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478 lines
19 KiB
Fortran
478 lines
19 KiB
Fortran
*DECK STOD
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SUBROUTINE STOD (NEQ, Y, YH, NYH, YH1, EWT, SAVF, ACOR, WM, IWM,
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+ F, JAC, RPAR, IPAR)
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C***BEGIN PROLOGUE STOD
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C***SUBSIDIARY
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C***PURPOSE Subsidiary to DEBDF
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C***LIBRARY SLATEC
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C***TYPE SINGLE PRECISION (STOD-S, DSTOD-D)
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C***AUTHOR Watts, H. A., (SNLA)
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C***DESCRIPTION
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C
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C STOD integrates a system of first order odes over one step in the
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C integrator package DEBDF.
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C ----------------------------------------------------------------------
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C STOD performs one step of the integration of an initial value
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C problem for a system of ordinary differential equations.
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C Note.. STOD is independent of the value of the iteration method
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C indicator MITER, when this is .NE. 0, and hence is independent
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C of the type of chord method used, or the Jacobian structure.
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C Communication with STOD is done with the following variables..
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C
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C Y = An array of length .GE. n used as the Y argument in
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C all calls to F and JAC.
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C NEQ = Integer array containing problem size in NEQ(1), and
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C passed as the NEQ argument in all calls to F and JAC.
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C YH = An NYH by LMAX array containing the dependent variables
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C and their approximate scaled derivatives, where
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C LMAX = MAXORD + 1. YH(I,J+1) contains the approximate
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C J-th derivative of Y(I), scaled by H**J/Factorial(j)
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C (J = 0,1,...,NQ). On entry for the first step, the first
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C two columns of YH must be set from the initial values.
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C NYH = A constant integer .GE. N, the first dimension of YH.
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C YH1 = A one-dimensional array occupying the same space as YH.
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C EWT = An array of N elements with which the estimated local
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C errors in YH are compared.
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C SAVF = An array of working storage, of length N.
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C ACOR = A work array of length N, used for the accumulated
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C corrections. On a successful return, ACOR(I) contains
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C the estimated one-step local error in Y(I).
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C WM,IWM = Real and integer work arrays associated with matrix
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C operations in chord iteration (MITER .NE. 0).
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C PJAC = Name of routine to evaluate and preprocess Jacobian matrix
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C if a chord method is being used.
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C SLVS = Name of routine to solve linear system in chord iteration.
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C H = The step size to be attempted on the next step.
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C H is altered by the error control algorithm during the
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C problem. H can be either positive or negative, but its
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C sign must remain constant throughout the problem.
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C HMIN = The minimum absolute value of the step size H to be used.
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C HMXI = Inverse of the maximum absolute value of H to be used.
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C HMXI = 0.0 is allowed and corresponds to an infinite HMAX.
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C HMIN and HMXI may be changed at any time, but will not
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C take effect until the next change of H is considered.
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C TN = The independent variable. TN is updated on each step taken.
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C JSTART = An integer used for input only, with the following
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C values and meanings..
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C 0 Perform the first step.
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C .GT.0 Take a new step continuing from the last.
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C -1 Take the next step with a new value of H, MAXORD,
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C N, METH, MITER, and/or matrix parameters.
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C -2 Take the next step with a new value of H,
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C but with other inputs unchanged.
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C On return, JSTART is set to 1 to facilitate continuation.
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C KFLAG = a completion code with the following meanings..
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C 0 The step was successful.
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C -1 The requested error could not be achieved.
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C -2 Corrector convergence could not be achieved.
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C A return with KFLAG = -1 or -2 means either
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C ABS(H) = HMIN or 10 consecutive failures occurred.
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C On a return with KFLAG negative, the values of TN and
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C the YH array are as of the beginning of the last
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C step, and H is the last step size attempted.
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C MAXORD = The maximum order of integration method to be allowed.
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C METH/MITER = The method flags. See description in driver.
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C N = The number of first-order differential equations.
