A Novel Multiagent Flexibility Aggregation Framework
This addresses the need for intelligent management of DERs in the Smart Grid, but it is incremental as it builds on existing multiagent and scoring rule approaches.
The paper tackles the problem of efficiently integrating Distributed Energy Resources (DERs) into the Smart Grid by proposing a multiagent aggregation framework with Local Flexibility Estimators and cooperative selection mechanisms, resulting in increased average payments for participants compared to traditional aggregators when using a CRPS scoring rule.
The increasing number of Distributed Energy Resources (DERs) in the emerging Smart Grid, has created an imminent need for intelligent multiagent frameworks able to utilize these assets efficiently. In this paper, we propose a novel DER aggregation framework, encompassing a multiagent architecture and various types of mechanisms for the effective management and efficient integration of DERs in the Grid. One critical component of our architecture is the Local Flexibility Estimators (LFEs) agents, which are key for offloading the Aggregator from serious or resource-intensive responsibilities -- such as addressing privacy concerns and predicting the accuracy of DER statements regarding their offered demand response services. The proposed framework allows the formation of efficient LFE cooperatives. To this end, we developed and deployed a variety of cooperative member selection mechanisms, including (a) scoring rules, and (b) (deep) reinforcement learning. We use data from the well-known PowerTAC simulator to systematically evaluate our framework. Our experiments verify its effectiveness for incorporating heterogeneous DERs into the Grid in an efficient manner. In particular, when using the well-known probabilistic prediction accuracy-incentivizing CRPS scoring rule as a selection mechanism, our framework results in increased average payments for participants, when compared with traditional commercial aggregators.