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Distilling Neuron Spike with High Temperature in Reinforcement Learning Agents

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arxiv 2108.10078 v1 pith:RUGQZ4CU submitted 2021-08-05 cs.NE cs.AIcs.LG

Distilling Neuron Spike with High Temperature in Reinforcement Learning Agents

classification cs.NE cs.AIcs.LG
keywords learningreinforcementconsumptionfasterlowermethodnetworkpower
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Spiking neural network (SNN), compared with depth neural network (DNN), has faster processing speed, lower energy consumption and more biological interpretability, which is expected to approach Strong AI. Reinforcement learning is similar to learning in biology. It is of great significance to study the combination of SNN and RL. We propose the reinforcement learning method of spike distillation network (SDN) with STBP. This method uses distillation to effectively avoid the weakness of STBP, which can achieve SOTA performance in classification, and can obtain a smaller, faster convergence and lower power consumption SNN reinforcement learning model. Experiments show that our method can converge faster than traditional SNN reinforcement learning and DNN reinforcement learning methods, about 1000 epochs faster, and obtain SNN 200 times smaller than DNN. We also deploy SDN to the PKU nc64c chip, which proves that SDN has lower power consumption than DNN, and the power consumption of SDN is more than 600 times lower than DNN on large-scale devices. SDN provides a new way of SNN reinforcement learning, and can achieve SOTA performance, which proves the possibility of further development of SNN reinforcement learning.

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