Multi-Objective Optimal Design of Obstacle-Avoiding Two-Dimensional Steiner Trees With Application to Ascent Assembly Engineering-Reference-Cited by-同舟云学术

Multi-Objective Optimal Design of Obstacle-Avoiding Two-Dimensional Steiner Trees With Application to Ascent Assembly Engineering

Published:2018-03-26 Issue:6 Volume:140 Page:
ISSN:1050-0472
Container-title:Journal of Mechanical Design
language:en
Short-container-title:

Author:

Zăvoianu Alexandru-Ciprian¹,Saminger-Platz Susanne¹,Entner Doris²,Prante Thorsten²,Hellwig Michael³,Schwarz Martin⁴,Fink Klara⁴

Affiliation:

1. Department of Knowledge-Based Mathematical Systems, Johannes Kepler University Linz, Altenbergerstraße 69, Linz 4040, Austria e-mail:

2. Design Automation, V-Research GmbH—Industrial Research and Development, Stadtstraße 33, Dornbirn 6850, Austria e-mail:

3. Research Centre Process and Product Engineering, Vorarlberg University of Applied Sciences, Hochschulstraße 1, Dornbirn 6850, Austria e-mail:

4. Technology Management, Liebherr-Werk Nenzing GmbH, Dr.-Hans-Liebherr-Str. 1, Nenzing 6710, Austria e-mail:

Abstract

We present an effective optimization strategy that is capable of discovering high-quality cost-optimal solution for two-dimensional (2D) path network layouts (i.e., groups of obstacle-avoiding Euclidean Steiner trees) that, among other applications, can serve as templates for complete ascent assembly structures (CAA-structures). The main innovative aspect of our approach is that our aim is not restricted to simply synthesizing optimal assembly designs with regard to a given goal, but we also strive to discover the best tradeoffs between geometric and domain-dependent optimal designs. As such, the proposed approach is centered on a variably constrained multi-objective formulation of the optimal design task and on an efficient coevolutionary solver. The results we obtained on both artificial problems and realistic design scenarios based on an industrial test case empirically support the value of our contribution to the fields of optimal obstacle-avoiding path generation in particular and design automation in general.

Funder

Österreichische Forschungsförderungsgesellschaft

Publisher

ASME International

Subject

Computer Graphics and Computer-Aided Design,Computer Science Applications,Mechanical Engineering,Mechanics of Materials

Link

http://asmedigitalcollection.asme.org/mechanicaldesign/article-pdf/doi/10.1115/1.4039009/6232392/md_140_06_061401.pdf

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