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1210 lines
40 KiB
FortranFixed
1210 lines
40 KiB
FortranFixed
15 years ago
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MODULE ERFCOREMOD
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IMPLICIT NONE
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INTERFACE CALERF
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MODULE PROCEDURE CALERF
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END INTERFACE
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INTERFACE DERF
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MODULE PROCEDURE DERF
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END INTERFACE
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INTERFACE DERFC
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MODULE PROCEDURE DERFC
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END INTERFACE
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INTERFACE DERFCX
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MODULE PROCEDURE DERFCX
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END INTERFACE
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CONTAINS
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C--------------------------------------------------------------------
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C
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C DERF subprogram computes approximate values for erf(x).
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C (see comments heading CALERF).
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C
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C Author/date: W. J. Cody, January 8, 1985
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C
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C--------------------------------------------------------------------
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FUNCTION DERF( X ) RESULT (VALUE)
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IMPLICIT NONE
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DOUBLE PRECISION, INTENT(IN) :: X
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DOUBLE PRECISION :: VALUE
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INTEGER, PARAMETER :: JINT = 0
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CALL CALERF(X,VALUE,JINT)
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RETURN
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END FUNCTION DERF
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C--------------------------------------------------------------------
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C
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C DERFC subprogram computes approximate values for erfc(x).
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C (see comments heading CALERF).
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C
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C Author/date: W. J. Cody, January 8, 1985
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C
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C--------------------------------------------------------------------
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FUNCTION DERFC( X ) RESULT (VALUE)
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IMPLICIT NONE
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DOUBLE PRECISION, INTENT(IN) :: X
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DOUBLE PRECISION :: VALUE
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INTEGER, PARAMETER :: JINT = 1
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CALL CALERF(X,VALUE,JINT)
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RETURN
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END FUNCTION DERFC
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C------------------------------------------------------------------
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C
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C DERFCX subprogram computes approximate values for exp(x*x) * erfc(x).
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C (see comments heading CALERF).
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C
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C Author/date: W. J. Cody, March 30, 1987
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C
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C------------------------------------------------------------------
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FUNCTION DERFCX( X ) RESULT (VALUE)
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IMPLICIT NONE
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DOUBLE PRECISION, INTENT(IN) :: X
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DOUBLE PRECISION :: VALUE
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INTEGER, PARAMETER :: JINT = 2
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CALL CALERF(X,VALUE,JINT)
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RETURN
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END FUNCTION DERFCX
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SUBROUTINE CALERF(ARG,RESULT,JINT)
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IMPLICIT NONE
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C------------------------------------------------------------------
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C
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C CALERF packet evaluates erf(x), erfc(x), and exp(x*x)*erfc(x)
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C for a real argument x. It contains three FUNCTION type
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C subprograms: ERF, ERFC, and ERFCX (or DERF, DERFC, and DERFCX),
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C and one SUBROUTINE type subprogram, CALERF. The calling
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C statements for the primary entries are:
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C
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C Y=ERF(X) (or Y=DERF(X)),
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C
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C Y=ERFC(X) (or Y=DERFC(X)),
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C and
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C Y=ERFCX(X) (or Y=DERFCX(X)).
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C
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C The routine CALERF is intended for internal packet use only,
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C all computations within the packet being concentrated in this
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C routine. The function subprograms invoke CALERF with the
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C statement
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C
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C CALL CALERF(ARG,RESULT,JINT)
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C
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C where the parameter usage is as follows
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C
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C Function Parameters for CALERF
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C call ARG Result JINT
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C
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C ERF(ARG) ANY REAL ARGUMENT ERF(ARG) 0
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C ERFC(ARG) ABS(ARG) .LT. XBIG ERFC(ARG) 1
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C ERFCX(ARG) XNEG .LT. ARG .LT. XMAX ERFCX(ARG) 2
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C
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C The main computation evaluates near-minimax approximations
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C from "Rational Chebyshev approximations for the error function"
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C by W. J. Cody, Math. Comp., 1969, PP. 631-638. This
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C transportable program uses rational functions that theoretically
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C approximate erf(x) and erfc(x) to at least 18 significant
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C decimal digits. The accuracy achieved depends on the arithmetic
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C system, the compiler, the intrinsic functions, and proper
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C selection of the machine-dependent constants.
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C
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C*******************************************************************
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C*******************************************************************
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C
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C Explanation of machine-dependent constants
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C
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C XMIN = the smallest positive floating-point number.
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C XINF = the largest positive finite floating-point number.
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C XNEG = the largest negative argument acceptable to ERFCX;
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C the negative of the solution to the equation
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C 2*exp(x*x) = XINF.
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C XSMALL = argument below which erf(x) may be represented by
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C 2*x/sqrt(pi) and above which x*x will not underflow.
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C A conservative value is the largest machine number X
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C such that 1.0 + X = 1.0 to machine precision.
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C XBIG = largest argument acceptable to ERFC; solution to
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C the equation: W(x) * (1-0.5/x**2) = XMIN, where
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C W(x) = exp(-x*x)/[x*sqrt(pi)].
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C XHUGE = argument above which 1.0 - 1/(2*x*x) = 1.0 to
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C machine precision. A conservative value is
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C 1/[2*sqrt(XSMALL)]
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C XMAX = largest acceptable argument to ERFCX; the minimum
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C of XINF and 1/[sqrt(pi)*XMIN].
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C
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C Approximate values for some important machines are:
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C
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C XMIN XINF XNEG XSMALL
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C
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C C 7600 (S.P.) 3.13E-294 1.26E+322 -27.220 7.11E-15
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C CRAY-1 (S.P.) 4.58E-2467 5.45E+2465 -75.345 7.11E-15
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C IEEE (IBM/XT,
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C SUN, etc.) (S.P.) 1.18E-38 3.40E+38 -9.382 5.96E-8
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C IEEE (IBM/XT,
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C SUN, etc.) (D.P.) 2.23D-308 1.79D+308 -26.628 1.11D-16
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C IBM 195 (D.P.) 5.40D-79 7.23E+75 -13.190 1.39D-17
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C UNIVAC 1108 (D.P.) 2.78D-309 8.98D+307 -26.615 1.73D-18
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C VAX D-Format (D.P.) 2.94D-39 1.70D+38 -9.345 1.39D-17
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C VAX G-Format (D.P.) 5.56D-309 8.98D+307 -26.615 1.11D-16
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C
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C
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C XBIG XHUGE XMAX
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C
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C C 7600 (S.P.) 25.922 8.39E+6 1.80X+293
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C CRAY-1 (S.P.) 75.326 8.39E+6 5.45E+2465
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C IEEE (IBM/XT,
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C SUN, etc.) (S.P.) 9.194 2.90E+3 4.79E+37
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C IEEE (IBM/XT,
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C SUN, etc.) (D.P.) 26.543 6.71D+7 2.53D+307
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C IBM 195 (D.P.) 13.306 1.90D+8 7.23E+75
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C UNIVAC 1108 (D.P.) 26.582 5.37D+8 8.98D+307
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C VAX D-Format (D.P.) 9.269 1.90D+8 1.70D+38
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C VAX G-Format (D.P.) 26.569 6.71D+7 8.98D+307
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C
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C*******************************************************************
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C*******************************************************************
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C
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C Error returns
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C
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C The program returns ERFC = 0 for ARG .GE. XBIG;
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C
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C ERFCX = XINF for ARG .LT. XNEG;
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C and
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C ERFCX = 0 for ARG .GE. XMAX.