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C ----------------------------------------------------------------------
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C
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C***SEE ALSO DEBDF
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C***ROUTINES CALLED CFOD, PJAC, SLVS, VNWRMS
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C***COMMON BLOCKS DEBDF1
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C***REVISION HISTORY (YYMMDD)
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C 800901 DATE WRITTEN
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C 890531 Changed all specific intrinsics to generic. (WRB)
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C 891214 Prologue converted to Version 4.0 format. (BAB)
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C 900328 Added TYPE section. (WRB)
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C 910722 Updated AUTHOR section. (ALS)
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C 920422 Changed DIMENSION statement. (WRB)
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C***END PROLOGUE STOD
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EXTERNAL F, JAC
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C
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CLLL. OPTIMIZE
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INTEGER NEQ, NYH, IWM, I, I1, IALTH, IER, IOWND, IREDO, IRET,
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1 IPUP, J, JB, JSTART, KFLAG, L, LMAX, M, MAXORD, MEO, METH,
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2 MITER, N, NCF, NEWQ, NFE, NJE, NQ, NQNYH, NQU, NST, NSTEPJ
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REAL Y, YH, YH1, EWT, SAVF, ACOR, WM,
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1 ROWND, CONIT, CRATE, EL, ELCO, HOLD, RC, RMAX, TESCO,
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2 EL0, H, HMIN, HMXI, HU, TN, UROUND,
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3 DCON, DDN, DEL, DELP, DSM, DUP, EXDN, EXSM, EXUP,
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4 R, RH, RHDN, RHSM, RHUP, TOLD, VNWRMS
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DIMENSION Y(*), YH(NYH,*), YH1(*), EWT(*), SAVF(*),
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1 ACOR(*), WM(*), IWM(*), RPAR(*), IPAR(*)
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COMMON /DEBDF1/ ROWND, CONIT, CRATE, EL(13), ELCO(13,12),
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1 HOLD, RC, RMAX, TESCO(3,12),
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2 EL0, H, HMIN, HMXI, HU, TN, UROUND, IOWND(7), KSTEPS, IOD(6),
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3 IALTH, IPUP, LMAX, MEO, NQNYH, NSTEPJ,
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4 IER, JSTART, KFLAG, L, METH, MITER, MAXORD, N, NQ, NST, NFE,
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5 NJE, NQU
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C
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C
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C***FIRST EXECUTABLE STATEMENT STOD
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KFLAG = 0
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TOLD = TN
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NCF = 0
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IF (JSTART .GT. 0) GO TO 200
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IF (JSTART .EQ. -1) GO TO 100
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IF (JSTART .EQ. -2) GO TO 160
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C-----------------------------------------------------------------------
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C ON THE FIRST CALL, THE ORDER IS SET TO 1, AND OTHER VARIABLES ARE
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C INITIALIZED. RMAX IS THE MAXIMUM RATIO BY WHICH H CAN BE INCREASED
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C IN A SINGLE STEP. IT IS INITIALLY 1.E4 TO COMPENSATE FOR THE SMALL
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C INITIAL H, BUT THEN IS NORMALLY EQUAL TO 10. IF A FAILURE
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C OCCURS (IN CORRECTOR CONVERGENCE OR ERROR TEST), RMAX IS SET AT 2
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C FOR THE NEXT INCREASE.
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C-----------------------------------------------------------------------
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LMAX = MAXORD + 1
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NQ = 1
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L = 2
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IALTH = 2
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RMAX = 10000.0E0
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RC = 0.0E0
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EL0 = 1.0E0
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CRATE = 0.7E0
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DELP = 0.0E0
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HOLD = H
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MEO = METH
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NSTEPJ = 0
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IRET = 3
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GO TO 140
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C-----------------------------------------------------------------------
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C THE FOLLOWING BLOCK HANDLES PRELIMINARIES NEEDED WHEN JSTART = -1.
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C IPUP IS SET TO MITER TO FORCE A MATRIX UPDATE.
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C IF AN ORDER INCREASE IS ABOUT TO BE CONSIDERED (IALTH = 1),
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C IALTH IS RESET TO 2 TO POSTPONE CONSIDERATION ONE MORE STEP.
