Convergence Rates for p Norm Minimization in Convex Vector Optimization

Abstract

We analyze convergence rates of norm-minimization-based outer approximation algorithms for convex vector optimization when the scalarization uses an p norm with p ∈ (1,∞). While the Euclidean case (p=2) achieves the optimal rate O(k2/(1-q)), the behavior under general p norms has remained open. A direct approach via the modulus of smoothness yields only the weaker exponent (p,2), which degrades for 1 < p < 2. We prove that the Hausdorff approximation error satisfies δH(Pk, A) = O(k2/(1-q)) for every p ∈ (1,∞), where q is the number of objectives and k is the iteration count. The proof introduces a Euclidean intermediary technique that exploits the ambient inner product structure of q to obtain a quadratic bound on the hyperplane distance, bypassing the p smoothness limitation; norm equivalence then converts this to any p metric at the cost of only a dimension-dependent constant, not a loss of exponent. Numerical experiments confirm the p-independent rate predicted by the theory.