Autonomous Navigation for Quadrupedal Robots with Optimized Jumping through Constrained Obstacles

Quadrupeds are strong candidates for navigating challenging environments because of their agile and dynamic designs. This paper presents a methodology that extends the range of exploration for quadrupedal robots by creating an end-to-end navigation framework that exploits walking and jumping modes....

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Bibliographic Details
Published in:arXiv.org 2021-07
Main Authors: Gilroy, Scott, Lau, Derek, Yang, Lizhi, Izaguirre, Ed, Biermayer, Kristen, Xiao, Anxing, Sun, Mengti, Agrawal, Ayush, Zeng, Jun, Li, Zhongyu, Koushil Sreenath
Format: Article
Language:English
Subjects:
Autonomous navigation
Constraints
Decision making
Obstacle avoidance
Robots
State machines
Trajectory optimization
Walking
Online Access:Get full text
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Summary:Quadrupeds are strong candidates for navigating challenging environments because of their agile and dynamic designs. This paper presents a methodology that extends the range of exploration for quadrupedal robots by creating an end-to-end navigation framework that exploits walking and jumping modes. To obtain a dynamic jumping maneuver while avoiding obstacles, dynamically-feasible trajectories are optimized offline through collocation-based optimization where safety constraints are imposed. Such optimization schematic allows the robot to jump through window-shaped obstacles by considering both obstacles in the air and on the ground. The resulted jumping mode is utilized in an autonomous navigation pipeline that leverages a search-based global planner and a local planner to enable the robot to reach the goal location by walking. A state machine together with a decision making strategy allows the system to switch behaviors between walking around obstacles or jumping through them. The proposed framework is experimentally deployed and validated on a quadrupedal robot, a Mini Cheetah, to enable the robot to autonomously navigate through an environment while avoiding obstacles and jumping over a maximum height of 13 cm to pass through a window-shaped opening in order to reach its goal.
ISSN:2331-8422