Trailing-Edge
-
PDP-10 Archives
-
decus_20tap2_198111
-
decus/20-0026/canor.ssp
There are 2 other files named canor.ssp in the archive. Click here to see a list.
C CANO 10
���C ..................................................................CANO 20
���C CANO 30
���C SUBROUTINE CANOR CANO 40
���C CANO 50
���C PURPOSE CANO 60
���C COMPUTE THE CANONICAL CORRELATIONS BETWEEN TWO SETS OF CANO 70
���C VARIABLES. CANOR IS NORMALLY PRECEDED BY A CALL TO SUBROU- CANO 80
���C TINE CORRE. CANO 90
���C CANO 100
���C USAGE CANO 110
���C CALL CANOR (N,MP,MQ,RR,ROOTS,WLAM,CANR,CHISQ,NDF,COEFR, CANO 120
���C COEFL,R) CANO 130
���C CANO 140
���C DESCRIPTION OF PARAMETERS CANO 150
���C N - NUMBER OF OBSERVATIONS CANO 160
���C MP - NUMBER OF LEFT HAND VARIABLES CANO 170
���C MQ - NUMBER OF RIGHT HAND VARIABLES CANO 180
���C RR - INPUT MATRIX (ONLY UPPER TRIANGULAR PORTION OF THE CANO 190
���C SYMMETRIC MATRIX OF M X M, WHERE M = MP + MQ) CANO 200
���C CONTAINING CORRELATION COEFFICIENTS. (STORAGE MODE CANO 210
���C OF 1) CANO 220
���C ROOTS - OUTPUT VECTOR OF LENGTH MQ CONTAINING EIGENVALUES CANO 230
���C COMPUTED IN THE NROOT SUBROUTINE. CANO 240
���C WLAM - OUTPUT VECTOR OF LENGTH MQ CONTAINING LAMBDA. CANO 250
���C CANR - OUTPUT VECTOR OF LENGTH MQ CONTAINING CANONICAL CANO 260
���C CORRELATIONS. CANO 270
���C CHISQ - OUTPUT VECTOR OF LENGTH MQ CONTAINING THE CANO 280
���C VALUES OF CHI-SQUARES. CANO 290
���C NDF - OUTPUT VECTOR OF LENGTH MQ CONTAINING THE DEGREES CANO 300
���C OF FREEDOM ASSOCIATED WITH CHI-SQUARES. CANO 310
���C COEFR - OUTPUT MATRIX (MQ X MQ) CONTAINING MQ SETS OF CANO 320
���C RIGHT HAND COEFFICIENTS COLUMNWISE. CANO 330
���C COEFL - OUTPUT MATRIX (MP X MQ) CONTAINING MQ SETS OF CANO 340
���C LEFT HAND COEFFICIENTS COLUMNWISE. CANO 350
���C R - WORK MATRIX (M X M) CANO 360
���C CANO 370
���C REMARKS CANO 380
���C THE NUMBER OF LEFT HAND VARIABLES (MP) SHOULD BE GREATER CANO 390
���C THAN OR EQUAL TO THE NUMBER OF RIGHT HAND VARIABLES (MQ). CANO 400
���C THE VALUES OF CANONICAL CORRELATION, LAMBDA, CHI-SQUARE, CANO 410
���C DEGREES OF FREEDOM, AND CANONICAL COEFFICIENTS ARE COMPUTED CANO 420
���C ONLY FOR THOSE EIGENVALUES IN ROOTS WHICH ARE GREATER THAN CANO 430
���C ZERO. CANO 440
���C CANO 450
���C SUBROUTINES AND FUNCTION SUBPROGRAMS REQUIRED CANO 460
���C MINV CANO 470
���C NROOT (WHICH, IN TURN, CALLS THE SUBROUTINE EIGEN.) CANO 480
���C CANO 490
���C METHOD CANO 500
���C REFER TO W. W. COOLEY AND P. R. LOHNES, 'MULTIVARIATE PRO- CANO 510
