A Regularized Procedure to Generate a Deep Learning Model for Topology Optimization of Electromagnetic Devices

Over the last decade, learning theory performed significant progress in the development of sophisticated algorithms and their theoretical foundations. The theory builds on concepts that exploit ideas and methodologies from mathematical areas such as optimization theory. Regularization is probably the key to address the challenging problem of overfitting, which usually occurs in high-dimensional learning. Its primary goal is to make the machine learning algorithm “learn” and not “memorize” by penalizing the algorithm to reduce its generalization error in order to avoid the risk of overfitting. As a result, the variance of the model is significantly reduced, without substantial increase in its bias and without losing any important properties in the data.

Section: Regularization Techniques For Machine Learning and Their App...mentioning

confidence: 99%

Special Issue: Regularization Techniques for Machine Learning and Their Applications

Kotsilieris

Anagnostopoulos

Livieris³

2022

“…Another strategy consists of keeping the mesh fixed and changing the "properties" of the FEM elements [2][3][4][5][6]. In the electromagnetism framework, the "property" can be the presence or absence of the ferromagnetic material.…”

Section: Introductionmentioning

confidence: 99%

“…In the electromagnetism framework, the "property" can be the presence or absence of the ferromagnetic material. For instance, in [3], the authors apply such a strategy for the T.E.A.M. 25 problem.…”

Section: Introductionmentioning

confidence: 99%

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Curved Domains in Magnetics: A Virtual Element Method Approach for the T.E.A.M. 25 Benchmark Problem

Dassi,

Di Barba,

Russo

2024

In this paper, we are interested in solving optimal shape design problems. A critical challenge within this framework is generating the mesh of the computational domain at each optimisation step according to the information provided by the minimising functional. To enhance efficiency, we propose a strategy based on the Finite Element Method (FEM) and the Virtual Element Method (VEM). Specifically, we exploit the flexibility of the VEM in dealing with generally shaped polygons, including those with hanging nodes, to update the mesh solely in regions where the shape varies. In the remaining parts of the domain, we employ the FEM, known for its robustness and applicability in such scenarios. We numerically validate the proposed approach on the T.E.A.M. 25 benchmark problem and compare the results obtained with this procedure with those proposed in the literature based solely on the FEM. Moreover, since the T.E.A.M. 25 benchmark problem is also characterised by curved shapes, we utilise the VEM to accurately incorporate these “exact” curves into the discrete solution itself.

“…In previous works, authors have proposed several ML models both for solving the direct [9] model and the inverse model [10], focusing attention on optimization through the use of the direct model and highlighting the difficulty behind the inverse models.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning Approaches for Inverse Problems and Optimal Design in Electromagnetism

Formisano,

Tucci

2024

Self Cite

The spread of high-performance personal computers, frequently equipped with powerful Graphic Processing Units (GPUs), has raised interest in a set of techniques that are able to extract models of electromagnetic phenomena (and devices) directly from available examples of desired behavior. Such approaches are collectively referred to as Machine Learning (ML). A typical representative ML approach is the so-called “Neural Network” (NN). Using such data-driven models allows the evaluation of the output in a much shorter time when a theoretical model is available, or allows the prediction of the behavior of the systems and devices when no theoretical model is available. With reference to a simple yet representative benchmark electromagnetic problem, some of the possibilities and pitfalls of the use of NNs for the interpretation of measurements (inverse problem) or to obtain required measurements (optimal design problem) are discussed. The investigated aspects include the choice of NN model, the generation of the dataset(s), and the selection of hyper-parameters (hidden layers, training paradigm). Finally, the capabilities in the handling of ill-posed problems are critically revised.