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decuslib10-02
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43,50145/dtlap.ssp
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C DTLA 10
���C ..................................................................DTLA 20
���C DTLA 30
���C SUBROUTINE DTLAP DTLA 40
���C DTLA 50
���C PURPOSE DTLA 60
���C A SERIES EXPANSION IN LAGUERRE POLYNOMIALS WITH INDEPENDENT DTLA 70
���C VARIABLE X IS TRANSFORMED TO A POLYNOMIAL WITH INDEPENDENT DTLA 80
���C VARIABLE Z, WHERE X=A*Z+B DTLA 90
���C DTLA 100
���C USAGE DTLA 110
���C CALL DTLAP(A,B,POL,N,C,WORK) DTLA 120
���C DTLA 130
���C DESCRIPTION OF PARAMETERS DTLA 140
���C A - FACTOR OF LINEAR TERM IN GIVEN LINEAR TRANSFORMATIONDTLA 150
���C DOUBLE PRECISION VARIABLE DTLA 160
���C B - CONSTANT TERM IN GIVEN LINEAR TRANSFORMATION DTLA 170
���C DOUBLE PRECISION VARIABLE DTLA 180
���C POL - COEFFICIENT VECTOR OF POLYNOMIAL (RESULTANT VALUE) DTLA 190
���C COEFFICIENTS ARE ORDERED FROM LOW TO HIGH DTLA 200
���C DOUBLE PRECISION VECTOR DTLA 210
���C N - DIMENSION OF COEFFICIENT VECTORS POL AND C DTLA 220
���C C - GIVEN COEFFICIENT VECTOR OF EXPANSION DTLA 230
���C COEFFICIENTS ARE ORDERED FROM LOW TO HIGH DTLA 240
���C POL AND C MAY BE IDENTICALLY LOCATED DTLA 250
���C DOUBLE PRECISION VECTOR DTLA 260
���C WORK - WORKING STORAGE OF DIMENSION 2*N DTLA 270
���C DOUBLE PRECISION ARRAY DTLA 280
���C DTLA 290
���C REMARKS DTLA 300
���C COEFFICIENT VECTOR C REMAINS UNCHANGED IF NOT COINCIDING DTLA 310
���C WITH COEFFICIENT VECTOR POL. DTLA 320
���C OPERATION IS BYPASSED IN CASE N LESS THAN 1. DTLA 330
���C THE LINEAR TRANSFORMATION X=A*Z+B OR Z=(1/A)(X-B) TRANSFORMSDTLA 340
���C THE RANGE (0,C) IN X TO THE RANGE (ZL,ZR) IN Z, WHERE DTLA 350
���C ZL=-B/A AND ZR=(C-B)/A. DTLA 360
���C FOR GIVEN ZL, ZR AND C WE HAVE A=C/(ZR-ZL) AND DTLA 370
���C B=-C*ZL/(ZR-ZL) DTLA 380
���C DTLA 390
���C SUBROUTINES AND FUNCTION SUBPROGRAMS REQUIRED DTLA 400
���C NONE DTLA 410
���C DTLA 420
���C METHOD DTLA 430
���C THE TRANSFORMATION IS BASED ON THE RECURRENCE EQUATION DTLA 440
���C FOR LAGUERRE POLYNOMIALS L(N,X) DTLA 450
���C L(N+1,X)=2*L(N,X)-L(N-1,X)-((1+X)*L(N,X)-L(N-1,X))/(N+1), DTLA 460
���C WHERE THE FIRST TERM IN BRACKETS IS THE INDEX, DTLA 470
���C THE SECOND IS THE ARGUMENT. DTLA 480
���C STARTING VALUES ARE L(0,X)=1, L(1,X)=1-X. DTLA 490
���C THE TRANSFORMATION IS IMPLICITLY DEFINED BY MEANS OF DTLA 500
���C X=A*Z+B TOGETHER WITH DTLA 510
���C SUM(POL(I)*Z**(I-1), SUMMED OVER I FROM 1 TO N) DTLA 520
���C =SUM(C(I)*L(I-1,X), SUMMED OVER I FROM 1 TO N). DTLA 530
���C DTLA 540
���C ..................................................................DTLA 550
���C DTLA 560
��� SUBROUTINE DTLAP(A,B,POL,N,C,WORK) DTLA 570
���C DTLA 580
��� DIMENSION POL(1),C(1),WORK(1) DTLA 590
��� DOUBLE PRECISION A,B,POL,C,WORK,H,P,Q,Q1,Q2,FI DTLA 600
���C DTLA 610
���C TEST OF DIMENSION DTLA 620
��� IF(N-1)2,1,3 DTLA 630
���C DTLA 640
���C DIMENSION LESS THAN 2 DTLA 650
��� 1 POL(1)=C(1) DTLA 660
��� 2 RETURN DTLA 670
���C DTLA 680
��� 3 POL(1)=C(1)+C(2)-B*C(2) DTLA 690
��� POL(2)=-C(2)*A DTLA 700
��� IF(N-2)2,2,4 DTLA 710
���C DTLA 720
���C INITIALIZATION DTLA 730
��� 4 WORK(1)=1.D0 DTLA 740
��� WORK(2)=1.D0-B DTLA 750
��� WORK(3)=0.D0 DTLA 760
��� WORK(4)=-A DTLA 770
��� FI=1.D0 DTLA 780
���C DTLA 790
���C CALCULATE COEFFICIENT VECTOR OF NEXT LAGUERRE POLYNOMIAL DTLA 800
���C AND ADD MULTIPLE OF THIS VECTOR TO POLYNOMIAL POL DTLA 810
��� DO 6 J=3,N DTLA 820
��� FI=FI+1.D0 DTLA 830
��� Q=1.D0/FI DTLA 840
��� Q1=Q-1.D0 DTLA 850
��� Q2=1.D0-Q1-B*Q DTLA 860
��� Q=Q*A DTLA 870
��� P=0.D0 DTLA 880
���C DTLA 890
��� DO 5 K=2,J DTLA 900
��� H=-P*Q+WORK(2*K-2)*Q2+WORK(2*K-3)*Q1 DTLA 910
��� P=WORK(2*K-2) DTLA 920
��� WORK(2*K-2)=H DTLA 930
��� WORK(2*K-3)=P DTLA 940
��� 5 POL(K-1)=POL(K-1)+H*C(J) DTLA 950
��� WORK(2*J-1)=0.D0 DTLA 960
��� WORK(2*J)=-Q*P DTLA 970
��� 6 POL(J)=C(J)*WORK(2*J) DTLA 980
��� RETURN DTLA 990
��� END DTLA1000