Abstract
The interconnection of dynamic subsystems that share limited resources are found in many applications, and the control of such systems of subsystems has fueled significant attention from scientists and engineers. For the operation of such systems, model predictive control (MPC) has become a popular technique, arguably for its ability to deal with complex dynamics and system constraints. The MPC algorithms found in the literature are mostly centralized, with a single controller receiving the signals and performing the computations of output signals. However, the distributed structure of such interconnected subsystems is not necessarily explored by standard MPC. To this end, this work proposes hierarchical decomposition to split the computations between a master problem (centralized component) and a set of decoupled subproblems (distributed components) with activation constraints, which brings about organizational flexibility and distributed computation. Two general methods are considered for hierarchical control and optimization, namely Benders decomposition and outer approximation. Results are reported from a numerical analysis of the decompositions and a simulated application to energy management, in which a limited source of energy is distributed among batteries of electric vehicles.
Highlights
Several systems found in the industry and society emerge from the interconnection of dynamic subsystems that share limited resources [1,2]
Given that Benders decomposition is similar to the outer approximation method, we show how the Benders formulation can be derived from the Outer Approximation (OA) formulation
The analysis showed that the electric vehicles can be recharged in a distributed fashion, approaching the optimal behavior that is achieved by a centralized counterpart
Summary
Several systems found in the industry and society emerge from the interconnection of dynamic subsystems that share limited resources [1,2]. Everything considered, the main contribution of this paper is a hierarchical formulation for management of energy systems sharing limited resources, while considering the possibility to activate/deactivate units (subsystems) by means of Benders Decomposition and Outer Approximation These formulations, tailored for MPC applications, bring about organizational flexibility to the central control unit (master problem), which does not need detailed information of the subsystems; only signals regarding the allocated resources and solutions are communicated. Such a flexibility allows for plug-and-play technology, becoming compatible with intelligent and distributed systems.
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