���C CEDURES FOR THE BEHAVIORAL SCIENCES', JOHN WILEY AND SONS, CANO 520
���C 1962, CHAPTER 3. CANO 530
���C CANO 540
���C ..................................................................CANO 550
���C CANO 560
��� SUBROUTINE CANOR (N,MP,MQ,RR,ROOTS,WLAM,CANR,CHISQ,NDF,COEFR, CANO 570
��� 1 COEFL,R) CANO 580
��� DIMENSION RR(1),ROOTS(1),WLAM(1),CANR(1),CHISQ(1),NDF(1),COEFR(1),CANO 590
��� 1 COEFL(1),R(1) CANO 600
���C CANO 610
���C ...............................................................CANO 620
���C CANO 630
���C IF A DOUBLE PRECISION VERSION OF THIS ROUTINE IS DESIRED, THE CANO 640
���C C IN COLUMN 1 SHOULD BE REMOVED FROM THE DOUBLE PRECISION CANO 650
���C STATEMENT WHICH FOLLOWS. CANO 660
���C CANO 670
���C DOUBLE PRECISION RR,ROOTS,WLAM,CANR,CHISQ,COEFR,COEFL,R,DET,SUM CANO 680
���C CANO 690
���C THE C MUST ALSO BE REMOVED FROM DOUBLE PRECISION STATEMENTS CANO 700
���C APPEARING IN OTHER ROUTINES USED IN CONJUNCTION WITH THIS CANO 710
���C ROUTINE. CANO 720
���C CANO 730
���C THE DOUBLE PRECISION VERSION OF THIS SUBROUTINE MUST ALSO CANO 740
���C CONTAIN DOUBLE PRECISION FORTRAN FUNCTIONS. SQRT IN STATEMENT CANO 750
���C 165 MUST BE CHANGED TO DSQRT. ALOG IN STATEMENT 175 MUST BE CANO 760
���C CHANGED TO DLOG. CANO 770
���C CANO 780
���C ...............................................................CANO 790
���C CANO 800
���C PARTITION INTERCORRELATIONS AMONG LEFT HAND VARIABLES, BETWEEN CANO 810
���C LEFT AND RIGHT HAND VARIABLES, AND AMONG RIGHT HAND VARIABLES. CANO 820
���C CANO 830
��� M=MP+MQ CANO 840
��� N1=0 CANO 850
��� DO 105 I=1,M CANO 860
��� DO 105 J=1,M CANO 870
��� IF(I-J) 102, 103, 103 CANO 880
��� 102 L=I+(J*J-J)/2 CANO 890
��� GO TO 104 CANO 900
��� 103 L=J+(I*I-I)/2 CANO 910
��� 104 N1=N1+1 CANO 920
��� 105 R(N1)=RR(L) CANO 930
��� L=MP CANO 940
��� DO 108 J=2,MP CANO 950
��� N1=M*(J-1) CANO 960
��� DO 108 I=1,MP CANO 970
��� L=L+1 CANO 980
��� N1=N1+1 CANO 990
��� 108 R(L)=R(N1) CANO1000
��� N2=MP+1 CANO1010
��� L=0 CANO1020
��� DO 110 J=N2,M CANO1030
��� N1=M*(J-1) CANO1040
��� DO 110 I=1,MP CANO1050
��� L=L+1 CANO1060
��� N1=N1+1 CANO1070
��� 110 COEFL(L)=R(N1) CANO1080
��� L=0 CANO1090
��� DO 120 J=N2,M CANO1100
��� N1=M*(J-1)+MP CANO1110
��� DO 120 I=N2,M CANO1120
��� L=L+1 CANO1130
��� N1=N1+1 CANO1140
��� 120 COEFR(L)=R(N1) CANO1150
���C CANO1160
���C SOLVE THE CANONICAL EQUATION CANO1170
���C CANO1180
��� L=MP*MP+1 CANO1190
��� K=L+MP CANO1200
��� CALL MINV (R,MP,DET,R(L),R(K)) CANO1210
