| blob | bec21a1fc87f61687cf73cba6a341bfccd7c2f03 |
1 ;;; -*- Mode: Lisp; Package: Maxima; Syntax: Common-Lisp; Base: 10 -*- ;;;;
2 ;;;
3 ;;; ** (c) Copyright 1976, 1983 Massachusetts Institute of Technology **
4 ;;;
5 ;;;
6 ;;; These are the main routines for finding the Laplace Transform
7 ;;; of special functions --- written by Yannis Avgoustis
8 ;;; --- modified by Edward Lafferty
9 ;;; Latest mod by jpg 8/21/81
10 ;;;
11 ;;; This program uses the programs on ELL;HYP FASL.
12 ;;;
13 ;;; References:
14 ;;;
15 ;;; Definite integration using the generalized hypergeometric functions
16 ;;; Avgoustis, Ioannis Dimitrios
17 ;;; Thesis. 1977. M.S.--Massachusetts Institute of Technology. Dept.
18 ;;; of Electrical Engineering and Computer Science
19 ;;; http://dspace.mit.edu/handle/1721.1/16269
20 ;;;
21 ;;; Avgoustis, I. D., Symbolic Laplace Transforms of Special Functions,
22 ;;; Proceedings of the 1977 MACSYMA Users' Conference, pp 21-41
29 $expintrep))
34 ;; The properties NOUN and VERB give correct linear display
39 "Return noun form instead of internal Lisp symbols for integrals
48 ;; The variables *var* and *par* are global to this file only.
49 ;; They are initialized in the routine defexec. The values are never changed.
50 ;; These globals are introduced to avoid passing the values of *par* and *var*
51 ;; through all functions of this file.
58 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
60 ;;; Helper function for this file
66 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
68 ;;; Test functions for pattern match, which use the globals var and *par*
77 ;;; Test functions which do not depend on globals
79 ;; Test if EXP is 1 or %e.
96 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
98 ;;; Some shortcuts for special functions.
100 ;; Lommel's little s[u,v](z) function.
104 ;; Whittaker's M function
108 ;; Whittaker's W function
112 ;; Jacobi P
116 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
118 ;;; Two general pattern for the routine lt-sf-log.
120 ;; Recognize c*u^v + a and a=0.
129 ;; Recognize c*u^v*(a+b*u)^w+d and d=0. This is a generalization of arbpow1.
141 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
143 ;;; The pattern to match special functions in the routine lt-sf-log.
145 ;; Recognize asin(w)
153 ;; Recognize atan(w)
161 ;; Recognize bessel_j(v,w)
170 ;; Recognize bessel_j(v1,w1)*bessel_j(v2,w2)
180 ;; Recognize bessel_y(v1,w1)*bessel_y(v2,w2)
190 ;; Recognize bessel_k(v1,w1)*bessel_k(v2,w2)
200 ;; Recognize bessel_k(v1,w1)*bessel_y(v2,w2)
210 ;; Recognize bessel_j(v,w)^2
221 ;; Recognize bessel_y(v,w)^2
232 ;; Recognize bessel_k(v,w)^2
243 ;; Recognize bessel_i(v,w)
252 ;; Recognize bessel_i(v1,w1)*bessel_i(v2,w2)
262 ;; Recognize hankel_1(v1,w1)*hankel_1(v2,w2), product of 2 Hankel 1 functions.
272 ;; Recognize hankel_2(v1,w1)*hankel_2(v2,w2), product of 2 Hankel 2 functions.
282 ;; Recognize hankel_1(v1,w1)*hankel_2(v2,w2), product of 2 Hankel functions.
292 ;; Recognize bessel_y(v1,w1)*bessel_j(v2,w2)
302 ;; Recognize bessel_k(v1,w1)*bessel_j(v2,w2)
312 ;; Recognize bessel_y(v1,w1)*hankel_1(v2,w2)
322 ;; Recognize bessel_y(v1,w1)*hankel_2(v2,w2)
332 ;; Recognize bessel_k(v1,w1)*hankel_1(v2,w2)
342 ;; Recognize bessel_k(v1,w1)*hankel_2(v2,w2)
352 ;; Recognize bessel_i(v1,w1)*bessel_j(v2,w2)
362 ;; Recognize bessel_i(v1,w1)*hankel_1(v2,w2)
372 ;; Recognize bessel_i(v1,w1)*hankel_2(v2,w2)
382 ;; Recognize hankel_1(v1,w1)*bessel_j(v2,w2)
392 ;; Recognize hankel_2(v1,w1)*bessel_j(v2,w2)
402 ;; Recognize bessel_i(v1,w1)*bessel_y(v2,w2)
412 ;; Recognize bessel_i(v1,w1)*bessel_k(v2,w2)
422 ;; Recognize bessel_i(v,w)^2
433 ;; Recognize hankel_1(v,w)^2
444 ;; Recognize hankel_2(v,w)^2
455 ;; Recognize bessel_y(v,w)
464 ;; Recognize bessel_k(v,w)
473 ;; Recognize hankel_1(v,w)
482 ;; Recognize hankel_2(v,w)
491 ;; Recognize log(w)
500 ;; Recognize erf(w)
509 ;; Recognize erfc(w)
518 ;; Recognize fresnel_s(w)
527 ;; Recognize fresnel_c(w)
536 ;; Recognize expintegral_e(v,w)
545 ;; Recognize expintegral_ei(w)
554 ;; Recognize expintegral_e1(w)
563 ;; Recognize expintegral_si(w)
572 ;; Recognize expintegral_shi(w)
581 ;; Recognize expintegral_ci(w)
590 ;; Recognize expintegral_chi(w)
599 ;; Recognize kelliptic(w), (new would be elliptic_kc)
608 ;; Recognize elliptic_kc
617 ;; Recognize %e(w), (new would be elliptic_ec)
626 ;; Recognize elliptic_ec
635 ;; Recognize gamma_incomplete(w1, w2), Incomplete Gamma function
644 ;; Recognize gamma_incomplete_lower(w1,w2), gamma(a)-gamma_incomplete(w1,w2)
653 ;; Recognize Struve H function.
662 ;; Recognize Struve L function.
671 ;; Recognize Lommel s[v1,v2](w) function.
681 ;; Recognize S[v1,v2](w), Lommel function
691 ;; Recognize parabolic_cylinder_d function
700 ;; Recognize kbatmann(v,w), Batemann function
710 ;; Recognize %l[v1,v2](w), Generalized Laguerre function
720 ;; Recognize gen_laguerre(v1,v2,w), Generalized Laguerre function
729 ;; Recognize laguerre(v1,w), Laguerre function
738 ;; Recognize %c[v1,v2](w), Gegenbauer function
748 ;; Recognize %t[v1](w), Chebyshev function of the first kind
757 ;; Recognize %u[v1](w), Chebyshev function of the second kind
766 ;; Recognize %p[v1,v2,v3](w), Jacobi function
777 ;; Recognize jacobi_p function
787 ;; Recognize %p[v1,v2](w), Associated Legendre P function
797 ;; Recognize assoc_legendre_p function
806 ;; Recognize %p[v1](w), Legendre P function
815 ;; Recognize %p[v1](w), Legendre P function
824 ;; Recognize hermite(v1,w), Hermite function
833 ;; Recognize %q[v1,v2](w), Associated Legendre function of the second kind
843 ;; Recognize assoc_legendre_q function
852 ;; Recognize %w[v1,v2](w), Whittaker W function.
862 ;; Recognize whittaker_w function.
871 ;; Recognize %m[v1,v2](w), Whittaker M function
881 ;; Recognize whittaker_m function.
