HARDCORE: H-field and power loss estimation for arbitrary waveforms with residual, dilated convolutional neural networks in ferrite cores

• URL: http://arxiv.org/abs/2401.11488v2
• Date: Tue, 23 Jan 2024 17:49:42 GMT
• Title: HARDCORE: H-field and power loss estimation for arbitrary waveforms with residual, dilated convolutional neural networks in ferrite cores
• Authors: Wilhelm Kirchg\"assner, Nikolas F\"orster, Till Piepenbrock, Oliver Schweins, Oliver Wallscheid
• Abstract summary: MagNet Challenge 2023 calls upon competitors to develop data-driven models for material-specific, waveform-agnostic estimation of steady-state power losses in toroidal ferrite cores. HardCORE approach shows that a residual convolutional neural network with physics-informed extensions can serve this task efficiently when trained on observational data beforehand. A model is trained from scratch for each material, while the topology remains the same.
• Score: 1.3437002403398262
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: The MagNet Challenge 2023 calls upon competitors to develop data-driven models for the material-specific, waveform-agnostic estimation of steady-state power losses in toroidal ferrite cores. The following HARDCORE (H-field and power loss estimation for Arbitrary waveforms with Residual, Dilated convolutional neural networks in ferrite COREs) approach shows that a residual convolutional neural network with physics-informed extensions can serve this task efficiently when trained on observational data beforehand. One key solution element is an intermediate model layer which first reconstructs the bh curve and then estimates the power losses based on the curve's area rendering the proposed topology physically interpretable. In addition, emphasis was placed on expert-based feature engineering and information-rich inputs in order to enable a lean model architecture. A model is trained from scratch for each material, while the topology remains the same. A Pareto-style trade-off between model size and estimation accuracy is demonstrated, which yields an optimum at as low as 1755 parameters and down to below 8\,\% for the 95-th percentile of the relative error for the worst-case material with sufficient samples.

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