Relaxation schemes for the M1 model with space-dependent flux in radiotherapy

Teddy Pichard; Martin Frank; Denise Aregba-Driollet; Stphane Brull; Bruno Dubroca

Relaxation schemes for the M₁ model with space-dependent flux in radiotherapy

Teddy Pichard
, Martin Frank
, Denise Aregba-Driollet
, Stphane Brull
, Bruno Dubroca

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

Abstract

Because of stability constraints, most numerical schemes applied to hyperbolic systems of equations turn out to be costly when the flux term is multiplied by some very large scalar. This problem emerges with the M\ system of equations in the field of radiotherapy when considering heterogeneous media with very disparate densities. Additionally, the flux term of the M₁ system is non-linear, and in order for the model to be well-posed the numerical solution needs to fulfill conditions called realizability. In this paper, we propose a numerical method that overcomes the stability constraint and preserves the realizability property. For this purpose, we relax the M₁ system to obtain a linear flux term. Then we extend the stencil of the difference quotient to obtain stability. The scheme is applied to a radiotherapy dose calculation example.

Original language	English
Title of host publication	Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015
Publisher	American Nuclear Society
Pages	547-558
Number of pages	12
ISBN (Electronic)	9781510808041
Publication status	Published - 1 Jan 2015
Externally published	Yes
Event	Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015 - Nashville, United States Duration: 19 Apr 2015 → 23 Apr 2015

Publication series

Name	Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015
Volume	1

Conference

Conference	Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015
Country/Territory	United States
City	Nashville
Period	19/04/15 → 23/04/15

Keywords

Method of characteristics
Moments models
Radiotherapy
Relaxation models

Cite this

Pichard, T., Frank, M., Aregba-Driollet, D., Brull, S., & Dubroca, B. (2015). Relaxation schemes for the M₁ model with space-dependent flux in radiotherapy. In Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015 (pp. 547-558). (Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015; Vol. 1). American Nuclear Society.

Pichard, Teddy ; Frank, Martin ; Aregba-Driollet, Denise et al. / Relaxation schemes for the M₁ model with space-dependent flux in radiotherapy. Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015. American Nuclear Society, 2015. pp. 547-558 (Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015).

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title = "Relaxation schemes for the M1 model with space-dependent flux in radiotherapy",

abstract = "Because of stability constraints, most numerical schemes applied to hyperbolic systems of equations turn out to be costly when the flux term is multiplied by some very large scalar. This problem emerges with the M\textbackslash{} system of equations in the field of radiotherapy when considering heterogeneous media with very disparate densities. Additionally, the flux term of the M1 system is non-linear, and in order for the model to be well-posed the numerical solution needs to fulfill conditions called realizability. In this paper, we propose a numerical method that overcomes the stability constraint and preserves the realizability property. For this purpose, we relax the M1 system to obtain a linear flux term. Then we extend the stencil of the difference quotient to obtain stability. The scheme is applied to a radiotherapy dose calculation example.",

keywords = "Method of characteristics, Moments models, Radiotherapy, Relaxation models",

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Pichard, T, Frank, M, Aregba-Driollet, D, Brull, S & Dubroca, B 2015, Relaxation schemes for the M₁ model with space-dependent flux in radiotherapy. in Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015. Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015, vol. 1, American Nuclear Society, pp. 547-558, Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015, Nashville, United States, 19/04/15.

Relaxation schemes for the M₁ model with space-dependent flux in radiotherapy. / Pichard, Teddy; Frank, Martin; Aregba-Driollet, Denise et al.
Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015. American Nuclear Society, 2015. p. 547-558 (Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015; Vol. 1).

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

TY - GEN

T1 - Relaxation schemes for the M1 model with space-dependent flux in radiotherapy

AU - Pichard, Teddy

AU - Frank, Martin

AU - Aregba-Driollet, Denise

AU - Brull, Stphane

AU - Dubroca, Bruno

PY - 2015/1/1

Y1 - 2015/1/1

N2 - Because of stability constraints, most numerical schemes applied to hyperbolic systems of equations turn out to be costly when the flux term is multiplied by some very large scalar. This problem emerges with the M\ system of equations in the field of radiotherapy when considering heterogeneous media with very disparate densities. Additionally, the flux term of the M1 system is non-linear, and in order for the model to be well-posed the numerical solution needs to fulfill conditions called realizability. In this paper, we propose a numerical method that overcomes the stability constraint and preserves the realizability property. For this purpose, we relax the M1 system to obtain a linear flux term. Then we extend the stencil of the difference quotient to obtain stability. The scheme is applied to a radiotherapy dose calculation example.

AB - Because of stability constraints, most numerical schemes applied to hyperbolic systems of equations turn out to be costly when the flux term is multiplied by some very large scalar. This problem emerges with the M\ system of equations in the field of radiotherapy when considering heterogeneous media with very disparate densities. Additionally, the flux term of the M1 system is non-linear, and in order for the model to be well-posed the numerical solution needs to fulfill conditions called realizability. In this paper, we propose a numerical method that overcomes the stability constraint and preserves the realizability property. For this purpose, we relax the M1 system to obtain a linear flux term. Then we extend the stencil of the difference quotient to obtain stability. The scheme is applied to a radiotherapy dose calculation example.

KW - Method of characteristics

KW - Moments models

KW - Radiotherapy

KW - Relaxation models

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M3 - Conference contribution

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T3 - Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015

SP - 547

EP - 558

BT - Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015

PB - American Nuclear Society

T2 - Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015

Y2 - 19 April 2015 through 23 April 2015

ER -

Pichard T, Frank M, Aregba-Driollet D, Brull S, Dubroca B. Relaxation schemes for the M₁ model with space-dependent flux in radiotherapy. In Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015. American Nuclear Society. 2015. p. 547-558. (Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015).