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Traction Control of Mobile Robot Based on Slippage Detection by Angular Acceleration Change

각가속도 변화에 의해 탐지된 슬립에 기반한 주행로봇의 견인력 제어

  • Published : 2009.02.01

Abstract

The common requirements of rough terrain mobile robots are long-term operation and high mobility in rough terrain to perform difficult tasks. In rough terrain, excessive wheel slip could cause an increase in the amount of dissipated energy at the contact point between the wheel and ground or, even more seriously, the robot could lose all mobility and become trapped. This paper proposes a traction control algorithm that can be independently implemented to each wheel without requiring extra sensors and devices compared with standard velocity control methods. The proposed traction algorithm is analogous to the stick-slip friction mechanism. The algorithm estimates the slippage of wheels by angular acceleration change, and controls the increase or decrease state of torque applied to wheels Simulations are performed to validate the algorithm. The proposed traction control algorithm yielded a 65.4% reduction of total slip distance and 70.6% reduction of power consumption compared with the standard velocity control method.

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Cited by

  1. Predicting Maximum Traction for Improving Traversability of Unmanned Robots on Rough Terrain vol.18, pp.10, 2012, https://doi.org/10.5302/J.ICROS.2012.18.10.940
  2. Real-Time Prediction of Optimal Control Parameters for Mobile Robots based on Estimated Strength of Ground Surface vol.20, pp.1, 2014, https://doi.org/10.5302/J.ICROS.2014.13.1921