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C IF THE CALLER HAS CHANGED METH, CFOD IS CALLED TO RESET
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C THE COEFFICIENTS OF THE METHOD.
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C IF THE CALLER HAS CHANGED MAXORD TO A VALUE LESS THAN THE CURRENT
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C ORDER NQ, NQ IS REDUCED TO MAXORD, AND A NEW H CHOSEN ACCORDINGLY.
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C IF H IS TO BE CHANGED, YH MUST BE RESCALED.
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C IF H OR METH IS BEING CHANGED, IALTH IS RESET TO L = NQ + 1
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C TO PREVENT FURTHER CHANGES IN H FOR THAT MANY STEPS.
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C-----------------------------------------------------------------------
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100 IPUP = MITER
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LMAX = MAXORD + 1
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IF (IALTH .EQ. 1) IALTH = 2
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IF (METH .EQ. MEO) GO TO 110
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CALL CFOD (METH, ELCO, TESCO)
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MEO = METH
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IF (NQ .GT. MAXORD) GO TO 120
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IALTH = L
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IRET = 1
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GO TO 150
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110 IF (NQ .LE. MAXORD) GO TO 160
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120 NQ = MAXORD
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L = LMAX
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DO 125 I = 1,L
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125 EL(I) = ELCO(I,NQ)
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NQNYH = NQ*NYH
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RC = RC*EL(1)/EL0
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EL0 = EL(1)
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CONIT = 0.5E0/(NQ+2)
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DDN = VNWRMS (N, SAVF, EWT)/TESCO(1,L)
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EXDN = 1.0E0/L
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RHDN = 1.0E0/(1.3E0*DDN**EXDN + 0.0000013E0)
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RH = MIN(RHDN,1.0E0)
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IREDO = 3
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IF (H .EQ. HOLD) GO TO 170
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RH = MIN(RH,ABS(H/HOLD))
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H = HOLD
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GO TO 175
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C-----------------------------------------------------------------------
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C CFOD IS CALLED TO GET ALL THE INTEGRATION COEFFICIENTS FOR THE
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C CURRENT METH. THEN THE EL VECTOR AND RELATED CONSTANTS ARE RESET
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C WHENEVER THE ORDER NQ IS CHANGED, OR AT THE START OF THE PROBLEM.
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C-----------------------------------------------------------------------
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140 CALL CFOD (METH, ELCO, TESCO)
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150 DO 155 I = 1,L
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155 EL(I) = ELCO(I,NQ)
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NQNYH = NQ*NYH
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RC = RC*EL(1)/EL0
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EL0 = EL(1)
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CONIT = 0.5E0/(NQ+2)
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GO TO (160, 170, 200), IRET
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C-----------------------------------------------------------------------
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C IF H IS BEING CHANGED, THE H RATIO RH IS CHECKED AGAINST
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C RMAX, HMIN, AND HMXI, AND THE YH ARRAY RESCALED. IALTH IS SET TO
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C L = NQ + 1 TO PREVENT A CHANGE OF H FOR THAT MANY STEPS, UNLESS
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C FORCED BY A CONVERGENCE OR ERROR TEST FAILURE.
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C-----------------------------------------------------------------------
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160 IF (H .EQ. HOLD) GO TO 200
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RH = H/HOLD
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H = HOLD
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IREDO = 3
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GO TO 175
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170 RH = MAX(RH,HMIN/ABS(H))
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175 RH = MIN(RH,RMAX)
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RH = RH/MAX(1.0E0,ABS(H)*HMXI*RH)
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R = 1.0E0
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DO 180 J = 2,L
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R = R*RH
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DO 180 I = 1,N
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180 YH(I,J) = YH(I,J)*R
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H = H*RH
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RC = RC*RH
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IALTH = L
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IF (IREDO .EQ. 0) GO TO 680
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C-----------------------------------------------------------------------
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C THIS SECTION COMPUTES THE PREDICTED VALUES BY EFFECTIVELY
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C MULTIPLYING THE YH ARRAY BY THE PASCAL TRIANGLE MATRIX.
