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Biologically-Based Computation: How Neural Details and Dynamics Are Suited for Implementing a Variety of Algorithms

Nicole Sandra-Yaffa Dumont, Andreas Stöckel, P. Michael Furlong, Madeleine Bartlett, Chris Eliasmith, Terrence C. Stewart

2023Brain Sciences22 citationsDOIOpen Access PDF

Abstract

The Neural Engineering Framework (Eliasmith & Anderson, 2003) is a long-standing method for implementing high-level algorithms constrained by low-level neurobiological details. In recent years, this method has been expanded to incorporate more biological details and applied to new tasks. This paper brings together these ongoing research strands, presenting them in a common framework. We expand on the NEF's core principles of (a) specifying the desired tuning curves of neurons in different parts of the model, (b) defining the computational relationships between the values represented by the neurons in different parts of the model, and (c) finding the synaptic connection weights that will cause those computations and tuning curves. In particular, we show how to extend this to include complex spatiotemporal tuning curves, and then apply this approach to produce functional computational models of grid cells, time cells, path integration, sparse representations, probabilistic representations, and symbolic representations in the brain.

Topics & Concepts

Computer scienceVariety (cybernetics)ComputationProbabilistic logicComputational neuroscienceGridAlgorithmPath (computing)Theoretical computer scienceDynamics (music)Artificial intelligenceMathematicsGeometryAcousticsProgramming languagePhysicsNeural dynamics and brain functionMemory and Neural MechanismsAdvanced Memory and Neural Computing
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