890 ;; Recognize %f[v1,v2](w1,w2,w3), Hypergeometric function
903 ;; Recognize hypergeometric function
912 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
914 ;;; Pattern for the routine hypgeo-exec.
915 ;;; RECOGNIZES L.T.E. "U*%E^(A*X+E*F(X)-P*X+C)+D".
923 $%e
931 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
933 ;;; Pattern for the routine defexec.
934 ;;; This is trying to match EXP to u*%e^(a*x+e*f+c)+d
935 ;;; where a, c, and e are free of x, f is free of p, and d is 0.
943 $%e
950 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
952 ;;; $specint is the Maxima User function
960 ;; This used to have $exponentialize enabled for everything, but I
961 ;; don't think we should do that. If various routines want
962 ;; $exponentialize, let them set it themselves. So, for here, we
963 ;; want to expand the form with $exponentialize to convert trig and
964 ;; hyperbolic functions to exponential functions that we can handle.
968 ;; Because we call defintegrate recursively, we add code to end the
969 ;; recursion safely.
975 ;; We try to find a constant denominator. This is necessary to get results
976 ;; for integrands like u(t)/(a+b+c+...).
983 ;; We search for a sum of Exponential functions which we can integrate.
984 ;; This code finds result for Trigonometric or Hyperbolic functions with
985 ;; a factor t^-1 or t^-2 e.g. t^-1*sin(a*t).
993 ;; c * t^-1 * (%e^(-a*t) - %e^(-b*t)) + d
1002 ;; c * t^(-3/2) * (%e^(-a*t) - %e^(-b*t)) + d
1014 ;; c * t^-2 * (1 - 2 * %e^(-a*t) + %e^(2*a*t)) + d
1025 ;; c * t^-1 * (1 - 2 * %e^(-a*t) + %e^(2*a*t)) + d
1038 ;; c * t^-1 * (1 - %e^(2*a*t)) + d
1046 ;; At this point we expand the integrand.
1049 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1051 ;;; Five pattern to find sums of Exponential functions which we can integrate.
1053 ;; Case 1: c * u^-1 * (%e^(-a*u) - %e^(-b*u))
1073 ;; Case 2: c * u^(-3/2) * (%e^(-a*u) - %e^(-b*u))
1093 ;; Case 3: c * u^-2 * (1 - 2 * %e^(-a*u) + %e^(2*a*u))
1116 ;; Case 4: c * t^-1 * (1 - 2 * %e^(-a*t) + %e^(2*a*t))
1139 ;; Case 5: c* t^-1 * (1 - %e^(2*a*t))
1155 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1157 ;;; Test functions for the pattern m2-sum-with-exp-case<n>
1168 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1170 ;;; Called by defintegrate.
1171 ;;; Call for every term of a sum defexec and add up the results.
1173 ;; Evaluate the transform of a sum as sum of transforms.
1179 ;; FUN is a list of addends. Compute the transform of each addend and
1180 ;; add them up.
1186 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1188 ;;; Called after transformation of a integrand to a new representation.
1189 ;;; Evalutate the tansform of a sum as sum of transforms.
1194 ;; Compute r*exp(-p*t), where t is the variable of integration and
1195 ;; p is the parameter of the Laplace transform.
1211 ;; It dispatches according to the kind of transform it matches.
1223 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1225 ;;; Compute transform of EXP wrt the variable of integration VAR.
1235 ;; If we have not found a parameter, we try to factor the integrand.
1242 ;; EXP is an expression of the form u*%e^(s*t+e*f+c). So s
1243 ;; is basically the parameter of the Laplace transform.
1245 ;; At this point we construct the noun form if one of the
1246 ;; called routines set the global flag. If the global flag
1247 ;; is not set, the noun form has been already constructed.
1250 result)))
1252 ;; If necessary we construct the noun form.
1257 ;; L is the integrand of the transform, after pattern matching. S is
1258 ;; the parameter (p) of the transform.
1262 ;; The parameter of transform must have a negative
1263 ;; realpart. Break out the integrand into its various
1264 ;; components.
1270 ;; To compute the transform, we replace A with PSEY for
1271 ;; simplicity. After the transform is computed, replace
1272 ;; PSEY with A.
1273 ;;
1274 ;; FIXME: Sometimes maxima will ask for the sign of PSEY.
1275 ;; But that doesn't occur in the original expression, so
1276 ;; it's very confusing. What should we do?
1278 ;; We know psey must be positive. psey is a substitution
1279 ;; for the paratemter a and we have checked the sign.
1280 ;; So it is the best to add a rule for the sign of psey.
1291 ;; We forget the rule after finishing the calculation.
1297 ;; Compute the transform of
1298 ;;
1299 ;; U * %E^(-VAR * (*PAR* - PAR0) + E*F + C)
1304 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1306 ;;; Compute the transform of u*%e^(-p*t+e*f)
1311 ;; We have found a summation.
1320 ;; We have found the Unit Step function.
1329 ;; The simple case of u*%e^(-p*t)
1333 ;; We have u*%e^(-p*t+e*f). Try to see if U is of the form
1334 ;; c*t^v. If so, we can handle it here.
1337 ;; The complicated case. Remove the e*f term and move it to u.
1340 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1342 ;;; Pattern for the routine lt-exec
1344 ;; Recognize c*sum(u,index,low,high)
1353 ;; Recognize u(t)*unit_step(x-a)
1362 ;; Recognize c*t^v.
1363 ;; This is a duplicate of m2-arbpow1. Look if we can use it.
1370 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1371 ;;;
1372 ;;; Algorithm 1: Laplace transform of c*t^v*exp(-s*t+e*f)
1373 ;;;
1374 ;;; L contains the pattern for c*t^v.
1375 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1384 ;; We don't do the transformation at this place. Because we take the
1385 ;; square of e we lost the sign and get wrong results.
1386 ;(setq e (mul* e e (inv 4)) v (add v 1))
1399 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1401 ;;; Pattern for the routine lt-exp
1403 ;; Recognize t^2
1407 ;; Recognize sqrt(t)
1411 ;; Recognize t^-1
1415 ;; Recognize %e^-t
1419 ;; Recognize %e^t
1423 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1424 ;;;
1425 ;;; Algorithm 1.1: Laplace transform of c*t^v*exp(-a*t^2)
1426 ;;;
1427 ;;; Table of Integral Transforms
1428 ;;;
1429 ;;; p. 146, formula 24:
1430 ;;;
1431 ;;; t^(v-1)*exp(-t^2/8/a)
1432 ;;; -> gamma(v)*2^v*a^(v/2)*exp(a*p^2)*D[-v](2*p*sqrt(a))
1433 ;;;
1434 ;;; Re(a) > 0, Re(v) > 0
1435 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1440 ;; Both a and v must be positive
1454 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1455 ;;;
1456 ;;; Algorithm 1.2: Laplace transform of c*t^v*exp(-a*sqrt(t))
1457 ;;;
1458 ;;; Table of Integral Transforms
1459 ;;;
1460 ;;; p. 147, formula 35:
1461 ;;;
1462 ;;; (2*t)^(v-1)*exp(-2*sqrt(a)*sqrt(t))
1463 ;;; -> gamma(2*v)*p^(-v)*exp(a/p/2)*D[-2*v](sqrt(2*a/p))
1464 ;;;
1465 ;;; Re(v) > 0, Re(p) > 0
1466 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1468 ;; Check if conditions for f35p147 hold
1471 ;; v must be positive
1474 ;; Set a global flag. When *hyp-return-noun-form-p* is T the noun
1475 ;; form will be constructed in the routine DEFEXEC.
1479 ;; We have not done the calculation v->v+1 and a-> a^2/4
1480 ;; and subsitute here accordingly.