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C RC IS THE RATIO OF NEW TO OLD VALUES OF THE COEFFICIENT H*EL(1).
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C WHEN RC DIFFERS FROM 1 BY MORE THAN 30 PERCENT, IPUP IS SET TO MITER
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C TO FORCE PJAC TO BE CALLED, IF A JACOBIAN IS INVOLVED.
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C IN ANY CASE, PJAC IS CALLED AT LEAST EVERY 20-TH STEP.
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C-----------------------------------------------------------------------
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200 IF (ABS(RC-1.0E0) .GT. 0.3E0) IPUP = MITER
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IF (NST .GE. NSTEPJ+20) IPUP = MITER
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TN = TN + H
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I1 = NQNYH + 1
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DO 215 JB = 1,NQ
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I1 = I1 - NYH
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DO 210 I = I1,NQNYH
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210 YH1(I) = YH1(I) + YH1(I+NYH)
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215 CONTINUE
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KSTEPS = KSTEPS + 1
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C-----------------------------------------------------------------------
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C UP TO 3 CORRECTOR ITERATIONS ARE TAKEN. A CONVERGENCE TEST IS
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C MADE ON THE R.M.S. NORM OF EACH CORRECTION, WEIGHTED BY THE ERROR
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C WEIGHT VECTOR EWT. THE SUM OF THE CORRECTIONS IS ACCUMULATED IN THE
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C VECTOR ACOR(I). THE YH ARRAY IS NOT ALTERED IN THE CORRECTOR LOOP.
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C-----------------------------------------------------------------------
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220 M = 0
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DO 230 I = 1,N
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230 Y(I) = YH(I,1)
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CALL F (TN, Y, SAVF, RPAR, IPAR)
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NFE = NFE + 1
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IF (IPUP .LE. 0) GO TO 250
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C-----------------------------------------------------------------------
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C IF INDICATED, THE MATRIX P = I - H*EL(1)*J IS REEVALUATED AND
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C PREPROCESSED BEFORE STARTING THE CORRECTOR ITERATION. IPUP IS SET
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C TO 0 AS AN INDICATOR THAT THIS HAS BEEN DONE.
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C-----------------------------------------------------------------------
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IPUP = 0
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RC = 1.0E0
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NSTEPJ = NST
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CRATE = 0.7E0
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CALL PJAC (NEQ, Y, YH, NYH, EWT, ACOR, SAVF, WM, IWM, F, JAC,
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1 RPAR, IPAR)
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IF (IER .NE. 0) GO TO 430
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250 DO 260 I = 1,N
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260 ACOR(I) = 0.0E0
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270 IF (MITER .NE. 0) GO TO 350
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C-----------------------------------------------------------------------
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C IN THE CASE OF FUNCTIONAL ITERATION, UPDATE Y DIRECTLY FROM
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C THE RESULT OF THE LAST FUNCTION EVALUATION.
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C-----------------------------------------------------------------------
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DO 290 I = 1,N
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SAVF(I) = H*SAVF(I) - YH(I,2)
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290 Y(I) = SAVF(I) - ACOR(I)
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DEL = VNWRMS (N, Y, EWT)
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DO 300 I = 1,N
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Y(I) = YH(I,1) + EL(1)*SAVF(I)
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300 ACOR(I) = SAVF(I)
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GO TO 400
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C-----------------------------------------------------------------------
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C IN THE CASE OF THE CHORD METHOD, COMPUTE THE CORRECTOR ERROR,
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C AND SOLVE THE LINEAR SYSTEM WITH THAT AS RIGHT-HAND SIDE AND
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C P AS COEFFICIENT MATRIX.
