Vector-based navigation using grid-like representations in artificial agents
| Autor: | Demis Hassabis, Raia Hadsell, Stephen Gaffney, Ross Goroshin, Timothy P. Lillicrap, Charles Beattie, Helen King, Caswell Barry, Piotr Mirowski, Neil C. Rabinowitz, Charles Blundell, Benigno Uria, Andrea Banino, Koray Kavukcuoglu, Joseph Modayil, Alexander Pritzel, Amir Sadik, Thomas Degris, Greg Wayne, Dharshan Kumaran, Stig Petersen, Brian Hu Zhang, Fabio Viola, Martin J. Chadwick, Razvan Pascanu, Hubert Soyer |
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| Rok vydání: | 2018 |
| Předmět: |
0301 basic medicine
Computer science Environment Spatial memory Machine Learning 03 medical and health sciences 0302 clinical medicine Biomimetics Path integration Animals Entorhinal Cortex Grid Cells Humans Reinforcement learning Leverage (statistics) Multidisciplinary Artificial neural network business.industry Cognitive neuroscience of visual object recognition Grid 030104 developmental biology Neural Networks Computer Artificial intelligence business 030217 neurology & neurosurgery Spatial Navigation Coding (social sciences) |
| Zdroj: | Nature. 557:429-433 |
| ISSN: | 1476-4687 0028-0836 |
| Popis: | Deep neural networks have achieved impressive successes in fields ranging from object recognition to complex games such as Go1,2. Navigation, however, remains a substantial challenge for artificial agents, with deep neural networks trained by reinforcement learning3–5 failing to rival the proficiency of mammalian spatial behaviour, which is underpinned by grid cells in the entorhinal cortex6. Grid cells are thought to provide a multi-scale periodic representation that functions as a metric for coding space7,8 and is critical for integrating self-motion (path integration)6,7,9 and planning direct trajectories to goals (vector-based navigation)7,10,11. Here we set out to leverage the computational functions of grid cells to develop a deep reinforcement learning agent with mammal-like navigational abilities. We first trained a recurrent network to perform path integration, leading to the emergence of representations resembling grid cells, as well as other entorhinal cell types12. We then showed that this representation provided an effective basis for an agent to locate goals in challenging, unfamiliar, and changeable environments—optimizing the primary objective of navigation through deep reinforcement learning. The performance of agents endowed with grid-like representations surpassed that of an expert human and comparison agents, with the metric quantities necessary for vector-based navigation derived from grid-like units within the network. Furthermore, grid-like representations enabled agents to conduct shortcut behaviours reminiscent of those performed by mammals. Our findings show that emergent grid-like representations furnish agents with a Euclidean spatial metric and associated vector operations, providing a foundation for proficient navigation. As such, our results support neuroscientific theories that see grid cells as critical for vector-based navigation7,10,11, demonstrating that the latter can be combined with path-based strategies to support navigation in challenging environments. Grid-like representations emerge spontaneously within a neural network trained to self-localize, enabling the agent to take shortcuts to destinations using vector-based navigation. |
| Databáze: | OpenAIRE |
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