Efficient Patient Fine-Tuned Seizure Detection with a Tensor Kernel Machine

• URL: http://arxiv.org/abs/2408.00437v1
• Date: Thu, 1 Aug 2024 10:16:57 GMT
• Title: Efficient Patient Fine-Tuned Seizure Detection with a Tensor Kernel Machine
• Authors: Seline J. S. de Rooij, Frederiek Wesel, Borbála Hunyadi,
• Abstract summary: In a wearable device one typically starts with a patient-independent model, until such patient-specific data is available. We propose a transfer learning approach with a tensor kernel machine. This method learns the primal weights in a compressed form using the canonical polyadic decomposition.
• Score: 4.7710033120220885
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Recent developments in wearable devices have made accurate and efficient seizure detection more important than ever. A challenge in seizure detection is that patient-specific models typically outperform patient-independent models. However, in a wearable device one typically starts with a patient-independent model, until such patient-specific data is available. To avoid having to construct a new classifier with this data, as required in conventional kernel machines, we propose a transfer learning approach with a tensor kernel machine. This method learns the primal weights in a compressed form using the canonical polyadic decomposition, making it possible to efficiently update the weights of the patient-independent model with patient-specific data. The results show that this patient fine-tuned model reaches as high a performance as a patient-specific SVM model with a model size that is twice as small as the patient-specific model and ten times as small as the patient-independent model.

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