Optimally Scheduling Public Safety Power Shutoffs
Published Online:7 Jun 2023https://doi.org/10.1287/stsy.2022.0004
References
- (2020) Population exposure to pre-emptive de-energization aimed at averting wildfires in Northern California. Environ. Res. Lett. 15(9):094046.Google Scholar
- (2019) Uniformly bounded regret in the multisecretary problem. Stochastic Systems 9(3):231–260.Link, Google Scholar
- (2022) Managing power systems-induced wildfire risks using optimal scheduled shutoffs. 2022 IEEE Power & Energy Society General Meeting (PESGM) (IEEE, Piscataway, NJ), 1–5.Google Scholar
- (2007) A knapsack secretary problem with applications. Charikar M, Jansen K, Reingold O, Rolim JDP, eds. Approximation, Randomization, and Combinatorial Optimization. Algorithms and Techniques, Lecture Notes in Computer Science, vol. 4627 (Springer, Berlin), 16–28.Google Scholar
- California Energy Commission (2021) Electricity consumption by county. Accessed August 15, 2021, https://ecdms.energy.ca.gov/elecbycounty.aspx.Google Scholar
- (2004) Dynamic programming equations for discounted constrained stochastic control. IEEE Trans. Automatic Control 49(5):699–709.Google Scholar
- (2007) Non-randomized policies for constrained Markov decision processes. Math. Methods Oper. Res. 66(1):165–179.Google Scholar
- (2013) Optimal scheduling of demand response events for electric utilities. IEEE Trans. Smart Grid 4(4):2309–2319.Google Scholar
- (1989) Who solved the secretary problem? Statist. Sci. 4(3):282–289.Google Scholar
- (1983) The secretary problem and its extensions: A review. Internat. Statist. Rev. 51(2):189–206.Google Scholar
- (2009) Electric load forecasting methods: Tools for decision making. Eur. J. Oper. Res. 199(3):902–907.Google Scholar
- (2007) Residential implementation of critical-peak pricing of electricity. Energy Policy 35(4):2121–2130.Google Scholar
- (2007) An exploratory analysis of California residential customer response to critical peak pricing of electricity. Energy 32(1):25–34.Google Scholar
- (2022) Data-driven power system optimal decision making strategy under wildfire events. Technical report, Lawrence Livermore National Laboratory, Livermore, CA.Google Scholar
- (2005) Analyzing the impact of weather variables on monthly electricity demand. IEEE Trans. Power Systems 20(4):2078–2085.Google Scholar
- Hydro-Québec (2021a) Dynamic pricing results. Accessed June 2021, https://www.hydroquebec.com/residential/customer-space/rates/dynamic-pricing-results.html.Google Scholar
- Hydro-Québec (2021b) Hydro-Québec rate flex D. Accessed June 2021, https://www.hydroquebec.com/residential/customer-space/rates/rate-flex-d.html.Google Scholar
- (2019) Review of wildfire management techniques—Part I: Causes, prevention, detection, suppression, and data analytics. IEEE Trans. Power Delivery 35(1):430–439.Google Scholar
- (2019) 2019 Wildfire risk report. https://www.corelogic.com/insights-download/wildfire-risk-report.aspx.Google Scholar
- (2007) Option valuation applied to implementing demand response via critical peak pricing. 2007 IEEE Power Engrg. Soc. General Meeting (IEEE, Piscataway, NJ), 1–7.Google Scholar
- (1996) Evaluation of reliability worth and value of lost load. IEE Proc. Generation Transmission Distribution 143(2):171–180.Google Scholar
- (2018) Historical patterns of wildfire ignition sources in California ecosystems. Internat. J. Wildland Fire 27(12):781–799.Google Scholar
- (2005) A multiple-choice secretary algorithm with applications to online auctions. Proc. 16th Annual ACM-SIAM Sympos. Discrete Algorithms (ACM, New York), 630–631.Google Scholar
- (2022a) Optimizing transmission infrastructure investments to support line de-energization for mitigating wildfire ignition risk. Preprint, submitted July 12, https://arxiv.org/abs/2203.10176.Google Scholar
