The paper explores the implications of a compositional neural representation of "what happened when" in working memory. It shows that neurons in such a representation must exhibit conjunctive receptive fields for stimulus identity ("what") and elapsed time ("when"). This allows the covariance matrix of the neural population to be written in a tractable form, enabling the study of population dynamics using linear dimensionality reduction techniques.
The authors consider two specific choices of temporal basis functions - Laplace and Inverse Laplace - which are related by a linear transformation. Despite this close relationship, the low-dimensional dynamics of the neural populations differ qualitatively, with the Laplace population showing stable stimulus-specific subspaces and the Inverse Laplace population exhibiting rotational dynamics.
The dimensionality of the neural trajectories is shown to depend on the density of the temporal basis functions. A logarithmic tiling of time, as proposed by work in cognitive psychology and supported by neuroscience evidence, provides a good match to empirical data on the growth of dimensionality over time.
Finally, the authors sketch a continuous attractor neural network model that can implement the Laplace Neural Manifold, exhibiting the required conjunctive receptive fields for "what" and "when". This model provides a bridge between abstract cognitive models of working memory and circuit-level implementation.
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