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C
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C
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C Intrinsic functions required are:
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C
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C ABS, AINT, EXP
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C
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C
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C Author: W. J. Cody
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C Mathematics and Computer Science Division
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C Argonne National Laboratory
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C Argonne, IL 60439
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C
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C Latest modification: March 19, 1990
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C Updated to F90 by pab 23.03.2003
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C
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C------------------------------------------------------------------
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DOUBLE PRECISION, INTENT(IN) :: ARG
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INTEGER, INTENT(IN) :: JINT
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DOUBLE PRECISION, INTENT(INOUT):: RESULT
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! Local variables
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INTEGER :: I
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DOUBLE PRECISION :: DEL,X,XDEN,XNUM,Y,YSQ
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C------------------------------------------------------------------
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C Mathematical constants
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C------------------------------------------------------------------
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DOUBLE PRECISION, PARAMETER :: ZERO = 0.0D0
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DOUBLE PRECISION, PARAMETER :: HALF = 0.05D0
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DOUBLE PRECISION, PARAMETER :: ONE = 1.0D0
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DOUBLE PRECISION, PARAMETER :: TWO = 2.0D0
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DOUBLE PRECISION, PARAMETER :: FOUR = 4.0D0
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DOUBLE PRECISION, PARAMETER :: SIXTEN = 16.0D0
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DOUBLE PRECISION, PARAMETER :: SQRPI = 5.6418958354775628695D-1
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DOUBLE PRECISION, PARAMETER :: THRESH = 0.46875D0
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C------------------------------------------------------------------
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C Machine-dependent constants
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C------------------------------------------------------------------
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DOUBLE PRECISION, PARAMETER :: XNEG = -26.628D0
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DOUBLE PRECISION, PARAMETER :: XSMALL = 1.11D-16
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DOUBLE PRECISION, PARAMETER :: XBIG = 26.543D0
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DOUBLE PRECISION, PARAMETER :: XHUGE = 6.71D7
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DOUBLE PRECISION, PARAMETER :: XMAX = 2.53D307
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DOUBLE PRECISION, PARAMETER :: XINF = 1.79D308
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!---------------------------------------------------------------
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! Coefficents to the rational polynomials
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!--------------------------------------------------------------
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DOUBLE PRECISION, DIMENSION(5) :: A, Q
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DOUBLE PRECISION, DIMENSION(4) :: B
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DOUBLE PRECISION, DIMENSION(9) :: C
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DOUBLE PRECISION, DIMENSION(8) :: D
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DOUBLE PRECISION, DIMENSION(6) :: P
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C------------------------------------------------------------------
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C Coefficients for approximation to erf in first interval
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C------------------------------------------------------------------
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PARAMETER (A = (/ 3.16112374387056560D00,
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& 1.13864154151050156D02,3.77485237685302021D02,
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& 3.20937758913846947D03, 1.85777706184603153D-1/))
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PARAMETER ( B = (/2.36012909523441209D01,2.44024637934444173D02,
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& 1.28261652607737228D03,2.84423683343917062D03/))
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C------------------------------------------------------------------
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C Coefficients for approximation to erfc in second interval
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C------------------------------------------------------------------
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PARAMETER ( C=(/5.64188496988670089D-1,8.88314979438837594D0,
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1 6.61191906371416295D01,2.98635138197400131D02,
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2 8.81952221241769090D02,1.71204761263407058D03,
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3 2.05107837782607147D03,1.23033935479799725D03,
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4 2.15311535474403846D-8/))
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PARAMETER ( D =(/1.57449261107098347D01,1.17693950891312499D02,
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1 5.37181101862009858D02,1.62138957456669019D03,
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2 3.29079923573345963D03,4.36261909014324716D03,
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3 3.43936767414372164D03,1.23033935480374942D03/))
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C------------------------------------------------------------------
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C Coefficients for approximation to erfc in third interval
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C------------------------------------------------------------------
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PARAMETER ( P =(/3.05326634961232344D-1,3.60344899949804439D-1,
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1 1.25781726111229246D-1,1.60837851487422766D-2,
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2 6.58749161529837803D-4,1.63153871373020978D-2/))
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PARAMETER (Q =(/2.56852019228982242D00,1.87295284992346047D00,
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1 5.27905102951428412D-1,6.05183413124413191D-2,
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2 2.33520497626869185D-3/))
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C------------------------------------------------------------------
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X = ARG
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Y = ABS(X)
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IF (Y .LE. THRESH) THEN
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C------------------------------------------------------------------
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C Evaluate erf for |X| <= 0.46875
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C------------------------------------------------------------------
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!YSQ = ZERO
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IF (Y .GT. XSMALL) THEN
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YSQ = Y * Y
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XNUM = A(5)*YSQ
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XDEN = YSQ
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DO I = 1, 3
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XNUM = (XNUM + A(I)) * YSQ
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XDEN = (XDEN + B(I)) * YSQ
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END DO
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RESULT = X * (XNUM + A(4)) / (XDEN + B(4))
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ELSE
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RESULT = X * A(4) / B(4)
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ENDIF
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IF (JINT .NE. 0) RESULT = ONE - RESULT
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IF (JINT .EQ. 2) RESULT = EXP(YSQ) * RESULT
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GO TO 800
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C------------------------------------------------------------------
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C Evaluate erfc for 0.46875 <= |X| <= 4.0
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C------------------------------------------------------------------
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ELSE IF (Y .LE. FOUR) THEN
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XNUM = C(9)*Y
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XDEN = Y
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DO I = 1, 7
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XNUM = (XNUM + C(I)) * Y
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XDEN = (XDEN + D(I)) * Y
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END DO
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RESULT = (XNUM + C(8)) / (XDEN + D(8))
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IF (JINT .NE. 2) THEN
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YSQ = AINT(Y*SIXTEN)/SIXTEN
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DEL = (Y-YSQ)*(Y+YSQ)
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RESULT = EXP(-YSQ*YSQ) * EXP(-DEL) * RESULT
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END IF
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C------------------------------------------------------------------
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C Evaluate erfc for |X| > 4.0
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C------------------------------------------------------------------
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ELSE
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RESULT = ZERO
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IF (Y .GE. XBIG) THEN
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IF ((JINT .NE. 2) .OR. (Y .GE. XMAX)) GO TO 300
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IF (Y .GE. XHUGE) THEN
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RESULT = SQRPI / Y
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GO TO 300
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END IF
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END IF
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YSQ = ONE / (Y * Y)
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XNUM = P(6)*YSQ
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XDEN = YSQ
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DO I = 1, 4
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XNUM = (XNUM + P(I)) * YSQ
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XDEN = (XDEN + Q(I)) * YSQ
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ENDDO
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RESULT = YSQ *(XNUM + P(5)) / (XDEN + Q(5))
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RESULT = (SQRPI - RESULT) / Y
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IF (JINT .NE. 2) THEN
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YSQ = AINT(Y*SIXTEN)/SIXTEN
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DEL = (Y-YSQ)*(Y+YSQ)
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RESULT = EXP(-YSQ*YSQ) * EXP(-DEL) * RESULT
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END IF
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|
END IF
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C------------------------------------------------------------------
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|
C Fix up for negative argument, erf, etc.
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||
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C------------------------------------------------------------------
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300 IF (JINT .EQ. 0) THEN
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RESULT = (HALF - RESULT) + HALF
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IF (X .LT. ZERO) RESULT = -RESULT
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ELSE IF (JINT .EQ. 1) THEN
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IF (X .LT. ZERO) RESULT = TWO - RESULT
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ELSE
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IF (X .LT. ZERO) THEN
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IF (X .LT. XNEG) THEN
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RESULT = XINF
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ELSE
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YSQ = AINT(X*SIXTEN)/SIXTEN
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DEL = (X-YSQ)*(X+YSQ)
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Y = EXP(YSQ*YSQ) * EXP(DEL)
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RESULT = (Y+Y) - RESULT
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||
|
END IF
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END IF
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END IF
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800 RETURN
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END SUBROUTINE CALERF
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||
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END MODULE ERFCOREMOD
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||
|
|
||
|
MODULE DUNNETMOD
|
||
|
|
||
|
SUBROUTINE MVNPRD(A, B, BPD, EPS, N, INF, IERC, HINC, PROB,
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& BOUND,IFAULT)
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||
|
C
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||
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C ALGORITHM AS 251.1 APPL.STATIST. (1989), VOL.38, NO.3
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|
C
|
||
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C FOR A MULTIVARIATE NORMAL VECTOR WITH CORRELATION STRUCTURE
|
||
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C DEFINED BY RHO(I,J) = BPD(I) * BPD(J), COMPUTES THE PROBABILITY
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|
C THAT THE VECTOR FALLS IN A RECTANGLE IN N-SPACE WITH ERROR
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C LESS THAN EPS.
