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33.1 A High-Accuracy and Energy-Efficient Zero-Shot-Retraining Seizure-Detection Processor with Hybrid-Feature-Driven Adaptive Processing and Learning-Based Adaptive Channel Selection

Jiahao Liu, Xiao Liu, Xu Wang, Ziyi Xie, Zirui Zhong, Jiajing Fan, Hui Qiu, Yiming Xu, Huajing Qin, Yu Long, Yuhong Zhou, Zixuan Shen, Liang Zhou, Liang Chang, Shanshan Liu, Shuisheng Lin, Chao Wang, Jun Zhou

202411 citationsDOI

Abstract

Seizure-detection processors using machine learning have been proposed to detect the seizure onset of patients for alert or stimulation purposes [1–4]. Existing designs can achieve high accuracy when large amounts of seizure data from a patient is available for the training. However, unlike the collection of non-seizure data, the collection of seizure data with low occurrence requires patients to undergo time-consuming and costly hospitalization, which is difficult in practice. To address this issue, [5] proposed a zero-shot-retraining seizure-detection processor achieving relatively high accuracy without seizure data from the patient for retraining (the zero-shot here means zero seizure data [5]). Instead, only 2-minute non-seizure data from the patient is required to calibrate the clustered features extracted with a neural network (NN) pre-trained on the public seizure dataset. Although this addresses the aforementioned issue, the accuracy (sensitivity 90.3% & specificity 93.6%) of this design is still limited for practical use, and the energy consumption is large for wearable EEG monitoring devices like other seizure-detection processors using NN, as shown in Fig. 33.1.1. In this work, we propose a zero-shot-retraining seizure-detection processor requiring no seizure data from the patient for retraining as in [5] but with much higher accuracy and energy efficiency. It has two major features: 1) a hybrid-feature-driven adaptive processing architecture with on-chip learning requiring no seizure data from the patient to achieve ultra-low energy consumption and high accuracy, and 2) a learning-based adaptive channel-selection technique to further reduce the energy consumption while maintaining high accuracy.

Topics & Concepts

Computer scienceFeature selectionArtificial intelligenceEnergy (signal processing)Feature (linguistics)Selection (genetic algorithm)StatisticsLinguisticsMathematicsPhilosophyEEG and Brain-Computer InterfacesBlind Source Separation TechniquesAdvanced Memory and Neural Computing