- (2022b) Sharing the load: Considering fairness in de-energization scheduling to mitigate wildfire ignition risk using rolling optimization. 2022 IEEE 61st Conf. Decision Control (CDC) (IEEE, Piscataway, NJ), 5705–5712.Google Scholar
- (1961) Dynamic programming and decision theory. J. Royal Statist. Soc. Series C Appl. Statist. 10(1):39–51.Google Scholar
- (2017) Electrically caused wildfires in Victoria, Australia are over-represented when fire danger is elevated. Landscape Urban Planning 167:267–274.Google Scholar
- Pacific Gas & Electricity (2020a) Community wildfire safety program—Public safety power shutoffs. Accessed January 2022, https://www.pge.com/pge_global/common/pdfs/safety/emergency-preparedness/natural-disaster/wildfires/Public-Safety-Power-Shutoff-Fact-Sheet.pdf.Google Scholar
- Pacific Gas & Electricity (2020b) Public safety power shutoff—Policies and procedures. Accessed January 2022, https://www.pge.com/pge_global/common/pdfs/safety/emergency-preparedness/natural-disaster/wildfires/Public-Safety-Power-Shutoff-Policies-and-Procedures.pdf.Google Scholar
- Pacific Gas & Electricity (2021) 2021 Wildfire mitigation plan report. Accessed January 2022, https://www.pge.com/pge_global/common/pdfs/safety/emergency-preparedness/natural-disaster/wildfires/wildfire-mitigation-plan/2021-Wildfire-Safety-Plan.pdf.Google Scholar
- Pacific Gas & Electricity (2022) Medical baseline program. Savings and safety for customers with additional energy needs. Accessed January 2022, https://www.pge.com/pge_global/common/pdfs/save-energy-money/help-paying-your-bill/longer-term-assistance/medical-condition-related/medical-baseline-allowance/Medical-Baseline-Fact-Sheet.pdf.Google Scholar
- (2013) Value of lost load: How much is supply security worth? 2013 IEEE Power Energy Soc. General Meeting (IEEE, Piscataway, NJ), 1–5.Google Scholar
- (2022) Co-optimization of power line shutoff and restoration for electric grids under high wildfire ignition risk. Preprint, submitted.Google Scholar
- (2020) Balancing wildfire risk and power outages through optimized power shut-offs. IEEE Trans. Power Systems 36(4):3118–3128.Google Scholar
- (2014) A First Course in Probability (Pearson, Harlow, UK).Google Scholar
- (2012) Distribution feeder caused wildfires: Mechanisms and prevention. 2012 65th Annual Conf. Protective Relay Engineers (IEEE, Piscataway, NJ), 43–51.Google Scholar
- (2009) Basics of Applied Stochastic Processes (Springer Science & Business Media, New York).Google Scholar
- (2014) Demand response and smart grids—A survey. Renewable Sustainable Energy Rev. 30:461–478.Google Scholar
- (1986) An exact penalty function approach for nonlinear integer programming problems. Eur. J. Oper. Res. 27(1):50–56.Google Scholar
- (2018) Estimating power system interruption costs: A guidebook for electric utilities. Accessed July 2021, https://eta-publications.lbl.gov/sites/default/files/interruption_cost_estimate_guidebook_final2_9july2018.pdf.Google Scholar
- (2010) Final report. 2009 Victorian bushfires royal commission summary and volume 1: The fires and the fire-related deaths. Report, Parliament of Victoria, State of Victoria, Melbourne, Australia.Google Scholar
- (2022) Data-driven spatio-temporal analysis of wildfire risk to power systems operation. IET Generation Transmission Distribution 16(13):2531–2546.Google Scholar
- (2014) A survey on demand response programs in smart grids: Pricing methods and optimization algorithms. IEEE Comm. Surveys Tutorials 17(1):152–178.Google Scholar
- (1997) Electricity supply reliability: Estimating the value of lost load. Energy Policy 25(1):97–103.Google Scholar
- (2009) Optimal implementation strategies for critical peak pricing. 2009 6th Internat. Conf. Eur. Energy Market (IEEE, Piscataway, NJ), 1–6.Google Scholar
