Electromagnetic Analysis of Electric Machines: First Principles, Modeling, and Design

Author: James L. Kirtley (Massachusetts Institute of Technology, USA) , Christopher H. T. Lee (Nanyang Technological University, Singapore) , Sajjad Mohammadi (University of Alberta, Canada)
Publisher: John Wiley & Sons Inc
ISBN:

9781394315277

Pages: 320
Publication Date: 04 December 2025
Format: Hardback
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Electromagnetic Analysis of Electric Machines: First Principles, Modeling, and Design

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9781394315277

ISBN 10: 1394315279
Pages: 320
Publication Date: 04 December 2025
Audience: Professional and scholarly , Professional & Vocational
Format: Hardback
Publisher's Status: Active
Availability: Awaiting stock

The supplier is currently out of stock of this item. It will be ordered for you and placed on backorder. Once it does come back in stock, we will ship it out for you.

Forward 1 Motors, Generators and Electromechanics A Introduction B Motors and Generators C Analyticl Modeling for Further Innovations in the Next Generation of electric machines D Analytical Modeling for Design Optimizations E Analytical Modeling for Integrated-Design of Electric Machines, Drives and Other Components F Analytical Modeling for Physics-Informed Artificial Intelligence G Developed in the book 2 Circuits and Field Analysis A Introduction B Electric Circuits B.1 Kirchoff's Current Law B.2 Kirchoff's Voltage Law B.3 Constitutive Relatioship: Ohm's Law C Magnetic Circuit Analogs C.1 Analogy to KCL: Flux Conservation C.2 Analogy to KVL: MMF C.3 Analogy to Ohm's Law: Reluctance D Permanent Magnets D.1 Permanent Magnetization D.2 Magnetic Circuits D.3 Amperian Current D.4 Chu Magnetic Charge E Scalar Potential for Field Analysis E.1 Scalar Porential in Rectangular Coordinates E.2 Scalar Potential in Cylindrical Coordinates F Example: Halbach Magnet Array G Problems for Chapter 2 3 Electromagnetic Fields, Forces and Energy Flow A Introduction B Energy Conversion Processes C Energy Approach to Electromagnetic Forces C.1 Multiply Excited Systems C.2 Coenergy C.3 Example: Simple Solenoid C.4 Synchronous Machine C.5 Current Driven Synchronous Machine C.6 Generalization to Continuous Media C.7 Permanent Magnets D Field Descriptiom of Energy Flows: Poynting's Theorem and Lorentz Force D.1 Rotary Machine: The Faraday Disk and Fields in Motion E Field Description of Force: Maxwell's Stress Tensor E.1 Example: Linear Induction Machine F Surface Impedance and Eddy Currents F.1 Uniform Conductors F.2 Example: The Linear Machine and lImiting Cases G Magnetic Materials G.1 Magnetization G.2 Saturation and Hysteresis G.3 Conduction, Eddy Currents and Laminations G.4 Complete Penetration in a Thin Lamination G.5 Solid Ferromagnetic Material H Semi-Empitical Method of Handling Iron Loss I Problems for Chapter 3 J. References for Chapter 3 4 Design Synthesis, Optimization and Modeling A Introduction B Design Synthesis B.1 Specifications: Requirements and Attributes B.2 Monte Carlo Based Synthesis C The Pareto Surface and Dominance D Design Example: a Single Phase Transformer D.1 Description D.2 Rating D.3 Equivalent Circuit Model D.4 Cost of Losses E Problems fo Chapter 4 F Appendix to Chapter 4: Simple Design Example with Code 5 Synchronous and Brushless DC Machines A Introduction B Current Sheet Description B.1 Continuous Approximation to Winding Patterns C Classical Synchronous Machine Model C.1 Balanced Operation D Operation of motors and generators E Reonciliation of torque angles F Per-Unit Systems F.1 Normal Operation F.2 Capability F.3 Vee Curve G Salient Pole Machines: Two Reaction Theory H Relating Rating to Size H.1 Voltage H.2 Current H.3 Rating H.4 Role of Reactance H.5 Field Winding I Permanent Magnet Synchronous Machines I.1 Surface Magnet Machines I.2 Interior Magnet Machines I.3 Rating I.4 Negatively Salient Machines: Operation J Problemsl for Chapter 5 6 Classical Winding Analysis A Introduction B Physical Description: Windings in Slots C Magnetomotive Force and Flux D Inductance D.1 Winding Factors D.2 Concentric Coils D.3 Examples of Concentric Coils D.4 Concentrated, Partial Pitch Windings D.5 Higher Phase Order D.6 Sequences E Stator Slot Leakage F Problems for Chapter 6 7 Synchronous Machine Dynamic Models A Introduction B Phase Variable Model C Two Reaction Theory C.1 Speed Voltage D Power and Torque E Per-Unit Normalization F Mechanical Dynamics G Equal Mutuals Base H Transient and Subtransient Approximations I Statement of Simulation Model I.1 Statement of Parameters I.2 Example: Balanced Fault Simulation I.3 Linearized Model I.4 Reduced Order Model for Electromechanical