Litcius/Paper detail

Efficient and flexible representation of higher-dimensional cognitive variables with grid cells

Mirko Klukas, Marcus Lewis, Ila Fiete

2020PLoS Computational Biology43 citationsDOIOpen Access PDF

Abstract

We shed light on the potential of entorhinal grid cells to efficiently encode variables of dimension greater than two, while remaining faithful to empirical data on their low-dimensional structure. Our model constructs representations of high-dimensional inputs through a combination of low-dimensional random projections and "classical" low-dimensional hexagonal grid cell responses. Without reconfiguration of the recurrent circuit, the same system can flexibly encode multiple variables of different dimensions while maximizing the coding range (per dimension) by automatically trading-off dimension with an exponentially large coding range. It achieves high efficiency and flexibility by combining two powerful concepts, modularity and mixed selectivity, in what we call "mixed modular coding". In contrast to previously proposed schemes, the model does not require the formation of higher-dimensional grid responses, a cell-inefficient and rigid mechanism. The firing fields observed in flying bats or climbing rats can be generated by neurons that combine activity from multiple grid modules, each representing higher-dimensional spaces according to our model. The idea expands our understanding of grid cells, suggesting that they could implement a general circuit that generates on-demand coding and memory states for variables in high-dimensional vector spaces.

Topics & Concepts

ENCODEComputer scienceModular designGridCoding (social sciences)Control reconfigurationTheoretical computer scienceNeural codingTopology (electrical circuits)MathematicsArtificial intelligenceOperating systemGeometryStatisticsCombinatoricsBiochemistryEmbedded systemGeneChemistryNeural dynamics and brain functionMemory and Neural MechanismsPhotoreceptor and optogenetics research