1 | ! NOTE: This routine is a vectorised version of Rosenbrock |
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2 | ! and can only be used with KP4. |
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3 | ! |
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4 | SUBROUTINE Rosenbrock(N,Y,Tstart,Tend, & |
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5 | AbsTol,RelTol, & |
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6 | RCNTRL,ICNTRL,RSTATUS,ISTATUS,IERR) |
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7 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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8 | ! |
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9 | ! Solves the system y'=F(t,y) using a Rosenbrock method defined by: |
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10 | ! |
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11 | ! G = 1/(H*gamma(1)) - Jac(t0,Y0) |
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12 | ! T_i = t0 + Alpha(i)*H |
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13 | ! Y_i = Y0 + \sum_{j=1}^{i-1} A(i,j)*K_j |
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14 | ! G * K_i = Fun( T_i, Y_i ) + \sum_{j=1}^S C(i,j)/H * K_j + |
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15 | ! gamma(i)*dF/dT(t0, Y0) |
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16 | ! Y1 = Y0 + \sum_{j=1}^S M(j)*K_j |
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17 | ! |
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18 | ! For details on Rosenbrock methods and their implementation consult: |
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19 | ! E. Hairer and G. Wanner |
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20 | ! "Solving ODEs II. Stiff and differential-algebraic problems". |
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21 | ! Springer series in computational mathematics, Springer-Verlag, 1996. |
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22 | ! The codes contained in the book inspired this implementation. |
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23 | ! |
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24 | ! (C) Adrian Sandu, August 2004 |
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25 | ! Virginia Polytechnic Institute and State University |
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26 | ! Contact: sandu@cs.vt.edu |
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27 | ! Revised by Philipp Miehe and Adrian Sandu, May 2006 |
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28 | ! This implementation is part of KPP - the Kinetic PreProcessor |
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29 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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30 | ! |
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31 | !~~~> INPUT ARGUMENTS: |
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32 | ! |
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33 | !- Y(N) = vector of initial conditions (at T=Tstart) |
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34 | !- [Tstart,Tend] = time range of integration |
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35 | ! (if Tstart>Tend the integration is performed backwards in time) |
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36 | !- RelTol, AbsTol = user precribed accuracy |
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37 | !- SUBROUTINE Fun( T, Y, Ydot ) = ODE function, |
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38 | ! returns Ydot = Y' = F(T,Y) |
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39 | !- SUBROUTINE Jac( T, Y, Jcb ) = Jacobian of the ODE function, |
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40 | ! returns Jcb = dFun/dY |
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41 | !- ICNTRL(1:20) = integer inputs parameters |
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42 | !- RCNTRL(1:20) = real inputs parameters |
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43 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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44 | ! |
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45 | !~~~> OUTPUT ARGUMENTS: |
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46 | ! |
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47 | !- Y(N) -> vector of final states (at T->Tend) |
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48 | !- ISTATUS(1:20) -> integer output parameters |
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49 | !- RSTATUS(1:20) -> real output parameters |
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50 | !- IERR -> job status upon return |
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51 | ! success (positive value) or |
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52 | ! failure (negative value) |
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53 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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54 | ! |
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55 | !~~~> INPUT PARAMETERS: |
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56 | ! |
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57 | ! Note: For input parameters equal to zero the default values of the |
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58 | ! corresponding variables are used. |
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59 | ! |
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60 | ! ICNTRL(1) = 1: F = F(y) Independent of T (AUTONOMOUS) |
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61 | ! = 0: F = F(t,y) Depends on T (NON-AUTONOMOUS) |
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62 | ! |
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63 | ! ICNTRL(2) = 0: AbsTol, RelTol are N-dimensional vectors |
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64 | ! = 1: AbsTol, RelTol are scalars |
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65 | ! |
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66 | ! ICNTRL(3) -> selection of a particular Rosenbrock method |
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67 | ! = 0 : Rodas3 (default) |
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68 | ! = 1 : Ros2 |
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69 | ! = 2 : Ros3 |
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70 | ! = 3 : Ros4F |
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71 | ! = 4 : Rodas3 |
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72 | ! = 5 : Rodas4 |
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73 | ! |
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74 | ! ICNTRL(4) -> maximum number of integration steps |
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75 | ! For ICNTRL(4)=0) the default value of 100000 is used |
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76 | ! |
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77 | ! RCNTRL(1) -> Hmin, lower bound for the integration step size |
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78 | ! It is strongly recommended to keep Hmin = ZERO |
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79 | ! RCNTRL(2) -> Hmax, upper bound for the integration step size |
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80 | ! RCNTRL(3) -> Hstart, starting value for the integration step size |
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81 | ! |
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82 | ! RCNTRL(4) -> FacMin, lower bound on step decrease factor (default=0.2) |
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83 | ! RCNTRL(5) -> FacMax, upper bound on step increase factor (default=6) |
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84 | ! RCNTRL(6) -> FacRej, step decrease factor after multiple rejections |
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85 | ! (default=0.1) |
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86 | ! RCNTRL(7) -> FacSafe, by which the new step is slightly smaller |
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87 | ! than the predicted value (default=0.9) |
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88 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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89 | ! |
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90 | ! |
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91 | ! OUTPUT ARGUMENTS: |
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92 | ! ----------------- |
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93 | ! |
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94 | ! T -> T value for which the solution has been computed |
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95 | ! (after successful return T=Tend). |
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96 | ! |
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97 | ! Y(N) -> Numerical solution at T |
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98 | ! |