Transients I.5 Current Driven Model: Connection to a System I.6 Restatement of The Model I.7 Network Constraints I.8 Example: Line-Line Fault J Permanent Magnet Machines J.1 Model: Voltage Driven Machine J.2 Current Driven Machine J.3 PM Machine with no Damper J.4 Current Driven PM Machines with no Damper K Problemsfor Chapter 7 8 DC (Commutator) Machines A Introduction B Basic Geometry C Torque D Voltage Induction E Voltage Driven Operation F Connections and Capability: Separately Excited G Series Connection H Universal Motors I Commutator I.1 Commutation Process I.2 Compensation J Compound Machines K Problems for Chapter 8 9 Induction Machines A Introduction B Transformer Model C Operation: Energy Balance C.1 Example D Squirrel Cage Machine Model D.1 Squirrel Cage Currents D.2 Squirrel Cage Impedance Elements D.3 Belt Leakage D.4 Zigzag Leakage D.5 Operation: Harmonics Interacctions D.6 Rotor Skew D.7 Stator Leakage Inductances D.8 Sattor Winding Resistance D.9 Rotor End Ring Effects D.10 Deep Rotor Slots D.11 Arbitrary Slot Model D.12 Magnetic Circuit Loss and Excitation D.13 Effective Air-Gap: Carter's Coefficient E Single Phase Induction Motors E.1 Squirrel Cage Model E.2 Winding Factor E.3 Operation E.4 Operation as Affected by Space Harmonics F Problems for Chapter 9 G References for Chapter 9 10 Switched Reluctance Motors A Fundamentals and Operating Principles B Drive Circuitry C Magnetic Equivelant Circuits Using Flux Tubes D Multi-Tooth SRMs E Connected and Modular C-Core SRMs F SRM G Self-Starting Torrque in Two-Phased SRMs H Current Hysteresis Control of SRMs I Problems for Chapter 10 11 Power electronics drives A Introduction B DC Converters B.1 Buck Converter (Step Down) B.2 Boost Converter (Step Up) B.3 Buck-Boost Converters B.4 Applications of DC Converters in Motor Drives C Voltage Source Inverter C.1 Single Phase Half Bridge Inverter C.2 Three Phase Voltage Source Inverters D Current Source Inverter D.1 Single Phase Current Source Inverter D.2 Three Phase Current Source Inverter E Pulse Width Modulation E.1 Fundmemantals of SPWM Technique E.2 Bipolar SPWM Inverter E.3 Unipolar SPWM Inverter E.4 Three Phase SPWM Inverter F Conductidon and Switching Losses F.1 Conduction Loss F.2 MOSFET Switching Power Loss F.3 Gate Charge Loss F.4 Deadtime Power Loss G Problems for Chapter 11 12 Basics of machine control A Introduction B Adjustable Frequency Drive in Induction Motors B.1 Idealized Model: No Stator Reistance B.2 Correction for Stator Resistance C Control and Simulation Models C.1 Induction Machine Model C.2 Idealized Model of Permanent Magnet Synchronous Machine D Position Sensors D.1 Encoder D.2 Resolver E Field Oriented Control E.1 Control Strategy for the Induction Motor E.2 Control Strategy for a Synchronous Machine E.3 Principle of Common Parts E.4 Space Vector Pulse Width Modulation (SVPWM) F Direct Torque Control F.1 Torque and Flux Estimator F.2 Bang-Bang Controller f.3 Voltage Vector Lookup Table G Control System Design G.1 Fundementals of Control System G.2 Phase and Gain Margins, and Crossover Frequencies G.3 Coltrol Loop Deisgn for DC Motors and Actuators G.4 Design Trade-offs of Curent Control Loop H Stability Analysis H.1 Mathematical Foundation H.2 Routh-Hurwitz I Problems J References Totals

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James L. Kirtley is a Professor of Electrical Engineering at the Massachusetts Institute of Technology and a recognized expert in electric machines and power systems. A Member of the National Academy of Engineering, Fellow of IEEE and recipient of the IEEE Nikola Tesla Award, he has decades of research and teaching experience. He is the author of Electric Power Principles. Christopher H. T. Lee is an Associate Professor and Assistant Chair (Research) at the School of Electrical and Electronic Engineering, Nanyang Technological University, Singapore, with expertise in electric machine analysis and renewable energy integration. He has held research positions at Massachusetts Institute of Technology and serves as an Associate Editor for several IEEE journals. He is a Fellow of IET, UK, and recipient of Nagamori Award. Sajjad Mohammadi is an Assistant Professor of Electrical Engineering at the University of Alberta, with expertise in electric machines, power magnetics, and power electronic drives. Previously, he was with Apple Inc. He has received several awards, including the George M. Sprowls Outstanding PhD Thesis Award from MIT, where he earned his PhD.

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Electromagnetic Analysis of Electric Machines: First Principles, Modeling, and Design

9781394315277

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