Abstract
Energy grids are facing a relatively new paradigm consisting in the formation of local distributed energy sources and loads that can operate in parallel independently from the main power grid (usually called microgrids). One of the main challenges in microgrid-like networks management is that of self-adapting to the production and demands in a decentralized coordinated way. Here, we propose a stylized model that allows to analytically predict the coordination of the elements in the network, depending on the network topology. Surprisingly, almost global coordination is attained when users interact locally, with a small neighborhood, instead of the obvious but more costly all-to-all coordination. We compute analytically the optimal value of coordinated users in random homogeneous networks. The methodology proposed opens a new way of confronting the analysis of energy demand-side management in networked systems.
Highlights
Local distributed energy production-consumption nodes are becoming an important complement, and even alternative, to centralized energy generation facilities
Energy transmission grids have been largely analyzed in the complex networks literature to assess performance, efficiency and robustness [1–13]
Let us discuss how the proposed model can be applied to energy demand side management
Summary
Local distributed energy production-consumption nodes (microgrids) are becoming an important complement, and even alternative, to centralized energy generation facilities. We take advantage of the theory of complex networks to propose a stylized model for coordinating the different users’ consumption demands according to the energy produced within the microgrid.
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