A fast assessment method for multiple values of power systems based on VCG mechanism and state-space compression

doi:10.11930/j.issn.1004-9649.202508002

Abstract

Abstract:

With the increasing penetration of renewable energy resources (RES), different types of electricity market entities, such as traditional thermal power, energy storage, and RES, have demonstrated distinct differentiated characteristics in terms of the core attributes of supporting the operation of power systems and society. To address the issue that the current electricity market mechanism struggles to comprehensively and accurately quantify the contributions of different market entities in dimensions such as safety and environmental friendliness, this paper proposes a multi-value evaluation method for power systems oriented towards multiple types of entities. Firstly, an evaluation index system and calculation model covering economic value, security value, and environmental value are established. The Vickrey-Clarke-Groves (VCG) auction mechanism is introduced, and based on the joint optimization clearing model of main and auxiliary services in power systems, the multiple values of various market entities are quantified through alternative benefits. Secondly, to tackle the problems of heavy computational burden in the VCG framework and high solving complexity of the security-constrained unit commitment (SCUC), a parallel solving acceleration algorithm based on time-period decoupling and state-space compression is proposed. Case studies are conducted on the modified IEEE 30-bus and IEEE 118-bus systems. The results demonstrate that the proposed method comprehensively and objectively evaluates the multiple values and externalities of various market entities, and the proposed acceleration algorithm significantly improves the solving efficiency of mixed-integer linear programming (MILP) problems while meeting the requirements of solving accuracy.

Key words: multi-value assessment, VCG mechanism, algorithmic acceleration, unit commitment

FAN Menghua, ZHANG Shengnan, DAI Fengzhe, ZHENG HaiFeng, ZHANG Xiaoxuan, LIU Zhaoxi, JING Zhaoxia. A fast assessment method for multiple values of power systems based on VCG mechanism and state-space compression[J]. Electric Power, 2026, 59(6): 101-111.

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References 34

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	经济价值/元	安全价值（调频、备用）/元	环境价值（污染治理）/元	环境价值（弃风、弃光）/元	安全价值（切负荷）/元	安全价值（EENS）/元
火电1	560018.760	4450.269	67785.563	0	18.252	1224.068
火电2	437250.190	2012.218	95113.894	0	0	623.407
火电3	244082.251	1472.674	58981.744	0	0	173.149
火电4	307135.630	3638.313	44927.981	0	2333553.300	281.533
火电5	0	0	0	0	0	0
火电6	112496.476	2220.771	13848.076	0	0	1749.295
储能1	21423.953	6709.897	223.736	0	0	170.712
储能2	44793.824	2022.454	3500.411	0	0	162.263
储能3	5643.475	687.065	523.917	0	0	719.112
储能4	11445.063	242.978	–56.147	0	0	591.195
风电1	102872.127	–497.307	29835.868	0	0	54.411
风电2	83950.570	–354.295	28514.256	0	0	88.601
光伏1	55505.261	–775.479	22833.895	0	0	31.442
光伏2	43805.943	–629.570	18097.774	0	0	27.786

	经济价值/元	安全价值（调频、备用）/元	环境价值（污染治理）/元	环境价值（弃风、弃光）/元	安全价值（切负荷）/元	安全价值（EENS）/元
火电1	560018.760	4450.269	67785.563	0	18.252	1224.068
火电2	437250.190	2012.218	95113.894	0	0	623.407
火电3	244082.251	1472.674	58981.744	0	0	173.149
火电4	307135.630	3638.313	44927.981	0	2333553.300	281.533
火电5	0	0	0	0	0	0
火电6	112496.476	2220.771	13848.076	0	0	1749.295
储能1	21423.953	6709.897	223.736	0	0	170.712
储能2	44793.824	2022.454	3500.411	0	0	162.263
储能3	5643.475	687.065	523.917	0	0	719.112
储能4	11445.063	242.978	–56.147	0	0	591.195
风电1	102872.127	–497.307	29835.868	0	0	54.411
风电2	83950.570	–354.295	28514.256	0	0	88.601
光伏1	55505.261	–775.479	22833.895	0	0	31.442
光伏2	43805.943	–629.570	18097.774	0	0	27.786

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