1487 ;; We need an additional factor -1 to get the expected results.
1488 ;; What is the mathematically reason?
1492 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1494 ;; Express a parabolic cylinder function as either a parabolic
1495 ;; cylinder function or as hypergeometric function.
1496 ;;
1497 ;; Tables of Integral Transforms, p. 386 gives this definition:
1498 ;;
1499 ;; D[v](z) = 2^(v/2+1/4)*z^(-1/2)*W[v/2+1/4,1/4](z^2/2)
1505 ;; At this time the Parabolic Cylinder D function is not implemented
1506 ;; as a simplifying function. We call nevertheless the simplifer
1507 ;; to simplify the arguments. When we implement the function
1508 ;; The symbol has to be changed to the noun form.
1517 ;; Return T if a is a non-positive integer.
1518 ;; (Do we really want maxima-integerp or hyp-integerp here?)
1524 ;; Express parabolic cylinder function as a hypergeometric function.
1525 ;;
1526 ;; A&S 19.3.1 says
1527 ;;
1528 ;; U(a,x) = D[-a-1/2](x)
1529 ;;
1530 ;; and A&S 19.12.3 gives
1531 ;;
1532 ;; U(a,+/-x) = sqrt(%pi)*2^(-1/4-a/2)*exp(-x^2/4)/gamma(3/4+a/2)
1533 ;; *M(a/2+1/4,1/2,x^2/2)
1534 ;; -/+ sqrt(%pi)*2^(1/4-a/2)*x*exp(-x^2/4)/gamma(1/4+a/2)
1535 ;; *M(a/2+3/4,3/2,x^2/2)
1536 ;;
1537 ;; So
1538 ;;
1539 ;; D[v](z) = U(-v-1/2,z)
1540 ;; = sqrt(%pi)*2^(v/2+1/2)*x*exp(-x^2/4)
1541 ;; *M(1/2-v/2,3/2,x^2/2)/gamma(-v/2)
1542 ;; + sqrt(%pi)*2^(v/2)*exp(-x^2/4)/gamma(1/2-v/2)
1543 ;; *M(-v/2,1/2,x^2/2)
1549 z
1552 pow
1558 pow
1564 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1565 ;;;
1566 ;;; Algorithm 1.3: Laplace transform of t^v*exp(1/t)
1567 ;;;
1568 ;;; Table of Integral Transforms
1569 ;;;
1570 ;;; p. 146, formula 29:
1571 ;;;
1572 ;;; t^(v-1)*exp(-a/t/4)
1573 ;;; -> 2*(a/p/4)^(v/2)*bessel_k(v, sqrt(a)*sqrt(p))
1574 ;;;
1575 ;;; Re(a) > 0
1576 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1578 ;; Check if conditions for f29p146test hold
1591 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1593 ;; bessel_k(v, sqrt(a)*sqrt(p)) in terms of bessel_k or in terms of
1594 ;; hypergeometric functions.
1595 ;;
1596 ;; Choose bessel_k if the order v is an integer. (Why?)
1605 ;; Express the Bessel K function in terms of hypergeometric functions.
1606 ;;
1607 ;; K[v](z) = %pi/2*(bessel_i(-v,z)-bessel(i,z))/sin(v*%pi)
1608 ;;
1609 ;; and
1610 ;;
1611 ;; bessel_i(v,z) = (z/2)^v/gamma(v+1)*0F1(;v+1;z^2/4)
1629 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1630 ;;;
1631 ;;; Algorithm 1.4: Laplace transform of exp(exp(-t))
1632 ;;;
1633 ;;; Table of Integral Transforms
1634 ;;;
1635 ;;; p. 147, formula 36:
1636 ;;;
1637 ;;; exp(-a*exp(-t))
1638 ;;; -> a^(-p)*gamma(p,a)
1639 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1647 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1648 ;;;
1649 ;;; Algorithm 1.5: Laplace transform of exp(exp(t))
1650 ;;;
1651 ;;; Table of Integral Transforms
1652 ;;;
1653 ;;; p. 147, formula 36:
1654 ;;;
1655 ;;; exp(-a*exp(t))
1656 ;;; -> a^(-p)*gamma_incomplete(-p,a)
1657 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1664 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1665 ;;;
1666 ;;; Algorithm 2: Laplace transform of u(t)*%e^(-p*t).
1667 ;;;
1668 ;;; u contains one or more special functions. Dispatches according to the
1669 ;;; special functions involved in the Laplace transformable expression.
1670 ;;;
1671 ;;; We have three general types of integrands:
1672 ;;;
1673 ;;; 1. Call a function to return immediately the Laplace transform,
1674 ;;; e.g. call lt-arbpow, lt-arbpow2, lt-log, whittest to return the
1675 ;;; Laplace transform.
1676 ;;; 2. Call lt-ltp directly or via an "expert function on Laplace transform",
1677 ;;; transform the special function to a representation in terms of one
1678 ;;; hypergeometric function and do the integration
1679 ;;; e.g. for a direct call of lt-ltp asin, atan or via lt2j for
1680 ;;; an integrand with two bessel function.
1681 ;;; 3. Call fractest, fractest1, ... which transform the involved special
1682 ;;; function to a new representation. Send the transformed expression with
1683 ;;; the routine sendexec to the integrator and try to integrate the new
1684 ;;; representation, e.g. gamma_incomplete is first transformed to a new
1685 ;;; representation.
1686 ;;;
1687 ;;; The ordering of the calls to match a pattern is important.
1688 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1693 ;; Laplace transform of asin(w)
1699 ;; Laplace transform of atan(w)
1705 ;; Laplace transform of two Bessel J functions
1714 ;; Laplace transform of two hankel_1 functions
1721 ;; Call the code for the symbol %h.
1724 ;; Laplace transform of two hankel_2 functions
1731 ;; Call the code for the symbol %h.
1734 ;; Laplace transform of hankel_1 * hankel_2
1741 ;; Call the code for the symbol %h.
1744 ;; Laplace transform of two Bessel Y functions
1753 ;; Laplace transform of two Bessel K functions
1762 ;; Laplace transform of Bessel K and Bessel Y functions
1771 ;; Laplace transform of Bessel I and Bessel J functions
1781 ;; Laplace transform of Bessel I and Hankel 1 functions
1790 ;; Laplace transform of Bessel I and Hankel 2 functions
1799 ;; Laplace transform of Bessel Y and Bessel J functions
1808 ;; Laplace transform of Bessel K and Bessel J functions
1817 ;; Laplace transform of Hankel 1 and Bessel J functions
1826 ;; Laplace transform of Hankel 2 and Bessel J functions
1835 ;; Laplace transform of Bessel Y and Hankel 1 functions
1844 ;; Laplace transform of Bessel Y and Hankel 2 functions
1853 ;; Laplace transform of Bessel K and Hankel 1 functions
1862 ;; Laplace transform of Bessel K and Hankel 2 functions
1871 ;; Laplace transform of Bessel I and Bessel Y functions
1880 ;; Laplace transform of Bessel I and Bessel K functions
1889 ;; Laplace transform of Struve H function
1896 ;; Laplace transform of Struve L function
1903 ;; Laplace transform of little Lommel s function
1911 ;; Laplace transform of Lommel S function
1919 ;; Laplace transform of Bessel Y function
1926 ;; Laplace transform of Bessel K function
1932 ;; Special case for a zero index
1937 ;; Laplace transform of Parabolic Cylinder function
1944 ;; Laplace transform of Incomplete Gamma function
1951 ;; Laplace transform of Batemann function
1958 ;; Laplace transform of Bessel J function
1965 ;; Laplace transform of lower incomplete Gamma function
1972 ;; Laplace transform of Hankel 1 function
1979 ;; Laplace transform of Hankel 2 function
1986 ;; Laplace transform of Whittaker M function
1994 ;; Laplace transform of Whittaker M function
2002 ;; Laplace transform of the Generalized Laguerre function, %l[v1,v2](w)
2010 ;; Laplace transform for the Generalized Laguerre function
2011 ;; We call the routine for %l[v1,v2](w).
