Homomorphism Tensors and Linear Equations
Advances in Combinatronics (2025)
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Lov\'asz (1967) showed that two graphs $G$ and $H$ are isomorphic if and only
if they are homomorphism indistinguishable over the class of all graphs, i.e.
for every graph $F$, the number of homomorphisms from $F$ to $G$ equals the
number of homomorphisms from $F$ to $H$. Recently, homomorphism
indistinguishability over restricted classes of graphs such as bounded
treewidth, bounded treedepth and planar graphs, has emerged as a surprisingly
powerful framework for capturing diverse equivalence relations on graphs
arising from logical equivalence and algebraic equation systems.
In this paper, we provide a unified algebraic framework for such results by
examining the linear-algebraic and representation-theoretic structure of
tensors counting homomorphisms from labelled graphs. The existence of certain
linear transformations between such homomorphism tensor subspaces can be
interpreted both as homomorphism indistinguishability over a graph class and as
feasibility of an equational system. Following this framework, we obtain
characterisations of homomorphism indistinguishability over several natural
graph classes, namely trees of bounded degree and graphs of bounded pathwidth,
answering a question of Dell et al. (2018), and graphs of bounded treedepth.
Publié le :
@article{ADVC_2025_a2,
author = {Martin Grohe and Gaurav Rattan and Tim Seppelt},
title = {Homomorphism {Tensors} and {Linear} {Equations}},
journal = {Advances in Combinatronics},
publisher = {mathdoc},
year = {2025},
language = {en},
url = {http://geodesic.mathdoc.fr/item/ADVC_2025_a2/}
}
Martin Grohe; Gaurav Rattan; Tim Seppelt. Homomorphism Tensors and Linear Equations. Advances in Combinatronics (2025). http://geodesic.mathdoc.fr/item/ADVC_2025_a2/