On the complexity of analyticity in semi-definite optimization

Abstract

It is well-known that the central path of semi-definite optimization, unlike linear optimization, has no analytic extension to μ = 0 in the absence of the strict complementarity condition. In this paper, we show the existence of a positive integer by which the reparametrization μ μ recovers the analyticity of the central path at μ = 0. We investigate the complexity of computing using algorithmic real algebraic geometry and the theory of complex algebraic curves. We prove that the optimal is bounded by 2O(m2+n2m+n4), where n is the matrix size and m is the number of affine constraints. Our approach leads to a symbolic algorithm, based on the Newton-Puiseux algorithm, which computes a feasible using 2O(m+n2) arithmetic operations.