2019 ;; Laplace transform for the Laguerre function
2020 ;; We call the routine for %l[v1,0](w).
2027 ;; Laplace transform of Gegenbauer function
2035 ;; Laplace transform of Chebyshev function of the first kind
2042 ;; Laplace transform of Chebyshev function of the second kind
2049 ;; Laplace transform for the Hermite function, hermite(index1,arg1)
2058 ;; When index1 is an even or odd integer, we transform
2059 ;; directly to a hypergeometric function. For this case we
2060 ;; get a Laplace transform when the arg is the
2061 ;; square root of the variable.
2066 ;; Laplace transform of %p[v1,v2](w), Associated Legendre P function
2074 ;; Laplace transform of Associated Legendre P function
2082 ;; Laplace transform of %p[v1,v2,v3](w), Jacobi function
2091 ;; Laplace transform of Jacobi P function
2100 ;; Laplace transform of Associated Legendre function of the second kind
2108 ;; Laplace transform of Associated Legendre function of the second kind
2116 ;; Laplace transform of %p[v1](w), Legendre P function
2119 index11 0
2124 ;; Laplace transform of Legendre P function
2131 ;; Laplace transform of Whittaker W function
2139 ;; Laplace transform of Whittaker W function
2147 ;; Laplace transform of square of Bessel J function
2154 ;; Laplace transform of square of Hankel 1 function
2161 ;; Laplace transform of square of Hankel 2 function
2168 ;; Laplace transform of square of Bessel Y function
2175 ;; Laplace transform of square of Bessel K function
2182 ;; Laplace transform of two Bessel I functions
2193 ;; Laplace transform of Bessel I. We use I[v](w)=%i^n*J[n](%i*w).
2200 ;; Laplace transform of square of Bessel I function
2209 ;; Laplace transform of Erf function
2215 ;; Laplace transform of the logarithmic function.
2216 ;; We add an algorithm for the Laplace transform and call the routine
2217 ;; lt-log. The old code is still present, but isn't called.
2223 ;; Laplace transform of Erfc function
2229 ;; Laplace transform of expintegral_ei.
2230 ;; Maxima uses the build in transformation to the gamma_incomplete
2231 ;; function and simplifies the log functions of the transformation. We do
2232 ;; not use the dispatch mechanism of fractest2, but call sendexec directly
2233 ;; with the transformed function.
2241 ;; Laplace transform of expintegral_e1
2249 ;; Laplace transform of expintegral_e
2258 ;; Laplace transform of expintegral_si
2262 ;; We transform to the hypergeometric representation.
2266 ;; Laplace transform of expintegral_shi
2270 ;; We transform to the hypergeometric representation.
2274 ;; Laplace transform of expintegral_ci
2278 ;; We transform to the hypergeometric representation.
2279 ;; Because we have Logarithmic terms in the transformation,
2280 ;; we switch on the flag $logexpand and do a ratsimp.
2286 ;; Laplace transform of expintegral_chi
2290 ;; We transform to the hypergeometric representation.
2291 ;; Because we have Logarithmic terms in the transformation,
2292 ;; we switch on the flag $logexpand and do a ratsimp.
2298 ;; Laplace transform of Complete elliptic integral of the first kind
2304 ;; Laplace transform of Complete elliptic integral of the first kind
2310 ;; Laplace transform of Complete elliptic integral of the second kind
2316 ;; Laplace transform of Complete elliptic integral of the second kind
2322 ;; Laplace transform of %f[v1,v2](w1,w2,w3), Hypergeometric function
2323 ;; We support the Laplace transform of the build in symbol %f. We do
2324 ;; not use the mechanism of defining an "Expert on Laplace transform",
2325 ;; the expert function does a call to lt-ltp. We do this call directly.
2332 ;; Laplace transform of Hypergeometric function
2339 ;; Laplace transform of c * t^v * (a+t)^w
2340 ;; It is possible to combine arbpow2 and arbpow.
2349 ;; Laplace transform of c * t^v
2356 ;; We have specialized the pattern for arbpow1. Now a lot of integrals
2357 ;; will fail correctly and we have to return a noun form.
2360 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2361 ;;;
2362 ;;; Algorithm 2.1: Laplace transform of c*t^v*%e(-p*t)
2363 ;;;
2364 ;;; Table of Integral Transforms
2365 ;;;
2366 ;;; p. 137, formula 1:
2367 ;;;
2368 ;;; t^u*exp(-p*t)
2369 ;;; -> gamma(u+1)*p^(-u-1)
2370 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2378 ;; Check if conditions for f1p137 hold
2389 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2390 ;;;
2391 ;;; Algorithm 2.2: Laplace transform of c*t^v*(1+t)^w
2392 ;;;
2393 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2399 ;; The Laplace transform is an Incomplete Gamma function.
2407 ;; The general result is a Hypergeometric U function U(a,b,z) which can
2408 ;; be represented by two Hypergeometic 1F1 functions for the special
2409 ;; case that the index b is not an integer value.
2428 ;; The most general case is a result with the Hypergeometric U function.
2439 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2440 ;;;
2441 ;;; Algorithm 2.3: Laplace transform of the Logarithmic function
2442 ;;;
2443 ;;; c*t^(v-1)*log(a*t)
2444 ;;; -> c*gamma(v)*s^(-v)*(psi[0](v)-log(s/a))
2445 ;;;
2446 ;;; This is the formula for an expression with log(t) scaled like 1/a*F(s/a).
2447 ;;;
2448 ;;; For the following cases we have to add further algorithm:
2449 ;;; log(1+a*x), log(x+a), log(x)^2.
2450 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2471 ;; Pattern for lt-log.
2472 ;; Extract the argument of a function: a*t+c for c=0.
2479 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2480 ;;; Algorithm 2.4: Laplace transfom of the Whittaker function
2481 ;;;
2482 ;;; Test for Whittaker W function. Simplify this if possible, or
2483 ;;; convert to Whittaker M function.
2484 ;;;
2485 ;;; We have r * %w[i1,i2](a)
2486 ;;;
2487 ;;; Formula 16, p. 217
2488 ;;;
2489 ;;; t^(v-1)*%w[k,u](a*t)
2490 ;;; -> gamma(u+v+1/2)*gamma(v-u+1/2)*a^(u+1/2)/
2491 ;;; (gamma(v-k+1)*(p+a/2)^(u+v+1/2)
2492 ;;; *2f1(u+v+1/2,u-k+1/2;v-k+1;(p-a/2)/(p+a/2))
2493 ;;;
2494 ;;; For Re(v +/- mu) > -1/2
2495 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2507 ;; 1/2-u-k and 1/2+u-k are not zero or a negative integer
2508 ;; Transform to Whittaker M and try again.
2511 ;; Both conditions fails, return a noun form.
2515 ;; We have r*%w[i1,i2](a)
2517 ;; Make sure r is of the form c*t^v
2521 ;; Check that v + i2 + 1/2 > 0 and v - i2 + 1/2 > 0.
2524 ;; Ok, we satisfy the conditions. Now extract the arg.
2525 ;; The transformation is only valid for an argument a*t. We have
2526 ;; to special the pattern to make sure that we satisfy the condition.
2530 ;; We're ready now to compute the transform.
