Related papers: AutoML for Multi-Class Anomaly Compensation of Sensor Drift

AutoML for Multi-Class Anomaly Compensation of Sensor Drift

URL: http://arxiv.org/abs/2502.19180v1
Date: Wed, 26 Feb 2025 14:34:53 GMT
Title: AutoML for Multi-Class Anomaly Compensation of Sensor Drift
Authors: Melanie Schaller, Mathis Kruse, Antonio Ortega, Marius Lindauer, Bodo Rosenhahn,
Abstract summary: Sensor drift degrades the performance of machine learning models over time.<n>Standard cross-validation method overestimates performance by inadequately accounting for drift.<n>This paper presents two solutions: (1) a novel sensor drift compensation learning paradigm for validating models, and (2) automated machine learning (AutoML) techniques to enhance classification performance and compensate sensor drift.
Score: 44.63945828405864
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Addressing sensor drift is essential in industrial measurement systems, where precise data output is necessary for maintaining accuracy and reliability in monitoring processes, as it progressively degrades the performance of machine learning models over time. Our findings indicate that the standard cross-validation method used in existing model training overestimates performance by inadequately accounting for drift. This is primarily because typical cross-validation techniques allow data instances to appear in both training and testing sets, thereby distorting the accuracy of the predictive evaluation. As a result, these models are unable to precisely predict future drift effects, compromising their ability to generalize and adapt to evolving data conditions. This paper presents two solutions: (1) a novel sensor drift compensation learning paradigm for validating models, and (2) automated machine learning (AutoML) techniques to enhance classification performance and compensate sensor drift. By employing strategies such as data balancing, meta-learning, automated ensemble learning, hyperparameter optimization, feature selection, and boosting, our AutoML-DC (Drift Compensation) model significantly improves classification performance against sensor drift. AutoML-DC further adapts effectively to varying drift severities.

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