# Irreducible Combinatorially Symmetric Sign Patterns Requiring a Unique Inertia

**Authors:** Partha Rana, Sriparna Bandopadhyay

arXiv: 2508.21509 · 2025-09-01

## TL;DR

This paper investigates combinatorially symmetric sign patterns with zero diagonals, identifying conditions under which they require a unique inertia, especially focusing on tree and cyclic graph structures.

## Contribution

It extends the study of symmetric sign patterns by analyzing patterns with zero diagonals and deriving conditions for unique inertia in complex graph configurations.

## Key findings

- Identifies combinatorially symmetric patterns with zero diagonals that do not require unique inertia.
- Provides necessary conditions for patterns with cycles to require unique inertia.
- Focuses on tridiagonal and cyclic graph structures to understand inertia requirements.

## Abstract

A sign pattern is a matrix whose entries belong to the set $\{+,-,0\}$. A sign pattern requires a unique inertia if every real matrix in its qualitative class has the same inertia. Symmetric tree sign patterns requiring a unique inertia has been studied extensively in \cite{2001, 2001a, 2018}. Necessary and sufficient conditions in terms of the symmetric minimal and maximal rank, as well as conditions depending on the position and sign of the loops in the underlying graph of such patterns has been used to characterize inertia of symmetric tree sign patterns. In this paper, we consider combinatorially symmetric sign patterns with a $0$-diagonal and identify some such patterns with interesting combinatorial properties, which does not require a unique inertia. Initially, we begin with combinatorially symmetric tree sign patterns with a $0$-diagonal, with a special focus on tridiagonal sign patterns. We then consider patterns whose underlying undirected graph contain cycles but no loops, and we derive necessary conditions based on the sign of the edges and the distance between the cycles in the underlying graph for such patterns to require a unique inertia.

## Full text

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## Figures

37 figures with captions in the complete paper: https://tomesphere.com/paper/2508.21509/full.md

## References

8 references — full list in the complete paper: https://tomesphere.com/paper/2508.21509/full.md

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Source: https://tomesphere.com/paper/2508.21509