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decuslib10-02
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43,50145/kolm2.ssp
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C KLM2 10
���C ..................................................................KLM2 20
���C KLM2 30
���C SUBROUTINE KOLM2 KLM2 40
���C KLM2 50
���C PURPOSE KLM2 60
���C KLM2 70
���C TESTS THE DIFFERENCE BETWEEN TWO SAMPLE DISTRIBUTION KLM2 80
���C FUNCTIONS USING THE KOLMOGOROV-SMIRNOV TEST KLM2 90
���C KLM2 100
���C USAGE KLM2 110
���C CALL KOLM2(X,Y,N,M,Z,PROB) KLM2 120
���C KLM2 130
���C DESCRIPTION OF PARAMETERS KLM2 140
���C X - INPUT VECTOR OF N INDEPENDENT OBSERVATIONS. ON KLM2 150
���C RETURN FROM KOLM2, X HAS BEEN SORTED INTO A KLM2 160
���C MONOTONIC NON-DECREASING SEQUENCE. KLM2 170
���C Y - INPUT VECTOR OF M INDEPENDENT OBSERVATIONS. ON KLM2 180
���C RETURN FROM KOLM2, Y HAS BEEN SORTED INTO A KLM2 190
���C MONOTONIC NON-DECREASING SEQUENCE. KLM2 200
���C N - NUMBER OF OBSERVATIONS IN X KLM2 210
���C M - NUMBER OF OBSERVATIONS IN Y KLM2 220
���C Z - OUTPUT VARIABLE CONTAINING THE GREATEST VALUE WITH KLM2 230
���C RESPECT TO THE SPECTRUM OF X AND Y OF KLM2 240
���C SQRT((M*N)/(M+N))*ABS(FN(X)-GM(Y)) WHERE KLM2 250
���C FN(X) IS THE EMPIRICAL DISTRIBUTION FUNCTION OF THE KLM2 260
���C SET (X) AND GM(Y) IS THE EMPIRICAL DISTRIBUTION KLM2 270
���C FUNCTION OF THE SET (Y). KLM2 280
���C PROB - OUTPUT VARIABLE CONTAINING THE PROBABILITY OF KLM2 290
���C THE STATISTIC BEING GREATER THAN OR EQUAL TO Z IF KLM2 300
���C THE HYPOTHESIS THAT X AND Y ARE FROM THE SAME PDF IS KLM2 310
���C TRUE. E.G., PROB= 0.05 IMPLIES THAT ONE CAN REJECT KLM2 320
���C THE NULL HYPOTHESIS THAT THE SETS X AND Y ARE FROM KLM2 330
���C THE SAME DENSITY WITH 5 PER CENT PROBABILITY OF BEINGKLM2 340
���C INCORRECT. PROB = 1. - SMIRN(Z). KLM2 350
���C KLM2 360
���C REMARKS KLM2 370
���C N AND M SHOULD BE GREATER THAN OR EQUAL TO 100. (SEE THE KLM2 380
���C MATHEMATICAL DESCRIPTION FOR THIS SUBROUTINE AND FOR THE KLM2 390
���C SUBROUTINE SMIRN, CONCERNING ASYMPTOTIC FORMULAE). KLM2 400
���C KLM2 410
���C DOUBLE PRECISION USAGE---IT IS DOUBTFUL THAT THE USER WILL KLM2 420
���C WISH TO PERFORM THIS TEST USING DOUBLE PRECISION ACCURACY. KLM2 430
���C IF ONE WISHES TO COMMUNICATE WITH KOLM2 IN A DOUBLE KLM2 440
���C PRECISION PROGRAM, HE SHOULD CALL THE FORTRAN SUPPLIED KLM2 450
���C PROGRAM SNGL(X) PRIOR TO CALLING KOLM2, AND CALL THE KLM2 460
���C FORTRAN SUPPLIED PROGRAM DBLE(X) AFTER EXITING FROM KOLM2. KLM2 470
���C (NOTE THAT SUBROUTINE SMIRN DOES HAVE DOUBLE PRECISION KLM2 480
���C CAPABILITY AS SUPPLIED BY THIS PACKAGE.) KLM2 490
���C KLM2 500
���C KLM2 510
���C SUBROUTINES AND FUNCTION SUBPROGRAMS REQUIRED KLM2 520
���C SMIRN KLM2 530
���C KLM2 540
