TY - BOOK AU - Glover,J.Duncan AU - Sarma,Mulukutla S. TI - Power system analysis and design. SN - 0534953670 U1 - 621.319 PY - 2002/// CY - Pacific PB - Wadsworth/Thomson Learning KW - ELECTRIC POWER SYSTEMS - DESIGN AND CONSTRUCTION - DATA PROCESSING KW - MICROCOMPUTERS KW - ELECTRIC CIRCUIT ANALYSIS KW - ELECTRICA N2 - The objetive ofthis book is to present methods ofpower system analysis and design, p, ticularly with the aid of a personal computer, in sufficient depth to give tli student the basic theory at the undergraduate level. The approach is designe to develop students' thinking process, enabling them to reach a sound un rstanding of a broad range of topics related to power system engineerh while motivating their interest in the electrical power industry. Because believe that fundamental physical concepts underlie creative engineerin and form the most valuable and permanent part of an engineer-ing educai 'n, we highiight physical concepts while giving due attention to mathemat' ¡I techniques. Both theory and modeling are developed from simple ben .nings so that they can be readily extended to new and complex situations. This ¡ition of the text has four new features: case studies for 12 chap-ters descril ig present-day, practical applications including ampie coverage of the ong( ig restructuring of the electric utility industry; the integration of PowerWori Simulator (PW Simulator), a user-friendiy power system analysis and sim .ition software package, with the text; six design projects including four at e end ofChapter 6, one that begins at the end ofChapter 6 and continúes a he end of Chapters 7 and 9, and one at the end of Chapter 9; and updatec is well as additional problems at the end ofeach chapter. Aiso, in response • a questionnaire sent to a number of power-engineering educa-tors, Symirk ¡cal Components covered in Chapter 3 of the first two editions has been me' d to Chapter 8 in this edition, just befare Unsymmetrical Faults. One o; lie most challenging aspeéis of engineering education is giving students an ;uitive feel for the systems they are studying. Engineering sys-tems are, fo he most part, complex. While paper-and-pencil exercises can be quite use 1 for highiighting the fundamentáis, they often fall short in imparting th desired intuitive insight. To help provide this insight, a CD enclosed witi ihe book contains PW Simulator, which is used to intégrate computer-ba- 1 examples, problems, and design projects throughout the text. PW Sin lator was originally developed at the University of Illinois at Urbana-Cha ;wgn to teach the basics of power systems to nontechnical people invoh in the electricity industry, with versión 1.0 introduced in June 1994. The pr« ram's interactive and graphical design made it an immediate hit as an educational too any size. PW Simulator is now used throughout the power industry, with í range of users encompassing universities, utilities of all sizes, govemmeni regulators, power marketers, and consulting firms. In integrating PW Simulator with the text, our design philosophy ha; been to use the software to extend, rather than replace, the fully worked ex-ampies provided in previous editions. Therefore, except when the problen size makes it impractical, each PW Simulator example includes a fully workec hand solution of the problem along with a PW Simulator case. This formal allows students to simultaneously see the details of how a problem is solvec and a computer implementation of the solution. The added benefit from PW Simulator is its ability to easily extend the example. Through its interactive design, students can quickiy vary example parameters and immediately see the impact such changes ha ve on the solution. By reworking the examples with the new parameters, students get immediate feedback on whether the} understand the solution process. The interactive and visual design of PW Simulator aiso makes it an excellent tool for instructors to use for in-clasi demonstrations. With the many examples and problem cases contained OB the CD, instructors can easily demónstrate many of the text topics. Addi-tional PW Simulator functionality is introduced in the text examples, problems, and design projects. The text is intended to be fully covered in a two-semester or three-quarter course offered to seniors and first-year gradúate students. The orga-nization of chapters and individual sections is flexible enough to give the instructor sufficient latitude in choosing topics to cover, especially in a one-semester course. The text is supported by an ampie number of worked examples covering most of the theoretical points raised. The many problems to be worked with a calculator as well as problems to be worked using a personal computer have been expanded in this edition. As background for this course, it is assumed that students have had courses in electric network theory (including transient analysis) and ordinary differential equations and have been exposed to linear systems, matrix algebra, and computer programming. In addition, it wouid be helpful, but not neces-sary, to have had an electric machines course. After an introduction to the history of electric power systems along with present and future trends, Chapter 2 on fundamentáis orients the students to the terminology and serves as a brief review. The chapter reviews phasor concepts, power, and single-phase as well as three-phase circuits. Chapters 3 through 6 examine power transformers, transmission-line parameters, steady-state operation of transmission lines, and power flows including the Newton-Raphson method. These chapters provide a basic under-standing of power systems under balanced three-phase, steady-state, normal operating conditions. Chapters 7 through 10, which cover symmetrical faults, symmetrical components, unsymmetrical faults, and system protection, come under the general heading of power system short-circuits protection. Chapter 11 is a selfcontained chapter on power systems control, including turbine-generator controls, load frecuency control, economic dispatch, and optimal power flow ER -