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99 | ! IDID -> Reports on successfulness upon return: |
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100 | ! = 1 for success |
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101 | ! < 0 for error (value equals error code) |
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102 | ! |
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103 | ! ISTATUS(1) -> No. of function calls |
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104 | ! ISTATUS(2) -> No. of jacobian calls |
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105 | ! ISTATUS(3) -> No. of steps |
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106 | ! ISTATUS(4) -> No. of accepted steps |
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107 | ! ISTATUS(5) -> No. of rejected steps (except at very beginning) |
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108 | ! ISTATUS(6) -> No. of LU decompositions |
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109 | ! ISTATUS(7) -> No. of forward/backward substitutions |
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110 | ! ISTATUS(8) -> No. of singular matrix decompositions |
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111 | ! |
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112 | ! RSTATUS(1) -> Texit, the time corresponding to the |
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113 | ! computed Y upon return |
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114 | ! RSTATUS(2) -> Hexit, last accepted step before exit |
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115 | ! RSTATUS(3) -> Hnew, last predicted step (not yet taken) |
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116 | ! For multiple restarts, use Hnew as Hstart |
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117 | ! in the subsequent run |
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118 | ! |
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119 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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120 | USE cpulog, ONLY: cpu_log, log_point_s |
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121 | |
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122 | IMPLICIT NONE |
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123 | |
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124 | !~~~> Arguments |
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125 | INTEGER, INTENT(IN) :: N |
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126 | REAL(kind=dp), INTENT(INOUT) :: Y(:,:) |
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127 | REAL(kind=dp), INTENT(IN) :: Tstart,Tend |
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128 | REAL(kind=dp), INTENT(IN) :: AbsTol(N),RelTol(N) |
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129 | INTEGER, INTENT(IN) :: ICNTRL(20) |
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130 | REAL(kind=dp), INTENT(IN) :: RCNTRL(20) |
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131 | INTEGER, INTENT(INOUT) :: ISTATUS(20) |
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132 | REAL(kind=dp), INTENT(INOUT) :: RSTATUS(20) |
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133 | INTEGER, INTENT(OUT) :: IERR |
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134 | !~~~> Parameters of the Rosenbrock method, up to 6 stages |
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135 | INTEGER :: ros_S, rosMethod |
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136 | INTEGER, PARAMETER :: RS2=1, RS3=2, RS4=3, RD3=4, RD4=5, RG3=6 |
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137 | REAL(kind=dp) :: ros_A(15), ros_C(15), ros_M(6), ros_E(6), & |
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138 | ros_Alpha(6), ros_Gamma(6), ros_ELO |
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139 | LOGICAL :: ros_NewF(6) |
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140 | CHARACTER(LEN=12) :: ros_Name |
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141 | !~~~> Local variables |
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142 | REAL(kind=dp) :: Roundoff, FacMin, FacMax, FacRej, FacSafe |
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143 | REAL(kind=dp) :: Hmin, Hmax, Hstart |
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144 | REAL(kind=dp) :: Texit |
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145 | INTEGER :: i, UplimTol, Max_no_steps |
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146 | LOGICAL :: Autonomous, VectorTol |
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147 | !~~~> Parameters |
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148 | REAL(kind=dp), PARAMETER :: ZERO = 0.0_dp, ONE = 1.0_dp |
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149 | REAL(kind=dp), PARAMETER :: DeltaMin = 1.0E-5_dp |
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150 | INTEGER :: solver_method |
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151 | |
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152 | |
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153 | !~~~> Autonomous or time dependent ODE. Default is time dependent. |
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154 | Autonomous = .NOT.(ICNTRL(1) == 0) |
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155 | |
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156 | !~~~> For Scalar tolerances (ICNTRL(2).NE.0) the code uses AbsTol(1) and RelTol(1) |
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157 | ! For Vector tolerances (ICNTRL(2) == 0) the code uses AbsTol(1:N) and RelTol(1:N) |
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158 | IF (ICNTRL(2) == 0) THEN |
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159 | VectorTol = .TRUE. |
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160 | UplimTol = N |
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161 | ELSE |
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162 | VectorTol = .FALSE. |
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163 | UplimTol = 1 |
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164 | END IF |
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165 | |
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166 | solver_method = ICNTRL(3) |
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167 | |
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168 | !~~~> Initialize the particular Rosenbrock method selected |
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169 | SELECT CASE (solver_method) |
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170 | CASE (1) |
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171 | CALL Ros2 |
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172 | CASE (2) |
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173 | CALL Ros3 |
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174 | CASE (3) |
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175 | CALL Ros4 |
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176 | CASE (0,4) |
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177 | CALL Rodas3 |
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178 | CASE (5) |
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179 | CALL Rodas4 |
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180 | CASE (6) |
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181 | CALL Rang3 |
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182 | CASE DEFAULT |
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183 | PRINT * , 'Unknown Rosenbrock method: ICNTRL(3)=',ICNTRL(3) |
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184 | CALL ros_ErrorMsg(-2,Tstart,ZERO,IERR) |
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185 | IERRV(:) = -2 |
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186 | RETURN |
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187 | END SELECT |
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188 | |
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189 | !~~~> The maximum number of steps admitted |
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190 | IF (ICNTRL(4) == 0) THEN |
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191 | Max_no_steps = 200000 |
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192 | ELSEIF (ICNTRL(4) > 0) THEN |
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193 | Max_no_steps=ICNTRL(4) |
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194 | ELSE |
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195 | PRINT * ,'User-selected max no. of steps: ICNTRL(4)=',ICNTRL(4) |
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196 | CALL ros_ErrorMsg(-1,Tstart,ZERO,IERR) |
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197 | IERRV(:) = -1 |
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198 | RETURN |
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199 | END IF |
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200 | |
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201 | !~~~> Unit roundoff (1+Roundoff>1) |
