Related papers: Embedding interpretable $\ell_1$-regression into neural networks for uncovering temporal structure in cell imaging

Embedding interpretable $\ell_1$-regression into neural networks for uncovering temporal structure in cell imaging

URL: http://arxiv.org/abs/2603.02899v1
Date: Tue, 03 Mar 2026 11:48:44 GMT
Title: Embedding interpretable $\ell_1$-regression into neural networks for uncovering temporal structure in cell imaging
Authors: Fabian Kabus, Maren Hackenberg, Julia Hindel, Thibault Cholvin, Antje Kilias, Thomas Brox, Abhinav Valada, Marlene Bartos, Harald Binder,
Abstract summary: We propose embedding a vector autoregressive ( VAR) model as an interpretable regression technique into a convolutional autoencoder.<n>A skip connection separately addresses non-sparse static spatial information, selectively channeling sparse structure into the VAR model.<n>Having an embedded statistical model also enables a testing approach for comparing temporal sequences from the same observational unit.
Score: 24.51358786006251
License: http://creativecommons.org/licenses/by/4.0/
Abstract: While artificial neural networks excel in unsupervised learning of non-sparse structure, classical statistical regression techniques offer better interpretability, in particular when sparseness is enforced by $\ell_1$ regularization, enabling identification of which factors drive observed dynamics. We investigate how these two types of approaches can be optimally combined, exemplarily considering two-photon calcium imaging data where sparse autoregressive dynamics are to be extracted. We propose embedding a vector autoregressive (VAR) model as an interpretable regression technique into a convolutional autoencoder, which provides dimension reduction for tractable temporal modeling. A skip connection separately addresses non-sparse static spatial information, selectively channeling sparse structure into the $\ell_1$-regularized VAR. $\ell_1$-estimation of regression parameters is enabled by differentiating through the piecewise linear solution path. This is contrasted with approaches where the autoencoder does not adapt to the VAR model. Having an embedded statistical model also enables a testing approach for comparing temporal sequences from the same observational unit. Additionally, contribution maps visualize which spatial regions drive the learned dynamics.

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