Arithmetic Circuits and Neural Networks for Regular Matroids

Christoph Hertrich; Stefan Kober; Georg Loho

doi:10.48550/arXiv.2511.02406

Arithmetic Circuits and Neural Networks for Regular Matroids

Christoph Hertrich
, Stefan Kober
, Georg Loho

Mathematics of Operations Research

Research output: Working paper › Preprint › Academic

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Abstract

We prove that there exist uniform $(+,\times,/)$-circuits of size $O(n^3)$ to compute the basis generating polynomial of regular matroids on $n$ elements. By tropicalization, this implies that there exist uniform $(\max,+,-)$-circuits and ReLU neural networks of the same size for weighted basis maximization of regular matroids. As a consequence in linear programming theory, we obtain a first example where taking the difference of two extended formulations can be more efficient than the best known individual extended formulation of size $O(n^6)$ by Aprile and Fiorini. Such differences have recently been introduced as virtual extended formulations. The proof of our main result relies on a fine-tuned version of Seymour's decomposition of regular matroids which allows us to identify and maintain graphic substructures to which we can apply a local version of the star-mesh transformation.

Original language	English
Publisher	ArXiv.org
DOIs	https://doi.org/10.48550/arXiv.2511.02406
Publication status	Published - 4 Nov 2025

Keywords

math.CO
cs.CC
cs.DM
cs.LG
math.OC

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title = "Arithmetic Circuits and Neural Networks for Regular Matroids",

abstract = "We prove that there exist uniform \$(+,\textbackslash{}times,/)\$-circuits of size \$O(n\textasciicircum{}3)\$ to compute the basis generating polynomial of regular matroids on \$n\$ elements. By tropicalization, this implies that there exist uniform \$(\textbackslash{}max,+,-)\$-circuits and ReLU neural networks of the same size for weighted basis maximization of regular matroids. As a consequence in linear programming theory, we obtain a first example where taking the difference of two extended formulations can be more efficient than the best known individual extended formulation of size \$O(n\textasciicircum{}6)\$ by Aprile and Fiorini. Such differences have recently been introduced as virtual extended formulations. The proof of our main result relies on a fine-tuned version of Seymour's decomposition of regular matroids which allows us to identify and maintain graphic substructures to which we can apply a local version of the star-mesh transformation.",

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T1 - Arithmetic Circuits and Neural Networks for Regular Matroids

AU - Hertrich, Christoph

AU - Kober, Stefan

AU - Loho, Georg

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N2 - We prove that there exist uniform $(+,\times,/)$-circuits of size $O(n^3)$ to compute the basis generating polynomial of regular matroids on $n$ elements. By tropicalization, this implies that there exist uniform $(\max,+,-)$-circuits and ReLU neural networks of the same size for weighted basis maximization of regular matroids. As a consequence in linear programming theory, we obtain a first example where taking the difference of two extended formulations can be more efficient than the best known individual extended formulation of size $O(n^6)$ by Aprile and Fiorini. Such differences have recently been introduced as virtual extended formulations. The proof of our main result relies on a fine-tuned version of Seymour's decomposition of regular matroids which allows us to identify and maintain graphic substructures to which we can apply a local version of the star-mesh transformation.

AB - We prove that there exist uniform $(+,\times,/)$-circuits of size $O(n^3)$ to compute the basis generating polynomial of regular matroids on $n$ elements. By tropicalization, this implies that there exist uniform $(\max,+,-)$-circuits and ReLU neural networks of the same size for weighted basis maximization of regular matroids. As a consequence in linear programming theory, we obtain a first example where taking the difference of two extended formulations can be more efficient than the best known individual extended formulation of size $O(n^6)$ by Aprile and Fiorini. Such differences have recently been introduced as virtual extended formulations. The proof of our main result relies on a fine-tuned version of Seymour's decomposition of regular matroids which allows us to identify and maintain graphic substructures to which we can apply a local version of the star-mesh transformation.

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Arithmetic Circuits and Neural Networks for Regular Matroids

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