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C
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||
|
INTEGER NN
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||
|
PARAMETER (NN = 50)
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||
|
REAL A(*), B(*), BPD(*), ESTT(22), FV(5), FD(5), F1T(22),
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* F2T(22), F3T(22), G1T(22), G3T(22), PSUM(22), H(NN), HL(NN),
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* BB(NN)
|
||
|
INTEGER INF(*), INFT(NN), LDIR(22)
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||
|
REAL ZERO, HALF, ONE, TWO, FOUR, SIX, PT1, PT24, ONEP5,
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* X2880, SMALL, DXMIN, SQRT2, PROB, ERRL, BI, START,
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||
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* Z, HINC, ADDN, EPS2, EPS1, EPS, ZU, Z2, Z3, Z4, Z5, ZZ,
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||
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* ERFAC, EL, EL1, BOUND, PART0, PART2, PART3, FUNC0, FUNC2,
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||
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* FUNCN, WT, CONTRB, DLG, DX, DA, ESTL, ESTR, SUM, EXCESS, ERROR,
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||
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* PROB1, SAFE
|
||
|
INTEGER N, IERC, IFAULT, I, NTM, NMAX, LVL, NR, NDIM
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||
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REAL ALNORM, PPND7
|
||
|
EXTERNAL ALNORM, PPND7
|
||
|
DATA ZERO, HALF, ONE, TWO, FOUR, SIX /0.0, 0.5, 1.0, 2.0,
|
||
|
* 4.0, 6.0/
|
||
|
DATA PT1, PT24, ONEP5, X2880 /0.1, 0.24, 1.5, 2880.0/
|
||
|
DATA SMALL, DXMIN, SQRT2 /1.0E-10, 0.0000001, 1.41421356237310/
|
||
|
C
|
||
|
C CHECK FOR INPUT VALUES OUT OF RANGE.
|
||
|
C
|
||
|
PROB = ZERO
|
||
|
BOUND = ZERO
|
||
|
IFAULT = 1
|
||
|
IF (N .LT. 1 .OR. N .GT. NN) RETURN
|
||
|
DO 10 I = 1, N
|
||
|
BI = ABS(BPD(I))
|
||
|
IFAULT = 2
|
||
|
IF (BI .GE. ONE) RETURN
|
||
|
IFAULT = 3
|
||
|
IF (INF(I) .LT. 0 .OR. INF(I) .GT. 2) RETURN
|
||
|
IFAULT = 4
|
||
|
IF (INF(I) .EQ. 2 .AND. A(I) .LE. B(I)) RETURN
|
||
|
10 CONTINUE
|
||
|
IFAULT = 0
|
||
|
PROB = ONE
|
||
|
C
|
||
|
C CHECK WHETHER ANY BPD(I) = 0.
|
||
|
C
|
||
|
NDIM = 0
|
||
|
DO 20 I = 1, N
|
||
|
IF (BPD(I) .NE. ZERO) THEN
|
||
|
NDIM = NDIM + 1
|
||
|
H(NDIM) = A(I)
|
||
|
HL(NDIM) = B(I)
|
||
|
BB(NDIM) = BPD(I)
|
||
|
INFT(NDIM) = INF(I)
|
||
|
ELSE
|
||
|
C
|
||
|
C IF ANY BPD(I) = 0, THE CONTRIBUTION TO PROB FOR THAT
|
||
|
C VARIABLE IS COMPUTED FROM A UNIVARIATE NORMAL.
|
||
|
C
|
||
|
IF (INF(I) .LT. 1) THEN
|
||
|
PROB = PROB * (ONE - ALNORM(B(I), .FALSE.))
|
||
|
ELSE IF (INF(I) .EQ. 1) THEN
|
||
|
PROB = PROB * ALNORM(A(I), .FALSE.)
|
||
|
ELSE
|
||
|
PROB = PROB * (ALNORM(A(I), .FALSE.) -
|
||
|
* ALNORM(B(I), .FALSE.))
|
||
|
END IF
|
||
|
IF (PROB .LE. SMALL) PROB = ZERO
|
||
|
END IF
|
||
|
20 CONTINUE
|
||
|
IF (NDIM .EQ. 0 .OR. PROB .EQ. ZERO) RETURN
|
||
|
C
|
||
|
C IF NOT ALL BPD(I) = 0, PROB IS COMPUTED BY SIMPSON'S RULE.
|
||
|
C BUT FIRST, INITIALIZE THE VARIABLES.
|
||
|
C
|
||
|
Z = ZERO
|
||
|
IF (HINC .LE. ZERO) HINC = PT24
|
||
|
ADDN = -ONE
|
||
|
DO 30 I = 1, NDIM
|
||
|
IF (INFT(I) .EQ. 2 .OR.
|
||
|
* (INFT(I) .NE. INFT(1) .AND. BB(I) * BB(1) .GT. ZERO) .OR.
|
||
|
* (INFT(I) .EQ. INFT(1) .AND. BB(I) * BB(1) .LT. ZERO))
|
||
|
* ADDN = ZERO
|
||
|
30 CONTINUE
|
||
|
C
|
||
|
C THE VALUE OF ADDN IS TO BE ADDED TO THE PRODUCT EXPRESSIONS IN
|
||
|
C THE INTEGRAND TO INSURE THAT THE LIMITING VALUE IS ZERO.
|
||
|
C
|
||
|
PROB1 = ZERO
|
||
|
NTM = 0
|
||
|
NMAX = 400
|
||
|
IF (IERC .EQ. 0) NMAX = NMAX * 2
|
||
|
CALL PFUNC (Z, H, HL, BB, NDIM, INFT, ADDN, SAFE, FUNC0, NTM,
|
||
|
* IERC, PART0)
|
||
|
EPS2 = EPS * PT1 * HALF
|
||
|
C
|
||
|
C SET UPPER BOUND ON Z AND APPORTION EPS.
|
||
|
C
|
||
|
ZU = -PPND7(EPS2, IFAULT) / SQRT2
|
||
|
IF (IFAULT .NE. 0) THEN
|
||
|
IFAULT = 6
|
||
|
RETURN
|
||
|
END IF
|
||
|
NR = IFIX(ZU / HINC) + 1
|
||
|
ERFAC = ONE
|
||
|
IF (IERC .NE. 0) ERFAC = X2880 / HINC ** 5
|
||
|
EL = (EPS - EPS2) / FLOAT(NR) * ERFAC
|
||
|
EL1 = EL
|
||
|
C
|
||
|
C START COMPUTATIONS FOR THE INTERVAL (Z, Z + HINC).
|
||
|
C
|
||
|
40 ERROR = ZERO
|
||
|
LVL = 0
|
||
|
FV(1) = PART0
|
||
|
FD(1) = SAFE
|
||
|
START = Z
|
||
|
DA = HINC
|
||
|
Z3 = START + HALF * DA
|
||
|
CALL PFUNC(Z3, H, HL, BB, NDIM, INFT, ADDN, FD(3), FUNCN, NTM,
|
||
|
* IERC, FV(3))
|
||
|
Z5 = START + DA
|
||
|
CALL PFUNC(Z5, H, HL, BB, NDIM, INFT, ADDN, FD(5), FUNC2, NTM,
|
||
|
* IERC, FV(5))
|
||
|
PART2 = FV(5)
|
||
|
SAFE = FD(5)
|
||
|
WT = DA / SIX
|
||
|
CONTRB = WT * (FV(1) + FOUR * FV(3) + FV(5))
|
||
|
DLG = ZERO
|
||
|
IF (IERC .NE. 0) THEN
|
||
|
CALL WMAX(FD(1), FD(3), FD(5), DLG)
|
||
|
IF (DLG .LE. EL) GO TO 90
|
||
|
DX = DA
|
||
|
GO TO 60
|
||
|
END IF
|
||
|
LVL = 1
|
||
|
LDIR(LVL) = 2
|
||
|
PSUM(LVL) = ZERO
|
||
|
C
|
||
|
C BISECT INTERVAL. IF IERC = 1, COMPUTE ESTIMATE ON LEFT
|
||
|
C HALF; IF IERC = 0, ON BOTH HALVES.
|
||
|
C
|
||
|
50 DX = HALF * DA
|
||
|
WT = DX / SIX
|
||
|
Z2 = START + HALF * DX
|
||
|
CALL PFUNC(Z2, H, HL, BB, NDIM, INFT, ADDN, FD(2), FUNCN, NTM,
|
||
|
* IERC,FV(2))
|
||
|
ESTL = WT * (FV(1) + FOUR * FV(2) + FV(3))
|
||
|
IF (IERC .EQ. 0) THEN
|
||
|
Z4 = START + ONEP5 * DX
|
||
|
CALL PFUNC(Z4, H, HL, BB, NDIM, INFT, ADDN, FD(4), FUNCN,
|
||
|
* NTM, IERC, FV(4))
|
||
|
ESTR = WT * (FV(3) + FOUR * FV(4) + FV(5))
|
||
|
SUM = ESTL + ESTR
|
||
|
DLG = ABS(CONTRB - SUM)
|
||
|
EPS1 = EL / TWO ** (LVL - 1)
|
||
|
ERRL = DLG
|
||
|
ELSE
|
||
|
FV(3) = FV(2)
|
||
|
FD(3) = FD(2)
|
||
|
CALL WMAX(FD(1), FD(3), FD(5), DLG)
|
||
|
ERRL = DLG / TWO ** (5 * LVL)
|
||
|
SUM = ESTL
|
||
|
EPS1 = EL * (TWO ** LVL) ** 4
|
||
|
END IF
|
||
|
C
|
||
|
C STOP SUBDIVIDING INTERVAL WHEN ACCURACY IS SUFFICIENT,
|
||
|
C OR IF INTERVAL TOO NARROW OR SUBDIVIDED TOO OFTEN.
