Aggregating Distributed Energy Resources: Efficiency and Market Power

References

• Adelman D, Uçkun C (2019) Dynamic electricity pricing to smart homes. Oper. Res. 67(6):1520–1542.Link, Google Scholar
• Aflaki S, Netessine S (2017) Strategic investment in renewable energy sources: The effect of supply intermittency. Manufacturing Service Oper. Management 19(3):489–507.Link, Google Scholar
• Al-Gwaiz M, Chao X, Wu OQ (2017) Understanding how generation flexibility and renewable energy affect power market competition. Manufacturing Service Oper. Management 19(1):114–131.Link, Google Scholar
• Alahmed AS, Tong L (2023) Resource sharing in energy communities: A cooperative game approach. Preprint, submitted November 30, https://arxiv.org/abs/2311.18792.Google Scholar
• Alessio Trivella SN, Fleten SE, Mazieres D, Pisinger D (2021) Managing shutdown decisions in merchant commodity and energy production: A social commerce perspective. Manufacturing Service Oper. Management 23(2):311–330.Google Scholar
• Alshehri K, Bose S, Başar T (2021) Centralized volatility reduction for electricity markets. Internat. J. Electric Power Energy Systems 133:107101.Crossref, Google Scholar
• Alshehri K, Ndrio M, Bose S, Başar T (2020) Quantifying market efficiency impacts of aggregated distributed energy resources. IEEE Trans. Power Systems 35(5):4067–4077.Crossref, Google Scholar
• Anupindi R, Jiang L (2008) Capacity investment under postponement strategies, market competition, and demand uncertainty. Management Sci. 54(11):1876–1890.Link, Google Scholar
• Aravena I, Lété Q, Papavasiliou A, Smeers Y (2021) Transmission capacity allocation in zonal electricity markets. Oper. Res. 69(4):1240–1255.Link, Google Scholar
• Ata B, Duran AS, Islegen O (2018) An analysis of time-based pricing in retail electricity markets. Preprint, submitted June 14, https://dx.doi.org/10.2139/ssrn.2826055.Google Scholar
• Babich V, Lobel R, Yücel S (2020) Promoting solar panel investments: Feed-in-tariff vs. tax-rebate policies. Manufacturing Service Oper. Management 22(6):1148–1164.Link, Google Scholar
• Başar T, Olsder GJ (1999) Dynamic Noncooperative Game Theory (SIAM, Philadelphia).Google Scholar
• Bertsimas D, Litvinov E, Sun XA, Zhao J, Zheng T (2013) Adaptive robust optimization for the security constrained unit commitment problem. IEEE Trans. Power Systems 28(1):52–63.Crossref, Google Scholar
• Bimpikis K, Ehsani S, İlkiliç R (2019) Cournot competition in networked markets. Management Sci. 65(6):2467–2481.Link, Google Scholar
• Birge JR, Hortaçsu A, Pavlin JM (2017) Inverse optimization for the recovery of market structure from market outcomes: An application to the MISO electricity market. Oper. Res. 65(4):837–855.Link, Google Scholar
• Burger S, Chaves-Ávila JP, Batlle C, Pérez-Arriaga IJ (2017) A review of the value of aggregators in electricity systems. Renewable Sustainable Energy Rev. 77:395–405.Crossref, Google Scholar
• Chen C, Alahmed AS, Mount TD, Tong L (2023a) Wholesale market participation of dera part II: Competitive DER aggregation. Preprint, submitted July 5, https://arxiv.org/abs/2307.02004.Google Scholar
• Chen C, Bose S, Mount TD, Tong L (2023b) Wholesale market participation of dera part I: DSO-DERA-ISO coordination. Preprint, submitted July 5, https://arxiv.org/abs/2307.01999.Google Scholar
• Commonwealth Edison Company (2024) FAQs: Hourly pricing. Accessed January 26, 2024, https://hourlypricing.comed.com/faqs/.Google Scholar
• Federal Energy Regulatory Commission (2020) Order No. 2222: Participation of distributed energy resource aggregations in markets operated by regional transmission organizations and independent system operators. Retrieved August 27, https://www.ferc.gov/sites/default/files/2020-09/E-1_0.pdf.Google Scholar
• Gao Z, Alshehri K, Birge JR (2021a) Aggregating distributed energy resources: Efficiency and market power. Preprint, submitted September 28, https://dx.doi.org/10.2139/ssrn.3931052.Google Scholar
