Flexible neural representation for physics prediction

Author(s)

Mrowca, Damian; Zhuang, Chengxu; Wang, Elias; Haber, Nick; Li, Fei-Fei; Tenenbaum, Joshua B; Yamins, Daniel L. K.; ... Show more Show less

Abstract

Humans have a remarkable capacity to understand the physical dynamics of objects in their environment, flexibly capturing complex structures and interactions at multiple levels of detail. Inspired by this ability, we propose a hierarchical particle-based object representation that covers a wide variety of types of three-dimensional objects, including both arbitrary rigid geometrical shapes and deformable materials. We then describe the Hierarchical Relation Network (HRN), an end-to-end differentiable neural network based on hierarchical graph convolution, that learns to predict physical dynamics in this representation. Compared to other neural network baselines, the HRN accurately handles complex collisions and nonrigid deformations, generating plausible dynamics predictions at long time scales in novel settings, and scaling to large scene configurations. These results demonstrate an architecture with the potential to form the basis of next-generation physics predictors for use in computer vision, robotics, and quantitative cognitive science.

Date issued

2018-12

URI

https://hdl.handle.net/1721.1/126557

Department

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory
Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences

Journal

Advances in Neural Imaging Processing Systems

Publisher

Neural Information Processing Systems Foundation/Curran Associates

Citation

Mrowca, Damian et al. "Flexible neural representation for physics prediction." Advances in Neural Imaging Processing Systems, December 2018, Montreal, Canada, Neural Information Processing Systems Foundation/Curran Associates, December 2018 © 2018 Curran Associates

Version: Final published version