|
||
|
C
|
||
|
IF (DLG .LE. EPS1 .OR. DLG .LT. SMALL) GO TO 70
|
||
|
IF (IFAULT .EQ. 0 .AND. NTM .GE. NMAX) IFAULT = 5
|
||
|
IF (ABS(DX) .LE. DXMIN .OR. LVL .GT. 21) IFAULT = 7
|
||
|
IF (IFAULT .NE. 0) GO TO 70
|
||
|
C
|
||
|
C RAISE LEVEL. STORE INFORMATION FOR RIGHT HALF AND APPLY
|
||
|
C SIMPSON'S RULE TO LEFT HALF.
|
||
|
C
|
||
|
60 LVL = LVL + 1
|
||
|
LDIR(LVL) = 1
|
||
|
F1T(LVL) = FV(3)
|
||
|
F3T(LVL) = FV(5)
|
||
|
DA = DX
|
||
|
FV(5) = FV(3)
|
||
|
IF (IERC .EQ. 0) THEN
|
||
|
F2T(LVL) = FV(4)
|
||
|
ESTT(LVL) = ESTR
|
||
|
CONTRB = ESTL
|
||
|
FV(3) = FV(2)
|
||
|
ELSE
|
||
|
G1T(LVL) = FD(3)
|
||
|
G3T(LVL) = FD(5)
|
||
|
FD(5) = FD(3)
|
||
|
END IF
|
||
|
GO TO 50
|
||
|
C
|
||
|
C ACCEPT APPROXIMATE VALUE FOR INTERVAL.
|
||
|
C RESTORE SAVED INFORMATION TO PROCESS
|
||
|
C RIGHT HALF INTERVAL.
|
||
|
C
|
||
|
70 ERROR = ERROR + ERRL
|
||
|
80 IF (LDIR(LVL) .EQ. 1) THEN
|
||
|
PSUM(LVL) = SUM
|
||
|
LDIR(LVL) = 2
|
||
|
IF (IERC .EQ. 0) DX = DX * TWO
|
||
|
START = START + DX
|
||
|
DA = HINC / TWO ** (LVL - 1)
|
||
|
FV(1) = F1T(LVL)
|
||
|
IF (IERC .EQ. 0) THEN
|
||
|
FV(3) = F2T(LVL)
|
||
|
CONTRB = ESTT(LVL)
|
||
|
ELSE
|
||
|
FV(3) = F3T(LVL)
|
||
|
FD(1) = G1T(LVL)
|
||
|
FD(5) = G3T(LVL)
|
||
|
END IF
|
||
|
FV(5) = F3T(LVL)
|
||
|
GO TO 50
|
||
|
END IF
|
||
|
SUM = SUM + PSUM(LVL)
|
||
|
LVL = LVL - 1
|
||
|
IF (LVL .GT. 0) GO TO 80
|
||
|
CONTRB = SUM
|
||
|
LVL = 1
|
||
|
DLG = ERROR
|
||
|
90 PROB1 = PROB1 + CONTRB
|
||
|
BOUND = BOUND + DLG
|
||
|
EXCESS = EL - DLG
|
||
|
EL = EL1
|
||
|
IF (EXCESS .GT. ZERO) EL = EL1 + EXCESS
|
||
|
IF ((FUNC0 .GT. ZERO .AND. FUNC2 .LE. FUNC0) .OR.
|
||
|
* (FUNC0 .LT. ZERO .AND. FUNC2 .GE. FUNC0)) THEN
|
||
|
ZZ = -SQRT2 * Z5
|
||
|
PART3 = ABS(FUNC2) * ALNORM(ZZ, .FALSE.) + BOUND / ERFAC
|
||
|
IF (PART3 .LE. EPS .OR. NTM .GE. NMAX .OR. Z5 .GE. ZU) GOTO 100
|
||
|
END IF
|
||
|
Z = Z5
|
||
|
PART0 = PART2
|
||
|
FUNC0 = FUNC2
|
||
|
IF (Z .LT. ZU .AND. NTM .LT. NMAX) GO TO 40
|
||
|
100 PROB = (PROB1 - ADDN * HALF) * PROB
|
||
|
BOUND = PART3
|
||
|
IF (NTM .GE. NMAX .AND. IFAULT .EQ. 0) IFAULT = 5
|
||
|
IF (BOUND .GT. EPS .AND. IFAULT .EQ. 0) IFAULT = 8
|
||
|
RETURN
|
||
|
END
|
||
|
SUBROUTINE PFUNC(Z, A, B, BPD, N, INF, ADDN, DERIV, FUNCN, NTM,
|
||
|
* IERC, RESULT)
|
||
|
C
|
||
|
C ALGORITHM AS 251.2 APPL.STATIST. (1989), VOL.38, NO.3
|
||
|
C
|
||
|
C
|
||
|
C COMPUTE FUNCTION IN INTEGRAND AND ITS 4TH DERIVATIVE.
|
||
|
C
|
||
|
INTEGER NN
|
||
|
PARAMETER (NN = 50)
|
||
|
REAL A(*), B(*), BPD(*), FOU(NN), FOU1(4, NN), TMP(4), GOU(NN),
|
||
|
* GOU1(4, NN), FF(4), GF(4), TERM(4), GERM(4)
|
||
|
INTEGER INF(*)
|
||
|
REAL ZERO, ONE, TWO, THREE, FOUR, SIX, EIGHT, TWELVE, SIXTN,
|
||
|
* SMALL, Z, U, U1, U2, BI, HI, HLI, BP, ADDN, DERIV, FUNCN,
|
||
|
* RESULT, RSLT1, RSLT2, DEN, SQRT2, SQRTPI, PHI, PHI1, PHI2,
|
||
|
* PHI3, PHI4, FRM, GRM
|
||
|
INTEGER N, NTM, IERC, INFI, I, J, K, M, L, IK
|
||
|
REAL ALNORM
|
||
|
EXTERNAL ALNORM
|
||
|
DATA ZERO, ONE, TWO, THREE, FOUR, SIX, EIGHT, TWELVE, SIXTN,
|
||
|
* SMALL /0.0, 1.0, 2.0, 3.0, 4.0, 6.0, 8.0, 12.0, 16.0, 0.1E-12/
|
||
|
DATA SQRT2, SQRTPI /1.41421356237310, 1.77245385090552/
|
||
|
DERIV = ZERO
|
||
|
NTM = NTM + 1
|
||
|
RSLT1 = ONE
|
||
|
RSLT2 = ONE
|
||
|
BI = ONE
|
||
|
HI = A(1) + ONE
|
||
|
HLI = B(1) + ONE
|
||
|
INFI = -1
|
||
|
DO 60 I = 1, N
|
||
|
IF (BPD(I) .EQ. BI .AND. A(I) .EQ. HI .AND. B(I) .EQ. HLI .AND.
|
||
|
* INF(I) .EQ. INFI) THEN
|
||
|
FOU(I) = FOU(I - 1)
|
||
|
GOU(I) = GOU(I - 1)
|
||
|
DO 10 IK = 1, 4
|
||
|
FOU1(IK, I) = FOU1(IK, I - 1)
|
||
|
GOU1(IK, I) = GOU1(IK, I - 1)
|
||
|
10 CONTINUE
|
||
|
ELSE
|
||
|
BI = BPD(I)
|
||
|
HI = A(I)
|
||
|
HLI = B(I)
|
||
|
INFI = INF(I)
|
||
|
IF (BI .EQ. ZERO) THEN
|
||
|
IF (INFI .LT. 1) THEN
|
||
|
FOU(I) = ONE - ALNORM(HLI, .FALSE.)
|
||
|
ELSE IF (INFI .EQ. 1) THEN
|
||
|
FOU(I) = ALNORM(HI, .FALSE.)
