SAM: A Unified Self-Adaptive Multicompartmental Spiking Neuron Model for Learning With Working Memory

Shuangming Yang; Tian Gao; Jiang Wang; Bin Deng; Mostafa Rahimi Azghadi; Tao Lei; Bernabe Linares-Barranco

doi:10.3389/fnins.2022.850945

SAM: A Unified Self-Adaptive Multicompartmental Spiking Neuron Model for Learning With Working Memory

Front Neurosci. 2022 Apr 18:16:850945. doi: 10.3389/fnins.2022.850945. eCollection 2022.

Authors

Shuangming Yang¹, Tian Gao¹, Jiang Wang¹, Bin Deng¹, Mostafa Rahimi Azghadi², Tao Lei³, Bernabe Linares-Barranco⁴

Affiliations

¹ School of Electrical and Information Engineering, Tianjin University, Tianjin, China.
² College of Science and Engineering, James Cook University, Townsville, QLD, Australia.
³ School of Electronic Information and Artificial Intelligence, Shaanxi University of Science and Technology, Xi'an, China.
⁴ Microelectronics Institute of Seville, Seville, Spain.

Abstract

Working memory is a fundamental feature of biological brains for perception, cognition, and learning. In addition, learning with working memory, which has been show in conventional artificial intelligence systems through recurrent neural networks, is instrumental to advanced cognitive intelligence. However, it is hard to endow a simple neuron model with working memory, and to understand the biological mechanisms that have resulted in such a powerful ability at the neuronal level. This article presents a novel self-adaptive multicompartment spiking neuron model, referred to as SAM, for spike-based learning with working memory. SAM integrates four major biological principles including sparse coding, dendritic non-linearity, intrinsic self-adaptive dynamics, and spike-driven learning. We first describe SAM's design and explore the impacts of critical parameters on its biological dynamics. We then use SAM to build spiking networks to accomplish several different tasks including supervised learning of the MNIST dataset using sequential spatiotemporal encoding, noisy spike pattern classification, sparse coding during pattern classification, spatiotemporal feature detection, meta-learning with working memory applied to a navigation task and the MNIST classification task, and working memory for spatiotemporal learning. Our experimental results highlight the energy efficiency and robustness of SAM in these wide range of challenging tasks. The effects of SAM model variations on its working memory are also explored, hoping to offer insight into the biological mechanisms underlying working memory in the brain. The SAM model is the first attempt to integrate the capabilities of spike-driven learning and working memory in a unified single neuron with multiple timescale dynamics. The competitive performance of SAM could potentially contribute to the development of efficient adaptive neuromorphic computing systems for various applications from robotics to edge computing.

Keywords: dendritic processing; meta-learning; neuromorphic computing; spike-driven learning; spiking neural network (SNN); working memory.