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TADA: Temporal Adversarial Data Augmentation for Time Series Data

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arxiv 2407.15174 v2 pith:5BWELXY3 submitted 2024-07-21 cs.LG cs.AIeess.SP

TADA: Temporal Adversarial Data Augmentation for Time Series Data

classification cs.LG cs.AIeess.SP
keywords timedatadistributiondomainshiftsseriestadaadversarial
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Domain generalization aim to train models to effectively perform on samples that are unseen and outside of the distribution. Adversarial data augmentation (ADA) is a widely used technique in domain generalization. It enhances the model robustness by including synthetic samples designed to simulate potential unseen scenarios into the training datasets, which is then used to train the model. However, in time series data, traditional ADA approaches often fail to address distribution shifts related to temporal characteristics. To address this limitation, we propose Temporal Adversarial Data Augmentation (TADA) for time series data, which incorporate time warping into ADA. Although time warping is inherently non-differentiable, ADA relies on generating samples through backpropagation. We resolve this issue by leveraging the duality between phase shifts in the frequency domain and time shifts in the time domain, thereby making the process differentiable. Our evaluations across various time series datasets demonstrate that TADA outperforms existing methods for domain generalization. In addition, using distribution visualization, we confirmed that the distribution shifts induced by TADA are clearly different from those induced by ADA, and together, they effectively simulate real-world distribution shifts.

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