Electromagnetics for Electrical Machines offers a comprehensive yet accessible treatment of the linear theory of electromagnetics and its application to the design of electrical machines. Leveraging valuable classroom insight gained by the authors during their impressive and ongoing teaching careers, this text emphasizes concepts rather than numerical methods, providing presentation/project problems at the end of each chapter to enhance subject knowledge.
Highlighting the essence of electromagnetic field (EMF) theory and its correlation with electrical machines, this book:
Reviews Maxwell’s equations and scalar and vector potentials
Describes the special cases leading to the Laplace, Poisson’s, eddy current, and wave equations
Explores the utility of the uniqueness, generalized Poynting, Helmholtz, and approximation theorems
Discusses the Schwarz–Christoffel transformation, as well as the determination of airgap permeance
Addresses the skin effects in circular conductors and eddy currents in solid and laminated iron cores
Contains examples relating to the slot leakage inductance of rotating electrical machines, transformer leakage inductance, and theory of hysteresis machines
Presents analyses of EMFs in laminated-rotor induction machines, three-dimensional field analyses for three-phase solid rotor induction machines, and more
Electromagnetics for Electrical Machines makes an ideal text for postgraduate-level students of electrical engineering, as well as of physics and electronics and communication engineering. It is also a useful reference for research scholars concerned with problems involving electromagnetics.