Perron number
In today's article we will explore the fascinating world of Perron number. From its origins to its relevance today, Perron number has been a topic of constant interest for researchers, academics and enthusiasts in general. Over the years, Perron number has demonstrated its impact on different aspects of everyday life, whether in history, science, culture or technology. Through this article, we will delve into its many facets, with the aim of better understanding its influence on the world around us. Join us on this tour and discover everything Perron number has to offer.
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In mathematics, a Perron number is an algebraic integer α which is real and greater than 1, but such that its conjugate elements are all less than α in absolute value. For example, the larger of the two roots of the irreducible polynomial is a Perron number.
Perron numbers are named after Oskar Perron; the Perron–Frobenius theorem asserts that, for a real square matrix with positive algebraic entries whose largest eigenvalue is greater than one, this eigenvalue is a Perron number. (Conversely, it was shown in the late 20th century by Douglas Lind that the Perron numbers are in fact the "closure" of the natural numbers, realized after only one iteration of taking spectral radii of aperiodic matrices, where entries are drawn from this set.) As a closely related case, the Perron number of a graph is defined to be the spectral radius of its adjacency matrix.
Any Pisot number or Salem number is a Perron number, as is the Mahler measure of a monic integer polynomial.
References
- Borwein, Peter (2007). Computational Excursions in Analysis and Number Theory. Springer Verlag. p. 24. ISBN 978-0-387-95444-8.
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