Expressive architectures enhance interpretability of dynamics-based
neural population models
- URL: http://arxiv.org/abs/2212.03771v4
- Date: Fri, 30 Jun 2023 17:49:34 GMT
- Title: Expressive architectures enhance interpretability of dynamics-based
neural population models
- Authors: Andrew R. Sedler, Christopher Versteeg, Chethan Pandarinath
- Abstract summary: We evaluate the performance of sequential autoencoders (SAEs) in recovering latent chaotic attractors from simulated neural datasets.
We found that SAEs with widely-used recurrent neural network (RNN)-based dynamics were unable to infer accurate firing rates at the true latent state dimensionality.
- Score: 2.294014185517203
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Artificial neural networks that can recover latent dynamics from recorded
neural activity may provide a powerful avenue for identifying and interpreting
the dynamical motifs underlying biological computation. Given that neural
variance alone does not uniquely determine a latent dynamical system,
interpretable architectures should prioritize accurate and low-dimensional
latent dynamics. In this work, we evaluated the performance of sequential
autoencoders (SAEs) in recovering latent chaotic attractors from simulated
neural datasets. We found that SAEs with widely-used recurrent neural network
(RNN)-based dynamics were unable to infer accurate firing rates at the true
latent state dimensionality, and that larger RNNs relied upon dynamical
features not present in the data. On the other hand, SAEs with neural ordinary
differential equation (NODE)-based dynamics inferred accurate rates at the true
latent state dimensionality, while also recovering latent trajectories and
fixed point structure. Ablations reveal that this is mainly because NODEs (1)
allow use of higher-capacity multi-layer perceptrons (MLPs) to model the vector
field and (2) predict the derivative rather than the next state. Decoupling the
capacity of the dynamics model from its latent dimensionality enables NODEs to
learn the requisite low-D dynamics where RNN cells fail. Additionally, the fact
that the NODE predicts derivatives imposes a useful autoregressive prior on the
latent states. The suboptimal interpretability of widely-used RNN-based
dynamics may motivate substitution for alternative architectures, such as NODE,
that enable learning of accurate dynamics in low-dimensional latent spaces.
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