Data-Driven Density Steering via the Gromov-Wasserstein Optimal Transport Distance
By: Haruto Nakashima, Siddhartha Ganguly, Kenji Kashima
Potential Business Impact:
Guides robots to reach exact spots using data.
We tackle the data-driven chance-constrained density steering problem using the Gromov-Wasserstein metric. The underlying dynamical system is an unknown linear controlled recursion, with the assumption that sufficiently rich input-output data from pre-operational experiments are available. The initial state is modeled as a Gaussian mixture, while the terminal state is required to match a specified Gaussian distribution. We reformulate the resulting optimal control problem as a difference-of-convex program and show that it can be efficiently and tractably solved using the DC algorithm. Numerical results validate our approach through various data-driven schemes.
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