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Practical Reinforcement Learning For MPC: Learning from sparse objectives in under an hour on a real robot

Napat Karnchanachari, Miguel de la Iglesia Valls, David Hoeller, Marco Hutter

2020Repository for Publications and Research Data (ETH Zurich)14 citationsDOIOpen Access PDF

Abstract

Model Predictive Control (MPC) is a powerful control technique that handles constraints, takes the system's dynamics into account, and optimizes for a given cost function. In practice, however, it often requires an expert to craft and tune this cost function and find trade-offs between different state penalties to satisfy simple high level objectives. In this paper, we use Reinforcement Learning and in particular value learning to approximate the value function given only high level objectives, which can be sparse and binary. Building upon previous works, we present improvements that allowed us to successfully deploy the method on a real world unmanned ground vehicle. Our experiments show that our method can learn the cost function from scratch and without human intervention, while reaching a performance level similar to that of an expert-tuned MPC. We perform a quantitative comparison of these methods with standard MPC approaches both in simulation and on the real robot.

Topics & Concepts

Reinforcement learningComputer scienceArtificial intelligenceFunction (biology)ScratchModel predictive controlBellman equationRobotMachine learningControl (management)Mathematical optimizationMathematicsEvolutionary biologyBiologyOperating systemAdvanced Control Systems OptimizationReal-time simulation and control systemsFault Detection and Control Systems