Augmenting Physical Simulators with Stochastic Neural Networks: Case Study of Planar Pushing and Bouncing

Author(s)

Ajay, Anurag; Wu, Jiajun; Fazeli, Nima; Bauza, Maria; Kaelbling, Leslie P.; Tenenbaum, Joshua B.; Rodriguez, Alberto; ... Show more Show less

Abstract

© 2018 IEEE. An efficient, generalizable physical simulator with universal uncertainty estimates has wide applications in robot state estimation, planning, and control. In this paper, we build such a simulator for two scenarios, planar pushing and ball bouncing, by augmenting an analytical rigid-body simulator with a neural network that learns to model uncertainty as residuals. Combining symbolic, deterministic simulators with learnable, stochastic neural nets provides us with expressiveness, efficiency, and generalizability simultaneously. Our model outperforms both purely analytical and purely learned simulators consistently on real, standard benchmarks. Compared with methods that model uncertainty using Gaussian processes, our model runs much faster, generalizes better to new object shapes, and is able to characterize the complex distribution of object trajectories.

Date issued

2018-10

URI

https://hdl.handle.net/1721.1/137711

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering
Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory

Publisher

IEEE

Citation

Ajay, Anurag, Wu, Jiajun, Fazeli, Nima, Bauza, Maria, Kaelbling, Leslie P. et al. 2018. "Augmenting Physical Simulators with Stochastic Neural Networks: Case Study of Planar Pushing and Bouncing."

Version: Author's final manuscript