Trailing-Edge
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PDP-10 Archives
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decuslib10-02
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43,50145/ahi.ssp
There are 2 other files named ahi.ssp in the archive. Click here to see a list.
C AHI 10
���C ..................................................................AHI 20
���C AHI 30
���C SUBROUTINE AHI AHI 40
���C AHI 50
���C PURPOSE AHI 60
���C TO INTERPOLATE FUNCTION VALUE Y FOR A GIVEN ARGUMENT VALUE AHI 70
���C X USING A GIVEN TABLE (ARG,VAL) OF ARGUMENT, FUNCTION, AND AHI 80
���C DERIVATIVE VALUES. AHI 90
���C AHI 100
���C USAGE AHI 110
���C CALL AHI (X,ARG,VAL,Y,NDIM,EPS,IER) AHI 120
���C AHI 130
���C DESCRIPTION OF PARAMETERS AHI 140
���C X - THE ARGUMENT VALUE SPECIFIED BY INPUT. AHI 150
���C ARG - THE INPUT VECTOR (DIMENSION NDIM) OF ARGUMENT AHI 160
���C VALUES OF THE TABLE (NOT DESTROYED). AHI 170
���C VAL - THE INPUT VECTOR (DIMENSION 2*NDIM) OF FUNCTION AHI 180
���C AND DERIVATIVE VALUES OF THE TABLE (DESTROYED). AHI 190
���C FUNCTION AND DERIVATIVE VALUES MUST BE STORED IN AHI 200
���C PAIRS, THAT MEANS BEGINNING WITH FUNCTION VALUE AT AHI 210
���C POINT ARG(1) EVERY FUNCTION VALUE MUST BE FOLLOWED AHI 220
���C BY THE VALUE OF DERIVATIVE AT THE SAME POINT. AHI 230
���C Y - THE RESULTING INTERPOLATED FUNCTION VALUE. AHI 240
���C NDIM - AN INPUT VALUE WHICH SPECIFIES THE NUMBER OF AHI 250
���C POINTS IN TABLE (ARG,VAL). AHI 260
���C EPS - AN INPUT CONSTANT WHICH IS USED AS UPPER BOUND AHI 270
���C FOR THE ABSOLUTE ERROR. AHI 280
���C IER - A RESULTING ERROR PARAMETER. AHI 290
���C AHI 300
���C REMARKS AHI 310
���C (1) TABLE (ARG,VAL) SHOULD REPRESENT A SINGLE-VALUED AHI 320
���C FUNCTION AND SHOULD BE STORED IN SUCH A WAY, THAT THE AHI 330
���C DISTANCES ABS(ARG(I)-X) INCREASE WITH INCREASING AHI 340
���C SUBSCRIPT I. TO GENERATE THIS ORDER IN TABLE (ARG,VAL), AHI 350
���C SUBROUTINES ATSG, ATSM OR ATSE COULD BE USED IN A AHI 360
���C PREVIOUS STAGE. AHI 370
���C (2) NO ACTION BESIDES ERROR MESSAGE IN CASE NDIM LESS AHI 380
���C THAN 1. AHI 390
���C (3) INTERPOLATION IS TERMINATED EITHER IF THE DIFFERENCE AHI 400
���C BETWEEN TWO SUCCESSIVE INTERPOLATED VALUES IS AHI 410
���C ABSOLUTELY LESS THAN TOLERANCE EPS, OR IF THE ABSOLUTE AHI 420
���C VALUE OF THIS DIFFERENCE STOPS DIMINISHING, OR AFTER AHI 430
���C (2*NDIM-2) STEPS. FURTHER IT IS TERMINATED IF THE AHI 440
���C PROCEDURE DISCOVERS TWO ARGUMENT VALUES IN VECTOR ARG AHI 450
���C WHICH ARE IDENTICAL. DEPENDENT ON THESE FOUR CASES, AHI 460
���C ERROR PARAMETER IER IS CODED IN THE FOLLOWING FORM AHI 470
���C IER=0 - IT WAS POSSIBLE TO REACH THE REQUIRED AHI 480
���C ACCURACY (NO ERROR). AHI 490
���C IER=1 - IT WAS IMPOSSIBLE TO REACH THE REQUIRED AHI 500
���C ACCURACY BECAUSE OF ROUNDING ERRORS. AHI 510
���C IER=2 - IT WAS IMPOSSIBLE TO CHECK ACCURACY BECAUSE AHI 520
