机器人无监督学习的神经形态装置规范

Mohammad Sarim, R. Jha, Manish Kumar
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引用次数: 0

摘要

我们最近开发了一种新的学习解决方案,用于机器人的无监督学习,该解决方案基于以横杆方式排列的电阻式记忆器件,并通过在具有随机放置障碍物的未知环境中导航机器人来验证[1]。在这项工作中,我们研究了器件掺杂浓度和电阻状态的变化对机器人在导航任务中的性能的影响。这种变化源于器件制造过程中工艺参数的变化。我们对初始器件掺杂浓度和器件电阻态更新的变化进行了建模。我们还考虑了器件陷入低电阻状态的可能性。这项研究将帮助我们评估我们的学习方案的性能,并为这些设备的特定应用任务制定可接受的可变性范围的规范。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Neuromorphic device specifications for unsupervised learning in robots
We recently developed a novel learning solution for unsupervised learning in robots based on resistive memory devices arranged in a crossbar fashion and validated it by navigating a robot in an unknown environment with randomly placed obstacles [1]. In this work, we study the effects of variations in device doping concentrations and the resistive states on the performance of the robot during navigation tasks. Such variabilities arise from the variation in process parameters during device fabrication. We have modeled the variabilities in the initial device doping concentration and in the update of the device resistive states. We have also considered the possibility of a device getting stuck in a low resistance state. This study will help us evaluate the performance of our learning scheme and develop specifications on acceptable range of variability in these devices for application-specific tasks.
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