Polynomial Chaos Expanded Gaussian Process
- URL: http://arxiv.org/abs/2405.01052v1
- Date: Thu, 2 May 2024 07:11:05 GMT
- Title: Polynomial Chaos Expanded Gaussian Process
- Authors: Dominik Polke, Tim Kösters, Elmar Ahle, Dirk Söffker,
- Abstract summary: In complex and unknown processes, global models are initially generated over the entire experimental space.
This study addresses the need for models that effectively represent both global and local experimental spaces.
- Score: 2.287415292857564
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: In complex and unknown processes, global models are initially generated over the entire experimental space, but they often fail to provide accurate predictions in local areas. Recognizing this limitation, this study addresses the need for models that effectively represent both global and local experimental spaces. It introduces a novel machine learning (ML) approach: Polynomial Chaos Expanded Gaussian Process (PCEGP), leveraging polynomial chaos expansion (PCE) to calculate input-dependent hyperparameters of the Gaussian process (GP). This approach provides a mathematically interpretable method that incorporates non-stationary covariance functions and heteroscedastic noise estimation to generate locally adapted models. The model performance is compared to different algorithms in benchmark tests for regression tasks. The results demonstrate low prediction errors of the PCEGP in these benchmark applications, highlighting model performance that is often competitive with or superior to previous methods. A key advantage of the presented model is the transparency and traceability in the calculation of hyperparameters and model predictions.
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