Solving of Two-Dimensional Unsteady Inverse Heat Conduction Problems Based on Boundary Element Method and Sequential Function Specification Method

Solving of Two-Dimensional Unsteady Inverse Heat Conduction Problems Based on Boundary Element Method and Sequential Function Specification Method

The boundary element method (BEM) and sequential function specification method (SFSM) are used to research the inverse problem of boundary heat flux identification in the two-dimensional heat conduction system. The future time step in the SFSM is optimized by introducing the residual error principle...

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Main Authors: Shoubin Wang, Yuanzheng Deng, Xiaogang Sun
Format: Article
Language:English
Published: Hindawi-Wiley 2018-01-01
Series:Complexity
Online Access:http://dx.doi.org/10.1155/2018/6741632
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spelling doaj-5d5afbd521a640558abc0c304fc6a3262020-11-25T01:11:50ZengHindawi-WileyComplexity1076-27871099-05262018-01-01201810.1155/2018/67416326741632Solving of Two-Dimensional Unsteady Inverse Heat Conduction Problems Based on Boundary Element Method and Sequential Function Specification MethodShoubin Wang0Yuanzheng Deng1Xiaogang Sun2School of Control and Mechanical Engineering, Tianjin Chengjian University, Tianjin 300384, ChinaSchool of Control and Mechanical Engineering, Tianjin Chengjian University, Tianjin 300384, ChinaSchool of Electrical Engineering and Automation, Harbin Institute of Technology, Harbin 150001, ChinaThe boundary element method (BEM) and sequential function specification method (SFSM) are used to research the inverse problem of boundary heat flux identification in the two-dimensional heat conduction system. The future time step in the SFSM is optimized by introducing the residual error principles to get the more accurate inversion results. For the forward problems, the BEM is used to calculate the required temperature value of discrete point; for the inverse problems, the impacts of different future time steps, measuring point position, and measuring error on the inversion results are discussed. Furthermore, the comparison is made for the optimal future time step obtained by introducing the residual error principle and the inherent future time step. The example analysis shows that the method proposed still has higher accuracy when the measuring error exists or the measuring point position is far away from the boundary heat flux.http://dx.doi.org/10.1155/2018/6741632
collection DOAJ
language English
format Article
sources DOAJ
author Shoubin Wang
Yuanzheng Deng
Xiaogang Sun
spellingShingle Shoubin Wang
Yuanzheng Deng
Xiaogang Sun
Solving of Two-Dimensional Unsteady Inverse Heat Conduction Problems Based on Boundary Element Method and Sequential Function Specification Method
Complexity
author_facet Shoubin Wang
Yuanzheng Deng
Xiaogang Sun
author_sort Shoubin Wang
title Solving of Two-Dimensional Unsteady Inverse Heat Conduction Problems Based on Boundary Element Method and Sequential Function Specification Method
title_short Solving of Two-Dimensional Unsteady Inverse Heat Conduction Problems Based on Boundary Element Method and Sequential Function Specification Method
title_full Solving of Two-Dimensional Unsteady Inverse Heat Conduction Problems Based on Boundary Element Method and Sequential Function Specification Method
title_fullStr Solving of Two-Dimensional Unsteady Inverse Heat Conduction Problems Based on Boundary Element Method and Sequential Function Specification Method
title_full_unstemmed Solving of Two-Dimensional Unsteady Inverse Heat Conduction Problems Based on Boundary Element Method and Sequential Function Specification Method
title_sort solving of two-dimensional unsteady inverse heat conduction problems based on boundary element method and sequential function specification method
publisher Hindawi-Wiley
series Complexity
issn 1076-2787
1099-0526
publishDate 2018-01-01
description The boundary element method (BEM) and sequential function specification method (SFSM) are used to research the inverse problem of boundary heat flux identification in the two-dimensional heat conduction system. The future time step in the SFSM is optimized by introducing the residual error principles to get the more accurate inversion results. For the forward problems, the BEM is used to calculate the required temperature value of discrete point; for the inverse problems, the impacts of different future time steps, measuring point position, and measuring error on the inversion results are discussed. Furthermore, the comparison is made for the optimal future time step obtained by introducing the residual error principle and the inherent future time step. The example analysis shows that the method proposed still has higher accuracy when the measuring error exists or the measuring point position is far away from the boundary heat flux.
url http://dx.doi.org/10.1155/2018/6741632
work_keys_str_mv AT shoubinwang solvingoftwodimensionalunsteadyinverseheatconductionproblemsbasedonboundaryelementmethodandsequentialfunctionspecificationmethod
AT yuanzhengdeng solvingoftwodimensionalunsteadyinverseheatconductionproblemsbasedonboundaryelementmethodandsequentialfunctionspecificationmethod
AT xiaogangsun solvingoftwodimensionalunsteadyinverseheatconductionproblemsbasedonboundaryelementmethodandsequentialfunctionspecificationmethod
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