Abstract
Problem statement: Let T be a set of n distinct positive integers, x1, x2, ..., xn. The n×n matrix [T] having (xi, xj), the greatest common divisor of xi and xj, as its (i,j)-entry is called the greatest common divisor (GCD) matrix on T. The matrix [[T]] whose (i,j)-entry is [xi, xj], the least common multiple of xi and xj, is called the least common multiple (LCM) matrix on T. Many aspects of arithmetics in the domain of natural integers can be carried out to Principal Ideal Domains (PID). In this study, we extend many recent results concerning GCD and LCM matrices defined on Factor Closed (FC) sets to an arbitrary PID such as the domain of Gaussian integers and the ring of polynomials over a finite field. Approach: In order to extend the various results, we modified the underlying computational procedures and number theoretic functions to the arbitrary PIDs. Properties of the modified functions and procedures were given in the new settings. Results: Modifications were used to extend the major results concerning GCD and LCM matrices defined on FC sets in PIDs. Examples in the domains of Gaussian integers and the ring of polynomials over a finite field were given to illustrate the new results. Conclusion: The extension of the GCD and LCM matrices to PIDs provided a lager class for such matrices. Many of the open problems can be investigated in the new settings.
Highlights
Let T = {x1, x2, ..., xn} be a set of n distinct positive integers
Smith considered the determinant of the least common multiple (LCM) matrix on a factor closed (FC) set and showed that it is n equal to the product ∏φ(xi )π(xi ), where π is a i =1 multiplicative function defined for a prime power pr by π(pr) = −p
The purpose of this study is to extend many of the recent results concerning Greatest Common Divisor (GCD) and LCM matrices defined on factor-closed sets to arbitrary Principal Ideal Domains (PID) such as the domain of Gaussian integers and the ring of polynomials over a finite field
Summary
The matrix [[T]] whose (i,j)-entry is [xi,xj], the least common multiple of xi and xj, is called the least common multiple (LCM) matrix on T. In 1876, Smith[11] showed that the determinant of the GCD matrix [T] on a FC set T is the n product ∏φ(xi ) , where φ is Euler's totient phii =1 function. Smith considered the determinant of the LCM matrix on a FC set and showed that it is n equal to the product ∏φ(xi )π(xi ) , where π is a i =1 multiplicative function defined for a prime power pr by π(pr) = −p. Since many papers related to Smith's results have been published This new inspiration started in by Beslin and Ligh[3,4]
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