Homotopy Techniques in Solving Systems of Nonlinear Equations: A Theoretical Justification of Convex Combinations

Authors

Nicholas Sun, Rutgers UniversityFollow

Publication Date

8-2014

Comments

Technical Report: UTEP-CS-14-54

To appear in Journal of Uncertain Systems

Abstract

One of the techniques for solving systems of non-linear equations F₁(x₁,...,x_n) = 0, ..., F_n(x₁,...,x_n) = 0, (F(x) = 0 in vector notations) is a homotopy method, when we start with a solution of a simplified (and thus easier-to-solve) approximate system G_i(x₁,...,x_n) = 0, and then gradually adjust this solution by solving intermediate systems of equation H_i(x₁,...,x_n) = 0 for an appropriate "transition" function H(x) = f(λ,F(x),G(x)). The success of this method depends on the selection of the appropriate combination function f(λ,u₁,u₂). The most commonly used combination function is the convex homotopy function f(λ,u₁,u₂) = λ * u₁ + (1 − λ) * u₂. In this paper, we provide a theoretical justification for this combination function.