|
||
|
ELSE
|
||
|
FOU(I) = ALNORM(HI, .FALSE.) - ALNORM(HLI, .FALSE.)
|
||
|
END IF
|
||
|
GOU(I) = FOU(I)
|
||
|
DO 20 IK = 1, 4
|
||
|
FOU1(IK, I) = ZERO
|
||
|
GOU1(IK, I) = ZERO
|
||
|
20 CONTINUE
|
||
|
ELSE
|
||
|
DEN = SQRT(ONE - BI * BI)
|
||
|
BP = BI * SQRT2 / DEN
|
||
|
IF (INFI .LT. 1) THEN
|
||
|
U = -HLI / DEN + Z * BP
|
||
|
FOU(I) = ALNORM(U, .FALSE.)
|
||
|
CALL ASSIGN (U, BP, FOU1(1, I))
|
||
|
BP = -BP
|
||
|
U = -HLI / DEN + Z * BP
|
||
|
GOU(I) = ALNORM(U, .FALSE.)
|
||
|
CALL ASSIGN (U, BP, GOU1(1, I))
|
||
|
ELSE IF (INFI .EQ. 1) THEN
|
||
|
U = HI / DEN + Z * BP
|
||
|
GOU(I) = ALNORM(U, .FALSE.)
|
||
|
CALL ASSIGN (U, BP, GOU1(1, I))
|
||
|
BP = -BP
|
||
|
U = HI / DEN + Z * BP
|
||
|
FOU(I) = ALNORM(U, .FALSE.)
|
||
|
CALL ASSIGN (U, BP, FOU1(1, I))
|
||
|
ELSE
|
||
|
U2 = -HLI / DEN + Z * BP
|
||
|
CALL ASSIGN (U2, BP, FOU1(1, I))
|
||
|
BP = -BP
|
||
|
U1 = HI / DEN + Z * BP
|
||
|
CALL ASSIGN (U1, BP, TMP(1))
|
||
|
FOU(I) = ALNORM(U1, .FALSE.) + ALNORM(U2, .FALSE.) - ONE
|
||
|
DO 30 IK = 1, 4
|
||
|
FOU1(IK, I) = FOU1(IK, I) + TMP(IK)
|
||
|
30 CONTINUE
|
||
|
IF (-HLI .EQ. HI) THEN
|
||
|
GOU(I) = FOU(I)
|
||
|
DO 40 IK = 1, 4
|
||
|
GOU1(IK, I) = FOU1(IK, I)
|
||
|
40 CONTINUE
|
||
|
ELSE
|
||
|
U2 = -HLI / DEN + Z * BP
|
||
|
CALL ASSIGN (U2, BP, GOU1(1, I))
|
||
|
BP = -BP
|
||
|
U1 = HI / DEN + Z * BP
|
||
|
GOU(I) = ALNORM(U1, .FALSE.) + ALNORM(U2, .FALSE.)-ONE
|
||
|
CALL ASSIGN (U1, BP, TMP(1))
|
||
|
DO 50 IK = 1, 4
|
||
|
GOU1(IK, I) = GOU1(IK, I) + TMP(IK)
|
||
|
50 CONTINUE
|
||
|
END IF
|
||
|
END IF
|
||
|
END IF
|
||
|
END IF
|
||
|
RSLT1 = RSLT1 * FOU(I)
|
||
|
RSLT2 = RSLT2 * GOU(I)
|
||
|
IF (RSLT1 .LE. SMALL) RSLT1 = ZERO
|
||
|
IF (RSLT2 .LE. SMALL) RSLT2 = ZERO
|
||
|
60 CONTINUE
|
||
|
FUNCN = RSLT1 + RSLT2 + ADDN
|
||
|
RESULT = FUNCN * EXP(-Z * Z) / SQRTPI
|
||
|
C
|
||
|
C IF 4TH DERIVATIVE IS NOT WANTED, STOP HERE.
|
||
|
C OTHERWISE, PROCEED TO COMPUTE 4TH DERIVATIVE.
|
||
|
C
|
||
|
IF (IERC .EQ. 0) RETURN
|
||
|
DO 70 IK = 1, 4
|
||
|
FF(IK) = ZERO
|
||
|
GF(IK) = ZERO
|
||
|
70 CONTINUE
|
||
|
DO 100 I = 1, N
|
||
|
FRM = ONE
|
||
|
GRM = ONE
|
||
|
DO 80 J = 1, N
|
||
|
IF (J .EQ. 1) GO TO 80
|
||
|
FRM = FRM * FOU(J)
|
||
|
GRM = GRM * GOU(J)
|
||
|
IF (FRM .LE. SMALL) FRM = ZERO
|
||
|
IF (GRM .LE. SMALL) GRM = ZERO
|
||
|
80 CONTINUE
|
||
|
DO 90 IK = 1, 4
|
||
|
FF(IK) = FF(IK) + FRM * FOU1(IK, I)
|
||
|
GF(IK) = GF(IK) + GRM * GOU1(IK, I)
|
||
|
90 CONTINUE
|
||
|
100 CONTINUE
|
||
|
IF (N .LE. 2) GO TO 230
|
||
|
DO 130 I = 1, N
|
||
|
DO 120 J = I + 1, N
|
||
|
TERM(2) = FOU1(1, I) * FOU1(1, J)
|
||
|
GERM(2) = GOU1(1, I) * GOU1(1, J)
|
||
|
TERM(3) = FOU1(2, I) * FOU1(1, J)
|
||
|
GERM(3) = GOU1(2, I) * GOU1(1, J)
|
||
|
TERM(4) = FOU1(3, I) * FOU1(1, J)
|
||
|
GERM(4) = GOU1(3, I) * GOU1(1, J)
|
||
|
TERM(1) = FOU1(2, I) * FOU1(2, J)
|
||
|
GERM(1) = GOU1(2, I) * GOU1(2, J)
|
||
|
DO 110 K = 1, N
|
||
|
IF (K .EQ. I .OR. K .EQ. J) GO TO 110
|
||
|
CALL TOOSML (1, TERM, FOU(K))
|
||
|
CALL TOOSML (1, GERM, GOU(K))
|
||
|
110 CONTINUE
|
||
|
FF(2) = FF(2) + TWO * TERM(2)
|
||
|
FF(3) = FF(3) + TWO * TERM(3) * THREE
|
||
|
FF(4) = FF(4) + TWO * (TERM(4) * FOUR + TERM(1) * THREE)
|
||
|
GF(2) = GF(2) + TWO * GERM(2)
|
||
|
GF(3) = GF(3) + TWO * GERM(3) * THREE
|
||
|
GF(4) = GF(4) + TWO * (GERM(4) * FOUR + GERM(1) * THREE)
|
||
|
120 CONTINUE
|
||
|
130 CONTINUE
|
||
|
DO 170 I = 1, N
|
||
|
DO 160 J = I + 1, N
|
||
|
DO 150 K = J + 1, N
|
||
|
TERM(3) = FOU1(1, I) * FOU1(1, J) * FOU1(1, K)
|
||
|
TERM(4) = FOU1(2, I) * FOU1(1, J) * FOU1(1, K)
|
||
|
GERM(3) = GOU1(1, I) * GOU1(1, J) * GOU1(1, K)
|
||
|
GERM(4) = GOU1(2, I) * GOU1(1, J) * GOU1(1, K)
|
||
|
IF (N .GT. 3) THEN
|
||
|
DO 140 M = 1, N
|
||
|
IF (M .EQ. I .OR. M .EQ. J .OR. M .EQ. K) GO TO 140
|
||
|
CALL TOOSML (3, TERM, FOU(M))
|
||
|
CALL TOOSML (3, GERM, GOU(M))
|
||
|
140 CONTINUE
|
||
|
END IF
|
||
|
FF(3) = FF(3) + SIX * TERM(3)
|
||
|
FF(4) = FF(4) + SIX * TERM(4) * SIX
|
||
|
GF(3) = GF(3) + SIX * GERM(3)
|
||
|
GF(4) = GF(4) + SIX * GERM(4) * SIX
|
||
|
150 CONTINUE
|
||
|
160 CONTINUE
|
||
|
170 CONTINUE
|
||
|
IF (N .LE. 3) GO TO 230
|
||
|
DO 220 I = 1, N
|
||
|
DO 210 J = I + 1, N
|
||
|
DO 200 K = J + 1, N
|
||
|
DO 190 M = K + 1, N
|
||
|
TERM(4) = FOU1(1, I) * FOU1(1, J) * FOU1(1, K) * FOU1(1, M)
|
||
|
GERM(4) = GOU1(1, I) * GOU1(1, J) * GOU1(1, K) * GOU1(1, M)
|
||
|
IF (N .GT. 4) THEN
|
||
|
DO 180 L = 1, N
|
||
|
IF (L .EQ. I .OR. L .EQ. J .OR. L .EQ. K .OR. L .EQ. M)GOTO 180
|
||
|
CALL TOOSML (4, TERM, FOU(L))
|
||
|
CALL TOOSML (4, GERM, GOU(L))
|
||
|
180 CONTINUE
|
||
|
END IF
|
||
|
FF(4) = FF(4) + FOUR * SIX * TERM(4)
|
||
|
GF(4) = GF(4) + FOUR * SIX * GERM(4)
|
||
|
190 CONTINUE
|
||
|
200 CONTINUE
|
||
|
210 CONTINUE
|
||
|
220 CONTINUE
|
||
|
C
|
||
|
230 CONTINUE
|
||
|
PHI = EXP(-Z * Z) / SQRTPI
|
||
|
PHI1 = -TWO * Z * PHI
|
||
|
PHI2 = (FOUR * Z ** 2 - TWO) * PHI
|
||
|
PHI3 = (-EIGHT * Z ** 3 + TWELVE * Z) * PHI
|
||
|
PHI4 = (SIXTN * Z ** 2 * (Z ** 2 - THREE) + TWELVE) * PHI
|
||
|
DERIV = PHI * (FF(4) + GF(4)) + FOUR * PHI1 * (FF(3) + GF(3))
|
||
|
* + SIX * PHI2 * (FF(2) + GF(2)) + FOUR * PHI3 * (FF(1) + GF(1))
|
||
|
* + PHI4 * FUNCN
|
||
|
RETURN
|
||
|
END
|
||
|
SUBROUTINE ASSIGN (U, BP, FF)
|
||
|
C
|
||
|
C ALGORITHM AS 251.3 APPL.STATIST. (1989), VOL.38, NO.3
|
||
|
C
|
||
|
C
|
||
|
C COMPUTE DERIVATIVES OF NORMAL CDF'S.
