A Stochastic-Robust Approach to Hierarchical Generation-Transmission Expansion Planning.

In this paper, the differences between an integrated and hierarchical generation and transmission expansion planning approaches are first described. Then, the hierarchical approach is described in detail. In general terms, in this scheme the investment decisions are made in steps, instead of an overall optimization scheme. This paper proposes a stochastic hierarchical generation-transmission expansion planning methodology based on a three-step procedure, as follows: 1. In this step, an integrated expansion planning problem of generation and interregional interconnections is solved; 2. Taking the optimal expansion plan of (generation and interconnections) into account, a production costing simulation with the detailed network representation is performed without monitoring circuit flow limits (except the ones in the interconnections, which are monitored); this simulation produces a set of optimal dispatch scenarios (vectors of bus loads and generation); 3. A Transmission Expansion Planning (TEP) model is then applied to determine the least-cost transmission expansion plan that is robust with respect to all operation scenarios of step 2, using an enhanced Benders decomposition scheme that: (a) incorporates a subset of the operation scenarios in the investment module; and (b) presents a "warm-up" step with a "greedy" algorithm that produces a (good) feasible solution and an initial set of feasibility cuts. The application of the hierarchical planning scheme is illustrated with a realistic multi-country generation and transmission planning case study of the Central America's electricity market.