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Variational Autoencoder-Based Metamodeling for Multi-Objective Topology Optimization of Electrical Machines

Vivek Parekh, Dominik Flore, Sebastian Schops

2022IEEE Transactions on Magnetics26 citationsDOIOpen Access PDF

Abstract

Conventional magneto-static finite element (FE) analysis of electrical machine design is time-consuming and computationally expensive. Since each machine topology has a distinct set of parameters, design optimization is commonly performed independently. This article presents a novel method for predicting key performance indicators (KPIs) of differently parameterized electrical machine topologies at the same time by mapping a high-dimensional integrated design parameters in a lower-dimensional latent space using a variational autoencoder (VAE). After training, via a latent space, the decoder and multi-layer neural network will function as meta-models for sampling new designs and predicting associated KPIs, respectively. This enables parameter-based concurrent multi-topology optimization.

Topics & Concepts

Computer scienceFinite element methodTopology optimizationParameterized complexityTopology (electrical circuits)MetamodelingNetwork topologyArtificial neural networkSet (abstract data type)AutoencoderAlgorithmSampling (signal processing)Key (lock)Design space explorationElectric machineElectrical networkFunction (biology)Optimal designError functionDesign of experimentsMathematical optimizationOptimization problemTopology Optimization in EngineeringElectric Motor Design and AnalysisMagnetic Properties and Applications
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