2544 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2545 ;;; Algorithm 2.5: Laplace transfom of bessel_k(0,a*t)
2546 ;;;
2547 ;;; The general algorithm handles the Bessel K function for an order |v|<1.
2548 ;;; but does not include the special case v=0. Return the Laplace transform:
2549 ;;;
2550 ;;; bessel_k(0,a*t) --> acosh(s/a)/sqrt(s^2-a^2)
2551 ;;;
2552 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2568 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2569 ;;;
2570 ;;; DISPATCH FUNCTIONS TO CHANGE THE REPRESENTATION OF SPECIAL FUNCTIONS
2571 ;;;
2572 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2574 ;; Laplace transform of a product of Bessel functions. A1, A2 are
2575 ;; the args of the two functions. I1, I2 are the indices of each
2576 ;; function. I11, I21 are secondary indices of each function, if any.
2577 ;; FLG is a symbol indicating how we should handle the special
2578 ;; functions (and also indicates what the special functions are.)
2579 ;;
2580 ;; I11 and I21 are for the Hankel functions.
2586 ;; We have to Bessel or Hankel functions. Both indizes have to be
2587 ;; rational numbers or we have two Hankel functions.
2604 ;; Laplace transform of a product of Bessel functions. A1, A2 are
2605 ;; the args of the two functions. I1, I2 are the indices of each
2606 ;; function. I is a secondary index to one function, if any.
2607 ;; FLG is a symbol indicating how we should handle the special
2608 ;; functions (and also indicates what the special functions are.)
2609 ;;
2610 ;; I is for the kind of Hankel function.
2616 ;; We have two Bessel or Hankel functions. The second index has to
2617 ;; be a rational number or one of the functions is a Hankel function
2618 ;; and the second function is Bessel J or Bessel I
2638 ;; Laplace transform of a single special function. A is the arg of
2639 ;; the special function. I1, I11 are the indices of the function. FLG
2640 ;; is a symbol indicating how we should handle the special functions
2641 ;; (and also indicates what the special functions are.)
2642 ;;
2643 ;; I11 is the kind of Hankel function
2655 ;; The index is a rational number or flg has the value of one of the
2656 ;; above special functions.
2677 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2693 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2694 ;; (-1)^n*n!*laguerre(n,a,x) = U(-n,a+1,x)
2695 ;;
2696 ;; W[k,u](z) = exp(-z/2)*z^(u+1/2)*U(1/2+u-k,1+2*u,z)
2697 ;;
2698 ;; So
2699 ;;
2700 ;; laguerre(n,a,x) = (-1)^n*U(-n,a+1,x)/n!
2701 ;;
2702 ;; U(-n,a+1,x) = exp(z/2)*z^(-a/2-1/2)*W[1/2+a/2+n,a/2](z)
2703 ;;
2704 ;; Finally,
2705 ;;
2706 ;; laguerre(n,a,x) = (-1)^n/n!*exp(z/2)*z^(-a/2-1/2)*M[1/2+a/2+n,a/2](z)
2707 ;;
2708 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2721 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2722 ;; Hermite He function as a parabolic cylinder function
2723 ;;
2724 ;; Tables of Integral Transforms
2725 ;;
2726 ;; p. 386
2727 ;;
2728 ;; D[n](z) = (-1)^n*exp(z^2/4)*diff(exp(-z^2/2),z,n);
2729 ;;
2730 ;; p. 369
2731 ;;
2732 ;; He[n](x) = (-1)^n*exp(x^2/2)*diff(exp(-x^2/2),x,n)
2733 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2737 ;; At this time the Parabolic Cylinder D function is not implemented
2738 ;; as a simplifying function. We call nevertheless the simplifer.
2741 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2743 ;; Transform Gegenbauer function to Jacobi P function
2744 ;; ultraspherical(n,v,x) = gamma(2*v+n)*gamma(v+1/2)/gamma(2*v)/gamma(v+n+1/2)
2745 ;; *jacobi_p(n,v-1/2,v-1/2,x)
2754 ;; Transform Chebyshev T function to Jacobi P function
2755 ;; chebyshev_t(n,x) = gamma(n+1)*sqrt(%pi)/gamma(n+1/2)*jacobi_p(n,-1/2,-1/2,x)
2763 ;; Transform Chebyshev U function to Jacobi P function
2764 ;; chebyshev_u(n,x) = gamma(n+2)*sqrt(%pi)/2/gamma(3/2+n)*jacobi_p(n,1/2,1/2,x)
2768 inv2
2773 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2778 rest
2779 arg
2784 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2785 ;;;
2786 ;;; Laplace transform of a single Bessel Y function.
2787 ;;;
2788 ;;; REST is the multiplier, ARG1 is the arg, and INDEX1 is the order of
2789 ;;; the Bessel Y function.
2790 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2793 ;; If the index is an integer, use LT1Y. Otherwise, convert Bessel
2794 ;; Y to Bessel J and compute the transform of that. We do this
2795 ;; because converting Y to J for an integer index doesn't work so
2796 ;; well without taking limits.
2798 ;; Do not call lt1y but lty directly.
2799 ;; lt1y calls lt-ltp with the flag 'oney. lt-ltp checks this flag
2800 ;; and calls lty. So we can do it at this place and the algorithm is
2801 ;; more simple.
2805 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2806 ;;;
2807 ;;; TRANSFORMATIONS TO CHANGE THE REPRESENTATION OF SPECIAL FUNCTIONS
2808 ;;;
2809 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2811 ;; erfc in terms of D, parabolic cylinder function
2812 ;;
2813 ;; Tables of Integral Transforms
2814 ;;
2815 ;; p 387:
2816 ;; erfc(x) = (%pi*x)^(-1/2)*exp(-x^2/2)*W[-1/4,1/4](x^2)
2817 ;;
2818 ;; p 386:
2819 ;; D[v](z) = 2^(v/2+1/2)*z^(-1/2)*W[v/2+1/4,1/4](z^2/2)
2820 ;;
2821 ;; So
2822 ;;
2823 ;; erfc(x) = %pi^(-1/2)*2^(1/4)*exp(-x^2/2)*D[-1](x*sqrt(2))
2830 ;; At this time the Parabolic Cylinder D function is not implemented
2831 ;; as a simplifying function. We call nevertheless the simplifer
2832 ;; to simplify the arguments. When we implement the function
2833 ;; The symbol has to be changed to the noun form.
2836 ;; Lommel S function in terms of Bessel J and Bessel Y.
2837 ;; Luke gives
2838 ;;
2839 ;; S[u,v](z) = s[u,v](z) + {2^(u-1)*gamma((u-v+1)/2)*gamma((u+v+1)/2)}
2840 ;; * {sin[(u-v)*%pi/2]*bessel_j(v,z)
2841 ;; - cos[(u-v)*%pi/2]*bessel_y(v,z)
2854 ;; Whittaker W function in terms of Whittaker M function
2855 ;;
2856 ;; A&S 13.1.34
2857 ;;
2858 ;; W[k,u](z) = gamma(-2*u)/gamma(1/2-u-k)*M[k,u](z)
2859 ;; + gamma(2*u)/gamma(1/2+u-k)*M[k,-u](z)
2869 ;; Incomplete gamma function in terms of Whittaker W function
2870 ;;
2871 ;; Tables of Integral Transforms, p. 387
2872 ;;
2873 ;; gamma_incomplete(a,x) = x^((a-1)/2)*exp(-x/2)*W[(a-1)/2,a/2](x)
2880 ;;; Incomplete Gamma function in terms of lower incomplete Gamma function
2881 ;;;
2882 ;;; Only for a=0 we use the general representation as a Whittaker W function:
2883 ;;;
2884 ;;; gamma_incomplete(a,x) = x^((a-1)/2)*exp(-x/2)*W[(a-1)/2,a/2](x)
2885 ;;;
2886 ;;; In all other cases we transform to a lower incomplete Gamma function:
2887 ;;;
2888 ;;; gamma_incomplete(a,x) = gamma(a)- gamma_incomplete_lower(a,x)
2889 ;;;
2890 ;;; The lower incomplete Gamma function will be further transformed to a Hypergeometric 1F1
2891 ;;; representation. With this change we get more simple and correct results for
2892 ;;; the Laplace transform of the Incomplete Gamma function.
