The local behavior of the solution of the radiosity equation at the vertices of polyhedral domains in \({\mathbb{R}}^3\) (Q2753571)
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scientific article; zbMATH DE number 1670373
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | The local behavior of the solution of the radiosity equation at the vertices of polyhedral domains in \({\mathbb{R}}^3\) |
scientific article; zbMATH DE number 1670373 |
Statements
11 November 2001
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radiosity integral equation
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regularity results
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Mellin transform
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weighted Sobolev spaces
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The local behavior of the solution of the radiosity equation at the vertices of polyhedral domains in \({\mathbb{R}}^3\) (English)
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The author considers the radiosity integral equation on the boundary \(S\) of a polyhedron \(\Omega \in R^3\). This equation has the form \((I-K)u(x)=E(x)\), where NEWLINE\[NEWLINE(Ku)(x)=\frac{\rho(x)}{\pi}\int\limits_{S} \beta(x,y) \frac{ [\overrightarrow{n}_x \cdot (y-x)][\overrightarrow{n}_y \cdot (x-y)]}{||x-y||^4} u(y)dy. \eqno(1)NEWLINE\]NEWLINE Here \(\rho\) is the reflectivity function, \(\beta\) is the visibility function, \(E(x)\) is the emissivity function and \(\overrightarrow{n}_x, \overrightarrow{n}_y\) are the inner normal vectors. The author studies the local behavior of the solution of the equation (1) near the vertices in the terms of the weighted Sobolev spaces.
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