Analytic Number Theory and Algebraic Asymptotic Analysis

Abstract

This monograph elucidates and extends many theorems and conjectures in analytic number theory and algebraic asymptotic analysis via the natural notion of "degree" and a more general notion that we call "logexponential degree." Specifically, we define the degree of a real function f whose domain is not bounded above to be the infimum of all real numbers t such that f(x) is O(xt). The Riemann hypothesis, for example, is equivalent to the statement that the degree of the function π(x)- li(x) is 1/2, where π(x) is the prime counting function and li(x) is the logarithmic integral function; likewise, the abc conjecture is equivalent to the statement that a particular function has degree 1. Part 1 of the text is a survey of analytic number theory, Part 2 introduces the notion of logexponential degree and uses it to extend results in algebraic asymptotic analysis, and Part 3 applies the results of Part 2 to the various functions that figure most prominently in analytic number theory and Diophantine analysis. Central to the notion of logexponential degree are Hardy's logarithmico-exponential functions, which are real functions defined in a neighborhood of ∞ that can be built from id, , and using the operations +, ·, /, and . Such functions are natural benchmarks for the orders of growth of functions in analytic number theory. The main goal of Part 3 is to express the logexponential degree of various functions in analytic number theory in terms of as few "logexponential primitives" as possible.

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