The order of convergence of an optimal quadrature formula with derivative in the space $W_2^{(2,1)}$
Abstract
The present work is devoted to extension of the trapezoidal rule in the space $W_2^{(2,1)}$.
The optimal quadrature formula is obtained by minimizing the error of the formula by coefficients
at values of the first derivative of a integrand.
Using the discrete analog of the operator $\frac{d^2}{dx^{2}}-1$ the explicit formulas for the coefficients of the
optimal quadrature formula are obtained. Furthermore, it is proved that the obtained quadrature formula is exact for any function of the set $\mathbf{F}=\mathrm{span}\{1,x,e^{x},e^{-x}\}$. Finally, in the space $W_2^{(2,1)}$ the square of the norm of the error
functional of the constructed quadrature formula is calculated. It is shown that the error of the obtained optimal quadrature formula
is less than the error of the Euler-Maclaurin quadrature formula on the space $L_2^{(2)}$.
The optimal quadrature formula is obtained by minimizing the error of the formula by coefficients
at values of the first derivative of a integrand.
Using the discrete analog of the operator $\frac{d^2}{dx^{2}}-1$ the explicit formulas for the coefficients of the
optimal quadrature formula are obtained. Furthermore, it is proved that the obtained quadrature formula is exact for any function of the set $\mathbf{F}=\mathrm{span}\{1,x,e^{x},e^{-x}\}$. Finally, in the space $W_2^{(2,1)}$ the square of the norm of the error
functional of the constructed quadrature formula is calculated. It is shown that the error of the obtained optimal quadrature formula
is less than the error of the Euler-Maclaurin quadrature formula on the space $L_2^{(2)}$.
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