一种用于设计控制有腿机器人运动的合成神经系统的功能子网方法。

A Functional Subnetwork Approach to Designing Synthetic Nervous Systems That Control Legged Robot Locomotion.

作者信息

Szczecinski Nicholas S, Hunt Alexander J, Quinn Roger D

机构信息

Biologically Inspired Robotics Laboratory, Department of Mechanical and Aerospace Engineering, Case Western Reserve University, Cleveland, OH, United States.

Department of Mechanical and Materials Engineering, Portland State University, Portland, OR, United States.

出版信息

Front Neurorobot. 2017 Aug 9;11:37. doi: 10.3389/fnbot.2017.00037. eCollection 2017.

DOI:10.3389/fnbot.2017.00037

PMID:28848419

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5552699/

Abstract

A dynamical model of an animal's nervous system, or synthetic nervous system (SNS), is a potentially transformational control method. Due to increasingly detailed data on the connectivity and dynamics of both mammalian and insect nervous systems, controlling a legged robot with an SNS is largely a problem of parameter tuning. Our approach to this problem is to design functional subnetworks that perform specific operations, and then assemble them into larger models of the nervous system. In this paper, we present networks that perform addition, subtraction, multiplication, division, differentiation, and integration of incoming signals. Parameters are set within each subnetwork to produce the desired output by utilizing the operating range of neural activity, , the gain of the operation, , and bounds based on biological values. The assembly of large networks from functional subnetworks underpins our recent results with MantisBot.

摘要

动物神经系统或合成神经系统（SNS）的动力学模型是一种具有潜在变革性的控制方法。由于关于哺乳动物和昆虫神经系统的连通性和动力学的数据越来越详细，用SNS控制有腿机器人在很大程度上是一个参数调整问题。我们解决这个问题的方法是设计执行特定操作的功能子网，然后将它们组装成更大的神经系统模型。在本文中，我们展示了能够对输入信号进行加、减、乘、除、微分和积分的网络。通过利用神经活动的工作范围、操作增益以及基于生物学值的界限，在每个子网内设置参数以产生期望的输出。从功能子网组装大型网络是我们最近在螳螂机器人上取得成果的基础。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0484/5552699/e5cc90cf3d24/fnbot-11-00037-g001.jpg

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一种用于设计控制有腿机器人运动的合成神经系统的功能子网方法。

A Functional Subnetwork Approach to Designing Synthetic Nervous Systems That Control Legged Robot Locomotion.

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