Electric Power Planning for Regulated and eregulation

Arthur Mazer, PhD, MBA, is Manager of Forward Transactions Planning at Southern California Edison, where he oversees the risk assessment of SCE's power, gas, and customer portfolio, as well as valuation and selection of power and gas contracts. He previously held positions at Electrabel, Progress Energy, and Entergy Power Marketing Corp. Additionally, he was visiting assistant professor at Utah State University and a lecturer at Singapore Polytechnic, both in the Department of Mathematics.

Preface. Acknowledgments. Figure Citations. About the Author. 1. Overview. 1.1 The Power Delivery Chain in a Vertically Integrated Utility. 1.2 The Power Delivery Chain in a Market Environment. 2. Energy, Load, and Generation Technologies. 2.1 Energy, Power, and their Measurements. 2.2 Load. 2.3 Generation Technologies. 3. The Grid. 3.1 Fundamentals: Load, Generation, and Alternating Current. 3.2 Grid Equipment. 3.3 Grid Reliability and Contingency Requirements. 3.4 Grid Confi guration. 3.5 Grid Operations. 3.6 Blackout August 14, 2003. 4. Short-Term Utility Planning. 4.1 Planning and Execution of Dispatch: Day-Ahead Planning Through Real-Time Delivery. 4.2 Day-Ahead Demand Forecasting: Load and Ancillary Service Requirements. 4.3 Least-Cost Dispatch in a Single Control Area: A Simple Model. 4.4 A Solution Using Profi t Maximization. 4.5 Least-Cost Dispatch in a Single Control Area with Operating Constraints. 4.6 Least-Cost Dispatch in a Single Node with Spinning Reserve and Regulation. 4.7 Least-Cost Dispatch in a Network. 4.8 Real Time. 5. Long-Term Utility Planning. 5.1 Project Development. 5.2 The Planning Process. 5.3 Long-Term Load Forecasting. 5.4 A Simplifi ed Look at Generation Capacity Additions. 5.5 Generation Additions and Retirements Within a Single Control Area. 5.6 Generation Additions and Retirements with Transmission to a Single Control Area. 5.7 Generation Additions and Retirements and Transmission Additions Within a Network. 5.8 Reserve Reuqirements. 6. Midterm Utility Planning. 6.1 Informational Requirements. 6.2 Formulation of the Optimization Problem. 7. A Market Environment. 7.1 Principles and Architecture. 7.2 Short-Term Market Design: Day-Ahead Scheduling Through Real-Time Delivery. 7.3 Long-Term Market Design: No Clear Solutions. 7.4 Midterm Market Design. 8. Asset Management in Short-Term Markets. 8.1 Retailers. 8.2 Power Producers. 8.3 Integrated Energy Companies. 9. Investment Analysis: Long-Term Planning in a Market Environment. 9.1 Investment Setting in Utility and Market Environments. 9.2 Project Analysis for a Merchant Plant. 9.3 Power Purchase Agreements (Long-Term Contracts). 10. Risk Management in the Midterm Markets. 10.1 Retailer Risk. 10.2 Power Producer Risk. 10.3 A Quick Risk Primer in Statistics for Risk Management. 10.4 Risk Management in Midterm Markets: Retailers. 10.5 Risk Management in Midterm Markets: Power Producers. 10.6 Risk Management in Midterm Markets: Integrated Electricity Suppliers. 11. The California Experience. 11.1 Market Fundamentals. 11.2 Short-Term Market Structure: The CALPX, CAISO, and Other Market Participants. 11.3 Fatboy, Get Shorty, Ricochet, and Death Star. 11.4 Market Contrast: PJM and California. Bibliography. Index.