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202 | Roundoff = WLAMCH('E') |
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203 | |
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204 | !~~~> Lower bound on the step size: (positive value) |
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205 | IF (RCNTRL(1) == ZERO) THEN |
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206 | Hmin = ZERO |
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207 | ELSEIF (RCNTRL(1) > ZERO) THEN |
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208 | Hmin = RCNTRL(1) |
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209 | ELSE |
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210 | PRINT * , 'User-selected Hmin: RCNTRL(1)=', RCNTRL(1) |
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211 | CALL ros_ErrorMsg(-3,Tstart,ZERO,IERR) |
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212 | IERRV(:) = -3 |
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213 | RETURN |
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214 | END IF |
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215 | !~~~> Upper bound on the step size: (positive value) |
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216 | IF (RCNTRL(2) == ZERO) THEN |
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217 | Hmax = ABS(Tend-Tstart) |
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218 | ELSEIF (RCNTRL(2) > ZERO) THEN |
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219 | Hmax = MIN(ABS(RCNTRL(2)),ABS(Tend-Tstart)) |
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220 | ELSE |
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221 | PRINT * , 'User-selected Hmax: RCNTRL(2)=', RCNTRL(2) |
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222 | CALL ros_ErrorMsg(-3,Tstart,ZERO,IERR) |
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223 | IERRV(:) = -3 |
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224 | RETURN |
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225 | END IF |
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226 | !~~~> Starting step size: (positive value) |
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227 | IF (RCNTRL(3) == ZERO) THEN |
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228 | Hstart = MAX(Hmin,DeltaMin) |
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229 | ELSEIF (RCNTRL(3) > ZERO) THEN |
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230 | Hstart = MIN(ABS(RCNTRL(3)),ABS(Tend-Tstart)) |
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231 | ELSE |
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232 | PRINT * , 'User-selected Hstart: RCNTRL(3)=', RCNTRL(3) |
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233 | CALL ros_ErrorMsg(-3,Tstart,ZERO,IERR) |
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234 | RETURN |
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235 | END IF |
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236 | !~~~> Step size can be changed s.t. FacMin < Hnew/Hold < FacMax |
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237 | IF (RCNTRL(4) == ZERO) THEN |
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238 | FacMin = 0.2_dp |
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239 | ELSEIF (RCNTRL(4) > ZERO) THEN |
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240 | FacMin = RCNTRL(4) |
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241 | ELSE |
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242 | PRINT * , 'User-selected FacMin: RCNTRL(4)=', RCNTRL(4) |
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243 | CALL ros_ErrorMsg(-4,Tstart,ZERO,IERR) |
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244 | IERRV(:) = -4 |
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245 | RETURN |
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246 | END IF |
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247 | IF (RCNTRL(5) == ZERO) THEN |
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248 | FacMax = 6.0_dp |
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249 | ELSEIF (RCNTRL(5) > ZERO) THEN |
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250 | FacMax = RCNTRL(5) |
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251 | ELSE |
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252 | PRINT * , 'User-selected FacMax: RCNTRL(5)=', RCNTRL(5) |
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253 | CALL ros_ErrorMsg(-4,Tstart,ZERO,IERR) |
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254 | IERRV(:) = -4 |
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255 | RETURN |
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256 | END IF |
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257 | !~~~> FacRej: Factor to decrease step after 2 succesive rejections |
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258 | IF (RCNTRL(6) == ZERO) THEN |
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259 | FacRej = 0.1_dp |
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260 | ELSEIF (RCNTRL(6) > ZERO) THEN |
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261 | FacRej = RCNTRL(6) |
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262 | ELSE |
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263 | PRINT * , 'User-selected FacRej: RCNTRL(6)=', RCNTRL(6) |
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264 | CALL ros_ErrorMsg(-4,Tstart,ZERO,IERR) |
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265 | IERRV(:) = -4 |
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266 | RETURN |
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267 | END IF |
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268 | !~~~> FacSafe: Safety Factor in the computation of new step size |
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269 | IF (RCNTRL(7) == ZERO) THEN |
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270 | FacSafe = 0.9_dp |
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271 | ELSEIF (RCNTRL(7) > ZERO) THEN |
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272 | FacSafe = RCNTRL(7) |
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273 | ELSE |
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274 | PRINT * , 'User-selected FacSafe: RCNTRL(7)=', RCNTRL(7) |
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275 | CALL ros_ErrorMsg(-4,Tstart,ZERO,IERR) |
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276 | IERRV(:) = -4 |
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277 | RETURN |
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278 | END IF |
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279 | !~~~> Check if tolerances are reasonable |
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280 | DO i=1,UplimTol |
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281 | IF ( (AbsTol(i) <= ZERO) .OR. (RelTol(i) <= 10.0_dp*Roundoff) & |
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282 | .OR. (RelTol(i) >= 1.0_dp) ) THEN |
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283 | PRINT * , ' AbsTol(',i,') = ',AbsTol(i) |
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284 | PRINT * , ' RelTol(',i,') = ',RelTol(i) |
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285 | CALL ros_ErrorMsg(-5,Tstart,ZERO,IERR) |
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286 | RETURN |
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287 | END IF |
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288 | END DO |
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289 | |
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290 | |
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291 | !~~~> CALL Rosenbrock method |
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292 | CALL ros_Integrator(Y, Tstart, Tend, Texit, & |
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293 | AbsTol, RelTol, & |
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294 | ! Integration parameters |
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295 | Autonomous, VectorTol, Max_no_steps, & |
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296 | Roundoff, Hmin, Hmax, Hstart, & |
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297 | FacMin, FacMax, FacRej, FacSafe, & |
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298 | ! Error indicator |
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299 | IERR) |
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300 | |
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301 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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302 | CONTAINS ! SUBROUTINES internal to Rosenbrock |
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303 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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304 | |
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305 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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306 | SUBROUTINE ros_ErrorMsg(Code,T,H,IERR) |
