This survey provides a comprehensive review and comparison of few-shot learning methods for biomedical time series applications. The key highlights are:
Few-shot learning problems are defined by the limited number of labeled samples available, in contrast to traditional machine learning pipelines that divide datasets into training, validation, and test subsets. Few-shot learning aims to leverage past experiences to learn new tasks with few examples.
The taxonomy of few-shot learning methods includes data-based, model-based, metric-based, optimization-based, and hybrid approaches. Data-based methods generate synthetic samples to expand the support set, model-based methods design specialized architectures for few-shot generalization, metric-based methods learn similarity metrics between samples, and optimization-based methods guide model convergence to parameter spaces that can be quickly adapted.
Few-shot learning methods have been applied to a wide range of biomedical time series applications, including seizure detection, emotion recognition, arrhythmia classification, hand gesture recognition, and more. These methods demonstrate improved performance compared to traditional supervised learning, especially when dealing with data scarcity, class imbalance, and inter-subject variability.
Key challenges include designing effective embedding networks and similarity metrics, handling noisy or mislabeled data, and transferring knowledge across diverse datasets and tasks. Future directions involve exploring self-supervised pre-training, meta-learning, and hybrid approaches to further enhance the few-shot learning capabilities.
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