Growth Rates of Sublinear Functional and Volterra Differential Equations

TL;DR

This paper analyzes the growth rates of positive solutions to certain nonlinear functional and Volterra differential equations, establishing how their asymptotic behavior can be derived from simpler autonomous ODEs and using regular variation theory.

Contribution

It introduces a method to determine the growth rates of solutions by relating them to trivial FDEs and extends results using regular variation theory.

Findings

Growth rate of solutions matches that of a trivial FDE with same nonlinearity.

Provides asymptotic estimates for solutions under additional nonlinearity conditions.

Extends classical results using regular variation to nonlinear functional equations.

Abstract

This paper considers the growth rates of positive solutions of scalar nonlinear functional and Volterra differential equations. The equations are assumed to be autonomous (or asymptotically so), and the nonlinear dependence grows less rapidly than any linear function. We impose extra regularity properties on a function asymptotic to this nonlinear function, rather than on the nonlinearity itself. The main result of the paper demonstrates that the growth rate of the solution can be found by determining the rate of growth of a trivial functional differential equation (FDE) with the same nonlinearity and all its associated measure concentrated at zero; the trivial FDE is nothing other than an autonomous nonlinear ODE. We also supply direct asymptotic information about the solution of the FDE under additional conditions on the nonlinearity, and exploit the theory of regular variation to sharpen and extend the results.