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307 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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308 | ! Handles all error messages |
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309 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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310 | |
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311 | REAL(kind=dp), INTENT(IN) :: T, H |
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312 | INTEGER, INTENT(IN) :: Code |
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313 | INTEGER, INTENT(OUT) :: IERR |
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314 | |
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315 | IERR = Code |
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316 | PRINT * , & |
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317 | 'Forced exit from Rosenbrock due to the following error:' |
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318 | |
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319 | SELECT CASE (Code) |
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320 | CASE (-1) |
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321 | PRINT * , '--> Improper value for maximal no of steps' |
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322 | CASE (-2) |
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323 | PRINT * , '--> Selected Rosenbrock method not implemented' |
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324 | CASE (-3) |
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325 | PRINT * , '--> Hmin/Hmax/Hstart must be positive' |
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326 | CASE (-4) |
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327 | PRINT * , '--> FacMin/FacMax/FacRej must be positive' |
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328 | CASE (-5) |
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329 | PRINT * , '--> Improper tolerance values' |
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330 | CASE (-6) |
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331 | PRINT * , '--> No of steps exceeds maximum bound' |
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332 | CASE (-7) |
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333 | PRINT * , '--> Step size too small: T + 10*H = T', & |
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334 | ' or H < Roundoff' |
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335 | CASE (-8) |
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336 | PRINT * , '--> Matrix is repeatedly singular' |
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337 | CASE DEFAULT |
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338 | PRINT *, 'Unknown Error code: ', Code |
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339 | END SELECT |
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340 | |
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341 | ! PRINT *, "T=", T, "and H=", H |
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342 | |
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343 | END SUBROUTINE ros_ErrorMsg |
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344 | |
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345 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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346 | SUBROUTINE ros_Integrator (Y, Tstart, Tend, Tout, & |
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347 | AbsTol, RelTol, & |
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348 | !~~~> Integration parameters |
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349 | Autonomous, VectorTol, Max_no_steps, & |
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350 | Roundoff, Hmin, Hmax, Hstart, & |
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351 | FacMin, FacMax, FacRej, FacSafe, & |
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352 | !~~~> Error indicator |
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353 | IERR_out ) |
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354 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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355 | ! Template for the implementation of a generic Rosenbrock method |
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356 | ! defined by ros_S (no of stages) |
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357 | ! and its coefficients ros_{A,C,M,E,Alpha,Gamma} |
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358 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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359 | |
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360 | USE kp4_compress, ONLY: kco_initialize, kco_compress, & |
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361 | kco_finalize, cell_done |
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362 | IMPLICIT NONE |
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363 | |
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364 | !~~~> Input: the initial condition at Tstart; Output: the solution at T |
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365 | REAL(kind=dp), INTENT(INOUT) :: Y(:,:) |
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366 | !~~~> Input: integration interval |
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367 | REAL(kind=dp), INTENT(IN) :: Tstart,Tend |
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368 | !~~~> Output: time at which the solution is returned (T=Tend if success) |
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369 | REAL(kind=dp), INTENT(OUT) :: Tout |
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370 | !~~~> Input: tolerances |
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371 | REAL(kind=dp), INTENT(IN) :: AbsTol(N), RelTol(N) |
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372 | !~~~> Input: integration parameters |
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373 | LOGICAL, INTENT(IN) :: Autonomous, VectorTol |
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374 | REAL(kind=dp), INTENT(IN) :: Hstart, Hmin, Hmax |
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375 | INTEGER, INTENT(IN) :: Max_no_steps |
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376 | REAL(kind=dp), INTENT(IN) :: Roundoff, FacMin, FacMax, FacRej, FacSafe |
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377 | !~~~> Output: Error indicator |
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378 | INTEGER, INTENT(OUT) :: IERR_out |
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379 | ! ~~~~ Local variables |
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380 | REAL(kind=dp) :: Ynew(VL_DIM,N), Fcn0(VL_DIM,N), Fcn(VL_DIM,N) |
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381 | REAL(kind=dp) :: K(VL_DIM,N*ros_S), dFdT(VL_DIM,N) |
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382 | REAL(kind=dp) :: Jac0(VL_DIM,LU_NONZERO), Ghimj(VL_DIM,LU_NONZERO) |
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383 | !kk REAL(kind=dp) :: H, Hnew, HC, HG, Fac, Tau |
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384 | REAL(kind=dp) :: Yerr(VL_DIM,N) |
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385 | REAL(kind=dp) :: Y_save(VL_DIM,N),Ynew_save(VL_DIM,N) |
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386 | REAL(kind=dp) :: Hnew_save(VL_DIM) |
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387 | INTEGER :: Pivot(N), Direction, ioffset, j, istage, i |
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388 | LOGICAL :: Singular |
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389 | !~~~> Local parameters |
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390 | REAL(kind=dp), PARAMETER :: ZERO = 0.0_dp, ONE = 1.0_dp |
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391 | REAL(kind=dp), PARAMETER :: DeltaMin = 1.0E-5_dp |
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392 | |
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393 | LOGICAL,SAVE :: lfirst = .TRUE. |
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394 | !~~~> Locally called functions |
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395 | ! REAL(kind=dp) WLAMCH |
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396 | ! EXTERNAL WLAMCH |
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397 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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398 | |
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399 | ! vector compression algorithm |
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400 | |
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401 | REAL(kind=dp), dimension(VL_dim) :: T |
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402 | REAL(kind=dp), dimension(VL_dim) :: H, Hnew, HC, HC2, HG, Fac, Tau, Err,ros_v |
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403 | LOGICAL, dimension(VL_dim) :: RejectLastH, RejectMoreH |
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404 | LOGICAL, dimension(VL_dim) :: Accept_step,y_copied |
