ReckOn: A 28nm Sub-mm2 Task-Agnostic Spiking Recurrent Neural Network Processor Enabling On-Chip Learning over Second-Long Timescales

2022 IEEE International Solid- State Circuits Conference (ISSCC) Pub Date : 2022-02-20 DOI:10.1109/ISSCC42614.2022.9731734

C. Frenkel, G. Indiveri

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引用次数: 40

Abstract

The robustness of autonomous inference-only devices deployed in the real world is limited by data distribution changes induced by different users, environments, and task requirements. This challenge calls for the development of edge devices with an always-on adaptation to their target ecosystems. However, the memory requirements of conventional neural-network training algorithms scale with the temporal depth of the data being processed, which is not compatible with the constrained power and area budgets at the edge. For this reason, previous works demonstrating end-to-end on-chip learning without external memory were restricted to the processing of static data such as images [1]–[4], or to instantaneous decisions involving no memory of the past, e.g. obstacle avoidance in mobile robots [5]. The ability to learn short-to-long-term temporal dependencies on-chip is a missing enabler for robust autonomous edge devices in applications such as gesture recognition, speech processing, and cognitive robotics.

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一种28纳米亚平方毫米任务不可知的脉冲递归神经网络处理器，能够在秒级时间尺度上进行片上学习

在现实世界中部署的自主推理设备的鲁棒性受到由不同用户、环境和任务需求引起的数据分布变化的限制。这一挑战要求开发边缘设备，并始终适应其目标生态系统。然而，传统的神经网络训练算法的内存需求随着被处理数据的时间深度而扩大，这与边缘处受限的功率和面积预算不兼容。由于这个原因，之前展示端到端片上学习没有外部记忆的工作仅限于处理静态数据，如图像[1]-[4]，或者不涉及过去记忆的瞬时决策，如移动机器人的避障[5]。对于手势识别、语音处理和认知机器人等应用中强大的自主边缘设备来说，学习芯片上短期到长期时间依赖性的能力是一个缺失的因素。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE International Solid- State Circuits Conference (ISSCC)

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