معرفی کتاب «Economic Market Design and Planning for Electric Power Systems (IEEE Press Series on Power and Energy Systems)» نوشتهٔ James A. Momoh; Lamine Mili، منتشرشده توسط نشر Wiley ; IEEE در سال 2009. این کتاب در فرمت pdf، زبان انگلیسی ارائه شده است.
Discover cutting-edge developments in electric power systems Stemming from cutting-edge research and education activities in the field of electric power systems, this book brings together the knowledge of a panel of experts in economics, the social sciences, and electric power systems. In ten concise and comprehensible chapters, the book provides unprecedented coverage of the operation, control, planning, and design of electric power systems. It also discusses: A framework for interdisciplinary research and education Modeling electricity markets Alternative economic criteria and proactive planning for transmission investment in deregulated power systems Payment cost minimization with demand bids and partial capacity cost compensations for day-ahead electricity auctions Dynamic oligopolistic competition in an electric power network and impacts of infrastructure disruptions Reliability in monopolies and duopolies Building an efficient, reliable, and sustainable power system Risk-based power system planning integrating social and economic direct and indirect costs Models for transmission expansion planning based on reconfiguration capacitor switching Next-generation optimization for electric power systems Most chapters end with a bibliography, closing remarks, conclusions, or future work. Economic Market Design and Planning for Electric Power Systems is an indispensable reference for policy-makers, executives and engineers of electric utilities, university faculty members, and graduate students and researchers in control theory, electric power systems, economics, and the social sciences. ECONOMIC MARKET DESIGN AND PLANNING FOR ELECTRIC POWER SYSTEMS......Page 5 CONTENTS......Page 7 PREFACE......Page 13 CONTRIBUTORS......Page 15 1.1 Introduction......Page 19 1.2 Power System Challenges......Page 21 1.2.1 The Power System Modeling and Computational Challenge......Page 22 1.3.1 Modular Description of the EPNES Architecture......Page 23 1.3.2 Some Expectations of Studies Using EPNES Benchmark Test Beds......Page 25 1.4.2 Definition of Objectives......Page 26 1.4.3 Selected Objective Functions and Pictorial Illustrations......Page 27 1.5.1 Power System Model for the Navy......Page 31 1.5.2 Civil Testbed—179-Bus WSCC Benchmark Power System......Page 33 1.6.1 Funded Research by Topical Areas/Groups under the EPNES Award......Page 34 1.6.2 EPNES Award Distribution......Page 35 1.8 Conclusions......Page 36 Bibliography......Page 37 2.1 Introduction......Page 39 2.2 The Basic Structure of a Market for Electricity......Page 40 2.2.1 Consumer Surplus......Page 41 2.2.3 Market Power......Page 42 2.2.4 Architecture of Electricity Markets......Page 43 2.3.1 Brief Literature Review......Page 44 2.3.2 Price-Based Models......Page 45 2.3.3 Quality-Based Models......Page 48 2.4.1 Introduction......Page 50 2.4.2 Congestion Charges and Financial Transmission Rights......Page 51 2.4.3 Example of a 3-Bus System......Page 52 2.5.1 Overview of the Static LMP Problem......Page 57 2.5.2 LMP in Stochastic and Dynamic Market with Uncertainty......Page 58 Bibliography......Page 60 3 ALTERNATIVE ECONOMIC CRITERIA AND PROACTIVE PLANNING FOR TRANSMISSION INVESTMENT IN DEREGULATED POWER SYSTEMS......Page 63 3.1 Introduction......Page 64 3.2.1 A Radial-Network Example......Page 67 3.2.2 Sensitivity Analysis in the Radial-Network Example......Page 74 3.4 Proactive Transmission Planning......Page 75 3.4.1 Model Assumptions......Page 76 3.4.2 Model Notation......Page 78 3.4.3 Model Formulation......Page 79 3.4.4 Transmission Investment Models Comparison......Page 80 3.5 Illustrative Example......Page 82 3.6 Conclusions and Future Work......Page 85 Appendix......Page 86 4 PAYMENT COST MINIMIZATION WITH DEMAND BIDS AND PARTIAL CAPACITY COST COMPENSATIONS FOR DAY-AHEAD ELECTRICITY AUCTIONS......Page 89 4.1 Introduction......Page 90 4.3 Problem Formulation......Page 91 4.4 Solution Methodology......Page 93 4.4.2 Formulating and Solving Unit Subproblems......Page 