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Direct and conjugate Neumann-Ulam schemes for solving non-linear integral equations. / Nekrutkin, V. V.

в: USSR Computational Mathematics and Mathematical Physics, Том 14, № 6, 1974, стр. 39-45.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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Nekrutkin, VV 1974, 'Direct and conjugate Neumann-Ulam schemes for solving non-linear integral equations', USSR Computational Mathematics and Mathematical Physics, Том. 14, № 6, стр. 39-45. https://doi.org/10.1016/0041-5553(74)90167-0

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Nekrutkin, V. V. / Direct and conjugate Neumann-Ulam schemes for solving non-linear integral equations. в: USSR Computational Mathematics and Mathematical Physics. 1974 ; Том 14, № 6. стр. 39-45.

BibTeX

@article{20d4d594825048b583354be8bbfaa057,
title = "Direct and conjugate Neumann-Ulam schemes for solving non-linear integral equations",
abstract = "ELEMENTARY unbiased estimates are constructed for a linear functional of the solution of a non-linear integral equation of fairly general type. The method of constructing the estimates, which is based on the {"}equivalence{"} of the initial equation to an infinite system of linear equations, makes it possible to transfer to the so-called conjugate Neumann-Ulam scheme, which can prove more advantageous when solving physical problems. We shall discuss the problem of estimating the functional I=∝φ{symbol}hdμ0 of the solution φ{symbol} of a non-linear integral equation of fairly general type. In accordance with the analogue of the Neumann-Ulam scheme, constructed for this case in [1], the functional is estimated on trajectories of a branched Markov process, which proves to be connected in a natural way with the iterations of the non-linear equation. Below we analyze a different approach to the Neumann-Ulam scheme, based on the equivalence of the initial equation to an infinite system of linear equations. It leads to somewhat more general Markov processes, the most natural of which prove to be branched, and it also enables us to consider the question of the so-called conjugate Neumann-Ulam scheme. Throughout, only elementary estimates of the {"}absorption{"} type will be constructed, though it is obviously possible to construct different types of estimate. In addition, we make no explicit stipulation about the absolute convergence of integrals and series, about the σ-finiteness of measures, or about the measurability of functions etc.; such conditions carry over almost automatically from the linear case examined in [2].",
author = "Nekrutkin, {V. V.}",
note = "Copyright: Copyright 2014 Elsevier B.V., All rights reserved.",
year = "1974",
doi = "10.1016/0041-5553(74)90167-0",
language = "English",
volume = "14",
pages = "39--45",
journal = "Computational Mathematics and Mathematical Physics",
issn = "0965-5425",
publisher = "МАИК {"}Наука/Интерпериодика{"}",
number = "6",

}

RIS

TY - JOUR

T1 - Direct and conjugate Neumann-Ulam schemes for solving non-linear integral equations

AU - Nekrutkin, V. V.

N1 - Copyright: Copyright 2014 Elsevier B.V., All rights reserved.

PY - 1974

Y1 - 1974

N2 - ELEMENTARY unbiased estimates are constructed for a linear functional of the solution of a non-linear integral equation of fairly general type. The method of constructing the estimates, which is based on the "equivalence" of the initial equation to an infinite system of linear equations, makes it possible to transfer to the so-called conjugate Neumann-Ulam scheme, which can prove more advantageous when solving physical problems. We shall discuss the problem of estimating the functional I=∝φ{symbol}hdμ0 of the solution φ{symbol} of a non-linear integral equation of fairly general type. In accordance with the analogue of the Neumann-Ulam scheme, constructed for this case in [1], the functional is estimated on trajectories of a branched Markov process, which proves to be connected in a natural way with the iterations of the non-linear equation. Below we analyze a different approach to the Neumann-Ulam scheme, based on the equivalence of the initial equation to an infinite system of linear equations. It leads to somewhat more general Markov processes, the most natural of which prove to be branched, and it also enables us to consider the question of the so-called conjugate Neumann-Ulam scheme. Throughout, only elementary estimates of the "absorption" type will be constructed, though it is obviously possible to construct different types of estimate. In addition, we make no explicit stipulation about the absolute convergence of integrals and series, about the σ-finiteness of measures, or about the measurability of functions etc.; such conditions carry over almost automatically from the linear case examined in [2].

AB - ELEMENTARY unbiased estimates are constructed for a linear functional of the solution of a non-linear integral equation of fairly general type. The method of constructing the estimates, which is based on the "equivalence" of the initial equation to an infinite system of linear equations, makes it possible to transfer to the so-called conjugate Neumann-Ulam scheme, which can prove more advantageous when solving physical problems. We shall discuss the problem of estimating the functional I=∝φ{symbol}hdμ0 of the solution φ{symbol} of a non-linear integral equation of fairly general type. In accordance with the analogue of the Neumann-Ulam scheme, constructed for this case in [1], the functional is estimated on trajectories of a branched Markov process, which proves to be connected in a natural way with the iterations of the non-linear equation. Below we analyze a different approach to the Neumann-Ulam scheme, based on the equivalence of the initial equation to an infinite system of linear equations. It leads to somewhat more general Markov processes, the most natural of which prove to be branched, and it also enables us to consider the question of the so-called conjugate Neumann-Ulam scheme. Throughout, only elementary estimates of the "absorption" type will be constructed, though it is obviously possible to construct different types of estimate. In addition, we make no explicit stipulation about the absolute convergence of integrals and series, about the σ-finiteness of measures, or about the measurability of functions etc.; such conditions carry over almost automatically from the linear case examined in [2].

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U2 - 10.1016/0041-5553(74)90167-0

DO - 10.1016/0041-5553(74)90167-0

M3 - Article

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VL - 14

SP - 39

EP - 45

JO - Computational Mathematics and Mathematical Physics

JF - Computational Mathematics and Mathematical Physics

SN - 0965-5425

IS - 6

ER -

ID: 76338006