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The Antisymmetric Line Graph

Combinatorics 2026-04-20 v2

Abstract

Let GG be a finite simple graph with oriented incidence matrix DD. The signed graph on edge set E(G)E(G) with adjacency matrix AA(G)=DTD2I A_{\mathcal A(G)}=D^{\mathsf T}D-2I is classical in the signed-line-graph literature. In this paper we study its canonical switching class as a source of invariants of the underlying unsigned graph. We prove that the switching class of A(G)\mathcal A(G) determines GG up to isomorphism modulo isolated vertices, and we relate the frustration index (A(G))\ell(\mathcal A(G)) to classical bipartization parameters. In particular, we show def(G)(A(G))(Δ(G)1)def(G), \operatorname{def}(G)\le \ell(\mathcal A(G))\le (\Delta(G)-1)\operatorname{def}(G), and, for cubic graphs, (A(G))=2oct(G). \ell(\mathcal A(G))=2\,\operatorname{oct}(G). We then prove the exact optimization identity (A(G))=14vV(G)d(v)214maxx{±1}E(G)Dx2, \ell(\mathcal A(G)) = \frac14\sum_{v\in V(G)} d(v)^2 -\frac14\max_{x\in\{\pm1\}^{E(G)}}\|Dx\|^2, so (A(G))\ell(\mathcal A(G)) is exactly a Boolean edge-space Laplacian optimization problem. This yields a spectral lower bound in terms of the largest Laplacian eigenvalue, a cubic spectral lower bound on odd cycle transversal, and explicit family-level comparisons showing that the spectral and defect bounds govern different regimes: on odd cycles the spectral bound is asymptotically vacuous, while on complete multipartite graphs it already captures exactly 3/43/4 of the true value of (A(G))\ell(\mathcal A(G)). Thus the paper uses a classical signed line graph in a new way: as a source of combinatorial invariants of ordinary graphs, especially through frustration and odd-cycle-transversal phenomena.

Keywords

Cite

@article{arxiv.2603.03087,
  title  = {The Antisymmetric Line Graph},
  author = {Hartosh Singh Bal},
  journal= {arXiv preprint arXiv:2603.03087},
  year   = {2026}
}
R2 v1 2026-07-01T11:01:15.430Z