Affiliation:
1. Energy Information Networks & Systems, Technical University of Darmstadt, 64283 Darmstadt, Germany
Abstract
For linear optimization problems with a parametric objective, so-called parametric linear programs (PLP), we show that the optimal decision values are, under few technical restrictions, unimodal functions of the parameter, at least in the two-degrees-of-freedom case. Assuming that the parameter is random and follows a known probability distribution, this allows for an efficient algorithm to determe the quantiles of linear combinations of the optimal decisions. The novel results are demonstrated with probabilistic economic dispatch. For an example setup with uncertain fuel costs, quantiles of the resulting inter-regional power flows are computed. The approach is compared against Monte Carlo and piecewise computation techniques, proving significantly reduced computation times for the novel procedure. This holds especially when the feasible set is complex and/or extreme quantiles are desired. This work is limited to problems with two effective degrees of freedom and a one-dimensional uncertainty. Future extensions to higher dimensions could yield a key tool for the analysis of probabilistic PLPs and, specifically, risk management in energy systems.
Funder
German Federal Ministry of Transport and Digital Infrastructure in project CO2030
Reference25 articles.
1. A review of recent advances in economic dispatch;Chowdhury;IEEE Trans. Power Syst.,1990
2. Wood, A.J., Wollenberg, B.F., and Sheble, G.B. (2013). Power Generation, Operation, and Control, Wiley-Blackwell. [3rd ed.].
3. Review of economic dispatch in multi-area power system: State-of-the-art and future prospective;Kunya;Electr. Power Syst. Res.,2023
4. Lin, J., and Magnago, F.H. (2017). Electricity Markets: Theories and Applications, John Wiley & Sons.
5. Composite systems reliability evaluation based on Monte Carlo simulation and cross-entropy methods;Resende;IEEE Trans. Power Syst.,2013