2897 ;; The representation as a Whittaker W function for a=0 or a negative
2898 ;; integer (The gamma function is not defined for this case.)
2902 ;; In all other cases the representation as a lower incomplete Gamma function
2906 ;; Bessel Y in terms of Bessel J
2907 ;;
2908 ;; A&S 9.1.2:
2909 ;;
2910 ;; bessel_y(v,z) = bessel_j(v,z)*cot(v*%pi)-bessel_j(-v,z)/sin(v*%pi)
2918 ;; Parabolic cylinder function in terms of Whittaker W function.
2919 ;;
2920 ;; See Table of Integral Transforms, p.386:
2921 ;;
2922 ;; D[v](z) = 2^(v/2+1/4)*z^(-1/2)*W[v/2+1/4,1/4](z^2/2)
2931 ;; Bateman's function in terms of Whittaker W function
2932 ;;
2933 ;; See Table of Integral Transforms, p.386:
2934 ;;
2935 ;; k[2*v](z) = 1/gamma(v+1)*W[v,1/2](2*z)
2941 ;; Bessel K in terms of Bessel I
2942 ;;
2943 ;; A&S 9.6.2
2944 ;;
2945 ;; bessel_k(v,z) = %pi/2*(bessel_i(-v,z)-bessel_i(v,z))/sin(v*%pi)
2954 ;; Express Hankel function in terms of Bessel J or Y function.
2955 ;;
2956 ;; A&S 9.1.3
2957 ;;
2958 ;; H[v,1](z) = %i*csc(v*%pi)*(exp(-v*%pi*%i)*bessel_j(v,z) - bessel_j(-v,z))
2959 ;;
2960 ;; A&S 9.1.4:
2961 ;; H[v,2](z) = %i*csc(v*%pi)*(bessel_j(-v,z) - exp(-v*%pi*%i)*bessel_j(v,z))
2962 ;;
2963 ;; Both formula are not valid for v an integer.
2964 ;; For this case use the definitions of the Hankel functions:
2965 ;; H[v,1](z) = bessel_j(v,z) + %i* bessel_y(v,z)
2966 ;; H[v,2](z) = bessel_j(v,z) - %i* bessel_y(v,z)
2967 ;;
2968 ;; All this can be implemented more simple.
2969 ;; We do not need the transformation to bessel_j for rational numbers,
2970 ;; because the correct transformation for bessel_y is already implemented.
2971 ;; It is enough to use the definitions for the Hankel functions.
2974 ;; V is the order, SORT is the kind of Hankel function (1 or 2), Z
2975 ;; is the arg.
2979 ;; If the order is a rational number of some sort,
2980 ;;
2981 ;; (bessel_j(-v,z) - bessel_j(v,z)*exp(-v*%pi*%i))/(%i*sin(v*%pi*%i))
2985 ;; Transform hankel_1(v,z) to bessel_j(v,z)+%i*bessel_y(v,z)
2989 ;; Transform hankel_2(v,z) to bessel_j(v,z)-%i*bessel_y(v,z)
2993 ;; We should never reach this point of code.
2994 ;; Problem: The user input for the symbol %h[v,sort](t) is not checked.
2995 ;; Therefore the user can generate this error as long as we do not cut
2996 ;; out the support for the Laplace transform of the symbol %h.
2999 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3001 ;;; Three helper functions only used by htjory
3003 ;; Bessel J or Y, depending on if FLG is 'J or not.
3012 ;; bessel(-v, z) - exp(-v*%pi*%i)*bessel(v, z)
3013 ;;
3014 ;; Where bessel is bessel_j if FLG is 'j. Otherwise, bessel
3015 ;; is bessel_y.
3016 ;;
3017 ;; bessel_y(-v, z) - exp(-v*%pi*%i)*bessel_y(v, z)
3022 ;; exp(-v*%pi*%i)*bessel(v,z) - bessel(-v,z), where bessel is
3023 ;; bessel_j or bessel_y, depending on if FLG is 'j or not.
3030 ;; bessel_j(v,z)
3033 ;; -bessel_y(v,z)
3036 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3037 ;;;
3038 ;;; TRANSFORM TO HYPERGEOMETRIC FUNCTION WITHOUT USING THE ROUTINE REF
3039 ;;;
3040 ;;; This functions are called in the routine lt-sf-log to get the
3041 ;;; representation in terms of a hypergeometric function.
3042 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3044 ;; The algorithm of the implemented Hermite function %he does not work for
3045 ;; the known Laplace transforms. For an even or odd integer order, we
3046 ;; can represent the Hermite function by the Hypergeometric function 1F1.
3047 ;; With this representations we get the expected Laplace transforms.
3052 ;; Transform to 1F1 for order an even integer
3064 ;; Transform to 1F1 for order an odd integer
3075 ;; The general case, transform to 2F0
3076 ;; For this case we have no Laplace transform.
3084 ;;; Hypergeometric representation of the Exponential Integral Si
3085 ;;; Si(z) = z*1F2([1/2],[3/2,3/2],-z^2/4)
3094 ;;; Hypergeometric representation of the Exponential Integral Shi
3095 ;;; Shi(z) = z*1F2([1/2],[3/2,3/2],z^2/4)
3104 ;;; Hypergeometric representation of the Exponential Integral Ci
3105 ;;; Ci(z) = -z^2/4*2F3([1,1],[2,2,3/2],-z^2/4)+log(z)+%gamma
3116 ;;; Hypergeometric representation of the Exponential Integral Chi
3117 ;;; Chi(z) = z^2/4*2F3([1,1],[2,2,3/2],z^2/4)+log(z)+%gamma
3128 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3129 ;;;
3130 ;;; EXPERTS ON LAPLACE TRANSFORMS
3131 ;;;
3132 ;;; LT<foo> functions are various experts on Laplace transforms of the
3133 ;;; function <foo>. The expression being transformed is
3134 ;;; r*<foo>(args). The first arg of each expert is r, The remaining
3135 ;;; args are the arg(s) and/or parameters.
3136 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3138 ;; Laplace transform of one Bessel J
3142 ;; Laplace transform of two Bessel J functions.
3143 ;; The argument of each must be the same, but the orders may be different.
3148 ;; Call lt-ltp two transform and integrate two Bessel J functions.
3151 ;; Laplace transform of a square of a Bessel J function
3154 ;; Special case: Laplace transform of bessel_j(v,arg)^2, v = -1/2.
3155 ;; For this case the algorithm for the product of two Bessel functions
3156 ;; does not work. Call the integrator with the hypergeometric
3157 ;; representation: 2/%pi/arg*1/2*(1+0F1([], [1/2], -arg*arg)).
