English

Object Files and Schemata: Factorizing Declarative and Procedural Knowledge in Dynamical Systems

Machine Learning 2020-11-16 v5 Machine Learning

Abstract

Modeling a structured, dynamic environment like a video game requires keeping track of the objects and their states declarative knowledge) as well as predicting how objects behave (procedural knowledge). Black-box models with a monolithic hidden state often fail to apply procedural knowledge consistently and uniformly, i.e., they lack systematicity. For example, in a video game, correct prediction of one enemy's trajectory does not ensure correct prediction of another's. We address this issue via an architecture that factorizes declarative and procedural knowledge and that imposes modularity within each form of knowledge. The architecture consists of active modules called object files that maintain the state of a single object and invoke passive external knowledge sources called schemata that prescribe state updates. To use a video game as an illustration, two enemies of the same type will share schemata but will have separate object files to encode their distinct state (e.g., health, position). We propose to use attention to determine which object files to update, the selection of schemata, and the propagation of information between object files. The resulting architecture is a drop-in replacement conforming to the same input-output interface as normal recurrent networks (e.g., LSTM, GRU) yet achieves substantially better generalization on environments that have multiple object tokens of the same type, including a challenging intuitive physics benchmark.

Keywords

Cite

@article{arxiv.2006.16225,
  title  = {Object Files and Schemata: Factorizing Declarative and Procedural Knowledge in Dynamical Systems},
  author = {Anirudh Goyal and Alex Lamb and Phanideep Gampa and Philippe Beaudoin and Sergey Levine and Charles Blundell and Yoshua Bengio and Michael Mozer},
  journal= {arXiv preprint arXiv:2006.16225},
  year   = {2020}
}

Comments

Type/Token Distinction in Deep learning Framework

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