Optimizing contact-based assemblies

Modern fabrication methods have greatly simplified manufacturing of complex free-form shapes at an affordable cost, and opened up new possibilities for improving functionality and customization through automatic optimization, shape optimization in particular. However, most existing shape optimizatio...

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Veröffentlicht in:	ACM transactions on graphics 2021-12, Vol.40 (6), p.1-19, Article 269
Hauptverfasser:	Tozoni, Davi Colli, Zhou, Yunfan, Zorin, Denis
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer graphics Computing methodologies Mesh models Shape modeling
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creator	Tozoni, Davi Colli Zhou, Yunfan Zorin, Denis
description	Modern fabrication methods have greatly simplified manufacturing of complex free-form shapes at an affordable cost, and opened up new possibilities for improving functionality and customization through automatic optimization, shape optimization in particular. However, most existing shape optimization methods focus on single parts. In this work, we focus on supporting shape optimization for assemblies, more specifically, assemblies that are held together by contact and friction. Examples of which include furniture joints, construction set assemblies, certain types of prosthetic devices and many other. To enable this optimization, we present a framework supporting robust and accurate optimization of a number of important functionals, while enforcing constraints essential for assembly functionality: weight, stress, difficulty of putting the assembly together, and how reliably it stays together. Our framework is based on smoothed formulation of elasticity equations with contact, analytically derived shape derivatives, and robust remeshing to enable large changes of shape, and at the same time, maintain accuracy. We demonstrate the improvements it can achieve for a number of computational and experimental examples.
doi_str_mv	10.1145/3478513.3480552
format	Article
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subjects	Computer graphics Computing methodologies Mesh models Shape modeling
title	Optimizing contact-based assemblies
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