|
||
|
C
|
||
|
REAL FF(4)
|
||
|
REAL U, U2, BP, HALF, ONE, THREE, SQ2PI, T1, T2, T3
|
||
|
INTEGER I
|
||
|
DATA HALF, ONE, THREE, SQ2PI /0.5, 1.0, 3.0, 2.50662827463100/
|
||
|
DATA ZERO, UMAX, SMALL /0.0, 8.0, 0.1E-07/
|
||
|
IF (ABS(U) .GT. UMAX) THEN
|
||
|
DO 10 I = 1, 4
|
||
|
FF(I) = ZERO
|
||
|
10 CONTINUE
|
||
|
ELSE
|
||
|
U2 = U * U
|
||
|
T1 = BP * EXP(-HALF * U2) / SQ2PI
|
||
|
T2 = BP * T1
|
||
|
T3 = BP * T2
|
||
|
FF(1) = T1
|
||
|
FF(2) = -U * T2
|
||
|
FF(3) = (U2 - ONE) * T3
|
||
|
FF(4) = (THREE - U2) * U * BP * T3
|
||
|
DO 20 I = 1, 4
|
||
|
IF(ABS(FF(I)) .LT. SMALL) FF(I) = ZERO
|
||
|
20 CONTINUE
|
||
|
END IF
|
||
|
RETURN
|
||
|
END
|
||
|
SUBROUTINE WMAX(W1, W2, W3, DLG)
|
||
|
C
|
||
|
C ALGORITHM AS 251.4 APPL.STATIST. (1989), VOL.38, NO.3
|
||
|
C
|
||
|
C
|
||
|
C LARGEST ABSOLUTE VALUE OF QUADRATIC FUNCTION FITTED
|
||
|
C TO THREE POINTS.
|
||
|
C
|
||
|
REAL W1, W2, W3, DLG, QUAD, QLIM, QMIN, ONE, TWO, B2C
|
||
|
DATA ONE, TWO, QMIN /1.0, 2.0, 0.00001/
|
||
|
DLG = MAX( ABS(W1), ABS(W3) )
|
||
|
QUAD = W1 - W2 * TWO + W3
|
||
|
QLIM = MAX( ABS(W1 - W3) / TWO , QMIN)
|
||
|
IF (ABS(QUAD) .LE. QLIM) RETURN
|
||
|
B2C = (W1 - W3) / QUAD / TWO
|
||
|
IF (ABS(B2C) .GE. ONE) RETURN
|
||
|
DLG = MAX( DLG, ABS(W2 - B2C * QUAD * B2C / TWO) )
|
||
|
RETURN
|
||
|
END
|
||
|
SUBROUTINE TOOSML (N, FF, F)
|
||
|
C
|
||
|
C ALGORITHM AS 251.5 APPL.STATIST. (1989), VOL.38, NO.3
|
||
|
C
|
||
|
C
|
||
|
C MULTIPLY FF(I) BY F FOR I = N TO 4. SET TO ZERO IF TOO SMALL.
|
||
|
C
|
||
|
REAL FF(4), F, ZERO, SMALL
|
||
|
INTEGER N, I
|
||
|
DATA ZERO, SMALL /0.0, 0.1E-12/
|
||
|
DO 10 I = N, 4
|
||
|
FF(I) = FF(I) * F
|
||
|
IF (ABS(FF(I)) .LE. SMALL) FF(I) = ZERO
|
||
|
10 CONTINUE
|
||
|
RETURN
|
||
|
END
|
||
|
REAL FUNCTION ALNORM(X, UPPER)
|
||
|
C
|
||
|
C ALGORITHM AS 66 APPL. STATIST. (1973) VOL.22, P.424
|
||
|
C
|
||
|
C EVALUATES THE TAIL AREA OF THE STANDARDIZED NORMAL CURVE
|
||
|
C FROM X TO INFINITY IF UPPER IS .TRUE. OR
|
||
|
C FROM MINUS INFINITY TO X IF UPPER IS .FALSE.
|
||
|
C
|
||
|
REAL LTONE, UTZERO, ZERO, HALF, ONE, CON, A1, A2, A3,
|
||
|
$ A4, A5, A6, A7, B1, B2, B3, B4, B5, B6, B7, B8, B9,
|
||
|
$ B10, B11, B12, X, Y, Z, ZEXP
|
||
|
LOGICAL UPPER, UP
|
||
|
C
|
||
|
C LTONE AND UTZERO MUST BE SET TO SUIT THE PARTICULAR COMPUTER
|
||
|
C (SEE INTRODUCTORY TEXT)
|
||
|
C
|
||
|
DATA LTONE, UTZERO /7.0, 18.66/
|
||
|
DATA ZERO, HALF, ONE, CON /0.0, 0.5, 1.0, 1.28/
|
||
|
DATA A1, A2, A3,
|
||
|
$ A4, A5, A6,
|
||
|
$ A7
|
||
|
$ /0.398942280444, 0.399903438504, 5.75885480458,
|
||
|
$ 29.8213557808, 2.62433121679, 48.6959930692,
|
||
|
$ 5.92885724438/
|
||
|
DATA B1, B2, B3,
|
||
|
$ B4, B5, B6,
|
||
|
$ B7, B8, B9,
|
||
|
$ B10, B11, B12
|
||
|
$ /0.398942280385, 3.8052E-8, 1.00000615302,
|
||
|
$ 3.98064794E-4, 1.98615381364, 0.151679116635,
|
||
|
$ 5.29330324926, 4.8385912808, 15.1508972451,
|
||
|
$ 0.742380924027, 30.789933034, 3.99019417011/
|
||
|
C
|
||
|
ZEXP(Z) = EXP(Z)
|
||
|
C
|
||
|
UP = UPPER
|
||
|
Z = X
|
||
|
IF (Z .GE. ZERO) GOTO 10
|
||
|
UP = .NOT. UP
|
||
|
Z = -Z
|
||
|
10 IF (Z .LE. LTONE .OR. UP .AND. Z .LE. UTZERO) GOTO 20
|
||
|
ALNORM = ZERO
|
||
|
GOTO 40
|
||
|
20 Y = HALF * Z * Z
|
||
|
IF (Z .GT. CON) GOTO 30
|
||
|
C
|
||
|
ALNORM = HALF - Z * (A1 - A2 * Y / (Y + A3 - A4 / (Y + A5 +
|
||
|
$ A6 / (Y + A7))))
|
||
|
GOTO 40
|
||
|
C
|
||
|
30 ALNORM = B1 * ZEXP(-Y) / (Z - B2 + B3 / (Z + B4 + B5 / (Z -
|
||
|
$ B6 + B7 / (Z + B8 - B9 / (Z + B10 + B11 / (Z + B12))))))
|
||
|
C
|
||
|
40 IF (.NOT. UP) ALNORM = ONE - ALNORM
|
||
|
RETURN
|
||
|
END
|
||
|
REAL FUNCTION PPND7 (P, IFAULT)
|
||
|
C
|
||
|
C ALGORITHM AS241 APPL. STATIST. (1988) VOL. 37, NO. 3
|
||
|
C
|
||
|
C PRODUCES THE NORMAL DEVIATE Z CORRESPONDING TO A GIVEN LOWER
|
||
|
C TAIL AREA OF P; Z IS ACCURATE TO ABOUT 1 PART IN 10**7.
