Table of Contents
Fetching ...

Eigenvalues of the product matrices of finite commutative rings

David Dolžan

Abstract

The product matrix of a finite commutative ring $R=\{x_1,x_2,\ldots,x_n\}$ and an element $u \in R$ is the matrix $A_u(R)=[a_{ij}]$, where $a_{ij}=1$ if $x_ix_j=u$, and $a_{ij}=0$ otherwise. This provides a natural extension of the concept of the adjacency matrix of the zero-divisor graph of a ring, which has been studied extensively. In this paper, we find the characteristic polynomial of $A_u(R)$ for a local ring $R$ of odd order and a unit $u$. By studying the structure of a finite local ring, we find the characteristic polynomial of $A_u(R)$ for a local ring $R$ and any $u \in R$ in two cases: when the Jacobson radical of $R$ has either the maximal or the minimal possible index of nilpotency.

Eigenvalues of the product matrices of finite commutative rings

Abstract

The product matrix of a finite commutative ring and an element is the matrix , where if , and otherwise. This provides a natural extension of the concept of the adjacency matrix of the zero-divisor graph of a ring, which has been studied extensively. In this paper, we find the characteristic polynomial of for a local ring of odd order and a unit . By studying the structure of a finite local ring, we find the characteristic polynomial of for a local ring and any in two cases: when the Jacobson radical of has either the maximal or the minimal possible index of nilpotency.
Paper Structure (5 sections, 9 theorems, 4 equations)

This paper contains 5 sections, 9 theorems, 4 equations.

Key Result

Lemma 2.1

Let $R$ be a (finite) commutative ring, $u \in R^*$ and $j \in J$. Then $u+j \in R^*$.

Theorems & Definitions (14)

  • Lemma 2.1
  • Theorem 2.2
  • Theorem 3.1
  • Theorem 4.1
  • Example 4.2
  • Remark
  • Lemma 4.3
  • Theorem 4.4
  • Example 4.5
  • Lemma 4.6
  • ...and 4 more