TY - JOUR
T1 - Extreme ray feasibility cuts for unit commitment with uncertainty
AU - Li, Chao
AU - Zhang, Muhong
AU - Hedman, Kory
N1 - Funding Information: History: Accepted by Pascal Van Hentenryck, Area Editor for Modeling: Methods & Analysis. Funding: This work was supported by the Division of Civil, Mechanical and Manufacturing Innovation [Grant 1333646]. Supplemental Material: The e-companion is available at https://doi.org/10.1287/ijoc.2020.0995. Publisher Copyright: Copyright: © 2020 INFORMS
PY - 2021/6
Y1 - 2021/6
N2 - The unit commitment problem with uncertainty is considered one of the most challenging power system scheduling problems. Different stochastic models have been proposed to solve the problem, but such approaches have yet to be applied in industry practice because of computational challenges. In practice, the problem is formulated as a deterministic model with reserve requirements to hedge against uncertainty. However, simply requiring a certain level of reserves cannot ensure power system reliability as the procured reserves may be nondispatchable because of transmission limitations. In this paper, we derive a set of feasibility cuts (constraints) for managing the unit commitment problem with uncertainty. These cuts eliminate unreliable scheduling solutions and reallocate reserves in the power system; they are induced by the extreme rays of a polyhedral dual cone. This paper shows that, with the proposed reformulation, the extreme rays of the dual cone can be characterized by combinatorial selections of transmission lines (arcs) and buses (nodes) of the power system. As a result, the cuts can then be characterized using engineering insights. The unit commitment problem with uncertainty is formulated as a deterministic model with the identified extreme ray feasibility cuts. Test results show that, with the proposed extreme ray feasibility cuts, the problem can be solved more efficiently, and the resulting scheduling decision is also more reliable.
AB - The unit commitment problem with uncertainty is considered one of the most challenging power system scheduling problems. Different stochastic models have been proposed to solve the problem, but such approaches have yet to be applied in industry practice because of computational challenges. In practice, the problem is formulated as a deterministic model with reserve requirements to hedge against uncertainty. However, simply requiring a certain level of reserves cannot ensure power system reliability as the procured reserves may be nondispatchable because of transmission limitations. In this paper, we derive a set of feasibility cuts (constraints) for managing the unit commitment problem with uncertainty. These cuts eliminate unreliable scheduling solutions and reallocate reserves in the power system; they are induced by the extreme rays of a polyhedral dual cone. This paper shows that, with the proposed reformulation, the extreme rays of the dual cone can be characterized by combinatorial selections of transmission lines (arcs) and buses (nodes) of the power system. As a result, the cuts can then be characterized using engineering insights. The unit commitment problem with uncertainty is formulated as a deterministic model with the identified extreme ray feasibility cuts. Test results show that, with the proposed extreme ray feasibility cuts, the problem can be solved more efficiently, and the resulting scheduling decision is also more reliable.
KW - Benders decomposition
KW - Mixed integer programming
KW - Polyhedral study
KW - Stochastic programming
KW - Unit commitment
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U2 - 10.1287/ijoc.2020.0995
DO - 10.1287/ijoc.2020.0995
M3 - Article
SN - 1091-9856
VL - 33
SP - 1037
EP - 1055
JO - INFORMS Journal on Computing
JF - INFORMS Journal on Computing
IS - 3
ER -