3160 rest)
3171 ;; Laplace transform of Incomplete Gamma function
3175 ;; Laplace transform of Whittaker M function
3179 ;; Laplace transform of Jacobi function
3183 ;; Laplace transform of Associated Legendre function of the second kind
3187 ;; Laplace transform of Erf function
3191 ;; Laplace transform of Log function
3195 ;; Laplace transform of Complete elliptic integral of the first kind
3199 ;; Laplace transform of Complete elliptic integral of the second kind
3203 ;; Laplace transform of Struve H function
3207 ;; Laplace transform of Struve L function
3211 ;; Laplace transform of Lommel s function
3215 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3216 ;;;
3217 ;;; TRANSFORM TO HYPERGEOMETRIC FUNCTION AND DO THE INTEGRATION
3218 ;;;
3219 ;;; FLG = special function we're transforming
3220 ;;; REST = other stuff
3221 ;;; ARG = arg of special function
3222 ;;; INDEX = index of special function.
3223 ;;;
3224 ;;; So we're transforming REST*FLG(INDEX, ARG).
3225 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3237 ;; Convert the special function to a hypgergeometric
3238 ;; function. L1 is the special function converted to the
3239 ;; hypergeometric function. d*x^m*%e^a*x looks for that
3240 ;; factor in the expanded form.
3243 ;; We currently don't know how to handle this yet.
3244 ;; We add the return of a noun form.
3247 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3248 ;; Dispatch function to convert the given function to a hypergeometric
3249 ;; function.
3250 ;;
3251 ;; The first arg is a symbol naming the function; the last is the
3252 ;; argument to the function. The second arg is the index (or list of
3253 ;; indices) to the function. Not used if the function doesn't have
3254 ;; any indices
3255 ;;
3256 ;; The result is a list of 2 elements: The first element is a
3257 ;; multiplier; the second, the hypergeometric function itself.
3258 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3279 ;; Transform %f to internal representation FPQ
3282 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3283 ;;;
3284 ;;; TRANSFORM FUNCTION IN TERMS OF HYPERGEOMETRIC FUNCTION
3285 ;;;
3286 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3288 ;; Create a hypergeometric form that we recognize. The function is
3289 ;; %f[n,m](p; q; arg). We represent this as a list of the form
3290 ;; (fpq (<length p> <length q>) <p> <q> <arg>)
3294 p q arg))
3296 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3298 ;; Whittaker M function in terms of hypergeometric function
3299 ;;
3300 ;; A&S 13.1.32:
3301 ;;
3302 ;; M[k,u](z) = exp(-z/2)*z^(1/2+u)*M(1/2+u-k,1+2*u,z)
3309 arg)))
3311 ;; Jacobi P in terms of hypergeometric function
3312 ;;
3313 ;; A&S 15.4.6:
3314 ;;
3315 ;; F(-n,a+1+b+n; a+1; x) = n!/poch(a+1,n)*jacobi_p(n,a,b,1-2*x)
3316 ;;
3317 ;; jacobi_p(n,a,b,x) = poch(a+1,n)/n!*F(-n,a+1+b+n; a+1; (1-x)/2)
3318 ;; = gamma(a+n+1)/gamma(a+1)/n!*F(-n,a+1+b+n; a+1; (1-x)/2)
3319 ;;
3320 ;; We have a problem:
3321 ;; We transform the argument x -> (1-x)/2. But an argument with a constant
3322 ;; part is not integrable with the implemented algorithm for the hypergeometric
3323 ;; function. It might be possible to get a result for an argument y=1-2*x
3324 ;; with x=t^-2. But for this case the routine lt-ltp fails. The routine
3325 ;; recognize a constant term in the argument, but does not take into account
3326 ;; that the constant term might vanish, when we transform to a hypergeometric
3327 ;; function.
3328 ;; Because of this the Laplace transform for the following functions does not
3329 ;; work too: Legendre P, Chebyshev T, Chebyshev U, and Gegenbauer.
3339 ;; ArcSin in terms of hypergeometric function
3340 ;;
3341 ;; A&S 15.1.6:
3342 ;;
3343 ;; F(1/2,1/2; 3/2; z^2) = asin(z)/z
3344 ;;
3345 ;; asin(z) = z*F(1/2,1/2; 3/2; z^2)
3354 ;; ArcTan in terms of hypergeometric function
3355 ;;
3356 ;; A&S 15.1.5
3357 ;;
3358 ;; F(1/2,1; 3/2; -z^2) = atan(z)/z
3359 ;;
3360 ;; atan(z) = z*F(1/2,1; 3/2; -z^2)
3368 ;; Associated Legendre function P in terms of hypergeometric function
3369 ;;
3370 ;; A&S 8.1.2
3371 ;;
3372 ;; assoc_legendre_p(v,u,z) = ((z+1)/(z-2))^(u/2)/gamma(1-u)*F(-v,v+1;1-u,(1-z)/2)
3373 ;;
3374 ;; FIXME: What about the branch cut? 8.1.2 is for z not on the real
3375 ;; line with -1 < z < 1.
3386 ;; Associated Legendre function Q in terms of hypergeometric function
3387 ;;
3388 ;; A&S 8.1.3:
3389 ;;
3390 ;; assoc_legendre_q(v,u,z)
3391 ;; = exp(%i*u*%pi)*2^(-v-1)*sqrt(%pi) *
3392 ;; gamma(v+u+1)/gamma(v+3/2)*z^(-v-u-1)*(z^2-1)^(u/2) *
3393 ;; F(1+v/2+u/2, 1/2+v/2+u/2; v+3/2; 1/z^2)
3394 ;;
3395 ;; FIXME: What about the branch cut?
3409 ;; Incomplete lower Gamma in terms of hypergeometric function
3410 ;;
3411 ;; A&S 13.6.10:
3412 ;;
3413 ;; M(a,a+1,-x) = a*x^(-a)*gamma_incomplete_lower(a,x)
3414 ;;
3415 ;; gamma_incomplete_lower(a,x) = x^a/a*M(a,a+1,-x)
3423 ;; Complete elliptic K in terms of hypergeometric function
3424 ;;
3425 ;; A&S 17.3.9
3426 ;;
3427 ;; K(k) = %pi/2*2F1(1/2,1/2; 1; k^2)
3436 ;; Complete elliptic E in terms of hypergeometric function
3437 ;;
3438 ;; A&S 17.3.10
3439 ;;
3440 ;; E(k) = %pi/2*2F1(-1/2,1/2;1;k^2)
3449 ;; erf in terms of hypgeometric function.
3450 ;;
3451 ;; A&S 7.1.21 gives
3452 ;;
3453 ;; erf(z) = 2*z/sqrt(%pi)*M(1/2,3/2,-z^2)
3454 ;; = 2*z/sqrt(%pi)*exp(-z^2)*M(1,3/2,z^2)
3462 ;; log in terms of hypergeometric function
3463 ;;
3464 ;; We know from A&S 15.1.3 that
3465 ;;
3466 ;; F(1,1;2;z) = -log(1-z)/z.
3467 ;;
3468 ;; So log(z) = (z-1)*F(1,1;2;1-z)
3476 ;; Bessel J function expressed as a hypergeometric function.
3477 ;;
3478 ;; A&S 9.1.10:
3479 ;; inf
3480 ;; bessel_j(v,z) = (z/2)^v*sum (-z^2/4)^k/k!/gamma(v+k+1)
3481 ;; k=0
3482 ;;
3483 ;; = (z/2)^v/gamma(v+1)*sum 1/poch(v+1,k)*(-z^2/4)^k/k!
3484 ;;
3485 ;; = (z/2)^v/gamma(v+1) * 0F1(; v+1; -z^2/4)
3495 ;; Product of 2 Bessel J functions in terms of hypergeometric function
3496 ;;
3497 ;; See Y. L. Luke, formula 39, page 216:
3498 ;;
3499 ;; bessel_j(u,z)*bessel_j(v,z)
3500 ;; = (z/2)^(u+v)/gamma(u+1)/gamma(v+1) *
3501 ;; 2F3((u+v+1)/2, (u+v+2)/2; u+1, v+1, u+v+1; -z^2)
3513 ;; Struve H function in terms of hypergeometric function.
