genhypergeo(U, L, z, tol=0, maxiter=2000, check_mod=TRUE,
polynomial=FALSE, debug=FALSE, series=TRUE)
genhypergeo_series(U, L, z, tol=0, maxiter=2000, check_mod=TRUE,
polynomial=FALSE, debug=FALSE)
genhypergeo_contfrac(U, L, z, tol = 0, maxiter = 2000)TRUE meaning to check
that the modulus of z is less than 1FALSE meaning to
evaluate the series until converged, or return a warning; and
TRUE meaning to return the sum of maxiter terms,
whether or not converged. This is useful when either TRUE meaning to return debugging
information and default FALSE meaning to return just the
evaluategenhypergeo(), Boolean argument with
default TRUE meaning to return the result of
genhypergeo_series() and FALSE the result of
genhypergeo_contfrac()genhypergeo() is a wrapper for functions
genhypergeo_series() and genhypergeo_contfrac().
Function genhypergeo_series() is the workhorse for the whole
package; every call to hypergeo() uses this function except for
the (apparently rare---but see the examples section) cases where
continued fractions are used. The generalized hypergeometric function [here genhypergeo()]
appears from time to time in the literature (eg Mathematica) as
$$F(U,L;z) = \sum_{n=0}^\infty\frac{(u_1)_n(u_2)_n\ldots
(u_i)_n}{(l_1)_n(l_2)_n\ldots
(l_j)_n}\cdot\frac{z^n}{n!}$$ where
$U=\left(u_1,\ldots,u_i\right)$ and
$L=\left(l_1,\ldots,l_i\right)$ are the
genhypergeo() with
length-1 vectors for arguments U and V.
For the ${}_0\!F_1$ function (ie no genhypergeo(NULL,L,x).
See documentation for genhypergeo_contfrac() for details of
the continued fraction representation.
hypergeo,genhypergeo_contfracgenhypergeo(U=c(1.1,0.2,0.3), L=c(10.1,pi*4), check_mod=FALSE, z=1.12+0.2i)
genhypergeo(U=c(1.1,0.2,0.3), L=c(10.1,pi*4),z=4.12+0.2i,series=FALSE)Run the code above in your browser using DataLab