Offline motion libraries and online MPC for advanced mobility skills
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Date
2022-08
Publication Type
Journal Article
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yes
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Abstract
We describe an optimization-based framework to perform complex locomotion skills for robots with legs and wheels. The generation of complex motions over a long-time horizon often requires offline computation due to current computing constraints and is mostly accomplished through trajectory optimization (TO). In contrast, model predictive control (MPC) focuses on the online computation of trajectories, robust even in the presence of uncertainty, albeit mostly over shorter time horizons and is prone to generating nonoptimal solutions over the horizon of the task's goals. Our article's contributions overcome this trade-off by combining offline motion libraries and online MPC, uniting a complex, long-time horizon plan with reactive, short-time horizon solutions. We start from offline trajectories that can be, for example, generated by TO or sampling-based methods. Also, multiple offline trajectories can be composed out of a motion library into a single maneuver. We then use these offline trajectories as the cost for the online MPC, allowing us to smoothly blend between multiple composed motions even in the presence of discontinuous transitions. The MPC optimizes from the measured state, resulting in feedback control, which robustifies the task's execution by reacting to disturbances and looking ahead at the offline trajectory. With our contribution, motion designers can choose their favorite method to iterate over behavior designs offline without tuning robot experiments, enabling them to author new behaviors rapidly. Our experiments demonstrate complex and dynamic motions on our traditional quadrupedal robot ANYmal and its roller-walking version. Moreover, the article's findings contribute to evaluating five planning algorithms.
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Publication status
published
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Book title
Journal / series
Volume
41 (9–10)
Pages / Article No.
903 - 924
Publisher
SAGE
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Edition / version
Methods
Software
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Date collected
Date created
Subject
robotics; wheeled and legged locomotion; model predictive control; offline motion library; trajectory optimization
Organisational unit
09570 - Hutter, Marco / Hutter, Marco
09620 - Coros, Stelian / Coros, Stelian
02284 - NFS Digitale Fabrikation / NCCR Digital Fabrication