3514 ;;
3515 ;; A&S 12.1.2 gives the following series for the Struve H function:
3516 ;;
3517 ;; inf
3518 ;; H[v](z) = (z/2)^(v+1)*sum (-1)^k*(z/2)^(2*k)/gamma(k+3/2)/gamma(k+v+3/2)
3519 ;; k=0
3520 ;;
3521 ;; We can write this in the form
3522 ;;
3523 ;; H[v](z) = 2/sqrt(%pi)*(z/2)^(v+1)/gamma(v+3/2)
3524 ;;
3525 ;; inf
3526 ;; * sum n!/poch(3/2,n)/poch(v+3/2,n)*(-z^2/4)^n/n!
3527 ;; n=0
3528 ;;
3529 ;; = 2/sqrt(%pi)*(z/2)^(v+1)/gamma(v+3/2) * 1F2(1;3/2,v+3/2;(-z^2/4))
3530 ;;
3531 ;; See also A&S 12.1.21.
3542 ;; Struve L function in terms of hypergeometric function
3543 ;;
3544 ;; A&S 12.2.1:
3545 ;;
3546 ;; L[v](z) = -%i*exp(-v*%i*%pi/2)*H[v](%i*z)
3547 ;;
3548 ;; This function computes exactly this way. (But why is %i written as
3549 ;; exp(%i*%pi/2) instead of just %i)
3550 ;;
3551 ;; A&S 12.2.1 gives the series expansion as
3552 ;;
3553 ;; inf
3554 ;; L[v](z) = (z/2)^(v+1)*sum (z/2)^(2*k)/gamma(k+3/2)/gamma(k+v+3/2)
3555 ;; k=0
3556 ;;
3557 ;; It's quite easy to derive
3558 ;;
3559 ;; L[v](z) = 2/sqrt(%pi)*(z/2)^(v+1)/gamma(v+3/2) * 1F2(1;3/2,v+3/2;(z^2/4))
3570 ;; Lommel s function in terms of hypergeometric function
3571 ;;
3572 ;; See Y. L. Luke, p 217, formula 1
3573 ;;
3574 ;; s(u,v,z) = z^(u+1)/(u-v+1)/(u+v+1)*1F2(1; (u-v+3)/2, (u+v+3)/2; -z^2/4)
3585 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3586 ;;;
3587 ;;; Algorithm 3: Laplace transform of a hypergeometric function
3588 ;;;
3589 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3596 loop
3606 ;; We specialized the pattern for the argument. Now the test fails
3607 ;; correctly and we have to add the return of a noun form.
3611 ;; Executive for recognizing the sort of argument to the
3612 ;; hypergeometric function. We look to see if the arg is of the form
3613 ;; a*x^m + c. Return a list of 'dionimo (what does that mean?) and
3614 ;; the match.
3622 ;; The return value has to be a list.
3625 ;; We have hypergeometric function whose arg looks like a*x^m+c. L1
3626 ;; matches the d*x^m... part, L2 is the hypergeometric function and
3627 ;; arg is the match for a*x^m+c.
3651 ;; At this point, we have the function d*x^s*%f[p,q](l1, l2, (a*t)^m).
3652 ;; Check to see if Formula 19, p 220 applies.
3657 l1
3658 l2
3659 a
3660 m)))))
3664 ;; Table of Laplace transforms, p 220, formula 19:
3665 ;;
3666 ;; If m + k <= n + 1, and Re(s) > 0, the Laplace transform of
3667 ;;
3668 ;; t^(s-1)*%f[m,n]([a1,...,am],[p1,...,pn],(c*t)^k)
3669 ;; is
3670 ;;
3671 ;; gamma(s)/p^s*%f[m+k,n]([a1,...,am,s/k,(s+1)/k,...,(s+k-1)/k],[p1,...,pm],(k*c/p)^k)
3672 ;;
3673 ;; with Re(p) > 0 if m + k <= n, Re(p+k*c*exp(2*%pi*%i*r/k)) > 0 for r
3674 ;; = 0, 1,...,k-1, if m + k = n + 1.
3675 ;;
3676 ;; The args below are s, [a's], [p's], c^k, k.
3682 l2
3687 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3689 ;; Return a list of s/k, (s+1)/k, ..., (s+|k|-1)/k
3697 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3699 ;;; Pattern for the Laplace transform of the hypergeometric function
3701 ;; Match d*x^m*%e^(a*x). If we match, Q is the e^(a*x) part, A is a,
3702 ;; M is M, and D is d.
3714 ;; Match f(x)+c
3721 ;; Match a*x^m+c.
3722 ;; The pattern was too general. We match also a*t^2+b*t. But that's not correct.
3731 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3732 ;;;
3733 ;;; Algorithm 4: SPECIAL HANDLING OF Bessel Y for an integer order
3734 ;;;
3735 ;;; This is called for one Bessel Y function, when the order is an integer.
3736 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3766 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3767 ;;;
3768 ;;; Algorithm 4.1: Laplace transform of t^n*bessel_y(v,a*t)
3769 ;;; v is an integer and n>=v
3770 ;;;
3771 ;;; Table of Integral Transforms
3772 ;;;
3773 ;;; Volume 2, p 105, formula 2 is a formula for the Y-transform of
3774 ;;;
3775 ;;; f(x) = x^(u-3/2)*exp(-a*x)
3776 ;;;
3777 ;;; where the Y-transform is defined by
3778 ;;;
3779 ;;; integrate(f(x)*bessel_y(v,x*y)*sqrt(x*y), x, 0, inf)
3780 ;;;
3781 ;;; which is
3782 ;;;
3783 ;;; -2/%pi*gamma(u+v)*sqrt(y)*(y^2+a^2)^(-u/2)
3784 ;;; *assoc_legendre_q(u-1,-v,a/sqrt(y^2+a^2))
3785 ;;;
3786 ;;; with a > 0, Re u > |Re v|.
3787 ;;;
3788 ;;; In particular, with a slight change of notation, we have
3789 ;;;
3790 ;;; integrate(x^(u-1)*exp(-p*x)*bessel_y(v,a*x)*sqrt(a), x, 0, inf)
3791 ;:;
3792 ;;; which is the Laplace transform of x^(u-1/2)*bessel_y(v,x).
3793 ;;;
3794 ;;; Thus, the Laplace transform is
3795 ;;;
3796 ;;; -2/%pi*gamma(u+v)*sqrt(a)*(a^2+p^2)^(-u/2)
3797 ;;; *assoc_legendre_q(u-1,-v,p/sqrt(a^2+p^2))
3798 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3815 ;; Call Associated Legendre Q function, which simplifies accordingly.
3816 ;; We have to do a Maxima function call, because $assoc_legendre_q is
3817 ;; not in Maxima core and has to be autoloaded.
3825 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3826 ;;;
3827 ;;; Algorithm 4.2: Laplace transform of t^n*bessel_y(v, a*sqrt(t))
3828 ;;;
3829 ;;; Table of Integral Transforms
3830 ;;;
3831 ;;; p. 188, formula 50:
3832 ;;;
3833 ;;; t^(u-1/2)*bessel_y(2*v,2*sqrt(a)*sqrt(t))
3834 ;;; -> a^(-1/2)*p^(-u)*exp(-a/2/p)
3835 ;;; * [tan((u-v)*%pi)*gamma(u+v+1/2)/gamma(2*v+1)*M[u,v](a/p)
3836 ;;; -sec((u-v)*%pi)*W[u,v](a/p)]
3837 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3865 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;