Shape optimal design using fictitious loads

S. D. Rajan; A. D. Belegundu

doi:10.2514/3.10100

Shape optimal design using fictitious loads

S. D. Rajan, A. D. Belegundu

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

46 Scopus citations

Abstract

Implementation aspects of the natural velocity field approach for shape optimal design are discussed. The problem of concern is to find the optimum shape of an elastic body that requires minimizing an objective function subject to stress, displacement, frequency, and manufacturing constraints. In this paper, fictitious loads are applied at certain control nodes on an auxiliary structure, and the deformation produced by these loads is used to update the shape. The use of beam stiffeners in the auxiliary structure leads to smoother shapes. Furthermore, softer material properties in the auxiliary structure result in faster convergence when iterating through the feasibile region. The method is applied in conjunction with both discrete and continuum methods of design sensitivity analysis.

Original language	English (US)
Pages (from-to)	102-107
Number of pages	6
Journal	AIAA journal
Volume	27
Issue number	1
DOIs	https://doi.org/10.2514/3.10100
State	Published - Jan 1989

All Science Journal Classification (ASJC) codes

Aerospace Engineering

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10.2514/3.10100

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title = "Shape optimal design using fictitious loads",

abstract = "Implementation aspects of the natural velocity field approach for shape optimal design are discussed. The problem of concern is to find the optimum shape of an elastic body that requires minimizing an objective function subject to stress, displacement, frequency, and manufacturing constraints. In this paper, fictitious loads are applied at certain control nodes on an auxiliary structure, and the deformation produced by these loads is used to update the shape. The use of beam stiffeners in the auxiliary structure leads to smoother shapes. Furthermore, softer material properties in the auxiliary structure result in faster convergence when iterating through the feasibile region. The method is applied in conjunction with both discrete and continuum methods of design sensitivity analysis.",

author = "Rajan, {S. D.} and Belegundu, {A. D.}",

note = "Funding Information: This research is supported by NSF Grants DMC 86-14205 and DMC 86-13438. The authors thank Dr. Wayne Nack and Professor T. R. Chandrupatla for giving valuable ideas on this topic.",

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N2 - Implementation aspects of the natural velocity field approach for shape optimal design are discussed. The problem of concern is to find the optimum shape of an elastic body that requires minimizing an objective function subject to stress, displacement, frequency, and manufacturing constraints. In this paper, fictitious loads are applied at certain control nodes on an auxiliary structure, and the deformation produced by these loads is used to update the shape. The use of beam stiffeners in the auxiliary structure leads to smoother shapes. Furthermore, softer material properties in the auxiliary structure result in faster convergence when iterating through the feasibile region. The method is applied in conjunction with both discrete and continuum methods of design sensitivity analysis.

AB - Implementation aspects of the natural velocity field approach for shape optimal design are discussed. The problem of concern is to find the optimum shape of an elastic body that requires minimizing an objective function subject to stress, displacement, frequency, and manufacturing constraints. In this paper, fictitious loads are applied at certain control nodes on an auxiliary structure, and the deformation produced by these loads is used to update the shape. The use of beam stiffeners in the auxiliary structure leads to smoother shapes. Furthermore, softer material properties in the auxiliary structure result in faster convergence when iterating through the feasibile region. The method is applied in conjunction with both discrete and continuum methods of design sensitivity analysis.

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Shape optimal design using fictitious loads

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