Abstract
In this work, we are interested in an optimal power flow problem with fixed voltage magnitudes in distribution networks. This optimization problem is known to be non-convex and thus difficult to solve. A well-known solution methodology consists in reformulating the objective function and the constraints of the original problem in terms of positive semi-definite matrix traces, to which we add a rank constraint. To convexify the problem, we remove this rank constraint. Our main focus is to provide a strong mathematical proof of the exactness of this convex relaxation technique. To this end, we explore the geometry of the feasible set of the problem via its Pareto-front. We prove that the feasible set of the original problem and the feasible set of its convexification share the same Pareto-front. From a numerical point of view, this exactness result allows to reduce the initial problem to a semi-definite program, which can be solved by more efficient algorithms.
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Acknowledgements
This work was achieved within the project VERTPOM supported by the French Environment and Energy Management Agency (ADEME), as part of the “Future Investment Program of the French government”. The revision time of the second author was supported by Czech Science Foundation project No. 22-15524 S.
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Desveaux, V., Handa, M. A SDP relaxation of an optimal power flow problem for distribution networks. Optim Eng 24, 2973–3002 (2023). https://doi.org/10.1007/s11081-023-09801-3
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DOI: https://doi.org/10.1007/s11081-023-09801-3