|
||
|
C
|
||
|
C THE HASH SUMS BELOW ARE THE SUMS OF THE MANTISSAS OF THE
|
||
|
C COEFFICIENTS. THEY ARE INCLUDED FOR USE IN CHECKING
|
||
|
C TRANSCRIPTION.
|
||
|
C
|
||
|
INTEGER IFAULT
|
||
|
REAL ZERO, ONE, HALF, SPLIT1, SPLIT2, CONST1, CONST2,
|
||
|
* A0, A1, A2, A3, B1, B2, B3, C0, C1, C2, C3, D1, D2,
|
||
|
* E0, E1, E2, E3, F1, F2, P, Q, R
|
||
|
PARAMETER (ZERO = 0.0E0, ONE = 1.0E0, HALF = 0.5E0,
|
||
|
* SPLIT1 = 0.425E0, SPLIT2 = 5.0E0,
|
||
|
* CONST1 = 0.180625E0, CONST2 = 1.6E0)
|
||
|
C
|
||
|
C COEFFICIENTS FOR P CLOSE TO 1/2
|
||
|
PARAMETER (A0 = 3.38713 27179E0,
|
||
|
* A1 = 5.04342 71938E1,
|
||
|
* A2 = 1.59291 13202E2,
|
||
|
* A3 = 5.91093 74720E1,
|
||
|
* B1 = 1.78951 69469E1,
|
||
|
* B2 = 7.87577 57664E1,
|
||
|
* B3 = 6.71875 63600E1)
|
||
|
C HASH SUM AB 32.31845 77772
|
||
|
C
|
||
|
C COEFFICIENTS FOR P NEITHER CLOSE TO 1/2 NOR 0 OR 1
|
||
|
PARAMETER (C0 = 1.42343 72777E0,
|
||
|
* C1 = 2.75681 53900E0,
|
||
|
* C2 = 1.30672 84816E0,
|
||
|
* C3 = 1.70238 21103E-1,
|
||
|
* D1 = 7.37001 64250E-1,
|
||
|
* D2 = 1.20211 32975E-1)
|
||
|
C HASH SUM CD 15.76149 29821
|
||
|
C
|
||
|
C COEFFICIENTS FOR P NEAR 0 OR 1
|
||
|
PARAMETER (E0 = 6.65790 51150E0,
|
||
|
* E1 = 3.08122 63860E0,
|
||
|
* E2 = 4.28682 94337E-1,
|
||
|
* E3 = 1.73372 03997E-2,
|
||
|
* F1 = 2.41978 94225E-1,
|
||
|
* F2 = 1.22582 02635E-2)
|
||
|
C HASH SUM EF 19.40529 10204
|
||
|
C
|
||
|
IFAULT = 0
|
||
|
Q = P - HALF
|
||
|
IF (ABS(Q) .LE. SPLIT1) THEN
|
||
|
R = CONST1 - Q * Q
|
||
|
PPND7 = Q * (((A3 * R + A2) * R + A1) * R + A0) /
|
||
|
* (((B3 * R + B2) * R + B1) * R + ONE)
|
||
|
RETURN
|
||
|
ELSE
|
||
|
IF (Q .LT. 0) THEN
|
||
|
R = P
|
||
|
ELSE
|
||
|
R = ONE - P
|
||
|
ENDIF
|
||
|
IF (R .LE. ZERO) THEN
|
||
|
IFAULT = 1
|
||
|
PPND7 = ZERO
|
||
|
RETURN
|
||
|
ENDIF
|
||
|
R = SQRT(-LOG(R))
|
||
|
IF (R .LE. SPLIT2) THEN
|
||
|
R = R - CONST2
|
||
|
PPND7 = (((C3 * R + C2) * R + C1) * R + C0) /
|
||
|
* ((D2 * R + D1) * R + ONE)
|
||
|
ELSE
|
||
|
R = R - SPLIT2
|
||
|
PPND7 = (((E3 * R + E2) * R + E1) * R + E0) /
|
||
|
* ((F2 * R + F1) * R + ONE)
|
||
|
ENDIF
|
||
|
IF (Q .LT. 0) PPND7 = -PPND7
|
||
|
RETURN
|
||
|
ENDIF
|
||
|
END
|
||
|
|
||
|
SUBROUTINE SIMPSN (NDF,A,B,BPD,ERRB,N,INF,D,IERC,HNC,PROB,
|
||
|
* BND,IFLT)
|
||
|
C
|
||
|
C STUDENTIZES A MULTIVARIATE INTEGRAL USING SIMPSON'S RULE.
|
||
|
C
|
||
|
DIMENSION A(*),B(*),BPD(*),INF(*),D(*),
|
||
|
* FV(5),F1T(30),F2T(30),F3T(30),
|
||
|
* LDIR(30),PSUM(30),ESTT(30),ERRR(30),GV(5),G1T(30),G2T(30),
|
||
|
* G3T(30),GSUM(30)
|
||
|
DATA ZERO,HALF,ONE,ONEP5,TWO,FOUR,SIX,DXMIN /0.0,0.5,1.0,1.5,
|
||
|
* 2.0,4.0,6.0,0.000004/
|
||
|
PROB = ZERO
|
||
|
BOUNDA = ZERO
|
||
|
BOUNDG = ZERO
|
||
|
IFLAG = 0
|
||
|
IER = 0
|
||
|
START = -ONE
|
||
|
DAX = ONE
|
||
|
ERB2 = ERRB * HALF
|
||
|
EPS1 = ERB2 * HALF
|
||
|
CALL FUN (ZERO,NDF,A,B,BPD,ERB2,N,INF,D,F0,G0,IERC,HNC,IER)
|
||
|
10 FV(1) = ZERO
|
||
|
GV(1) = ZERO
|
||
|
ERROR = ZERO
|
||
|
DA = DAX
|
||
|
LVL = 1
|
||
|
Z3 = START + HALF*DA
|
||
|
CALL FUN(Z3,NDF,A,B,BPD,ERB2,N,INF,D,FV(3),GV(3),IERC,HNC,IER)
|
||
|
FV(5) = F0
|
||
|
GV(5) = G0
|
||
|
WT = ABS(DA) / SIX
|
||
|
CONTRB = WT * (FV(1) + FOUR * FV(3) + FV(5))
|
||
|
CONTRG = WT * (GV(1) + FOUR * GV(3) + GV(5))
|
||
|
LDIR(LVL) = 2
|
||
|
PSUM(LVL) = ZERO
|
||
|
GSUM(LVL) = ZERO
|
||
|
C
|
||
|
C BISECT INTERVAL; COMPUTE ESTIMATES FOR EACH HALF.
|
||
|
C
|
||
|
20 DX = HALF * DA
|
||
|
WT = ABS(DX) / SIX
|
||
|
Z2 = START + HALF * DX
|
||
|
CALL FUN(Z2,NDF,A,B,BPD,ERB2,N,INF,D,FV(2),GV(2),IERC,HNC,IER)
|
||
|
Z4 = START + ONEP5 * DX
|
||
|
CALL FUN(Z4,NDF,A,B,BPD,ERB2,N,INF,D,FV(4),GV(4),IERC,HNC,IER)
|
||
|
ESTL = WT * (FV(1) + FOUR * FV(2) + FV(3))
|
||
|
ESTR = WT * (FV(3) + FOUR * FV(4) + FV(5))
|
||
|
ESTGL = WT * (GV(1) + FOUR * GV(2) + GV(3))
|
||
|
ESTGR = WT * (GV(3) + FOUR * GV(4) + GV(5))
|
||
|
SUM = ESTL + ESTR
|
||
|
SUMG = ESTGL + ESTGR
|
||
|
DLG = ABS(CONTRB - SUM)
|
||
|
ERRL = DLG
|
||
|
C
|
||
|
C STOP BISECTING WHEN ACCURACY SUFFICIENT, OR IF
|
||
|
C INTERVAL TOO NARROW OR BISECTED TOO OFTEN.