���C METHOD KLM2 550
���C FOR REFERENCE, SEE (1) W. FELLER--ON THE KOLMOGOROV-SMIRNOV KLM2 560
���C LIMIT THEOREMS FOR EMPIRICAL DISTRIBUTIONS-- KLM2 570
���C ANNALS OF MATH. STAT., 19, 1948. 177-189, KLM2 580
���C (2) N. SMIRNOV--TABLE FOR ESTIMATING THE GOODNESS OF FIT KLM2 590
���C OF EMPIRICAL DISTRIBUTIONS--ANNALS OF MATH. STAT., 19, KLM2 600
���C 1948. 279-281. KLM2 610
���C (3) R. VON MISES--MATHEMATICAL THEORY OF PROBABILITY AND KLM2 620
���C STATISTICS--ACADEMIC PRESS, NEW YORK, 1964. 490-493, KLM2 630
���C (4) B.V. GNEDENKO--THE THEORY OF PROBABILITY--CHELSEA KLM2 640
���C PUBLISHING COMPANY, NEW YORK, 1962. 384-401. KLM2 650
���C KLM2 660
���C ..................................................................KLM2 670
���C KLM2 680
��� SUBROUTINE KOLM2(X,Y,N,M,Z,PROB) KLM2 690
��� DIMENSION X(1),Y(1) KLM2 700
���C KLM2 710
���C SORT X INTO ASCENDING SEQUENCE KLM2 720
���C KLM2 730
��� DO 5 I=2,N KLM2 740
��� IF(X(I)-X(I-1))1,5,5 KLM2 750
��� 1 TEMP=X(I) KLM2 760
��� IM=I-1 KLM2 770
��� DO 3 J=1,IM KLM2 780
��� L=I-J KLM2 790
��� IF(TEMP-X(L))2,4,4 KLM2 800
��� 2 X(L+1)=X(L) KLM2 810
��� 3 CONTINUE KLM2 820
��� X(1)=TEMP KLM2 830
��� GO TO 5 KLM2 840
��� 4 X(L+1)=TEMP KLM2 850
��� 5 CONTINUE KLM2 860
���C KLM2 870
���C SORT Y INTO ASCENDING SEQUENCE KLM2 880
���C KLM2 890
��� DO 10 I=2,M KLM2 900
��� IF(Y(I)-Y(I-1))6,10,10 KLM2 910
��� 6 TEMP=Y(I) KLM2 920
��� IM=I-1 KLM2 930
��� DO 8 J=1,IM KLM2 940
��� L=I-J KLM2 950
��� IF(TEMP-Y(L))7,9,9 KLM2 960
��� 7 Y(L+1)=Y(L) KLM2 970
��� 8 CONTINUE KLM2 980
��� Y(1)=TEMP KLM2 990
��� GO TO 10 KLM21000
��� 9 Y(L+1)=TEMP KLM21010
��� 10 CONTINUE KLM21020
���C KLM21030
���C CALCULATE D = ABS(FN-GM) OVER THE SPECTRUM OF X AND Y KLM21040
���C KLM21050
��� XN=FLOAT(N) KLM21060
��� XN1=1./XN KLM21070
��� XM=FLOAT(M) KLM21080
��� XM1=1./XM KLM21090
��� D=0.0 KLM21100
��� I=0 KLM21110
��� J=0 KLM21120
��� K=0 KLM21130
��� L=0 KLM21140
��� 11 IF(X(I+1)-Y(J+1))12,13,18 KLM21150
��� 12 K=1 KLM21160
��� GO TO 14 KLM21170
��� 13 K=0 KLM21180
��� 14 I=I+1 KLM21190
��� IF(I-N)15,21,21 KLM21200
��� 15 IF(X(I+1)-X(I))14,14,16 KLM21210
��� 16 IF(K)17,18,17 KLM21220
���C KLM21230
���C CHOOSE THE MAXIMUM DIFFERENCE, D KLM21240
���C KLM21250
��� 17 D=AMAX1(D,ABS(FLOAT(I)*XN1-FLOAT(J)*XM1)) KLM21260
��� IF(L)22,11,22 KLM21270
��� 18 J=J+1 KLM21280
��� IF(J-M)19,20,20 KLM21290
��� 19 IF(Y(J+1)-Y(J))18,18,17 KLM21300
��� 20 L=1 KLM21310
��� GO TO 17 KLM21320
��� 21 L=1 KLM21330
��� GO TO 16 KLM21340
���C KLM21350
���C CALCULATE THE STATISTIC Z KLM21360
���C KLM21370
��� 22 Z=D*SQRT((XN*XM)/(XN+XM)) KLM21380
���C KLM21390
���C CALCULATE THE PROBABILITY ASSOCIATED WITH Z KLM21400
���C KLM21410
��� CALL SMIRN(Z,PROB) KLM21420
��� PROB=1.0-PROB KLM21430
��� RETURN KLM21440
��� END KLM21450