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405 | integer :: vl_save |
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406 | integer :: loop_count |
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407 | |
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408 | if (lfirst) then |
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409 | write(9,'(a,i4,/)') 'kpp4palm vector version ==> Vector length = ',vl_dim |
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410 | end if |
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411 | |
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412 | !~~~> Initial preparations |
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413 | T(1:VL) = Tstart |
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414 | RSTATUS(Nhexit) = ZERO |
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415 | Tout = Tend |
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416 | H(1:VL) = MIN( MAX(ABS(Hmin),ABS(Hstart)) , ABS(Hmax) ) |
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417 | where (ABS(H(1:VL)) <= 10.0_dp*Roundoff) H(1:VL) = DeltaMin |
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418 | |
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419 | |
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420 | IF (Tend >= Tstart) THEN |
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421 | Direction = +1 |
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422 | ELSE |
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423 | Direction = -1 |
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424 | END IF |
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425 | H = Direction*H |
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426 | |
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427 | RejectLastH(1:VL)=.FALSE. |
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428 | RejectMoreH(1:VL)=.FALSE. |
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429 | |
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430 | loop_count = 0 |
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431 | !~~~> Time loop begins below |
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432 | |
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433 | IERRV(1:VL) = 1 ! successful integration |
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434 | vl_save = VL |
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435 | Kacc = 0 |
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436 | Krej = 0 |
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437 | |
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438 | !kk IF (.not. l_fixed_step) then |
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439 | call kco_initialize (VL, y, IERRV, Kacc, Krej) |
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440 | !kk end if |
---|
441 | |
---|
442 | TimeLoop: DO |
---|
443 | !kk Eventuell als Where einbauen |
---|
444 | where ( (Direction > 0).AND.((T(1:VL)-Tend)+Roundoff <= ZERO) & |
---|
445 | .OR. (Direction < 0).AND.((Tend-T(1:VL))+Roundoff <= ZERO) ) |
---|
446 | cell_done(1:VL) = .FALSE. |
---|
447 | elsewhere |
---|
448 | cell_done(1:VL) = .TRUE. |
---|
449 | end where |
---|
450 | ! do i=1,vl |
---|
451 | ! if ( (Direction > 0).AND.((T(i)-Tend)+Roundoff <= ZERO) & |
---|
452 | ! .OR. (Direction < 0).AND.((Tend-T(i))+Roundoff <= ZERO) ) then |
---|
453 | ! cell_done(i) = .FALSE. |
---|
454 | ! else |
---|
455 | ! cell_done(i) = .TRUE. |
---|
456 | ! end if |
---|
457 | ! end do |
---|
458 | |
---|
459 | if(count(cell_done(1:VL)) == vl_save) then ! EXIT 1, all cells converge at the same time |
---|
460 | EXIT ! Iteration terminates without without compress |
---|
461 | end if |
---|
462 | |
---|
463 | loop_count = loop_count+1 |
---|
464 | |
---|
465 | call kco_compress (VL, T, H, Hnew, IERRV, y, RCONST, FIX, RejectLastH, RejectMoreH, Kacc, Krej) |
---|
466 | |
---|
467 | if(all(cell_done(1:VL))) then ! EXIT 2, all cells converge have been converged |
---|
468 | EXIT |
---|
469 | end if |
---|
470 | |
---|
471 | IF ( ISTATUS(Nstp) > Max_no_steps ) THEN ! Too many steps |
---|
472 | CALL ros_ErrorMsg(-6,T(1),H(1),IERR) |
---|
473 | IERRV(1:VL) = -6 |
---|
474 | RETURN |
---|
475 | END IF |
---|
476 | |
---|
477 | IERRV = 0 |
---|
478 | WHERE ( ((T(1:VL)+0.1_dp*H(1:VL)) == T(1)).OR.(H(1:VL) <= Roundoff) ) ! Step size too small |
---|
479 | IERRV(1:VL) = -7 |
---|
480 | END WHERE |
---|
481 | |
---|
482 | IF(MINVAL(IERRV) == -7) then |
---|
483 | CALL ros_ErrorMsg(-7,T(1),H(1),IERR) |
---|
484 | RETURN |
---|
485 | END IF |
---|
486 | |
---|
487 | !~~~> Limit H if necessary to avoid going beyond Tend |
---|
488 | H(1:VL) = MIN(H(1:VL),ABS(Tend-T(1:VL))) |
---|
489 | |
---|
490 | !~~~> Compute the function at current time |
---|
491 | CALL FunTemplate(T,Y,Fcn0) |
---|
492 | ISTATUS(Nfun) = ISTATUS(Nfun) + 1 |
---|
493 | |
---|
494 | !~~~> Compute the function derivative with respect to T |
---|
495 | IF (.NOT.Autonomous) THEN |
---|
496 | CALL ros_FunTimeDerivative ( T, Roundoff, Y, & |
---|
497 | Fcn0, dFdT ) |
---|
498 | END IF |
---|
499 | |
---|
500 | !~~~> Compute the Jacobian at current time |
---|
501 | CALL JacTemplate(T,Y,Jac0) |
---|
502 | ISTATUS(Njac) = ISTATUS(Njac) + 1 ! This is not correct in vector mode, please use xnacc and xnrej |
---|
503 | |
---|
504 | !~~~> Repeat step calculation until current step accepted |
---|
505 | Accept_step(1:VL) = .FALSE. |
---|
506 | y_copied(1:VL) = .FALSE. |
---|
507 | |
---|
508 | UntilAccepted: DO |
---|
509 | |
---|
510 | CALL ros_PrepareMatrix(H,Direction,ros_Gamma(1), & |
---|
511 | Jac0,Ghimj,Pivot,Singular) |
---|
512 | IF (Singular) THEN ! More than 5 consecutive failed decompositions |
---|
513 | CALL ros_ErrorMsg(-8,T(1),H(1),IERR) |
---|
514 | RETURN |
---|
515 | END IF |
---|
516 | |
---|
517 | !~~~> Compute the stages |
---|
518 | Stage: DO istage = 1, ros_S |
---|
519 | |
---|
520 | ! Current istage offset. Current istage vector is K(ioffset+1:ioffset+N) |
---|
521 | ioffset = N*(istage-1) |
---|
522 | |
---|
523 | ! For the 1st istage the function has been computed previously |
---|
524 | IF ( istage == 1 ) THEN |
---|
525 | Fcn(1:VL,1:N) = Fcn0(1:VL,1:N) |
---|
526 | ! istage>1 and a new function evaluation is needed at the current istage |
---|
527 | ELSEIF ( ros_NewF(istage) ) THEN |
---|
528 | Ynew(1:VL,1:N) = Y(1:VL,1:N) |
---|
529 | DO j = 1, istage-1 |
---|
530 | ! ros_v = ros_A((istage-1)*(istage-2)/2+j) |
---|
531 | ! CALL WAXPY(N,ros_v,K(:,N*(j-1)+1:N*(j-1)+N),1,Ynew,1) |
---|
532 | Ynew(1:vl,1:N) = Ynew(1:vl,1:N)+ros_A((istage-1)*(istage-2)/2+j)*K(1:VL,N*(j-1)+1:N*(j-1)+N) |
---|
533 | END DO |
---|
534 | Tau = T + ros_Alpha(istage)*Direction*H |
---|
535 | CALL FunTemplate(Tau,Ynew,Fcn) |
---|
536 | ISTATUS(Nfun) = ISTATUS(Nfun) + 1 |
---|
537 | END IF ! if istage == 1 elseif ros_NewF(istage) |
---|
538 | K(1:VL,ioffset+1:ioffset+N) = Fcn(1:VL,1:N) |
---|
539 | DO j = 1, istage-1 |
---|
540 | HC(1:vl) = ros_C((istage-1)*(istage-2)/2+j)/(Direction*H(1:vl)) |
---|
541 | ! CALL WAXPY(N,HC,K(:,N*(j-1)+1:N*(j-1)+N),1,K(:,ioffset+1:ioffset+n),1) |
---|
542 | DO i=1,N |
---|
543 | K(1:vl,ioffset+i) = K(1:vl,ioffset+i) + HC(1:vl)*K(1:vl,N*(j-1)+i) |
---|
544 | END DO |
---|
545 | |
---|
546 | END DO |
---|
547 | IF ((.NOT. Autonomous).AND.(ros_Gamma(istage).NE.ZERO)) THEN |
---|
548 | HG(1:vl) = Direction*H(1:vl)*ros_Gamma(istage) |
---|
549 | CALL WAXPY(N,HG,dFdT,1,K(:,ioffset+1:ioffset+n),1) |
---|
550 | END IF |
---|
551 | |
---|
552 | CALL ros_Solve(Ghimj, K(:,ioffset+1:ioffset+n)) |
---|
553 | |
---|
554 | END DO Stage |
---|
555 | |
---|
556 | |
---|
557 | !~~~> Compute the new solution |
---|
558 | Ynew(1:vl,1:N) = Y(1:vl,1:N) |
---|
559 | DO j=1,ros_S |
---|
560 | ros_v = ros_M(j) |
---|
561 | CALL WAXPY(N,ros_v,K(:,N*(j-1)+1:),1,Ynew,1) |
---|
562 | END DO |
---|
563 | |
---|
564 | !~~~> Compute the error estimation |
---|
565 | Yerr(1:vl,1:N) = ZERO |
---|
566 | DO j=1,ros_S |
---|
567 | ros_v = ros_E(j) |
---|
568 | CALL WAXPY(N,ros_v,K(:,N*(j-1)+1:N*(j-1)+N),1,Yerr,1) |
---|
569 | END DO |
---|
570 | Err(1:VL) = ros_ErrorNorm ( Y, Ynew, Yerr, AbsTol, RelTol, VectorTol ) |
---|
571 | |
---|
572 | !~~~> New step size is bounded by FacMin <= Hnew/H <= FacMax |
---|
573 | Fac(1:vl) = MIN(FacMax,MAX(FacMin,FacSafe/Err(1:vl)**(ONE/ros_ELO))) |
---|
574 | Hnew(1:vl) = H(1:vl)*Fac(1:vl) |
---|
575 | |
---|
576 | !~~~> Check the error magnitude and adjust step size |
---|
577 | ISTATUS(Nstp) = ISTATUS(Nstp) + 1 |
---|
578 | ! write(9,*) 'Hmin ',Hmin,Hmax |
---|
579 | do i=1,VL |
---|
580 | IF(Accept_step(i)) then |
---|
581 | Ynew(i,:) = Ynew_save(i,:) |
---|
582 | Hnew(i) = Hnew_save(i) |
---|
583 | ELSE IF ( (Err(i) <= ONE).OR.(H(i) <= Hmin) ) THEN !~~~> Accept step |
---|
584 | ISTATUS(Nacc) = ISTATUS(Nacc) + 1 |
---|
585 | Y(i,1:N) = Ynew(i,1:N) |
---|
586 | T(i) = T(i) + Direction*H(i) |
---|
587 | Hnew(i) = MAX(Hmin,MIN(Hnew(i),Hmax)) |
---|
588 | IF (RejectLastH(i)) THEN ! No step size increase after a rejected step |
---|
589 | Hnew(i) = MIN(Hnew(i),H(i)) |
---|
590 | END IF |
---|
591 | RSTATUS(Nhexit) = H(i) ! ueberdenken |