|
||
|
C
|
||
|
30 IF (DLG .LE. EPS1) GO TO 50
|
||
|
IF (ABS(DX) .LE. DXMIN .OR. LVL .GE. 30) GO TO 40
|
||
|
C
|
||
|
C RAISE LEVEL. STORE INFORMATION FOR RIGHT HALF
|
||
|
C AND APPLY SIMPSON'S RULE TO LEFT HALF.
|
||
|
C
|
||
|
LVL = LVL + 1
|
||
|
LDIR(LVL) = 1
|
||
|
F1T(LVL) = FV(3)
|
||
|
F2T(LVL) = FV(4)
|
||
|
F3T(LVL) = FV(5)
|
||
|
G1T(LVL) = GV(3)
|
||
|
G2T(LVL) = GV(4)
|
||
|
G3T(LVL) = GV(5)
|
||
|
DA = DX
|
||
|
FV(5) = FV(3)
|
||
|
FV(3) = FV(2)
|
||
|
GV(5) = GV(3)
|
||
|
GV(3) = GV(2)
|
||
|
ESTT(LVL) = ESTR
|
||
|
CONTRB = ESTL
|
||
|
CONTRG = ESTGL
|
||
|
EPS1 = EPS1 * HALF
|
||
|
ERRR(LVL) = EPS1
|
||
|
GO TO 20
|
||
|
C
|
||
|
C ACCEPT APPROXIMATE VALUE FOR INTERVAL.
|
||
|
C
|
||
|
40 IFLAG = 11
|
||
|
50 ERROR = ERROR + ERRL
|
||
|
60 IF (LDIR(LVL) .EQ. 1) GO TO 70
|
||
|
SUM = SUM + PSUM(LVL)
|
||
|
SUMG = SUMG + GSUM(LVL)
|
||
|
LVL = LVL - 1
|
||
|
IF (LVL .GT. 0) GO TO 60
|
||
|
CONTRB = SUM
|
||
|
CONTRG = SUMG
|
||
|
LVL = 1
|
||
|
DLG = ERROR
|
||
|
GO TO 80
|
||
|
C
|
||
|
C RESTORE SAVED INFORMATION TO PROCESS RIGHT HALF.
|
||
|
C
|
||
|
70 PSUM(LVL) = SUM
|
||
|
GSUM(LVL) = SUMG
|
||
|
LDIR(LVL) = 2
|
||
|
DA = DAX / TWO**(LVL-1)
|
||
|
START = START + DX * TWO
|
||
|
FV(1) = F1T(LVL)
|
||
|
FV(3) = F2T(LVL)
|
||
|
FV(5) = F3T(LVL)
|
||
|
GV(1) = G1T(LVL)
|
||
|
GV(3) = G2T(LVL)
|
||
|
GV(5) = G3T(LVL)
|
||
|
CONTRB = ESTT(LVL)
|
||
|
EXCESS = EPS1 - DLG
|
||
|
EPS1 = ERRR(LVL)
|
||
|
IF (EXCESS .GT. ZERO) EPS1 = EPS1 + EXCESS
|
||
|
GO TO 20
|
||
|
80 PROB = PROB + CONTRB
|
||
|
BOUNDG = BOUNDG + CONTRG
|
||
|
BOUNDA = BOUNDA + DLG
|
||
|
IF (Z4 .LE. ZERO) GO TO 90
|
||
|
IF (IFLT .EQ. 0) IFLT = IER
|
||
|
IF (IFLT .EQ. 0) IFLT = IFLAG
|
||
|
BOUNDA = BOUNDA + BOUNDG
|
||
|
IF (BND .LT. BOUNDA) BND = BOUNDA
|
||
|
RETURN
|
||
|
90 EPS1 = ERB2 * HALF
|
||
|
EXCESS = EPS1 - BND
|
||
|
IF (EXCESS .GT. ZERO) EPS1 = EPS1 + EXCESS
|
||
|
START = ONE
|
||
|
DAX = -ONE
|
||
|
GO TO 10
|
||
|
END
|
||
|
FUNCTION SDIST(Y,N)
|
||
|
C
|
||
|
C COMPUTE Y**(N/2 - 1) EXP(-Y) / GAMMA(N/2)
|
||
|
C
|
||
|
C (Revised: 1994-01-19)
|
||
|
C
|
||
|
DATA ZERO, HALF, ONE, X23 / 0.0, 0.5, 1.0, -23.0 /
|
||
|
DATA SQRTPI / 1.77245385090552 /
|
||
|
SDIST = ZERO
|
||
|
IF (Y .LE. ZERO) RETURN
|
||
|
JJ = N/2 - 1
|
||
|
JK = 2 * JJ - N + 2
|
||
|
JKP = JJ - JK
|
||
|
SDIST = ONE
|
||
|
IF (JK .LT. 0) SDIST = SDIST / SQRT(Y) / SQRTPI
|
||
|
IF (JKP .EQ. 0) GO TO 20
|
||
|
XN = FLOAT(N) * HALF
|
||
|
TEST = ALOG(Y) - Y / FLOAT(JKP)
|
||
|
IF ( TEST .LT. X23 ) THEN
|
||
|
SDIST = ZERO
|
||
|
RETURN
|
||
|
ENDIF
|
||
|
SDIST = ALOG ( SDIST )
|
||
|
DO 10 J = 1, JKP
|
||
|
XN = XN - ONE
|
||
|
SDIST = SDIST + TEST - ALOG(XN)
|
||
|
10 CONTINUE
|
||
|
IF ( SDIST .LT. X23 ) THEN
|
||
|
SDIST = ZERO
|
||
|
ELSE
|
||
|
SDIST = EXP( SDIST )
|
||
|
ENDIF
|
||
|
RETURN
|
||
|
20 SDIST = SDIST * EXP(-Y)
|
||
|
RETURN
|
||
|
END
|
||
|
SUBROUTINE FUN (Z,NDF,H,HL,BPD,ERB2,N,INF,D,F0,G0,IERC
|
||
|
* ,HNC,IER)
|
||
|
INTEGER NN
|
||
|
PARAMETER (NN=50)
|
||
|
DIMENSION A(NN),B(NN),H(*),HL(*),BPD(*),INF(*),D(*)
|
||
|
DATA ZERO, ONE, TWO, SMALL / 0.0, 1.0, 2.0, 1.0E-08 /
|
||
|
F0 = ZERO
|
||
|
G0 = ZERO
|
||
|
IF (Z .LE. -ONE .OR. Z .GE. ONE) RETURN
|
||
|
DF = FLOAT(NDF)
|
||
|
ARG = (ONE + Z) / (ONE - Z)
|
||
|
TERM = ARG * DF * TWO / (ONE-Z)**2 * SDIST(DF/TWO*ARG*ARG,NDF)
|
||
|
IF (TERM .LE. SMALL) RETURN
|
||
|
DO 10 I = 1, N
|
||
|
A(I) = ARG * H(I) - D(I)
|
||
|
B(I) = ARG * HL(I) - D(I)
|
||
|
10 CONTINUE
|
||
|
CALL MVNPRD (A,B,BPD,ERB2,N,INF,IERC,HNC,PROB,BND,IFLT)
|
||
|
IF (IER .EQ. 0) IER = IFLT
|
||
|
G0 = TERM * BND
|
||
|
F0 = TERM * PROB
|
||
|
RETURN
|
||
|
END
|
||
|
|
||
|
C * * * * * * * * * * * * * * * * * * * * * * * * * * * *
|
||
|
C Charles Dunnett
|
||
|
C Dept. of Mathematics and Statistics
|
||
|
C McMaster University
|
||
|
C Hamilton, Ontario L8S 4K1
|
||
|
C Canada
|
||
|
C E-mail: dunnett@mcmaster.ca
|
||
|
C Tel.: (905) 525-9140 (Ext. 27104)
|
||
|
C * * * * * * * * * * * * * * * * * * * * * * * * * * * *
|
||
|
END MODULE DUNNETMOD
|