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C-----------------------------------------------------------------------
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350 DO 360 I = 1,N
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360 Y(I) = H*SAVF(I) - (YH(I,2) + ACOR(I))
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CALL SLVS (WM, IWM, Y, SAVF)
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IF (IER .NE. 0) GO TO 410
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DEL = VNWRMS (N, Y, EWT)
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DO 380 I = 1,N
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ACOR(I) = ACOR(I) + Y(I)
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380 Y(I) = YH(I,1) + EL(1)*ACOR(I)
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C-----------------------------------------------------------------------
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C TEST FOR CONVERGENCE. IF M.GT.0, AN ESTIMATE OF THE CONVERGENCE
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C RATE CONSTANT IS STORED IN CRATE, AND THIS IS USED IN THE TEST.
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C-----------------------------------------------------------------------
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400 IF (M .NE. 0) CRATE = MAX(0.2E0*CRATE,DEL/DELP)
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DCON = DEL*MIN(1.0E0,1.5E0*CRATE)/(TESCO(2,NQ)*CONIT)
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IF (DCON .LE. 1.0E0) GO TO 450
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M = M + 1
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IF (M .EQ. 3) GO TO 410
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IF (M .GE. 2 .AND. DEL .GT. 2.0E0*DELP) GO TO 410
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DELP = DEL
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CALL F (TN, Y, SAVF, RPAR, IPAR)
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NFE = NFE + 1
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GO TO 270
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C-----------------------------------------------------------------------
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C THE CORRECTOR ITERATION FAILED TO CONVERGE IN 3 TRIES.
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C IF MITER .NE. 0 AND THE JACOBIAN IS OUT OF DATE, PJAC IS CALLED FOR
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C THE NEXT TRY. OTHERWISE THE YH ARRAY IS RETRACTED TO ITS VALUES
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C BEFORE PREDICTION, AND H IS REDUCED, IF POSSIBLE. IF H CANNOT BE
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C REDUCED OR 10 FAILURES HAVE OCCURRED, EXIT WITH KFLAG = -2.
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C-----------------------------------------------------------------------
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410 IF (IPUP .EQ. 0) GO TO 430
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IPUP = MITER
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GO TO 220
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430 TN = TOLD
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NCF = NCF + 1
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RMAX = 2.0E0
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I1 = NQNYH + 1
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DO 445 JB = 1,NQ
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I1 = I1 - NYH
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DO 440 I = I1,NQNYH
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440 YH1(I) = YH1(I) - YH1(I+NYH)
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445 CONTINUE
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IF (ABS(H) .LE. HMIN*1.00001E0) GO TO 670
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IF (NCF .EQ. 10) GO TO 670
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RH = 0.25E0
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IPUP = MITER
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IREDO = 1
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GO TO 170
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C-----------------------------------------------------------------------
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C THE CORRECTOR HAS CONVERGED. IPUP IS SET TO -1 IF MITER .NE. 0,
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C TO SIGNAL THAT THE JACOBIAN INVOLVED MAY NEED UPDATING LATER.
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C THE LOCAL ERROR TEST IS MADE AND CONTROL PASSES TO STATEMENT 500
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C IF IT FAILS.
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C-----------------------------------------------------------------------
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450 IF (MITER .NE. 0) IPUP = -1
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IF (M .EQ. 0) DSM = DEL/TESCO(2,NQ)
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IF (M .GT. 0) DSM = VNWRMS (N, ACOR, EWT)/TESCO(2,NQ)
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IF (DSM .GT. 1.0E0) GO TO 500
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C-----------------------------------------------------------------------
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C AFTER A SUCCESSFUL STEP, UPDATE THE YH ARRAY.
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C CONSIDER CHANGING H IF IALTH = 1. OTHERWISE DECREASE IALTH BY 1.
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C IF IALTH IS THEN 1 AND NQ .LT. MAXORD, THEN ACOR IS SAVED FOR
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C USE IN A POSSIBLE ORDER INCREASE ON THE NEXT STEP.
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C IF A CHANGE IN H IS CONSIDERED, AN INCREASE OR DECREASE IN ORDER
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C BY ONE IS CONSIDERED ALSO. A CHANGE IN H IS MADE ONLY IF IT IS BY A
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C FACTOR OF AT LEAST 1.1. IF NOT, IALTH IS SET TO 3 TO PREVENT
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C TESTING FOR THAT MANY STEPS.
