Formulation of a computational asymptotic bifurcation theory applicable to hill-top branching and multiple bifurcation analyses

Masato TANAKA; Takashi SASAGAWA; Ryuji OMOTE; Fumio FUJII

doi:10.1299/transjsme.18-00346

Nihon Kikai Gakkai ronbunshu (Nov 2018)

Formulation of a computational asymptotic bifurcation theory applicable to hill-top branching and multiple bifurcation analyses

Masato TANAKA,
Takashi SASAGAWA,
Ryuji OMOTE,
Fumio FUJII

Affiliations

Masato TANAKA: Toyota Central R&D Labs., INC.
Takashi SASAGAWA: Toyota Central R&D Labs., INC.
Ryuji OMOTE: Toyota Central R&D Labs., INC.
Fumio FUJII: Department of Mechanical Engineering, Gifu University

DOI: https://doi.org/10.1299/transjsme.18-00346
Journal volume & issue: Vol. 84, no. 868
pp. 18-00346 – 18-00346

Abstract

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To diagnose hill-top branching and multiple bifurcation, which exhibit two critical eigenvalues of the tangent stiffness matrix in stability problems, a sophisticated computational asymptotic bifurcation theory is developed. The theory generally uses three modes which are composed of two homogeneous solutions (critical eigenvectors) and one particular solution of the singular stiffness equations. The first- and second-order derivatives of the stiffness matrix with respect to nodal degrees-of-freedom (DoF) are required to formulate the proposed computational asymptotic bifurcation theory. In two benchmark problems of hill-top branching and multiple bifurcation, the validation and performance of the proposed theory are discussed.

Published in Nihon Kikai Gakkai ronbunshu

ISSN: 2187-9761 (Online)
Publisher: The Japan Society of Mechanical Engineers
Country of publisher: Japan
LCC subjects: Technology: Mechanical engineering and machinery; Technology: Engineering (General). Civil engineering (General): Engineering machinery, tools, and implements
Website: https://www.jsme.or.jp/publish/transact/

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