---|
592 | RSTATUS(Nhnew) = Hnew(i) |
---|
593 | RSTATUS(Ntexit) = T(i) ! ueberdenken ende |
---|
594 | RejectLastH(i) = .FALSE. |
---|
595 | RejectMoreH(i) = .FALSE. |
---|
596 | H(i) = Hnew(i) |
---|
597 | |
---|
598 | Accept_step(i) = .TRUE. ! EXIT THE LOOP: WHILE STEP NOT ACCEPTED |
---|
599 | Kacc(i) = Kacc(i) +1 |
---|
600 | ELSE !~~~> Reject step |
---|
601 | IF (RejectMoreH(i)) THEN |
---|
602 | Hnew (i)= H(i)*FacRej |
---|
603 | END IF |
---|
604 | RejectMoreH(i) = RejectLastH(i) |
---|
605 | RejectLastH(i) = .TRUE. |
---|
606 | H(i) = Hnew(i) |
---|
607 | |
---|
608 | IF (ISTATUS(Nacc) >= 1) ISTATUS(Nrej) = ISTATUS(Nrej) + 1 |
---|
609 | Krej(i) = Krej(i)+1 |
---|
610 | |
---|
611 | END IF ! Err <= 1 |
---|
612 | END DO |
---|
613 | if(all(Accept_step(1:VL))) EXIT |
---|
614 | |
---|
615 | do i=1,VL |
---|
616 | IF(Accept_step(i)) then |
---|
617 | if(.not. y_copied(i)) then |
---|
618 | y_save(i,:) = y(i,:) |
---|
619 | Ynew_save(i,:) = Ynew(i,:) |
---|
620 | Hnew_save(i) = Hnew(i) |
---|
621 | y_copied(i) = .TRUE. |
---|
622 | end if |
---|
623 | end if |
---|
624 | end do |
---|
625 | |
---|
626 | |
---|
627 | END DO UntilAccepted |
---|
628 | |
---|
629 | do i=1,VL |
---|
630 | if(y_copied(i)) then |
---|
631 | y(i,:) = y_save(i,:) |
---|
632 | end if |
---|
633 | end do |
---|
634 | |
---|
635 | END DO TimeLoop |
---|
636 | |
---|
637 | call kco_finalize (y, IERRV, Kacc, Krej) |
---|
638 | |
---|
639 | VL = VL_save |
---|
640 | |
---|
641 | !~~~> Succesful exit |
---|
642 | IERR_out = 1 !~~~> The integration was successful |
---|
643 | |
---|
644 | lfirst = .FALSE. |
---|
645 | |
---|
646 | END SUBROUTINE ros_Integrator |
---|
647 | |
---|
648 | |
---|
649 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
650 | FUNCTION ros_ErrorNorm ( Y, Ynew, Yerr, & |
---|
651 | AbsTol, RelTol, VectorTol ) |
---|
652 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
653 | !~~~> Computes the "scaled norm" of the error vector Yerr |
---|
654 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
655 | IMPLICIT NONE |
---|
656 | |
---|
657 | ! Input arguments |
---|
658 | REAL(kind=dp), INTENT(IN) :: Y(:,:), Ynew(:,:), & |
---|
659 | Yerr(:,:), AbsTol(N), RelTol(N) |
---|
660 | LOGICAL, INTENT(IN) :: VectorTol |
---|
661 | ! Local variables |
---|
662 | REAL(kind=dp), dimension(VL) :: Err, Scale, Ymax |
---|
663 | INTEGER :: i,j |
---|
664 | REAL(kind=dp), PARAMETER :: ZERO = 0.0_dp |
---|
665 | REAL(kind=dp), dimension(VL) :: ros_ErrorNorm |
---|
666 | |
---|
667 | Err = ZERO |
---|
668 | DO i=1,NVAR |
---|
669 | do j=1,VL |
---|
670 | Ymax(j) = MAX( ABS(Y(j,i)),ABS(Ynew(j,i))) |
---|
671 | IF (VectorTol) THEN |
---|
672 | Scale(j) = AbsTol(i)+ RelTol(i)*Ymax(j) |
---|
673 | ELSE |
---|
674 | Scale(j) = AbsTol(1)+ RelTol(1)*Ymax(1) |
---|
675 | END IF |
---|
676 | Err(j) = Err(j)+ (Yerr(j,i)/Scale(j))**2 |
---|
677 | end do |
---|
678 | END DO |
---|
679 | Err = SQRT(Err/N) |
---|
680 | |
---|
681 | ros_ErrorNorm = max(err, 1.0d-10) |
---|
682 | |
---|
683 | END FUNCTION ros_ErrorNorm |
---|
684 | |
---|
685 | |
---|
686 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
687 | SUBROUTINE ros_FunTimeDerivative ( T, Roundoff, Y, & |
---|
688 | Fcn0, dFdT ) |
---|
689 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
690 | !~~~> The time partial derivative of the function by finite differences |
---|
691 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
692 | IMPLICIT NONE |
---|
693 | |
---|
694 | !~~~> Input arguments |
---|
695 | REAL(kind=dp), INTENT(IN) :: T(:), Roundoff, Y(:,:), Fcn0(:,:) |
---|
696 | !~~~> Output arguments |
---|
697 | REAL(kind=dp), INTENT(OUT) :: dFdT(:,:) |
---|
698 | !~~~> Local variables |
---|
699 | REAL(kind=dp) :: Delta(1:vl_dim),one_v(1:vl_dim) |
---|
700 | REAL(kind=dp), PARAMETER :: ONE = 1.0_dp, DeltaMin = 1.0E-6_dp |
---|
701 | INTEGER :: i |
---|
702 | |
---|
703 | Delta(1:vl) = SQRT(Roundoff)*MAX(DeltaMin,ABS(T(1:vl))) |
---|
704 | CALL FunTemplate(T(1:vl)+Delta(1:vl),Y,dFdT) |
---|
705 | ISTATUS(Nfun) = ISTATUS(Nfun) + 1 |
---|
706 | one_v = -ONE |
---|
707 | CALL WAXPY(N,one_v,Fcn0,1,dFdT,1) |
---|
708 | ! CALL WSCAL(N,(ONE/Delta),dFdT,1) |
---|
709 | do i=1,size(dFdT,2) |
---|
710 | dFdT(1:vl,i) = 1.0_dp/Delta(1:vl)*dFdT(1:vl,i) |
---|
711 | end do |
---|
712 | |
---|
713 | END SUBROUTINE ros_FunTimeDerivative |
---|
714 | |
---|
715 | |
---|
716 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
717 | SUBROUTINE ros_PrepareMatrix ( H, Direction, gam, & |
---|
718 | Jac0, Ghimj, Pivot, Singular ) |
---|
719 | ! --- --- --- --- --- --- --- --- --- --- --- --- --- |
---|
720 | ! Prepares the LHS matrix for stage calculations |
---|
721 | ! 1. Construct Ghimj = 1/(H*ham) - Jac0 |
---|
722 | ! "(Gamma H) Inverse Minus Jacobian" |
---|
723 | ! 2. Repeat LU decomposition of Ghimj until successful. |
---|
724 | ! -half the step size if LU decomposition fails and retry |
---|
725 | ! -exit after 5 consecutive fails |
---|
726 | ! --- --- --- --- --- --- --- --- --- --- --- --- --- |
---|
727 | IMPLICIT NONE |
---|
728 | |
---|
729 | !~~~> Input arguments |
---|
730 | REAL(kind=dp), INTENT(IN) :: Jac0(:,:) |
---|
731 | REAL(kind=dp), INTENT(IN) :: gam |
---|
732 | INTEGER, INTENT(IN) :: Direction |
---|
733 | !~~~> Output arguments |
---|
734 | REAL(kind=dp), INTENT(OUT) :: Ghimj(:,:) |
---|
735 | |
---|
736 | LOGICAL, INTENT(OUT) :: Singular |
---|
737 | INTEGER, INTENT(OUT) :: Pivot(N) |
---|
738 | !~~~> Inout arguments |
---|
739 | REAL(kind=dp), INTENT(INOUT) :: H(:) ! step size is decreased when LU fails |
---|
740 | !~~~> Local variables |
---|
741 | INTEGER :: i, ISING, Nconsecutive |
---|
742 | REAL(kind=dp) :: ghinv(1:VL) |
---|
743 | REAL(kind=dp), PARAMETER :: ONE = 1.0_dp, HALF = 0.5_dp |
---|
744 | |
---|
745 | Nconsecutive = 0 |
---|
746 | Singular = .FALSE. |
---|
747 | |
---|
748 | !kk DO WHILE (Singular) !test of Singular currently disabled |
---|
749 | |
---|
750 | !~~~> Construct Ghimj = 1/(H*gam) - Jac0 |
---|
751 | Ghimj(1:VL,1:LU_NONZERO) = -JAC0(1:VL,1:LU_NONZERO) |
---|
752 | ghinv(1:VL) = 1.0_dp/(H(1:VL)*gam) |
---|
753 | DO i=1,N |
---|
754 | Ghimj(1:VL,LU_DIAG(i)) = Ghimj(1:VL,LU_DIAG(i))+ghinv(1:VL) |
---|
755 | END DO |
---|
756 | |
---|
757 | !~~~> Compute LU decomposition |
---|
758 | CALL KppDecomp( Ghimj, ising ) |
---|
759 | |
---|
760 | !kk Original code, implement singular check if necessary |
---|
761 | !!~~~> Compute LU decomposition |
---|
762 | ! CALL ros_Decomp( Ghimj, Pivot, ISING ) |
---|
763 | ! IF (ISING == 0) THEN |
---|
764 | !!~~~> If successful done |
---|
765 | ! Singular = .FALSE. |
---|
766 | ! ELSE ! ISING .ne. 0 |
---|
767 | !!~~~> If unsuccessful half the step size; if 5 consecutive fails then return |
---|
768 | ! ISTATUS(Nsng) = ISTATUS(Nsng) + 1 |
---|
769 | ! Nconsecutive = Nconsecutive+1 |
---|
770 | ! Singular = .TRUE. |
---|
771 | ! PRINT*,'Warning: LU Decomposition returned ISING = ',ISING |
---|
772 | ! IF (Nconsecutive <= 5) THEN ! Less than 5 consecutive failed decompositions |
---|
773 | ! H = H*HALF |
---|
774 | ! ELSE ! More than 5 consecutive failed decompositions |
---|
775 | ! RETURN |
---|
776 | ! END IF ! Nconsecutive |
---|
777 | ! END IF ! ISING |
---|
778 | |
---|
779 | ! END DO ! WHILE Singular |
---|
780 | |
---|
781 | Pivot = 0 !Set to avoid compiler warnings |
---|
782 | |
---|
783 | END SUBROUTINE ros_PrepareMatrix |
---|
784 | |
---|
785 | |
---|
786 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
787 | ! SUBROUTINE ros_Decomp( A, Pivot, ISING ) |
---|
788 | !!~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
789 | !! Template for the LU decomposition |
---|
790 | !!~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
791 | ! IMPLICIT NONE |
---|
792 | !!~~~> Inout variables |
---|
793 | !#ifdef FULL_ALGEBRA |
---|
794 | ! REAL(kind=dp), INTENT(INOUT) :: A(N,N) |
---|
795 | !#else |
---|
796 | ! REAL(kind=dp), INTENT(INOUT) :: A(LU_NONZERO) |
---|
797 | !#endif |
---|
798 | !!~~~> Output variables |
---|
799 | ! INTEGER, INTENT(OUT) :: Pivot(N), ISING |
---|
800 | ! |
---|
801 | !#ifdef FULL_ALGEBRA |
---|
802 | ! CALL DGETRF( N, N, A, N, Pivot, ISING ) |
---|
803 | !#else |
---|
804 | ! CALL KppDecomp ( A, ISING ) |
---|
805 | ! Pivot(1) = 1 |
---|
806 | !#endif |
---|
807 | ! ISTATUS(Ndec) = ISTATUS(Ndec) + 1 |
---|
808 | ! |
---|
809 | ! END SUBROUTINE ros_Decomp |
---|
810 | |
---|
811 | |
---|
812 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
813 | SUBROUTINE ros_Solve( A, b ) |
---|
814 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
815 | ! Template for the forward/backward substitution (using pre-computed LU decomposition) |
---|
816 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
817 | IMPLICIT NONE |
---|
818 | !~~~> Input variables |
---|
819 | REAL(kind=dp), INTENT(IN) :: A(:,:) |
---|
820 | !~~~> InOut variables |
---|
821 | REAL(kind=dp), INTENT(INOUT) :: b(:,:) |
---|
822 | |
---|
823 | CALL KppSolve( A, b ) |
---|
824 | |
---|
825 | ISTATUS(Nsol) = ISTATUS(Nsol) + VL |
---|
826 | |
---|
827 | END SUBROUTINE ros_Solve |
---|
828 | |
---|
829 | |
---|
830 | |
---|
831 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