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C-----------------------------------------------------------------------
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KFLAG = 0
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IREDO = 0
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NST = NST + 1
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HU = H
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NQU = NQ
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DO 470 J = 1,L
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DO 470 I = 1,N
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470 YH(I,J) = YH(I,J) + EL(J)*ACOR(I)
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IALTH = IALTH - 1
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IF (IALTH .EQ. 0) GO TO 520
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IF (IALTH .GT. 1) GO TO 690
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IF (L .EQ. LMAX) GO TO 690
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DO 490 I = 1,N
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490 YH(I,LMAX) = ACOR(I)
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GO TO 690
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C-----------------------------------------------------------------------
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C THE ERROR TEST FAILED. KFLAG KEEPS TRACK OF MULTIPLE FAILURES.
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C RESTORE TN AND THE YH ARRAY TO THEIR PREVIOUS VALUES, AND PREPARE
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C TO TRY THE STEP AGAIN. COMPUTE THE OPTIMUM STEP SIZE FOR THIS OR
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C ONE LOWER ORDER. AFTER 2 OR MORE FAILURES, H IS FORCED TO DECREASE
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C BY A FACTOR OF 0.2 OR LESS.
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C-----------------------------------------------------------------------
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500 KFLAG = KFLAG - 1
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TN = TOLD
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I1 = NQNYH + 1
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DO 515 JB = 1,NQ
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I1 = I1 - NYH
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DO 510 I = I1,NQNYH
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510 YH1(I) = YH1(I) - YH1(I+NYH)
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515 CONTINUE
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RMAX = 2.0E0
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IF (ABS(H) .LE. HMIN*1.00001E0) GO TO 660
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IF (KFLAG .LE. -3) GO TO 640
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IREDO = 2
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RHUP = 0.0E0
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GO TO 540
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C-----------------------------------------------------------------------
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C REGARDLESS OF THE SUCCESS OR FAILURE OF THE STEP, FACTORS
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C RHDN, RHSM, AND RHUP ARE COMPUTED, BY WHICH H COULD BE MULTIPLIED
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C AT ORDER NQ - 1, ORDER NQ, OR ORDER NQ + 1, RESPECTIVELY.
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C IN THE CASE OF FAILURE, RHUP = 0.0 TO AVOID AN ORDER INCREASE.
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C THE LARGEST OF THESE IS DETERMINED AND THE NEW ORDER CHOSEN
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C ACCORDINGLY. IF THE ORDER IS TO BE INCREASED, WE COMPUTE ONE
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C ADDITIONAL SCALED DERIVATIVE.
|
|
C-----------------------------------------------------------------------
|
|
520 RHUP = 0.0E0
|
|
IF (L .EQ. LMAX) GO TO 540
|
|
DO 530 I = 1,N
|
|
530 SAVF(I) = ACOR(I) - YH(I,LMAX)
|
|
DUP = VNWRMS (N, SAVF, EWT)/TESCO(3,NQ)
|
|
EXUP = 1.0E0/(L+1)
|
|
RHUP = 1.0E0/(1.4E0*DUP**EXUP + 0.0000014E0)
|
|
540 EXSM = 1.0E0/L
|
|
RHSM = 1.0E0/(1.2E0*DSM**EXSM + 0.0000012E0)
|
|
RHDN = 0.0E0
|
|
IF (NQ .EQ. 1) GO TO 560
|
|
DDN = VNWRMS (N, YH(1,L), EWT)/TESCO(1,NQ)
|
|
EXDN = 1.0E0/NQ
|
|
RHDN = 1.0E0/(1.3E0*DDN**EXDN + 0.0000013E0)
|
|
560 IF (RHSM .GE. RHUP) GO TO 570
|
|
IF (RHUP .GT. RHDN) GO TO 590
|
|
GO TO 580
|
|
570 IF (RHSM .LT. RHDN) GO TO 580
|
|
NEWQ = NQ
|
|
RH = RHSM
|
|
GO TO 620
|
|
580 NEWQ = NQ - 1
|
|
RH = RHDN
|
|
IF (KFLAG .LT. 0 .AND. RH .GT. 1.0E0) RH = 1.0E0
|
|
GO TO 620
|
|
590 NEWQ = L
|
|
RH = RHUP
|
|
IF (RH .LT. 1.1E0) GO TO 610
|
|
R = EL(L)/L
|
|
DO 600 I = 1,N
|
|
600 YH(I,NEWQ+1) = ACOR(I)*R
|
|
GO TO 630
|
|
610 IALTH = 3
|
|
GO TO 690
|
|
620 IF ((KFLAG .EQ. 0) .AND. (RH .LT. 1.1E0)) GO TO 610
|
|
IF (KFLAG .LE. -2) RH = MIN(RH,0.2E0)
|
|
C-----------------------------------------------------------------------
|
|
C IF THERE IS A CHANGE OF ORDER, RESET NQ, L, AND THE COEFFICIENTS.
