03169nmm a2200313 u 4500001001200000003002700012005001700039007002400056008004100080020001800121100002200139245011800161250001700279260004200296300002700338505100200365653002701367653002701394653001701421653003001438700002801468710003401496041001901530989003801549490006501587856007201652082001001724520112101734EB000629252EBX0100000000000000048233400000000000000.0cr|||||||||||||||||||||140122 ||| eng a97814684549321 aChristensen, G.S.00aOptimal Long-Term Operation of Electric Power SystemshElektronische Ressourcecby G.S. Christensen, S.A. Soliman a1st ed. 1988 aNew York, NYbSpringer USc1988, 1988 a324 pbonline resource0 a1. Introduction -- 1.1. A Historical Survey -- 1.2. Hydro Plant Modeling for Long-Term Operation -- 1.3. Outline of the Book -- 2. Mathematical Optimization Techniques -- 2.1. Introduction -- 2.2. A Review of Matrices -- 2.3. Discrete Variational Calculus -- 2.4. Discrete Maximum Principle -- 2.5. Dynamic Programming -- 2.6. Functional Analysis Optimization Technique -- 3. Long-Term Operation of Reservoirs in Series -- 3.1. Introduction -- 3.2. Problem Formulation -- 3.3. The Problem Solution -- 4. Long-Term Operation of Multichain Power Systems -- 4.1. Introduction -- 4.2. Problem Formulation -- 4.3. The Aggregation Approach (Turgeon Approach) -- 4.4. Discrete Maximum Principle -- 4.5. A Minimum Norm Approach, Linear Model -- 4.6. A Minimum Norm Approach, Nonlinear Model -- 5. Modeling and Optimization of a Multireservoir Power System for Critical Water Conditions -- 5.1. Introduction -- 5.2. Problem Formulation -- 5.3. Nonlinear Storage Model -- 5.4. A Discrete Maximum Principle A aElectrical Engineering aElectrical engineering aOptimization aMathematical optimization1 aSoliman, S.A.e[author]2 aSpringerLink (Online service)07aeng2ISO 639-2 bSBAaSpringer Book Archives -20040 aMathematical Concepts and Methods in Science and Engineering uhttps://doi.org/10.1007/978-1-4684-5493-2?nosfx=yxVerlag3Volltext0 a519.6 aThis book deals with a very important problem in power system planning for countries in which hydrogeneration accounts for the greatest part of the system power production. During the past thirty years many techniques have been developed to cope with the long-term operation of hydro reserÂ voirs. These techniques have been discussed in a number of publications, but they have not until now been documented in book form. This book is intended as the foundation for a special graduate course dealing with aspects of electrical engineering, operational research, water resource research, and applied mathematics. It may also be used for selfÂ study by practicing personnel involved in the planning and operation of hydroelectric power systems for utilities, consulting groups, and government regulatory agencies. The book consists of eight chapters. Chapter 1 reviews the historical developments in the field, discusses briefly all techniques used to solve the problem, and summarizes the modeling of hydroplants for long-term operation studies. At the end of the chapter we present in detail an outline of the book