832 | SUBROUTINE Ros2 |
---|
833 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
834 | ! --- AN L-STABLE METHOD, 2 stages, order 2 |
---|
835 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
836 | |
---|
837 | IMPLICIT NONE |
---|
838 | DOUBLE PRECISION g |
---|
839 | |
---|
840 | g = 1.0_dp + 1.0_dp/SQRT(2.0_dp) |
---|
841 | rosMethod = RS2 |
---|
842 | !~~~> Name of the method |
---|
843 | ros_Name = 'ROS-2' |
---|
844 | !~~~> Number of stages |
---|
845 | ros_S = 2 |
---|
846 | |
---|
847 | !~~~> The coefficient matrices A and C are strictly lower triangular. |
---|
848 | ! The lower triangular (subdiagonal) elements are stored in row-wise order: |
---|
849 | ! A(2,1) = ros_A(1), A(3,1)=ros_A(2), A(3,2)=ros_A(3), etc. |
---|
850 | ! The general mapping formula is: |
---|
851 | ! A(i,j) = ros_A( (i-1)*(i-2)/2 + j ) |
---|
852 | ! C(i,j) = ros_C( (i-1)*(i-2)/2 + j ) |
---|
853 | |
---|
854 | ros_A(1) = (1.0_dp)/g |
---|
855 | ros_C(1) = (-2.0_dp)/g |
---|
856 | !~~~> Does the stage i require a new function evaluation (ros_NewF(i)=TRUE) |
---|
857 | ! or does it re-use the function evaluation from stage i-1 (ros_NewF(i)=FALSE) |
---|
858 | ros_NewF(1) = .TRUE. |
---|
859 | ros_NewF(2) = .TRUE. |
---|
860 | !~~~> M_i = Coefficients for new step solution |
---|
861 | ros_M(1)= (3.0_dp)/(2.0_dp*g) |
---|
862 | ros_M(2)= (1.0_dp)/(2.0_dp*g) |
---|
863 | ! E_i = Coefficients for error estimator |
---|
864 | ros_E(1) = 1.0_dp/(2.0_dp*g) |
---|
865 | ros_E(2) = 1.0_dp/(2.0_dp*g) |
---|
866 | !~~~> ros_ELO = estimator of local order - the minimum between the |
---|
867 | ! main and the embedded scheme orders plus one |
---|
868 | ros_ELO = 2.0_dp |
---|
869 | !~~~> Y_stage_i ~ Y( T + H*Alpha_i ) |
---|
870 | ros_Alpha(1) = 0.0_dp |
---|
871 | ros_Alpha(2) = 1.0_dp |
---|
872 | !~~~> Gamma_i = \sum_j gamma_{i,j} |
---|
873 | ros_Gamma(1) = g |
---|
874 | ros_Gamma(2) =-g |
---|
875 | |
---|
876 | END SUBROUTINE Ros2 |
---|
877 | |
---|
878 | |
---|
879 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
880 | SUBROUTINE Ros3 |
---|
881 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
882 | ! --- AN L-STABLE METHOD, 3 stages, order 3, 2 function evaluations |
---|
883 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
884 | |
---|
885 | IMPLICIT NONE |
---|
886 | rosMethod = RS3 |
---|
887 | !~~~> Name of the method |
---|
888 | ros_Name = 'ROS-3' |
---|
889 | !~~~> Number of stages |
---|
890 | ros_S = 3 |
---|
891 | |
---|
892 | !~~~> The coefficient matrices A and C are strictly lower triangular. |
---|
893 | ! The lower triangular (subdiagonal) elements are stored in row-wise order: |
---|
894 | ! A(2,1) = ros_A(1), A(3,1)=ros_A(2), A(3,2)=ros_A(3), etc. |
---|
895 | ! The general mapping formula is: |
---|
896 | ! A(i,j) = ros_A( (i-1)*(i-2)/2 + j ) |
---|
897 | ! C(i,j) = ros_C( (i-1)*(i-2)/2 + j ) |
---|
898 | |
---|
899 | ros_A(1)= 1.0_dp |
---|
900 | ros_A(2)= 1.0_dp |
---|
901 | ros_A(3)= 0.0_dp |
---|
902 | |
---|
903 | ros_C(1) = -0.10156171083877702091975600115545E+01_dp |
---|
904 | ros_C(2) = 0.40759956452537699824805835358067E+01_dp |
---|
905 | ros_C(3) = 0.92076794298330791242156818474003E+01_dp |
---|
906 | !~~~> Does the stage i require a new function evaluation (ros_NewF(i)=TRUE) |
---|
907 | ! or does it re-use the function evaluation from stage i-1 (ros_NewF(i)=FALSE) |
---|
908 | ros_NewF(1) = .TRUE. |
---|
909 | ros_NewF(2) = .TRUE. |
---|
910 | ros_NewF(3) = .FALSE. |
---|
911 | !~~~> M_i = Coefficients for new step solution |
---|
912 | ros_M(1) = 0.1E+01_dp |
---|
913 | ros_M(2) = 0.61697947043828245592553615689730E+01_dp |
---|
914 | ros_M(3) = -0.42772256543218573326238373806514_dp |
---|
915 | ! E_i = Coefficients for error estimator |
---|
916 | ros_E(1) = 0.5_dp |
---|
917 | ros_E(2) = -0.29079558716805469821718236208017E+01_dp |
---|
918 | ros_E(3) = 0.22354069897811569627360909276199_dp |
---|
919 | !~~~> ros_ELO = estimator of local order - the minimum between the |
---|
920 | ! main and the embedded scheme orders plus 1 |
---|
921 | ros_ELO = 3.0_dp |
---|
922 | !~~~> Y_stage_i ~ Y( T + H*Alpha_i ) |
---|
923 | ros_Alpha(1)= 0.0_dp |
---|
924 | ros_Alpha(2)= 0.43586652150845899941601945119356_dp |
---|
925 | ros_Alpha(3)= 0.43586652150845899941601945119356_dp |
---|
926 | !~~~> Gamma_i = \sum_j gamma_{i,j} |
---|
927 | ros_Gamma(1)= 0.43586652150845899941601945119356_dp |
---|
928 | ros_Gamma(2)= 0.24291996454816804366592249683314_dp |
---|
929 | ros_Gamma(3)= 0.21851380027664058511513169485832E+01_dp |
---|
930 | |
---|
931 | END SUBROUTINE Ros3 |
---|
932 | |
---|
933 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
934 | |
---|
935 | |
---|
936 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
937 | SUBROUTINE Ros4 |
---|
938 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
939 | ! L-STABLE ROSENBROCK METHOD OF ORDER 4, WITH 4 STAGES |
---|
940 | ! L-STABLE EMBEDDED ROSENBROCK METHOD OF ORDER 3 |
---|
941 | ! |
---|
942 | ! E. HAIRER AND G. WANNER, SOLVING ORDINARY DIFFERENTIAL |
---|
943 | ! EQUATIONS II. STIFF AND DIFFERENTIAL-ALGEBRAIC PROBLEMS. |
---|
944 | ! SPRINGER SERIES IN COMPUTATIONAL MATHEMATICS, |
---|
945 | ! SPRINGER-VERLAG (1990) |
---|
946 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
947 | |
---|
948 | IMPLICIT NONE |
---|
949 | |
---|
950 | rosMethod = RS4 |
---|
951 | !~~~> Name of the method |
---|
952 | ros_Name = 'ROS-4' |
---|
953 | !~~~> Number of stages |
---|
954 | ros_S = 4 |
---|
955 | |
---|
956 | !~~~> The coefficient matrices A and C are strictly lower triangular. |
---|
957 | ! The lower triangular (subdiagonal) elements are stored in row-wise order: |
---|
958 | ! A(2,1) = ros_A(1), A(3,1)=ros_A(2), A(3,2)=ros_A(3), etc. |
---|
959 | ! The general mapping formula is: |
---|
960 | ! A(i,j) = ros_A( (i-1)*(i-2)/2 + j ) |
---|
961 | ! C(i,j) = ros_C( (i-1)*(i-2)/2 + j ) |
---|
962 | |
---|
963 | ros_A(1) = 0.2000000000000000E+01_dp |
---|
964 | ros_A(2) = 0.1867943637803922E+01_dp |
---|
965 | ros_A(3) = 0.2344449711399156_dp |
---|
966 | ros_A(4) = ros_A(2) |
---|
967 | ros_A(5) = ros_A(3) |
---|
968 | ros_A(6) = 0.0_dp |
---|
969 | |
---|
970 | ros_C(1) =-0.7137615036412310E+01_dp |
---|
971 | ros_C(2) = 0.2580708087951457E+01_dp |
---|
972 | ros_C(3) = 0.6515950076447975_dp |
---|
973 | ros_C(4) =-0.2137148994382534E+01_dp |
---|
974 | ros_C(5) =-0.3214669691237626_dp |
---|
975 | ros_C(6) =-0.6949742501781779_dp |
---|
976 | !~~~> Does the stage i require a new function evaluation (ros_NewF(i)=TRUE) |
---|
977 | ! or does it re-use the function evaluation from stage i-1 (ros_NewF(i)=FALSE) |
---|
978 | ros_NewF(1) = .TRUE. |
---|
979 | ros_NewF(2) = .TRUE. |
---|
980 | ros_NewF(3) = .TRUE. |
---|
981 | ros_NewF(4) = .FALSE. |
---|
982 | !~~~> M_i = Coefficients for new step solution |
---|
983 | ros_M(1) = 0.2255570073418735E+01_dp |
---|
984 | ros_M(2) = 0.2870493262186792_dp |
---|
985 | ros_M(3) = 0.4353179431840180_dp |
---|
986 | ros_M(4) = 0.1093502252409163E+01_dp |
---|
987 | !~~~> E_i = Coefficients for error estimator |
---|
988 | ros_E(1) =-0.2815431932141155_dp |
---|
989 | ros_E(2) =-0.7276199124938920E-01_dp |
---|
990 | ros_E(3) =-0.1082196201495311_dp |
---|
991 | ros_E(4) =-0.1093502252409163E+01_dp |
---|
992 | !~~~> ros_ELO = estimator of local order - the minimum between the |
---|
993 | ! main and the embedded scheme orders plus 1 |
---|
994 | ros_ELO = 4.0_dp |
---|
995 | !~~~> Y_stage_i ~ Y( T + H*Alpha_i ) |
---|
996 | ros_Alpha(1) = 0.0_dp |
---|
997 | ros_Alpha(2) = 0.1145640000000000E+01_dp |
---|
998 | ros_Alpha(3) = 0.6552168638155900_dp |
---|
999 | ros_Alpha(4) = ros_Alpha(3) |
---|
1000 | !~~~> Gamma_i = \sum_j gamma_{i,j} |
---|
1001 | ros_Gamma(1) = 0.5728200000000000_dp |
---|
1002 | ros_Gamma(2) =-0.1769193891319233E+01_dp |
---|
1003 | ros_Gamma(3) = 0.7592633437920482_dp |
---|
1004 | ros_Gamma(4) =-0.1049021087100450_dp |
---|
1005 | |
---|
1006 | END SUBROUTINE Ros4 |
---|
1007 | |
---|
1008 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1009 | SUBROUTINE Rodas3 |
---|
1010 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1011 | ! --- A STIFFLY-STABLE METHOD, 4 stages, order 3 |
---|
1012 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1013 | |
---|
1014 | IMPLICIT NONE |
---|
1015 | |
---|
1016 | rosMethod = RD3 |
---|
1017 | !~~~> Name of the method |
---|
1018 | ros_Name = 'RODAS-3' |
---|
1019 | !~~~> Number of stages |
---|
1020 | ros_S = 4 |
---|
1021 | |
---|
1022 | !~~~> The coefficient matrices A and C are strictly lower triangular. |
---|
1023 | ! The lower triangular (subdiagonal) elements are stored in row-wise order: |
---|
1024 | ! A(2,1) = ros_A(1), A(3,1)=ros_A(2), A(3,2)=ros_A(3), etc. |
---|
1025 | ! The general mapping formula is: |
---|
1026 | ! A(i,j) = ros_A( (i-1)*(i-2)/2 + j ) |
---|
1027 | ! C(i,j) = ros_C( (i-1)*(i-2)/2 + j ) |
---|
1028 | |
---|
1029 | ros_A(1) = 0.0_dp |
---|
1030 | ros_A(2) = 2.0_dp |
---|
1031 | ros_A(3) = 0.0_dp |
---|
1032 | ros_A(4) = 2.0_dp |
---|
1033 | ros_A(5) = 0.0_dp |
---|
1034 | ros_A(6) = 1.0_dp |
---|
1035 | |
---|
1036 | ros_C(1) = 4.0_dp |
---|
1037 | ros_C(2) = 1.0_dp |
