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Continuous Bump Attractor Networks Require Explicit Error Coding for Gain Recalibration.

Gorkem Secer1,2, James J Knierim2,3,4, Noah J Cowan1,5

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Continuous bump attractor networks (CBANs) represent continuous variables but accumulate errors. This study reveals that gain recalibration, unlike error correction, requires an explicit error-rate code for accurate neural representations.

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Area of Science:

  • Computational neuroscience
  • Neural networks
  • Cognitive modeling

Background:

  • Continuous bump attractor networks (CBANs) are models for representing continuous variables in brain functions like spatial navigation and working memory.
  • CBANs integrate input to update representations but accumulate errors over time.
  • Existing models lack mechanisms for recalibrating the integration gain, a process observed experimentally.

Purpose of the Study:

  • To investigate the neural mechanisms behind integration gain recalibration in CBANs.
  • To model experimental findings on gain recalibration in hippocampal place cells.
  • To bridge the gap in understanding how CBANs achieve plasticity in their integration process.

Main Methods:

  • Utilized a ring attractor network, a type of CBAN, to simulate experimental conditions.
  • Analyzed the network dynamics required for gain recalibration.
  • Developed a modified ring attractor network incorporating an error-rate code and Hebbian plasticity.

Main Results:

  • Identified that gain recalibration, distinct from error correction, necessitates an explicit neural signal encoding representation error via a rate code.
  • Demonstrated that ground-truth inputs fine-tune integration gain, a crucial factor for accurate representation updates.
  • The proposed modified CBAN model successfully achieved integration gain recalibration.

Conclusions:

  • Gain recalibration in CBANs requires specific neural mechanisms beyond simple error correction.
  • An explicit error-rate code combined with Hebbian plasticity enables integration gain recalibration.
  • This work provides a theoretical and computational framework for understanding neural plasticity in continuous variable representation.