94 4.4.3 Formulating and Solving Bid Subproblems......Page 97 4.4.5 Generating Feasible Solutions......Page 98 4.5 Results and Insights......Page 99 Bibliography......Page 102 5.1 Introduction and Motivation......Page 105 5.2 Summary and Modeling Approach......Page 107 5.3.1 Notation......Page 108 5.3.2 Generating Firm’s Extremal Problem......Page 110 5.3.3 ISO’s Problem......Page 112 5.4.1 Complementary Conditions for Generating Firms......Page 113 5.4.2 Complementary Conditions for the ISO......Page 115 5.5 Numerical Example......Page 116 Appendix: Glossary of Relevant Terms form Electricity Economics......Page 126 Bibliography......Page 128 6 PLANT RELIABILITY IN MONOPOLIES AND DUOPOLIES: A COMPARISON OF MARKET OUTCOMES WITH SOCIALLY OPTIMAL LEVELS......Page 131 6.1 Introduction......Page 132 6.2 Modeling Framework......Page 134 6.3 Profit Maximizing Outcome of a Monopolistic Generator......Page 136 6.4 Nash Equilibrium in a Duopolistic Market Structure......Page 138 6.5 Social Optimum......Page 140 6.6 Comparison of Equilibria and Discussion......Page 141 6.7 Asymmetric Maintenance Policies......Page 143 6.8 Conclusion......Page 145 Bibliography......Page 146 7.1 Introduction......Page 149 7.1.2 Our Proposed Solutions to the Above Shortcomings......Page 150 7.2.1 Reliability......Page 151 7.2.2 Bulk Power System Reliability Requirements......Page 152 7.2.4 Power System / New Technology......Page 153 7.3.1 Contingency Issues......Page 158 7.3.2 Foundation of Public Perception......Page 159 7.3.3 Available Transmission Capability (ATC)......Page 160 7.3.4 Reliability Measures/Indices......Page 161 7.3.5 Expected Socially Unserved Energy (ESUE) and Load Loss......Page 163 7.3.6 System Performance Index......Page 165 7.3.7 Computation of Weighted Probability Index (WPI)......Page 166 7.4 Design Methodologies......Page 167 7.5.1 Load Flow Analysis with FACTS Devices (TCSC) for WSCC System......Page 168 7.6.1 Load Flow Analysis with FACTS Devices (TCSC) for WSCC System......Page 169 7.6.2 Performance Evaluation Studies on IEEE 30-Bus System......Page 171 7.6.3 Performance Evaluation Studies on the WSCC System......Page 173 7.7 Conclusion......Page 175 Bibliography......Page 176 8 RISK-BASED POWER SYSTEM PLANNING INTEGRATING SOCIAL AND ECONOMIC DIRECT AND INDIRECT COSTS......Page 179 8.1 Introduction......Page 180 8.2 The Partitioned Multiobjective Risk Method......Page 182 8.3 Partitioned Mutiobjective Risk Method Applied to Power System Planning......Page 184 8.4 Integrating the Social and Economic Impacts in Power System Planning......Page 187 8.5.1 Describing the Methodology for Economic and Social Cost Assessment......Page 188 8.5.2 The CRA Method......Page 190 8.5.3 Data Analysis of the California Crises and of the 2003 U.S. Blackout......Page 191 8.6 Conclusions and Future Work......Page 194 Bibliography......Page 195 9.1 Introduction......Page 199 9.2 Planning Processes......Page 202 9.2.1 Engineering Analyses and Cost Responsibilities......Page 203 9.2.2 Cost Recovery for Transmission Owners......Page 205 9.2.3 Economically Motivated Expansion......Page 206 9.3 Transmission Limits......Page 207 9.4 Decision Support Models......Page 209 9.4.1 Optimization Formulation......Page 210 9.4.2 Planning Transmission Circuits......Page 213 9.4.3 Planning Transmission Control......Page 217 9.4.4 Dynamic Analysis......Page 231 9.5 Market Efficiency and Transmission Investment......Page 237 Bibliography......Page 250 10.1 Introduction......Page 255 10.2.1 Overview of Modules......Page 257 10.2.2 Organization......Page 259 10.3.1 Overview......Page 260 10.3.2 Decision Analysis Tools......Page 261 10.3.3 Selected Methods in Classical Optimization......Page 266 10.3.4 Optimal Control......Page 268 10.3.5 Dynamic Programming (DP)......Page 270 10.3.6 Adaptive Dynamic Programming (ADP)......Page 271 10.3.7 Variants of Adaptive Dynamic Programming......Page 273 10.3.8 Comparison of ADP Variants......Page 276 10.4.1 Overview......Page 278 10.4.2 Framework for Implementation of DSOPF......Page 279 10.4.3 Applications of DSOPF to Power Systems Problems......Page 280 10.5 Grant Challenges in Next Generation Optimization and Research Needs......Page 290 Acknowledgments......Page 291 Bibliography......Page 292 INDEX......Page 295