���C NDIM IS LESS THAN 2, OR THE REQUIRED ACCURACY AHI 530
���C COULD NOT BE REACHED BY MEANS OF THE GIVEN AHI 540
���C TABLE. NDIM SHOULD BE INCREASED. AHI 550
���C IER=3 - THE PROCEDURE DISCOVERED TWO ARGUMENT VALUES AHI 560
���C IN VECTOR ARG WHICH ARE IDENTICAL. AHI 570
���C AHI 580
���C SUBROUTINES AND FUNCTION SUBPROGRAMS REQUIRED AHI 590
���C NONE AHI 600
���C AHI 610
���C METHOD AHI 620
���C INTERPOLATION IS DONE BY MEANS OF AITKENS SCHEME OF AHI 630
���C HERMITE INTERPOLATION. ON RETURN Y CONTAINS AN INTERPOLATED AHI 640
���C FUNCTION VALUE AT POINT X, WHICH IS IN THE SENSE OF REMARK AHI 650
���C (3) OPTIMAL WITH RESPECT TO GIVEN TABLE. FOR REFERENCE, SEE AHI 660
���C F.B.HILDEBRAND, INTRODUCTION TO NUMERICAL ANALYSIS, AHI 670
���C MCGRAW-HILL, NEW YORK/TORONTO/LONDON, 1956, PP.314-317, AND AHI 680
���C GERSHINSKY/LEVINE, AITKEN-HERMITE INTERPOLATION, AHI 690
���C JACM, VOL.11, ISS.3 (1964), PP.352-356. AHI 700
���C AHI 710
���C ..................................................................AHI 720
���C AHI 730
��� SUBROUTINE AHI(X,ARG,VAL,Y,NDIM,EPS,IER) AHI 740
���C AHI 750
���C AHI 760
��� DIMENSION ARG(1),VAL(1) AHI 770
��� IER=2 AHI 780
��� H2=X-ARG(1) AHI 790
��� IF(NDIM-1)2,1,3 AHI 800
��� 1 Y=VAL(1)+VAL(2)*H2 AHI 810
��� 2 RETURN AHI 820
���C AHI 830
���C VECTOR ARG HAS MORE THAN 1 ELEMENT. AHI 840
���C THE FIRST STEP PREPARES VECTOR VAL SUCH THAT AITKEN SCHEME CAN BE AHI 850
���C USED. AHI 860
��� 3 I=1 AHI 870
��� DO 5 J=2,NDIM AHI 880
��� H1=H2 AHI 890
��� H2=X-ARG(J) AHI 900
��� Y=VAL(I) AHI 910
��� VAL(I)=Y+VAL(I+1)*H1 AHI 920
��� H=H1-H2 AHI 930
��� IF(H)4,13,4 AHI 940
��� 4 VAL(I+1)=Y+(VAL(I+2)-Y)*H1/H AHI 950
��� 5 I=I+2 AHI 960
��� VAL(I)=VAL(I)+VAL(I+1)*H2 AHI 970
���C END OF FIRST STEP AHI 980
���C AHI 990
���C PREPARE AITKEN SCHEME AHI 1000
��� DELT2=0. AHI 1010
��� IEND=I-1 AHI 1020
���C AHI 1030
���C START AITKEN-LOOP AHI 1040
��� DO 9 I=1,IEND AHI 1050
��� DELT1=DELT2 AHI 1060
��� Y=VAL(1) AHI 1070
��� M=(I+3)/2 AHI 1080
��� H1=ARG(M) AHI 1090
��� DO 6 J=1,I AHI 1100
��� K=I+1-J AHI 1110
��� L=(K+1)/2 AHI 1120
��� H=ARG(L)-H1 AHI 1130
��� IF(H)6,14,6 AHI 1140
��� 6 VAL(K)=(VAL(K)*(X-H1)-VAL(K+1)*(X-ARG(L)))/H AHI 1150
��� DELT2=ABS(Y-VAL(1)) AHI 1160
��� IF(DELT2-EPS)11,11,7 AHI 1170
��� 7 IF(I-5)9,8,8 AHI 1180
��� 8 IF(DELT2-DELT1)9,12,12 AHI 1190
��� 9 CONTINUE AHI 1200
���C END OF AITKEN-LOOP AHI 1210
���C AHI 1220
��� 10 Y=VAL(1) AHI 1230
��� RETURN AHI 1240
���C AHI 1250
���C THERE IS SUFFICIENT ACCURACY WITHIN 2*NDIM-2 ITERATION STEPS AHI 1260
��� 11 IER=0 AHI 1270
��� GOTO 10 AHI 1280
���C AHI 1290
���C TEST VALUE DELT2 STARTS OSCILLATING AHI 1300
��� 12 IER=1 AHI 1310
��� RETURN AHI 1320
���C AHI 1330
���C THERE ARE TWO IDENTICAL ARGUMENT VALUES IN VECTOR ARG AHI 1340
��� 13 Y=VAL(1) AHI 1350
��� 14 IER=3 AHI 1360
��� RETURN AHI 1370
��� END AHI 1380