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Geometric Degrees of Freedom and Non-conventional Spatial Structural Forms Read chapter Read first chapter

2020 | OriginalPaper | Chapter

An Interactive Structural Optimization of Space Frame Structures Using Machine Learning

Authors : Zeynep Aksöz, Clemens Preisinger

Published in: Impact: Design With All Senses

Publisher: Springer International Publishing

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Abstract

The conventional methods used for structural optimization are handled by iterative simulation and evaluation runs, that are developed specifically for each problem, these processes can become computationally expensive very quickly. This work describes an approach to optimization of free form space structures, using Finite Element Analysis and Machine Learning, to overcome long computation periods.
As Hajela and Berke also state, approaching a structural problem as a single optimization problem results in a large dimensionality problem that can be cumbersome to solve by heuristic methods that are commonly used for the optimization of complex problems. Subsampling the problem into smaller independent parts can ease the problem-solving process. Through the use of artificial neural networks, the solutions can be obtained in parallel [1].
Through their modularity, space frames can be decomposed into sub-structures that share the same topology, and the complex problem can be simplified into independent modules. A supervised learning algorithm (in this case Back Propagation) is trained on a set of optimized modules to execute an optimal geometry for each structural node in parallel on a given load.
The trained ANN can be applied to any spaceframe structure regardless of their topology, size or complexity. This strategy shifts the optimization procedure from being a problem-specific process to domain-specific process, where within the same domain different problems can be solved. Thus the procedure becomes more sustainable.

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previous chapter Geometric Degrees of Freedom and Non-conventional Spatial Structural Forms
next chapter Application of Human-Machine Design Processes to Tensile Structures
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Metadata
Title
An Interactive Structural Optimization of Space Frame Structures Using Machine Learning
Authors
Zeynep Aksöz
Clemens Preisinger
Copyright Year
2020
Book
Impact: Design With All Senses

Print ISBN: 978-3-030-29828-9

Electronic ISBN: 978-3-030-29829-6

Copyright Year: 2020

DOI
https://doi.org/10.1007/978-3-030-29829-6_2

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