• Gao Z, Alshehri K, Birge JR (2021b) On efficient aggregation of distributed energy resources. 2021 60th IEEE Conf. Decision Control (CDC) (IEEE, Piscataway, NJ), 7064–7069.Google Scholar
• Gao Z, Alshehri K, Birge JR (2022) Quantification of market power mitigation via efficient aggregation of distributed energy resources. 2022 IEEE 61st Conf. Decision Control (CDC) (IEEE, Piscataway, NJ), 4406–4411.Google Scholar
• Gao Z, Sunar N, Birge JR (2023a) Designing renewable power purchase agreements: Impact on green energy investment. Preprint, submitted December 20, https://dx.doi.org/10.2139/ssrn.4670536.Google Scholar
• Gao Z, Sunar N, Birge JR (2023b) Power purchase agreements with renewables: Optimal timing and design. 2023 62nd IEEE Conf. Decision Control (CDC) (IEEE, Piscataway, NJ), 7580–7585.Google Scholar
• Gharesifard B, Başar T, Domínguez-García AD (2016) Price-based coordinated aggregation of networked distributed energy resources. IEEE Trans. Automated Control 61(10):2936–2946.Crossref, Google Scholar
• Greer M (2012) Electricity Marginal Cost Pricing: Applications in Eliciting Demand Responses (Elsevier, New York).Google Scholar
• Gundlach J, Webb R (2018) Distributed energy resource participation in wholesale markets: Lessons from the California ISO. Energy Law J. 39(1):47–77.Google Scholar
• Hu S, Souza GC, Ferguson ME, Wang W (2015) Capacity investment in renewable energy technology with supply intermittency: Data granularity matters! Manufacturing Service Oper. Management 17(4):480–494.Link, Google Scholar
• Kök AG, Shang K, Yücel Ş (2018) Impact of electricity pricing policies on renewable energy investments and carbon emissions. Management Sci. 64(1):131–148.Link, Google Scholar
• Lavillotti M (2018) DER market design: Aggregations. Technical report, ISO, New York.Google Scholar
• Ljungqvist L, Sargent TJ (2018) Recursive Macroeconomic Theory (MIT Press, Cambridge, MA).Google Scholar
• Manshadi SD, Khodayar ME (2016) A hierarchical electricity market structure for the smart grid paradigm. IEEE Trans. Smart Grid 7(4):1866–1875.Crossref, Google Scholar
• Parag Y, Sovacool BK (2016) Electricity market design for the prosumer era. Natural Energy 1(4):1–6.Google Scholar
• Peura H, Bunn DW (2021) Renewable power and electricity prices: The impact of forward markets. Management Sci. 67(8):4772–4788.Link, Google Scholar
• Qin J, Poolla K, Varaiya P (2021) Mobile storage for demand charge reduction. IEEE Trans. Intelligent Transportation Systems 23(7):7952–7962.Crossref, Google Scholar
• Ritzenhofen I, Birge JR, Spinler S (2016) The structural impact of renewable portfolio standards and feed-in tariffs on electricity markets. Eur. J. Oper. Res. 255(1):224–242.Crossref, Google Scholar
• Ruhi NA, Dvijotham K, Chen N, Wierman A (2018) Opportunities for price manipulation by aggregators in electricity markets. IEEE Trans. Smart Grid 9(6):5687–5698.Crossref, Google Scholar
• Secomandi N, Kekre S (2014) Optimal energy procurement in spot and forward markets. Manufacturing Service Oper. Management 16(2):270–282.Link, Google Scholar
• Singh SP, Scheller-Wolf A (2022) That’s not fair: Tariff structures for electric utilities with rooftop solar. Manufacturing Service Oper. Management 24(1):40–58.Link, Google Scholar
• Sunar N, Birge JR (2019) Strategic commitment to a production schedule with uncertain supply and demand: Renewable energy in day-ahead electricity markets. Management Sci. 65(2):714–734.Link, Google Scholar
• Wu OQ, Kapuscinski R (2013) Curtailing intermittent generation in electrical systems. Manufacturing Service Oper. Management 15(4):578–595.Link, Google Scholar
• Zhao F, Zheng T, Litvinov E (2018) Constructing demand curves in forward capacity market. IEEE Trans. Power Systems 33(1):525–535.Crossref, Google Scholar
• Zhou YH, Scheller-Wolf A, Secomandi N, Smith S (2019) Managing wind-based electricity generation in the presence of storage and transmission capacity. Production Oper. Management 28(4):970–989.Crossref, Google Scholar