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Generalizability Under Sensor Failure: Tokenization + Transformers Enable More Robust Latent Spaces

Machine Learning 2024-03-21 v3

Abstract

A major goal in neuroscience is to discover neural data representations that generalize. This goal is challenged by variability along recording sessions (e.g. environment), subjects (e.g. varying neural structures), and sensors (e.g. sensor noise), among others. Recent work has begun to address generalization across sessions and subjects, but few study robustness to sensor failure which is highly prevalent in neuroscience experiments. In order to address these generalizability dimensions we first collect our own electroencephalography dataset with numerous sessions, subjects, and sensors, then study two time series models: EEGNet (Lawhern et al., 2018) and TOTEM (Talukder et al., 2024). EEGNet is a widely used convolutional neural network, while TOTEM is a discrete time series tokenizer and transformer model. We find that TOTEM outperforms or matches EEGNet across all generalizability cases. Finally through analysis of TOTEM's latent codebook we observe that tokenization enables generalization.

Keywords

Cite

@article{arxiv.2402.18546,
  title  = {Generalizability Under Sensor Failure: Tokenization + Transformers Enable More Robust Latent Spaces},
  author = {Geeling Chau and Yujin An and Ahamed Raffey Iqbal and Soon-Jo Chung and Yisong Yue and Sabera Talukder},
  journal= {arXiv preprint arXiv:2402.18546},
  year   = {2024}
}

Comments

9 pages, 8 figures

R2 v1 2026-06-28T15:03:36.400Z