Incorporating the external zeros and poles of the integrand into Gauss-type quadrature rules
Само за регистроване кориснике
2023
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Quadrature formulas are often constructed to be exact on the space of functions that are easily integrated and that are in some sense similar to the integrand. This motivates us to explore how the known properties of the integrand can be used to improve the accuracy of certain quadrature rules. In the present paper, we propose an $l$-point Gauss-type quadrature rule $\mathcal G_l$ into which the zeros and poles of the integrand outside the integration interval are incorporated. Formula $\mathcal G_l$ proves to be exact for certain rational functions which have the same zeros and poles as the integrand. It converges, all its nodes are pairwise distinct and belong to the interior of the integration interval, and all its weights are positive. Theoretical results on the remainder term of $\mathcal G_l$ suggest that formula $\mathcal G_l$ is applicable both when the incorporated zeros and poles of the integrand are known exactly, as well as when they are known approximately. To practically ...and economically estimate the error of $\mathcal G_l$, some extensions that inherit the $l$ nodes of $\mathcal G_l$ are developed. They are analogous to the Gauss-Kronrod, averaged Gauss, and generalized averaged Gauss quadrature rules. Numerical experiments confirm the accuracy of $\mathcal G_l$ and its extensions.
Кључне речи:
Gauss quadrature formula / External zeros / External polesИзвор:
Applied Numerical Mathematics, 2023Издавач:
- Elsevier
Колекције
Институција/група
Mašinski fakultetTY - JOUR AU - Tomanović, Jelena PY - 2023 UR - https://machinery.mas.bg.ac.rs/handle/123456789/6924 AB - Quadrature formulas are often constructed to be exact on the space of functions that are easily integrated and that are in some sense similar to the integrand. This motivates us to explore how the known properties of the integrand can be used to improve the accuracy of certain quadrature rules. In the present paper, we propose an $l$-point Gauss-type quadrature rule $\mathcal G_l$ into which the zeros and poles of the integrand outside the integration interval are incorporated. Formula $\mathcal G_l$ proves to be exact for certain rational functions which have the same zeros and poles as the integrand. It converges, all its nodes are pairwise distinct and belong to the interior of the integration interval, and all its weights are positive. Theoretical results on the remainder term of $\mathcal G_l$ suggest that formula $\mathcal G_l$ is applicable both when the incorporated zeros and poles of the integrand are known exactly, as well as when they are known approximately. To practically and economically estimate the error of $\mathcal G_l$, some extensions that inherit the $l$ nodes of $\mathcal G_l$ are developed. They are analogous to the Gauss-Kronrod, averaged Gauss, and generalized averaged Gauss quadrature rules. Numerical experiments confirm the accuracy of $\mathcal G_l$ and its extensions. PB - Elsevier T2 - Applied Numerical Mathematics T1 - Incorporating the external zeros and poles of the integrand into Gauss-type quadrature rules DO - 10.1016/j.apnum.2023.05.001 ER -
@article{ author = "Tomanović, Jelena", year = "2023", abstract = "Quadrature formulas are often constructed to be exact on the space of functions that are easily integrated and that are in some sense similar to the integrand. This motivates us to explore how the known properties of the integrand can be used to improve the accuracy of certain quadrature rules. In the present paper, we propose an $l$-point Gauss-type quadrature rule $\mathcal G_l$ into which the zeros and poles of the integrand outside the integration interval are incorporated. Formula $\mathcal G_l$ proves to be exact for certain rational functions which have the same zeros and poles as the integrand. It converges, all its nodes are pairwise distinct and belong to the interior of the integration interval, and all its weights are positive. Theoretical results on the remainder term of $\mathcal G_l$ suggest that formula $\mathcal G_l$ is applicable both when the incorporated zeros and poles of the integrand are known exactly, as well as when they are known approximately. To practically and economically estimate the error of $\mathcal G_l$, some extensions that inherit the $l$ nodes of $\mathcal G_l$ are developed. They are analogous to the Gauss-Kronrod, averaged Gauss, and generalized averaged Gauss quadrature rules. Numerical experiments confirm the accuracy of $\mathcal G_l$ and its extensions.", publisher = "Elsevier", journal = "Applied Numerical Mathematics", title = "Incorporating the external zeros and poles of the integrand into Gauss-type quadrature rules", doi = "10.1016/j.apnum.2023.05.001" }
Tomanović, J.. (2023). Incorporating the external zeros and poles of the integrand into Gauss-type quadrature rules. in Applied Numerical Mathematics Elsevier.. https://doi.org/10.1016/j.apnum.2023.05.001
Tomanović J. Incorporating the external zeros and poles of the integrand into Gauss-type quadrature rules. in Applied Numerical Mathematics. 2023;. doi:10.1016/j.apnum.2023.05.001 .
Tomanović, Jelena, "Incorporating the external zeros and poles of the integrand into Gauss-type quadrature rules" in Applied Numerical Mathematics (2023), https://doi.org/10.1016/j.apnum.2023.05.001 . .