| jacobi.g.quadrature {gaussquad} | R Documentation |
Perform Gauss Jacobi quadrature
Description
This function evaluates the integral of the given function between the lower and upper limits using the weight and abscissa values specified in the rule data frame. The quadrature formula uses the weight function for Jacobi G polynomials.
Usage
jacobi.g.quadrature(functn, rule, p = 1, q = 1, lower = 0, upper = 1,
weighted = TRUE, ...)
Arguments
functn |
an R function which should take a numeric argument x and possibly some parameters. The function returns a numerical vector value for the given argument x. |
rule |
a data frame containing the order |
p |
numeric value for the first Jacobi polynomial parameter |
q |
numeric value for the second Jacobi polynomial parameter |
lower |
numeric value for the lower limit of the integral with a default value of 0 |
upper |
numeric value for the upper limit of the integral with a default value of 1 |
weighted |
boolean value which if true causes the ultraspherical weight function to be included in the integrand |
... |
other arguments passed to the give function |
Details
The rule argument corresponds to an order n Jacobi polynomial,
weight function and interval \left[ {0,1} \right].
The lower and upper limits of the integral must be finite.
Value
The value of definite integral evaluated using Gauss Jacobi quadrature
Author(s)
Frederick Novomestky fnovomes@poly.edu
References
Abramowitz, M. and I. A. Stegun, 1968. Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables, Dover Publications, Inc., New York.
Press, W. H., S. A. Teukolsky, W. T. Vetterling, and B. P. Flannery, 1992. Numerical Recipes in C, Cambridge University Press, Cambridge, U.K.
Stroud, A. H., and D. Secrest, 1966. Gaussian Quadrature Formulas, Prentice-Hall, Englewood Cliffs, NJ.
See Also
Examples
###
### this example evaluates the quadrature function for
### the Jacobi G polynomials. it computes the integral
### of the product for all pairs of orthogonal polynomials
### from order 0 to order 10. the results are compared to
### the diagonal matrix of the inner products for the
### polynomials. it also computes the integral of the product
### of all pairs of orthonormal polynomials from order 0
### to order 10. the resultant matrix should be an identity matrix
###
###
### set the polynomial parameter
###
p <- 3
q <- 2
###
### set the value for the maximum polynomial order
###
n <- 10
###
### maximum order plus 1
###
np1 <- n + 1
###
### function to construct the polynomial products by column
###
by.column.products <- function( c, p.list, p.p.list )
{
###
### function to construct the polynomial products by row
###
by.row.products <- function( r, c, p.list )
{
row.column.product <- p.list[[r]] * p.list[[c]]
return (row.column.product )
}
np1 <- length( p.list )
row.list <- lapply( 1:np1, by.row.products, c, p.list )
return( row.list )
}
###
### function construct the polynomial functions by column
###
by.column.functions <- function( c, p.p.products )
{
###
### function to construct the polynomial functions by row
###
by.row.functions <- function( r, c, p.p.products )
{
row.column.function <- as.function( p.p.products[[r]][[c]] )
return( row.column.function )
}
np1 <- length( p.p.products[[1]] )
row.list <- lapply( 1:np1, by.row.functions, c, p.p.products )
return( row.list )
}
###
### function to compute the integral of the polynomials by column
###
by.column.integrals <- function( c, p.p.functions )
{
###
### function to compute the integral of the polynomials by row
###
by.row.integrals <- function( r, c, p.p.functions )
{
row.column.integral <- jacobi.g.quadrature(
p.p.functions[[r]][[c]], order.np1.rule, p, q )
return( row.column.integral )
}
np1 <- length( p.p.functions[[1]] )
row.vector <- sapply( 1:np1, by.row.integrals, c, p.p.functions )
return( row.vector )
}
###
### construct a list of the Jacobi G orthogonal polynomials
###
p.list <- jacobi.g.polynomials( n, p, q )
###
### construct the two dimensional list of pair products
### of polynomials
###
p.p.products <- lapply( 1:np1, by.column.products, p.list )
###
### compute the two dimensional list of functions
### corresponding to the polynomial products in
### the two dimensional list p.p.products
###
p.p.functions <- lapply( 1:np1, by.column.functions, p.p.products )
###
### get the rule table for the order np1 polynomial
###
rules <- jacobi.g.quadrature.rules( np1, p, q )
order.np1.rule <- rules[[np1]]
###
### construct the square symmetric matrix containing
### the definite integrals over the default limits
### corresponding to the two dimensional list of
### polynomial functions
###
p.p.integrals <- sapply( 1:np1, by.column.integrals, p.p.functions )
###
### construct the diagonal matrix with the inner products
### of the orthogonal polynomials on the diagonal
###
p.p.inner.products <- diag( jacobi.g.inner.products( n,p, q ) )
print( "Integral of cross products for the orthogonal polynomials " )
print( apply( p.p.integrals, 2, round, digits=5 ) )
print( apply( p.p.inner.products, 2, round, digits=5 ) )
###
### construct a list of the Jacobi G orthonormal polynomials
###
p.list <- jacobi.g.polynomials( n, p, q, TRUE )
###
### construct the two dimensional list of pair products
### of polynomials
###
p.p.products <- lapply( 1:np1, by.column.products, p.list )
###
### compute the two dimensional list of functions
### corresponding to the polynomial products in
### the two dimensional list p.p.products
###
p.p.functions <- lapply( 1:np1, by.column.functions, p.p.products )
###
### get the rule table for the order np1 polynomial
###
rules <- jacobi.g.quadrature.rules( np1, p, q, TRUE )
order.np1.rule <- rules[[np1]]
###
### construct the square symmetric matrix containing
### the definite integrals over the default limits
### corresponding to the two dimensional list of
### polynomial functions
###
p.p.integrals <- sapply( 1:np1, by.column.integrals, p.p.functions )
###
### display the matrix of integrals
###
print( "Integral of cross products for the orthonormal polynomials " )
print(apply( p.p.integrals, 2, round, digits=5 ) )