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Fast contouring of solutions to partial differential equations
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Source ACM Transactions on Mathematical Software (TOMS) archive
Volume 29 ,  Issue 4  (December 2003) table of contents
Pages: 418 - 439  
Year of Publication: 2003
ISSN:0098-3500
Authors
Emma L. Bradbury  University of Toronto, Toronto, Canada
Wayne H. Enright  University of Toronto, Toronto, Canada
Publisher
ACM  New York, NY, USA
Bibliometrics
Downloads (6 Weeks): 10,   Downloads (12 Months): 57,   Citation Count: 2
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ABSTRACT

The application of Differential Equation Interpolants (DEIs) to the visualization of the solutions to Partial Differential Equations (PDEs) is investigated. In particular, we describe how a DEI can be used to generate a fine mesh approximation from a coarse mesh approximation; this fine mesh approximation can then be used by a standard contouring function to render an accurate contour plot of the surface. However, the standard approach has a time complexity equivalent to that of rendering a surface plot, O(fm2) for each element of the coarse mesh, (where fm is the ratio of the width of the coarse mesh to the fine mesh). To address this concern three fast contouring algorithms are proposed that compute accurate contour lines directly from the DEI, and have time complexity at most O(fm) for each coarse mesh element.


REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

 
1
Bradbury, E. L. 2002. Fast contouring of solutions to partial differential equations. M.S. thesis, Department of Computer Science, University of Toronto.
 
2
Burden, R. L. and Faires, J. D. 2001. Numerical Analysis, 7 ed. Brooks/Cole.
3
W. H. Enright, Accurate approximate solution of partial differential equations at off-mesh points, ACM Transactions on Mathematical Software (TOMS), v.26 n.2, p.274-292, June 2000  [doi>10.1145/353474.353482]
 
4
Thomas A. Grandine, Applications of Contouring, SIAM Review, v.42 n.2, p.297-316, June 2000  [doi>10.1137/S003614459936403X]
 
5
MathWorks. MATLAB online documentation, 12 ed. MathWorks.
 
6
Ramos, G. A. and Enright, W. H. 2001. Interpolation of surfaces over scattered data. Proceedings of the IASTED International Conference VISUALIZATION, IMAGING, AND IMAGE PROCESSING, 219--224.
 
7
Schiesser, W. 1991. The Numerical Method of Lines Integration of Partial Differential Equations. Academic Press.

CITED BY  2
Hassan Goldani-Moghaddam , Wayne H. Enright, Efficient Contouring on Unstructured Meshes for Partial Differential Equations, ACM Transactions on Mathematical Software (TOMS), v.34 n.4, p.1-25, July 2008
Chandan Singh , Jaswinder Singh, Accurate contour plotting using 6-node triangular elements in 2D, Finite Elements in Analysis and Design, v.45 n.2, p.81-93, January, 2009

INDEX TERMS

Primary Classification:
  G. Mathematics of Computing
  G.1 NUMERICAL ANALYSIS
      G.1.2 Approximation

Additional Classification:
  G. Mathematics of Computing
  G.1 NUMERICAL ANALYSIS
      G.1.7 Ordinary Differential Equations
      G.1.8 Partial Differential Equations
  G.4 MATHEMATICAL SOFTWARE

  J. Computer Applications
  J.2 PHYSICAL SCIENCES AND ENGINEERING


General Terms:
Algorithms, Performance


Keywords:
PDEs, contour, interpolation, rendering, visualization


REVIEW

"Muhammed Ibrahem Syam : Reviewer"

Bradbury and Enright investigate the application of differential equation interpolants to the visualization of solutions to partial differential equations. In particular, they describe how a differential equation interpolant can be used to generat  more...

Collaborative Colleagues:
Emma L. Bradbury: colleagues
Wayne H. Enright: colleagues

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