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1. Verfasser: Beurich, Johann
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2408.13524
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author Beurich, Johann
author_facet Beurich, Johann
contents We give an upper bound for the difference of two solutions of Euler schemes approximating the Cauchy problem \[\begin{cases} \dot{u}(t) + Au(t) \ni f(t) \quad (t \in [0, T]), \\ u(0) = u^0, \end{cases}\] where $A \subseteq X \times X$ is a quasi-accretive operator on a Banach space $X$, $T > 0$, $f \in L^1(0, T; X)$ and $u^0 \in X$. This upper bound generalizes a result from Kobayashi, who established an upper bound for the problem with $f = 0$. We show, that the upper bound can be used to establish existence and uniqueness of Euler solutions as limits of solutions of Euler schemes as well as regularity of Euler solutions.
format Preprint
id arxiv_https___arxiv_org_abs_2408_13524
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Differences of solutions of implicit Euler schemes with accretive operators on Banach spaces
Beurich, Johann
Analysis of PDEs
Functional Analysis
47H06
We give an upper bound for the difference of two solutions of Euler schemes approximating the Cauchy problem \[\begin{cases} \dot{u}(t) + Au(t) \ni f(t) \quad (t \in [0, T]), \\ u(0) = u^0, \end{cases}\] where $A \subseteq X \times X$ is a quasi-accretive operator on a Banach space $X$, $T > 0$, $f \in L^1(0, T; X)$ and $u^0 \in X$. This upper bound generalizes a result from Kobayashi, who established an upper bound for the problem with $f = 0$. We show, that the upper bound can be used to establish existence and uniqueness of Euler solutions as limits of solutions of Euler schemes as well as regularity of Euler solutions.
title Differences of solutions of implicit Euler schemes with accretive operators on Banach spaces
topic Analysis of PDEs
Functional Analysis
47H06
url https://arxiv.org/abs/2408.13524