An Improved Arbitrary Resolution MRTD Method

Qunsheng Cao; Kumar K Tamma

An Improved Arbitrary Resolution MRTD Method

Mechanical Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

In this paper, an improved arbitrary resolution algorithm for the multiresolution time domain (MRTD) scheme based on the cubic spline Battle-Lemarie wavelet function is presented. The analytic coefficients, orthogonal and integral relations are derived. Through an example of a TEM one-dimensional propagating wave the update equations of a dielectric region are proposed. The results have been compared with those derived from the FDTD, and it is found that the high-order wavelet components of the MRTD obtain more accuracy in numerical computations; however, they could increase addition complexity and computational burden in MRTD applications.

Original language	English (US)
Title of host publication	Annual Review of Progress in Applied Computational Electromagnetics
Pages	665-668
Number of pages	4
State	Published - Dec 1 2003
Event	19th Annual Review of Progress in Applied Computational Electromagnetics - Monterey, CA, United States Duration: Mar 24 2003 → Mar 28 2003

Other

Other	19th Annual Review of Progress in Applied Computational Electromagnetics
Country	United States
City	Monterey, CA
Period	3/24/03 → 3/28/03

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Keywords

Multiresolution Time Domain (MRTD) scheme
Reflected coefficients
Resolution level

Cite this

Cao, Q., & Tamma, K. K. (2003). An Improved Arbitrary Resolution MRTD Method. In Annual Review of Progress in Applied Computational Electromagnetics (pp. 665-668)

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title = "An Improved Arbitrary Resolution MRTD Method",

abstract = "In this paper, an improved arbitrary resolution algorithm for the multiresolution time domain (MRTD) scheme based on the cubic spline Battle-Lemarie wavelet function is presented. The analytic coefficients, orthogonal and integral relations are derived. Through an example of a TEM one-dimensional propagating wave the update equations of a dielectric region are proposed. The results have been compared with those derived from the FDTD, and it is found that the high-order wavelet components of the MRTD obtain more accuracy in numerical computations; however, they could increase addition complexity and computational burden in MRTD applications.",

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author = "Qunsheng Cao and Tamma, {Kumar K}",

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T1 - An Improved Arbitrary Resolution MRTD Method

AU - Cao, Qunsheng

AU - Tamma, Kumar K

PY - 2003/12/1

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N2 - In this paper, an improved arbitrary resolution algorithm for the multiresolution time domain (MRTD) scheme based on the cubic spline Battle-Lemarie wavelet function is presented. The analytic coefficients, orthogonal and integral relations are derived. Through an example of a TEM one-dimensional propagating wave the update equations of a dielectric region are proposed. The results have been compared with those derived from the FDTD, and it is found that the high-order wavelet components of the MRTD obtain more accuracy in numerical computations; however, they could increase addition complexity and computational burden in MRTD applications.

AB - In this paper, an improved arbitrary resolution algorithm for the multiresolution time domain (MRTD) scheme based on the cubic spline Battle-Lemarie wavelet function is presented. The analytic coefficients, orthogonal and integral relations are derived. Through an example of a TEM one-dimensional propagating wave the update equations of a dielectric region are proposed. The results have been compared with those derived from the FDTD, and it is found that the high-order wavelet components of the MRTD obtain more accuracy in numerical computations; however, they could increase addition complexity and computational burden in MRTD applications.

KW - Multiresolution Time Domain (MRTD) scheme

KW - Reflected coefficients

KW - Resolution level

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M3 - Conference contribution

AN - SCOPUS:1642458685

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EP - 668

BT - Annual Review of Progress in Applied Computational Electromagnetics

T2 - 19th Annual Review of Progress in Applied Computational Electromagnetics

Y2 - 24 March 2003 through 28 March 2003

ER -

An Improved Arbitrary Resolution MRTD Method

Abstract

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Keywords

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