Volume 16, pp. 143-164, 2003.
A quadrature formula of rational type for integrands with one endpoint singularity
J. Illán
Abstract
The paper deals with the construction of an efficient quadrature
formula of rational type to evaluate the integral of functions
which are analytic in the interval of integration, except at the
endpoints. Basically our approach consists in introducing a change
of variable $u_q$ into the integral $I(f,h,r)$
$$I(f,h,r)=\int_{-(1-h)}^{(1-h)r} f(x)dx=\int_{\mu_q}^{\rho_q}F(u_q(x))u_q^\prime(x)dx=I(f,q,h,r),$$
where $f \in H^p$ and $u_q(x)=w^q_a(x)=w_a(w_a^{q-1}(x))$, $w_a(z)=(z-a)/(1-az)$, $0 < a < 1$.
We evaluate the new form $I(f,q,h,r)$ by a quadrature approximant $Q_n(f)=Q(f,n,q,h,r,a)$ which is
based on Hermite interpolation by means of rational functions. The nodes of $Q_n(f)$ are derived from
a fundamental result proved by Ganelius [Anal. Math., 5 (1979), pp. 19-33] in connection with the
problem of approximating the function $f_\alpha(x)=x^\alpha$, $0\leq x \leq 1$, by means of rational functions.
We find $(a_n)$ such that $Q_n(f)\to I(f,r)=I(f,0,r)$ as $h_n=\epsilon(1-a_n)\to 0$, for all $f \in H^p$.
For functions in $H^p$, $1< p<\infty$, which satisfy an integral Lipschitz condition of order $\beta$,
the following estimate is deduced
$$E_n(f)=\left|I(f,r)-Q_n(f)\right|\leq M \sqrt{n}\,\exp\left(-\pi\sqrt{n\beta(2q-1-1/p)}\right).$$
If $\beta=q=1$ then the upper bound for $E_n(f)$ is that which is exact for the optimal quadrature error in $H^p$, $p>1$.
We report some numerical examples to illustrate the behavior of the method for several values of the parameters.
Full Text (PDF) [383 KB], BibTeX
Key words
interpolatory quadrature formulas, rational approximation, order of convergence, boundary singularities.
AMS subject classifications
41A25, 41A55, 65D30, 65D32.
Links to the cited ETNA articles
| [14] | Vol. 9 (1999), pp. 39-52 F. Cala Rodriguez, P. Gonzalez-Vera, and M. Jimenez Paiz: Quadrature formulas for rational functions |
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