Discrete, compositional, and symbolic representations through attractor dynamics

Andrew J. Nam, Eric Elmoznino, Nikolay Malkin, Chen Sun, Yoshua Bengio, Guillaume Lajoie

Research output: Contribution to conferencePaperpeer-review

Abstract / Description of output

Compositionality is an important feature of discrete symbolic systems, such as language and programs, as it enables them to have infinite capacity despite a finite symbol set. It serves as a useful abstraction for reasoning in both cognitive science and in AI, yet the interface between continuous and symbolic processing is often imposed by fiat at the algorithmic level, such as by means of quantization or a softmax sampling step. In this work, we explore how discretization could be implemented in a more neurally plausible manner through the modeling of attractor dynamics that partition the continuous representation space into basins that correspond to sequences of symbols. Building on established work in attractor networks and introducing novel training methods, we show that imposing structure in the symbolic space can produce compositionality in the attractor-supported representation space of rich sensory inputs. Lastly, we argue that our model exhibits the process of an information bottleneck that is thought to play a role in conscious experience, decomposing the rich information of a sensory input into stable components encoding symbolic information.
Original languageEnglish
Pages1-11
Number of pages11
Publication statusPublished - 15 Dec 2023
EventNeurIPS 2023 Workshop on Information-Theoretic Principles in Cognitive Systems - New Orleans Convention Center, New Orleans, United States
Duration: 15 Dec 202315 Dec 2023
https://sites.google.com/view/infocog-neurips-2023

Workshop

WorkshopNeurIPS 2023 Workshop on Information-Theoretic Principles in Cognitive Systems
Country/TerritoryUnited States
CityNew Orleans
Period15/12/2315/12/23
Internet address

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