Rolling Horizon Robust Real-Time Economic Dispatch with Multi-Stage Dynamic Modeling

A multi-stage robust real-time economic dispatch model (MRRTD) for power systems is proposed in this paper. The MRRTD takes the dynamic form of multi-stage robust optimization as the framework to naturally simulate the operation of equipment that is temporally coupled, e.g., utility-level energy storage systems. For normal systems, the MRRTD can work directly in short time slots with a rolling horizon. For large-scale systems, the MRRTD expands the time-slot scale and generates optimal dispatch policies. With this guidance, the real-time dispatch decision can be swiftly made thereafter. In addition, a dynamic uncertainty set based on deep learning is proposed, which can dynamically refine the covering ability for probable occurred wind power scenarios. To efficiently solve the MRRTD, a novel fast robust dual dynamic programming method is employed. The effectiveness of the proposed model and solution algorithm, especially the improved scalability compared to several other dynamic economic dispatch methods, are demonstrated by simulation results from six benchmark test cases ranging from a modified IEEE 6-bus system to a 6495-bus system.

Automated summary

This paper proposes a multi-stage robust real-time economic dispatch model (MRRTD) for power systems. The MRRTD uses the dynamic form of multi-stage robust optimization as the framework to simulate the operation of temporally coupled equipment, such as utility-level energy storage systems. The effectiveness of the proposed model and solution algorithm is demonstrated through simulation results from benchmark test cases.