Conference on Cognitive Computational Neuroscience

San Francisco • August 25 - 28, 2022

P-2.29

A multi-level account of the hippocampus from behavior to neurons

Robert Mok, University of Cambridge, United Kingdom; Bradley Love, University College London, United Kingdom
Session:
Posters 2 Poster
Track:
Cognitive science
Location:
Pacific Ballroom H-O
Presentation Time:
Fri, 26 Aug, 19:30 - 21:30 Pacific Time (UTC -8)
Abstract:
A complete neuroscience requires multi-level theories that address phenomena ranging from higher-level cognitive behaviors to activities within a cell. Unfortunately, we don't have cognitive models of behavior whose components can be decomposed into the neural dynamics that give rise to behavior, leaving an explanatory gap. Inspired by algorithms that capture flocking behavior in birds, we introduce a neural flocking learning rule to coordinates units that collectively form higher-level mental constructs and parallels recurrent hippocampal activity. The decomposed model shows how brain-scale neural populations coordinate to form assemblies encoding concept and spatial representations, and why many neurons are required for robust performance. Our account provides a multi-level explanation for how cognition and symbol-like representations are supported by coordinated neural assemblies formed through learning.
Manuscript:
View Manuscript
License:
Creative Commons License
This work is licensed under a Creative Commons Attribution 3.0 Unported License.
DOI:
10.32470/CCN.2022.1066-0
Publication:
2022 Conference on Cognitive Computational Neuroscience
Presentation
Discussion
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No resources available.
Session P-2
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