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Kazumi Matsui

Researcher at Yokohama National University

Publications -  37
Citations -  787

Kazumi Matsui is an academic researcher from Yokohama National University. The author has contributed to research in topics: Finite element method & Topology optimization. The author has an hindex of 9, co-authored 34 publications receiving 699 citations. Previous affiliations of Kazumi Matsui include Tohoku University.

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Continuous approximation of material distribution for topology optimization

TL;DR: In this paper, a checkboard-free topology optimization method without introducing any additional constraint parameter is proposed, which is called the method of continuous approximation of material distribution (CAMD) to emphasize the continuity imposed on the material field.
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Finite element modeling of multi-pass welding and shaped metal deposition processes

TL;DR: In this article, the authors describe the formulation adopted for the numerical simulation of the shaped metal deposition process (SMD) and the experimental work carried out at ITP Industry to calibrate and validate the proposed model.
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Two-scale finite element analysis of heterogeneous solids with periodic microstructures

TL;DR: This work makes a feasibility study and introduces a parallel algorithm to achieve the computational efficiency of a two-scale analysis method for nonlinear heterogeneous solids with periodic microstructures.
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Structural topology optimization of vibrating structures with specified eigenfrequencies and eigenmode shapes

TL;DR: In this article, a new topology optimization method for designing vibrating structures that targets desired eigenfrequencies and eigenmode shapes is proposed, which is applicable to the design of mechanical resonators and actuators.
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Two-scale kinematics and linearization for simultaneous two-scale analysis of periodic heterogeneous solids at finite strain

TL;DR: In this paper, the authors introduce the notion of two-scale kinematics and the procedure of twoscale linearization, which are indispensable to the simultaneous twoscale analysis of periodic heterogeneous solids at finite strain.