Discover cutting-edge developments in electric power systems
Stemming from cutting-edge research and education activities in the field of electric power systems, this book brings together the knowledge of a panel of experts in economics, the social sciences, and electric power systems. In ten concise and comprehensible chapters, the book provides unprecedented coverage of the operation, control, planning, and design of electric power systems. It also discusses:
-
A framework for interdisciplinary research and education
-
Modeling electricity markets
-
Alternative economic criteria and proactive planning for transmission investment in deregulated power systems
-
Payment cost minimization with demand bids and partial capacity cost compensations for day-ahead electricity auctions
-
Dynamic oligopolistic competition in an electric power network and impacts of infrastructure disruptions
-
Reliability in monopolies and duopolies
-
Building an efficient, reliable, and sustainable power system
-
Risk-based power system planning integrating social and economic direct and indirect costs
-
Models for transmission expansion planning based on reconfiguration capacitor switching
-
Next-generation optimization for electric power systems
Most chapters end with a bibliography, closing remarks, conclusions, or future work. Economic Market Design and Planning for Electric Power Systems is an indispensable reference for policy-makers, executives and engineers of electric utilities, university faculty members, and graduate students and researchers in control theory, electric power systems, economics, and the social sciences.
Discover cutting-edge developments in electric power systems
Stemming from cutting-edge research and education activities in the field of electric power systems, this book brings together the knowledge of a panel of experts in economics, the social sciences, and electric power systems. In ten concise and comprehensible chapters, the book provides unprecedented coverage of the operation, control, planning, and design of electric power systems. It also discusses:
- A framework for interdisciplinary research and education
- Modeling electricity markets
- Alternative economic criteria and proactive planning for transmission investment in deregulated power systems
- Payment cost minimization with demand bids and partial capacity cost compensations for day-ahead electricity auctions
- Dynamic oligopolistic competition in an electric power network and impacts of infrastructure disruptions
- Reliability in monopolies and duopolies
- Building an efficient, reliable, and sustainable power system
- Risk-based power system planning integrating social and economic direct and indirect costs
- Models for transmission expansion planning based on reconfiguration capacitor switching
- Next-generation optimization for electric power systems
Most chapters end with a bibliography, closing remarks, conclusions, or future work. Economic Market Design and Planning for Electric Power Systems is an indispensable reference for policy-makers, executives and engineers of electric utilities, university faculty members, and graduate students and researchers in control theory, electric power systems, economics, and the social sciences.
Addressing the economic, social, and security aspects of the operation and planning of restructured electric power systems as envisioned by the NSF-ONR EPNES initiative, this book introduces developments in electric power systems operation and control, risk-based power system planning, and electric market design. Design and Planning for Electric Power Systems introduces newdevelopments in electric power systems operation and control, risk-based power system planning, and electric market design,recognizing the importance of the design of robust power networks for sustainable economic growth on a global scale Design and Planning for Electric Power Systems introduces newdevelopments in electric power systems operation & control, risk-based power system planning, & electric market design, recognizing the importance of the design of robust power networks for sustainable economic growth on a global scale