Derivative-free global minimization for a class of multiple minima problems

Abstract

We prove that the finite-difference based derivative-free descent (FD-DFD) methods have a capability to find the global minima for a class of multiple minima problems. Our main result shows that, for a class of multiple minima objectives that is extended from strongly convex functions with Lipschitz-continuous gradients, the iterates of FD-DFD converge to the global minimizer x* with the linear convergence \|xk+1-x*\|22≤slantk \|x1-x*\|22 for a fixed 0<<1 and any initial iteration x1∈Rd when the parameters are properly selected. Since the per-iteration cost, i.e., the number of function evaluations, is fixed and almost independent of the dimension d, the FD-DFD algorithm has a complexity bound O(1ε) for finding a point x such that the optimality gap \|x-x*\|22 is less than ε>0. Numerical experiments in various dimensions from 5 to 500 demonstrate the benefits of the FD-DFD method.