Convex Relaxations of Probabilistic AC Optimal Power Flow for Interconnected AC and HVDC Grids

High voltage direct current (HVDC) systems interconnect ac grids to increase reliability, connect offshore wind generation, and enable coupling of electricity markets. Considering the growing uncertainty in power infeed and the complexity introduced by additional controls, robust decision support tools are necessary. This paper proposes a chance constrained ac optimal power flow (AC-OPF) for ac and HVDC grids, which considers wind uncertainty, fully utilizes HVDC control capabilities, and uses the semi definite relaxation of the AC-OPF. We consider a joint chance constraint for both ac and HVDC systems, we introduce a piecewise of ne approximation to achieve the tractability of the chance constraint, and we allow corrective control policies for HVDC converters and generators to be determined. An active loss penalty term in the objective function and a systematic procedure to choose the penalty weights allow us to obtain ac-feasible solutions. We introduce Benders decomposition to maintain the scalability. Using realistic forecast data, we demonstrate our approach on a 53-bus and a 214-bus ac-dc systems, obtaining tight near-global optimality guarantees. With a Monte Carlo analysis, we show that a chance-constrained dc optimal power flow leads to violations, whereas our proposed approach complies with the joint chance constraint.