| 363 | IF (.NOT.IsReject) THEN |
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| 364 | H = Hnew ! Do not increase stepsize IF previos step was rejected |
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| 365 | END IF |
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| 366 | IsReject = .false. |
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| 367 | Naccept = Naccept+1 |
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| 368 | END IF |
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| 369 | |
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| 370 | |
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| 371 | C ======= End of the time loop =============================== |
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| 372 | IF ( T .lt. Tnext ) GO TO 10 |
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| 373 | |
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| 374 | |
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| 375 | C ======= Output Information ================================= |
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| 376 | Info(2) = Nfcn |
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| 377 | Info(3) = Njac |
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| 378 | Info(4) = Naccept |
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| 379 | Info(5) = Nreject |
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| 380 | Hstart = H |
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| 381 | |
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| 382 | RETURN |
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| 383 | END |
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| 384 | |
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| 385 | |
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| 386 | |
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| 387 | SUBROUTINE FUNC_CHEM(N, T, Y, P) |
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| 388 | INCLUDE 'KPP_ROOT_params.h' |
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| 389 | INCLUDE 'KPP_ROOT_global.h' |
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| 390 | INTEGER N |
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| 391 | KPP_REAL T, Told |
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| 392 | KPP_REAL Y(NVAR), P(NVAR) |
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| 393 | Told = TIME |
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| 394 | TIME = T |
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| 395 | CALL Update_SUN() |
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| 396 | CALL Update_RCONST() |
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| 397 | CALL Fun( Y, FIX, RCONST, P ) |
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| 398 | TIME = Told |
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| 399 | RETURN |
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| 400 | END |
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| 401 | |
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| 402 | |
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| 403 | SUBROUTINE DFUNDPAR(N, NSENSIT, T, Y, P) |
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| 404 | C --- Computes the partial derivatives of FUNC_CHEM w.r.t. parameters |
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| 405 | INCLUDE 'KPP_ROOT_params.h' |
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| 406 | INCLUDE 'KPP_ROOT_global.h' |
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| 407 | C --- NCOEFF, JCOEFF useful for derivatives w.r.t. rate coefficients |
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| 408 | INTEGER N |
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| 409 | INTEGER NCOEFF, JCOEFF(NREACT) |
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| 410 | COMMON /DDMRCOEFF/ NCOEFF, JCOEFF |
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| 411 | |
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| 412 | KPP_REAL T, Told |
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| 413 | KPP_REAL Y(NVAR), P(NVAR*NSENSIT) |
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| 414 | Told = TIME |
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| 415 | TIME = T |
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| 416 | CALL Update_SUN() |
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| 417 | CALL Update_RCONST() |
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| 418 | C |
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| 419 | IF (DDMTYPE .EQ. 0) THEN |
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| 420 | C --- Note: the values below are for sensitivities w.r.t. initial values; |
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| 421 | C --- they may have to be changed for other applications |
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| 422 | DO j=1,NSENSIT |
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| 423 | DO i=1,NVAR |
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| 424 | P(i+NVAR*(j-1)) = 0.0D0 |
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| 425 | END DO |
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| 426 | END DO |
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| 427 | ELSE |
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| 428 | C --- Example: the call below is for sensitivities w.r.t. rate coefficients; |
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| 429 | C --- JCOEFF(1:NSENSIT) are the indices of the NSENSIT rate coefficients |
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| 430 | C --- w.r.t. which one differentiates |
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| 431 | CALL dFun_dRcoeff( Y, FIX, NCOEFF, JCOEFF, P ) |
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| 432 | END IF |
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| 433 | TIME = Told |
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| 434 | RETURN |
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| 435 | END |
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| 436 | |
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| 437 | SUBROUTINE JAC_CHEM(N, T, Y, J) |
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| 438 | INCLUDE 'KPP_ROOT_params.h' |
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| 439 | INCLUDE 'KPP_ROOT_global.h' |
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| 440 | INTEGER N |
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| 441 | KPP_REAL Told, T |
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| 442 | KPP_REAL Y(NVAR), J(LU_NONZERO) |
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| 443 | Told = TIME |
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| 444 | TIME = T |
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| 445 | CALL Update_SUN() |
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| 446 | CALL Update_RCONST() |
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| 447 | CALL Jac_SP( Y, FIX, RCONST, J ) |
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| 448 | TIME = Told |
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| 449 | RETURN |
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| 450 | END |
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| 451 | |
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| 452 | |
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| 453 | SUBROUTINE DJACDPAR(N, NSENSIT, T, Y, U, P) |
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| 454 | C --- Computes the partial derivatives of JAC w.r.t. parameters times user vector U |
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| 455 | INCLUDE 'KPP_ROOT_params.h' |
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| 456 | INCLUDE 'KPP_ROOT_global.h' |
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| 457 | C --- NCOEFF, JCOEFF useful for derivatives w.r.t. rate coefficients |
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| 458 | INTEGER N |
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| 459 | INTEGER NCOEFF, JCOEFF(NREACT) |
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| 460 | COMMON /DDMRCOEFF/ NCOEFF, JCOEFF |
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| 461 | |
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| 462 | KPP_REAL T, Told |
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| 463 | KPP_REAL Y(NVAR), U(NVAR) |
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| 464 | KPP_REAL P(NVAR*NSENSIT) |
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| 465 | Told = TIME |
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| 466 | TIME = T |
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| 467 | CALL Update_SUN() |
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| 468 | CALL Update_RCONST() |
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| 469 | C |
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| 470 | IF (DDMTYPE .EQ. 0) THEN |
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| 471 | C --- Note: the values below are for sensitivities w.r.t. initial values; |
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| 472 | C --- they may have to be changed for other applications |
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| 473 | DO j=1,NSENSIT |
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| 474 | DO i=1,NVAR |
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| 475 | P(i+NVAR*(j-1)) = 0.0D0 |
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| 476 | END DO |
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| 477 | END DO |
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| 478 | ELSE |
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| 479 | C --- Example: the call below is for sensitivities w.r.t. rate coefficients; |
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| 480 | C --- JCOEFF(1:NSENSIT) are the indices of the NSENSIT rate coefficients |
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| 481 | C --- w.r.t. which one differentiates |
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| 482 | CALL dJac_dRcoeff( Y, FIX, U, NCOEFF, JCOEFF, P ) |
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| 483 | END IF |
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| 484 | TIME = Told |
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| 485 | RETURN |
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| 486 | END |
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| 487 | |
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| 488 | |
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| 489 | SUBROUTINE HESS_CHEM(N, T, Y, HESS) |
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| 490 | INCLUDE 'KPP_ROOT_params.h' |
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| 491 | INCLUDE 'KPP_ROOT_global.h' |
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| 492 | INTEGER N |
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| 493 | KPP_REAL Told, T |
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| 494 | KPP_REAL Y(NVAR), HESS(NHESS) |
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| 495 | Told = TIME |
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| 496 | TIME = T |
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| 497 | CALL Update_SUN() |
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| 498 | CALL Update_RCONST() |
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| 499 | CALL Hessian( Y, FIX, RCONST, HESS ) |
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| 500 | TIME = Told |
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| 501 | RETURN |
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| 502 | END |
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| 503 | |
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