Performance analysis of Electrical Machines based on Electromagnetic
System Characterization using Deep Learning
- URL: http://arxiv.org/abs/2201.09603v1
- Date: Mon, 24 Jan 2022 11:21:32 GMT
- Title: Performance analysis of Electrical Machines based on Electromagnetic
System Characterization using Deep Learning
- Authors: Vivek Parekh, Dominik Flore, Sebastian Sch\"ops
- Abstract summary: This paper presents a novel data-driven deep learning (DL) approach to approximate the electromagnetic behavior of an electrical machine.
The key idea is to train the proposed multibranch deep neural network (DNN) step by step on a large volume of stored FE data in a supervised manner.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: The numerical optimization of an electrical machine entails computationally
intensive and time-consuming magneto-static finite element (FE) simulation.
Generally, this FE-simulation involves varying input geometry, electrical, and
material parameters of an electrical machine. The result of the FE simulation
characterizes the electromagnetic behavior of the electrical machine. It
usually includes nonlinear iron losses and electromagnetic torque and flux at
different time-steps for an electrical cycle at each operating point (varying
electrical input phase current and control angle). In this paper, we present a
novel data-driven deep learning (DL) approach to approximate the
electromagnetic behavior of an electrical machine by predicting intermediate
measures that include non-linear iron losses, a non-negligible fraction
($\frac{1}{6}$ of a whole electrical period) of the electromagnetic torque and
flux at different time-steps for each operating point. The remaining time-steps
of the electromagnetic flux and torque for an electrical cycle are estimated by
exploiting the magnetic state symmetry of the electrical machine. Then these
calculations, along with the system parameters, are fed as input to the
physics-based analytical models to estimate characteristic maps and key
performance indicators (KPIs) such as material cost, maximum torque, power,
torque ripple, etc. The key idea is to train the proposed multi-branch deep
neural network (DNN) step by step on a large volume of stored FE data in a
supervised manner. Preliminary results exhibit that the predictions of
intermediate measures and the subsequent computations of KPIs are close to the
ground truth for a new machine design in the input design space. In the end,
the quantitative analysis validates that the hybrid approach is more accurate
than the existing DNN-based direct prediction of KPIs, which avoids
electromagnetic calculations.
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