---|
1038 | ros_C(3) =-1.0_dp |
---|
1039 | ros_C(4) = 1.0_dp |
---|
1040 | ros_C(5) =-1.0_dp |
---|
1041 | ros_C(6) =-(8.0_dp/3.0_dp) |
---|
1042 | |
---|
1043 | !~~~> Does the stage i require a new function evaluation (ros_NewF(i)=TRUE) |
---|
1044 | ! or does it re-use the function evaluation from stage i-1 (ros_NewF(i)=FALSE) |
---|
1045 | ros_NewF(1) = .TRUE. |
---|
1046 | ros_NewF(2) = .FALSE. |
---|
1047 | ros_NewF(3) = .TRUE. |
---|
1048 | ros_NewF(4) = .TRUE. |
---|
1049 | !~~~> M_i = Coefficients for new step solution |
---|
1050 | ros_M(1) = 2.0_dp |
---|
1051 | ros_M(2) = 0.0_dp |
---|
1052 | ros_M(3) = 1.0_dp |
---|
1053 | ros_M(4) = 1.0_dp |
---|
1054 | !~~~> E_i = Coefficients for error estimator |
---|
1055 | ros_E(1) = 0.0_dp |
---|
1056 | ros_E(2) = 0.0_dp |
---|
1057 | ros_E(3) = 0.0_dp |
---|
1058 | ros_E(4) = 1.0_dp |
---|
1059 | !~~~> ros_ELO = estimator of local order - the minimum between the |
---|
1060 | ! main and the embedded scheme orders plus 1 |
---|
1061 | ros_ELO = 3.0_dp |
---|
1062 | !~~~> Y_stage_i ~ Y( T + H*Alpha_i ) |
---|
1063 | ros_Alpha(1) = 0.0_dp |
---|
1064 | ros_Alpha(2) = 0.0_dp |
---|
1065 | ros_Alpha(3) = 1.0_dp |
---|
1066 | ros_Alpha(4) = 1.0_dp |
---|
1067 | !~~~> Gamma_i = \sum_j gamma_{i,j} |
---|
1068 | ros_Gamma(1) = 0.5_dp |
---|
1069 | ros_Gamma(2) = 1.5_dp |
---|
1070 | ros_Gamma(3) = 0.0_dp |
---|
1071 | ros_Gamma(4) = 0.0_dp |
---|
1072 | |
---|
1073 | END SUBROUTINE Rodas3 |
---|
1074 | |
---|
1075 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1076 | SUBROUTINE Rodas4 |
---|
1077 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1078 | ! STIFFLY-STABLE ROSENBROCK METHOD OF ORDER 4, WITH 6 STAGES |
---|
1079 | ! |
---|
1080 | ! E. HAIRER AND G. WANNER, SOLVING ORDINARY DIFFERENTIAL |
---|
1081 | ! EQUATIONS II. STIFF AND DIFFERENTIAL-ALGEBRAIC PROBLEMS. |
---|
1082 | ! SPRINGER SERIES IN COMPUTATIONAL MATHEMATICS, |
---|
1083 | ! SPRINGER-VERLAG (1996) |
---|
1084 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1085 | |
---|
1086 | IMPLICIT NONE |
---|
1087 | |
---|
1088 | rosMethod = RD4 |
---|
1089 | !~~~> Name of the method |
---|
1090 | ros_Name = 'RODAS-4' |
---|
1091 | !~~~> Number of stages |
---|
1092 | ros_S = 6 |
---|
1093 | |
---|
1094 | !~~~> Y_stage_i ~ Y( T + H*Alpha_i ) |
---|
1095 | ros_Alpha(1) = 0.000_dp |
---|
1096 | ros_Alpha(2) = 0.386_dp |
---|
1097 | ros_Alpha(3) = 0.210_dp |
---|
1098 | ros_Alpha(4) = 0.630_dp |
---|
1099 | ros_Alpha(5) = 1.000_dp |
---|
1100 | ros_Alpha(6) = 1.000_dp |
---|
1101 | |
---|
1102 | !~~~> Gamma_i = \sum_j gamma_{i,j} |
---|
1103 | ros_Gamma(1) = 0.2500000000000000_dp |
---|
1104 | ros_Gamma(2) =-0.1043000000000000_dp |
---|
1105 | ros_Gamma(3) = 0.1035000000000000_dp |
---|
1106 | ros_Gamma(4) =-0.3620000000000023E-01_dp |
---|
1107 | ros_Gamma(5) = 0.0_dp |
---|
1108 | ros_Gamma(6) = 0.0_dp |
---|
1109 | |
---|
1110 | !~~~> The coefficient matrices A and C are strictly lower triangular. |
---|
1111 | ! The lower triangular (subdiagonal) elements are stored in row-wise order: |
---|
1112 | ! A(2,1) = ros_A(1), A(3,1)=ros_A(2), A(3,2)=ros_A(3), etc. |
---|
1113 | ! The general mapping formula is: A(i,j) = ros_A( (i-1)*(i-2)/2 + j ) |
---|
1114 | ! C(i,j) = ros_C( (i-1)*(i-2)/2 + j ) |
---|
1115 | |
---|
1116 | ros_A(1) = 0.1544000000000000E+01_dp |
---|
1117 | ros_A(2) = 0.9466785280815826_dp |
---|
1118 | ros_A(3) = 0.2557011698983284_dp |
---|
1119 | ros_A(4) = 0.3314825187068521E+01_dp |
---|
1120 | ros_A(5) = 0.2896124015972201E+01_dp |
---|
1121 | ros_A(6) = 0.9986419139977817_dp |
---|
1122 | ros_A(7) = 0.1221224509226641E+01_dp |
---|
1123 | ros_A(8) = 0.6019134481288629E+01_dp |
---|
1124 | ros_A(9) = 0.1253708332932087E+02_dp |
---|
1125 | ros_A(10) =-0.6878860361058950_dp |
---|
1126 | ros_A(11) = ros_A(7) |
---|
1127 | ros_A(12) = ros_A(8) |
---|
1128 | ros_A(13) = ros_A(9) |
---|
1129 | ros_A(14) = ros_A(10) |
---|
1130 | ros_A(15) = 1.0_dp |
---|
1131 | |
---|
1132 | ros_C(1) =-0.5668800000000000E+01_dp |
---|
1133 | ros_C(2) =-0.2430093356833875E+01_dp |
---|
1134 | ros_C(3) =-0.2063599157091915_dp |
---|
1135 | ros_C(4) =-0.1073529058151375_dp |
---|
1136 | ros_C(5) =-0.9594562251023355E+01_dp |
---|
1137 | ros_C(6) =-0.2047028614809616E+02_dp |
---|
1138 | ros_C(7) = 0.7496443313967647E+01_dp |
---|
1139 | ros_C(8) =-0.1024680431464352E+02_dp |
---|
1140 | ros_C(9) =-0.3399990352819905E+02_dp |
---|
1141 | ros_C(10) = 0.1170890893206160E+02_dp |
---|
1142 | ros_C(11) = 0.8083246795921522E+01_dp |
---|
1143 | ros_C(12) =-0.7981132988064893E+01_dp |
---|
1144 | ros_C(13) =-0.3152159432874371E+02_dp |
---|
1145 | ros_C(14) = 0.1631930543123136E+02_dp |
---|
1146 | ros_C(15) =-0.6058818238834054E+01_dp |
---|
1147 | |
---|
1148 | !~~~> M_i = Coefficients for new step solution |
---|
1149 | ros_M(1) = ros_A(7) |
---|
1150 | ros_M(2) = ros_A(8) |
---|
1151 | ros_M(3) = ros_A(9) |
---|
1152 | ros_M(4) = ros_A(10) |
---|
1153 | ros_M(5) = 1.0_dp |
---|
1154 | ros_M(6) = 1.0_dp |
---|
1155 | |
---|
1156 | !~~~> E_i = Coefficients for error estimator |
---|
1157 | ros_E(1) = 0.0_dp |
---|
1158 | ros_E(2) = 0.0_dp |
---|
1159 | ros_E(3) = 0.0_dp |
---|
1160 | ros_E(4) = 0.0_dp |
---|
1161 | ros_E(5) = 0.0_dp |
---|
1162 | ros_E(6) = 1.0_dp |
---|
1163 | |
---|
1164 | !~~~> Does the stage i require a new function evaluation (ros_NewF(i)=TRUE) |
---|
1165 | ! or does it re-use the function evaluation from stage i-1 (ros_NewF(i)=FALSE) |
---|
1166 | ros_NewF(1) = .TRUE. |
---|
1167 | ros_NewF(2) = .TRUE. |
---|
1168 | ros_NewF(3) = .TRUE. |
---|
1169 | ros_NewF(4) = .TRUE. |
---|
1170 | ros_NewF(5) = .TRUE. |
---|
1171 | ros_NewF(6) = .TRUE. |
---|
1172 | |
---|
1173 | !~~~> ros_ELO = estimator of local order - the minimum between the |
---|
1174 | ! main and the embedded scheme orders plus 1 |
---|
1175 | ros_ELO = 4.0_dp |
---|
1176 | |
---|
1177 | END SUBROUTINE Rodas4 |
---|
1178 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1179 | SUBROUTINE Rang3 |
---|
1180 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1181 | ! STIFFLY-STABLE W METHOD OF ORDER 3, WITH 4 STAGES |
---|
1182 | ! |
---|
1183 | ! J. RANG and L. ANGERMANN |
---|
1184 | ! NEW ROSENBROCK W-METHODS OF ORDER 3 |
---|
1185 | ! FOR PARTIAL DIFFERENTIAL ALGEBRAIC |
---|
1186 | ! EQUATIONS OF INDEX 1 |
---|
1187 | ! BIT Numerical Mathematics (2005) 45: 761-787 |
---|
1188 | ! DOI: 10.1007/s10543-005-0035-y |
---|
1189 | ! Table 4.1-4.2 |
---|
1190 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1191 | |
---|
1192 | IMPLICIT NONE |
---|
1193 | |
---|
1194 | rosMethod = RG3 |
---|
1195 | !~~~> Name of the method |
---|
1196 | ros_Name = 'RANG-3' |
---|
1197 | !~~~> Number of stages |
---|
1198 | ros_S = 4 |
---|
1199 | |
---|
1200 | ros_A(1) = 5.09052051067020d+00; |
---|
1201 | ros_A(2) = 5.09052051067020d+00; |
---|
1202 | ros_A(3) = 0.0d0; |
---|
1203 | ros_A(4) = 4.97628111010787d+00; |
---|
1204 | ros_A(5) = 2.77268164715849d-02; |
---|
1205 | ros_A(6) = 2.29428036027904d-01; |
---|
1206 | |
---|
1207 | ros_C(1) = -1.16790812312283d+01; |
---|
1208 | ros_C(2) = -1.64057326467367d+01; |
---|
1209 | ros_C(3) = -2.77268164715850d-01; |
---|
1210 | ros_C(4) = -8.38103960500476d+00; |
---|
1211 | ros_C(5) = -8.48328409199343d-01; |
---|
1212 | ros_C(6) = 2.87009860433106d-01; |
---|
1213 | |
---|
1214 | ros_M(1) = 5.22582761233094d+00; |
---|
1215 | ros_M(2) = -5.56971148154165d-01; |
---|
1216 | ros_M(3) = 3.57979469353645d-01; |
---|
1217 | ros_M(4) = 1.72337398521064d+00; |
---|
1218 | |
---|
1219 | ros_E(1) = -5.16845212784040d+00; |
---|
1220 | ros_E(2) = -1.26351942603842d+00; |
---|
1221 | ros_E(3) = -1.11022302462516d-16; |
---|
1222 | ros_E(4) = 2.22044604925031d-16; |
---|
1223 | |
---|
1224 | ros_Alpha(1) = 0.0d00; |
---|
1225 | ros_Alpha(2) = 2.21878746765329d+00; |
---|
1226 | ros_Alpha(3) = 2.21878746765329d+00; |
---|
1227 | ros_Alpha(4) = 1.55392337535788d+00; |
---|
1228 | |
---|
1229 | ros_Gamma(1) = 4.35866521508459d-01; |
---|
1230 | ros_Gamma(2) = -1.78292094614483d+00; |
---|
1231 | ros_Gamma(3) = -2.46541900496934d+00; |
---|
1232 | ros_Gamma(4) = -8.05529997906370d-01; |
---|
1233 | |
---|
1234 | |
---|
1235 | !~~~> Does the stage i require a new function evaluation (ros_NewF(i)=TRUE) |
---|
1236 | ! or does it re-use the function evaluation from stage i-1 (ros_NewF(i)=FALSE) |
---|
1237 | ros_NewF(1) = .TRUE. |
---|
1238 | ros_NewF(2) = .TRUE. |
---|
1239 | ros_NewF(3) = .TRUE. |
---|
1240 | ros_NewF(4) = .TRUE. |
---|
1241 | |
---|
1242 | !~~~> ros_ELO = estimator of local order - the minimum between the |
---|
1243 | ! main and the embedded scheme orders plus 1 |
---|
1244 | ros_ELO = 3.0_dp |
---|
1245 | |
---|
1246 | END SUBROUTINE Rang3 |
---|
1247 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1248 | |
---|
1249 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1250 | ! End of the set of internal Rosenbrock subroutines |
---|
1251 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1252 | END SUBROUTINE Rosenbrock |
---|
1253 | !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
---|
1254 | |
---|
1255 | |
---|
1256 | |
---|
1257 | |
---|
1258 | |
---|