���C CANO1220
���C CALCULATE T = INVERSE OF R11 * R12 CANO1230
���C CANO1240
��� DO 140 I=1,MP CANO1250
��� N2=0 CANO1260
��� DO 130 J=1,MQ CANO1270
��� N1=I-MP CANO1280
��� ROOTS(J)=0.0 CANO1290
��� DO 130 K=1,MP CANO1300
��� N1=N1+MP CANO1310
��� N2=N2+1 CANO1320
��� 130 ROOTS(J)=ROOTS(J)+R(N1)*COEFL(N2) CANO1330
��� L=I-MP CANO1340
��� DO 140 J=1,MQ CANO1350
��� L=L+MP CANO1360
��� 140 R(L)=ROOTS(J) CANO1370
���C CANO1380
���C CALCULATE A = R21 * T CANO1390
���C CANO1400
��� L=MP*MQ CANO1410
��� N3=L+1 CANO1420
��� DO 160 J=1,MQ CANO1430
��� N1=0 CANO1440
��� DO 160 I=1,MQ CANO1450
��� N2=MP*(J-1) CANO1460
��� SUM=0.0 CANO1470
��� DO 150 K=1,MP CANO1480
��� N1=N1+1 CANO1490
��� N2=N2+1 CANO1500
��� 150 SUM=SUM+COEFL(N1)*R(N2) CANO1510
��� L=L+1 CANO1520
��� 160 R(L)=SUM CANO1530
���C CANO1540
���C CALCULATE EIGENVALUES WITH ASSOCIATED EIGENVECTORS OF THE CANO1550
���C INVERSE OF R22 * A CANO1560
���C CANO1570
��� L=L+1 CANO1580
��� CALL NROOT (MQ,R(N3),COEFR,ROOTS,R(L)) CANO1590
���C CANO1600
���C FOR EACH VALUE OF I = 1, 2, ..., MQ, CALCULATE THE FOLLOWING CANO1610
���C STATISTICS CANO1620
���C CANO1630
��� DO 210 I=1,MQ CANO1640
���C CANO1650
���C TEST WHETHER EIGENVALUE IS GREATER THAN ZERO CANO1660
���C CANO1670
��� IF(ROOTS(I)) 220, 220, 165 CANO1680
���C CANO1690
���C CANONICAL CORRELATION CANO1700
���C CANO1710
��� 165 CANR(I)= SQRT(ROOTS(I)) CANO1720
���C CANO1730
���C CHI-SQUARE CANO1740
���C CANO1750
��� WLAM(I)=1.0 CANO1760
��� DO 170 J=I,MQ CANO1770
��� 170 WLAM(I)=WLAM(I)*(1.0-ROOTS(J)) CANO1780
��� FN=N CANO1790
��� FMP=MP CANO1800
��� FMQ=MQ CANO1810
��� 175 CHISQ(I)=-(FN-0.5*(FMP+FMQ+1.0))*ALOG(WLAM(I)) CANO1820
���C CANO1830
���C DEGREES OF FREEDOM FOR CHI-SQUARE CANO1840
���C CANO1850
��� N1=I-1 CANO1860
��� NDF(I)=(MP-N1)*(MQ-N1) CANO1870
���C CANO1880
���C I-TH SET OF RIGHT HAND COEFFICIENTS CANO1890
���C CANO1900
��� N1=MQ*(I-1) CANO1910
��� N2=MQ*(I-1)+L-1 CANO1920
��� DO 180 J=1,MQ CANO1930
��� N1=N1+1 CANO1940
��� N2=N2+1 CANO1950
��� 180 COEFR(N1)=R(N2) CANO1960
���C CANO1970
���C I-TH SET OF LEFT HAND COEFFICIENTS CANO1980
���C CANO1990
��� DO 200 J=1,MP CANO2000
��� N1=J-MP CANO2010
��� N2=MQ*(I-1) CANO2020
��� K=MP*(I-1)+J CANO2030
��� COEFL(K)=0.0 CANO2040
��� DO 190 JJ=1,MQ CANO2050
��� N1=N1+MP CANO2060
��� N2=N2+1 CANO2070
��� 190 COEFL(K)=COEFL(K)+R(N1)*COEFR(N2) CANO2080
��� 200 COEFL(K)=COEFL(K)/CANR(I) CANO2090
��� 210 CONTINUE CANO2100
��� 220 RETURN CANO2110
��� END CANO2120
���