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arxiv 2106.02568 v1 pith:R7KUFDPK submitted 2021-06-04 cs.NE

Training Energy-Efficient Deep Spiking Neural Networks with Time-to-First-Spike Coding

classification cs.NE
keywords deepcodingsnnsenergy-efficienttrainingefficiencynetworksneural
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The tremendous energy consumption of deep neural networks (DNNs) has become a serious problem in deep learning. Spiking neural networks (SNNs), which mimic the operations in the human brain, have been studied as prominent energy-efficient neural networks. Due to their event-driven and spatiotemporally sparse operations, SNNs show possibilities for energy-efficient processing. To unlock their potential, deep SNNs have adopted temporal coding such as time-to-first-spike (TTFS)coding, which represents the information between neurons by the first spike time. With TTFS coding, each neuron generates one spike at most, which leads to a significant improvement in energy efficiency. Several studies have successfully introduced TTFS coding in deep SNNs, but they showed restricted efficiency improvement owing to the lack of consideration for efficiency during training. To address the aforementioned issue, this paper presents training methods for energy-efficient deep SNNs with TTFS coding. We introduce a surrogate DNN model to train the deep SNN in a feasible time and analyze the effect of the temporal kernel on training performance and efficiency. Based on the investigation, we propose stochastically relaxed activation and initial value-based regularization for the temporal kernel parameters. In addition, to reduce the number of spikes even further, we present temporal kernel-aware batch normalization. With the proposed methods, we could achieve comparable training results with significantly reduced spikes, which could lead to energy-efficient deep SNNs.

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Cited by 1 Pith paper

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  1. Frozen Backpropagation: Relaxing Weight Symmetry in Deep Spiking Neural Networks

    cs.CV 2025-05 unverdicted novelty 6.0

    fBP trains SNNs with separate forward and feedback networks by freezing feedback weights periodically during updates, matching BP accuracy while cutting transport costs up to 10,000x via partial schemes.