Fast primal-dual methods for convex-concave bilinear saddle point problems: continuous-time dynamics and discrete algorithms

Abstract

This paper studies Nesterov accelerated methods for continuously differentiable convex-concave bilinear saddle point problems. For the continuous-time model, we analyze a second-order primal-dual dynamical system with vanishing damping α/t, where α≥ 3. Under the merely convex-concave setting, we prove convergence of the primal-dual trajectory to a saddle point. In the noncritical regime α>3, we further obtain the improved rate o(1/t2) for the primal-dual gap and o(1/t) for the velocity, and, under an additional Lipschitz gradient assumption, o(1/t) for the stationarity residual. We then derive a structure-preserving finite-difference discretization, which leads to a fast primal-dual algorithm with Nesterov extrapolation. For a general accelerated parameter sequence tk satisfying tk+12-tk2 ρtk+1 with ρ∈(0,1], we prove the O(1/tk2) convergence rate for the primal-dual gap and convergence of the generated sequence. In the noncritical case ρ<1, we further establish the improved rate o(1/tk2) for the gap and o(1/tk) for the stationarity residual. These results provide continuous-discrete acceleration methods for bilinear saddle point problems in the merely convex-concave setting.