Solution of the Hyperbolic Partial Differential Equation on Graphs and Digital Spaces: a Klein Bottle a Projective Plane and a 4D Sphere
Alexander V. Evako

TL;DR
This paper explores computational solutions to hyperbolic PDEs on digital models of continuous manifolds like the Klein bottle and 4D sphere, emphasizing topologically correct digital domains for accurate results.
Contribution
It introduces conditions for the existence of solutions and demonstrates numerical solutions on digital manifolds, bridging continuous PDEs and digital topology.
Findings
Conditions for solution existence established
Numerical solutions demonstrated on digital manifolds
Highlights importance of topologically correct digital domains
Abstract
In many cases, analytic solutions of partial differential equations may not be possible. For practical problems, it is more reasonable to carry out computational solutions. However, the standard grid in the finite difference approximation is not a correct model of the continuous domain in terms of digital topology. In order to avoid serious problems in computational solutions it is necessary to use topologically correct digital domains. This paper studies the structure of the hyperbolic partial differential equation on graphs and digital n-dimensional manifolds, which are digital models of continuous n-manifolds. Conditions for the existence of solutions are determined and investigated. Numerical solutions of the equation on graphs and digital n-manifolds are presented.
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Taxonomy
TopicsDigital Image Processing Techniques · Algebraic and Geometric Analysis · Mathematical Analysis and Transform Methods
