This paper presents the design principles for highly efficient legged robots, the implementation of the principles in the design of the MIT Cheetah, and the analysis of the high-speed trotting experimental results. The design principles were derived by analyzing three major energy-loss mechanisms in locomotion: heat losses from the actuators, friction losses in transmission, and the interaction losses caused by the interface between the system and the environment. Four design principles that minimize these losses are discussed: employment of high torque-density motors, energy regenerative electronic system, low loss transmission, and a low leg inertia. These principles were implemented in the design of the MIT Cheetah; the major design features are large gap diameter motors, regenerative electric motor drivers, single-stage low gear transmission, dual coaxial motors with composite legs, and the differential actuated spine. The experimental results of fast trotting are presented; the 33-kg robot runs at 22 km/h (6 m/s). The total power consumption from the battery pack was 973 W and resulted in a total cost of transport of 0.5, which rivals running animals' at the same scale. 76% of the total energy consumption is attributed to heat loss from the motor, and the remaining 24% is used in mechanical work, which is dissipated as interaction loss as well as friction losses at the joint and transmission.
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机译:本文介绍了高效腿式机器人的设计原理,MIT猎豹设计中原理的实现以及高速小跑实验结果的分析。通过分析运动中的三种主要能量损失机制得出了设计原理:执行器的热损失,传动系统的摩擦损失以及系统与环境之间的界面所引起的相互作用损失。讨论了使这些损失最小化的四个设计原理:采用高扭矩密度的电动机,能量再生电子系统,低损失的传动装置和低的支腿惯性。这些原则已在MIT猎豹的设计中实现;主要设计特征是大间隙直径电机,再生式电机驱动器,单级低速齿轮传动,带复合支脚的双同轴电机以及差动式脊柱。给出了快速小跑的实验结果。 33公斤重的机器人以22 km / h(6 m / s)的速度运行。电池组的总功耗为973 W,运输总成本为0.5,可与同等规模的动物相匹敌。总能耗的76%归因于电动机的热量损失,其余24%用于机械功,这是作为相互作用损失以及接头和变速器的摩擦损失而耗散的。
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