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Trajectory Optimization with Optimization-Based Dynamics

Taylor A. Howell, Simon Le Cleac’h, Sumeet Singh, Pete Florence, Zachary Manchester, Vikas Sindhwani

2022IEEE Robotics and Automation Letters23 citationsDOI

Abstract

We present a framework for bi-level trajectory optimization in which a system’s dynamics are encoded as the solution to a constrained optimization problem and smooth gradients of this lower-level problem are passed to an upper-level trajectory optimizer. This optimization-based dynamics representation enables constraint handling, additional variables, and non-smooth behavior to be abstracted away from the upper-level optimizer, and allows classical unconstrained optimizers to synthesize trajectories for more complex systems. We provide a path-following method for efficient evaluation of constrained dynamics and utilize the implicit-function theorem to compute smooth gradients of this representation. We demonstrate the framework by modeling systems from locomotion, aerospace, and manipulation domains including: acrobot with joint limits, cart-pole subject to Coulomb friction, Raibert hopper, rocket landing with thrust limits, and planar-push task with optimization-based dynamics and then optimize trajectories using iterative LQR.

Topics & Concepts

Trajectory optimizationTrajectoryOptimization problemComputer scienceMathematical optimizationConstraint (computer-aided design)Representation (politics)System dynamicsConstrained optimizationControl theory (sociology)Convergence (economics)Optimal controlMathematicsArtificial intelligenceControl (management)PhysicsEconomic growthPoliticsAstronomyGeometryPolitical scienceEconomicsLawRobotic Path Planning AlgorithmsRobotic Mechanisms and DynamicsControl and Stability of Dynamical Systems
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