|
|
C IN ANY CASE H IS RESET ACCORDING TO RH AND THE YH ARRAY IS RESCALED.
|
|
C THEN EXIT FROM 680 IF THE STEP WAS OK, OR REDO THE STEP OTHERWISE.
|
|
C-----------------------------------------------------------------------
|
|
IF (NEWQ .EQ. NQ) GO TO 170
|
|
630 NQ = NEWQ
|
|
L = NQ + 1
|
|
IRET = 2
|
|
GO TO 150
|
|
C-----------------------------------------------------------------------
|
|
C CONTROL REACHES THIS SECTION IF 3 OR MORE FAILURES HAVE OCCURRED.
|
|
C IF 10 FAILURES HAVE OCCURRED, EXIT WITH KFLAG = -1.
|
|
C IT IS ASSUMED THAT THE DERIVATIVES THAT HAVE ACCUMULATED IN THE
|
|
C YH ARRAY HAVE ERRORS OF THE WRONG ORDER. HENCE THE FIRST
|
|
C DERIVATIVE IS RECOMPUTED, AND THE ORDER IS SET TO 1. THEN
|
|
C H IS REDUCED BY A FACTOR OF 10, AND THE STEP IS RETRIED,
|
|
C UNTIL IT SUCCEEDS OR H REACHES HMIN.
|
|
C-----------------------------------------------------------------------
|
|
640 IF (KFLAG .EQ. -10) GO TO 660
|
|
RH = 0.1E0
|
|
RH = MAX(HMIN/ABS(H),RH)
|
|
H = H*RH
|
|
DO 645 I = 1,N
|
|
645 Y(I) = YH(I,1)
|
|
CALL F (TN, Y, SAVF, RPAR, IPAR)
|
|
NFE = NFE + 1
|
|
DO 650 I = 1,N
|
|
650 YH(I,2) = H*SAVF(I)
|
|
IPUP = MITER
|
|
IALTH = 5
|
|
IF (NQ .EQ. 1) GO TO 200
|
|
NQ = 1
|
|
L = 2
|
|
IRET = 3
|
|
GO TO 150
|
|
C-----------------------------------------------------------------------
|
|
C ALL RETURNS ARE MADE THROUGH THIS SECTION. H IS SAVED IN HOLD
|
|
C TO ALLOW THE CALLER TO CHANGE H ON THE NEXT STEP.
|
|
C-----------------------------------------------------------------------
|
|
660 KFLAG = -1
|
|
GO TO 700
|
|
670 KFLAG = -2
|
|
GO TO 700
|
|
680 RMAX = 10.0E0
|
|
690 R = 1.0E0/TESCO(2,NQU)
|
|
DO 695 I = 1,N
|
|
695 ACOR(I) = ACOR(I)*R
|
|
700 HOLD = H
|
|
JSTART = 1
|
|
RETURN
|
|
C----------------------- END OF SUBROUTINE STOD -----------------------
|
|
END
|