PrefaceCHAPTER 1 COMMON ANALYSIS TOOLS1.1 INTRODUCTION1.2 STEADY-STATE PHASOR CALCULATIONSPower and Reactive Power1.3 STATIONARY MAGNETICALLY-LINEAR SYSTEMSTwo-Winding Transformer1.4 WINDING CONFIGURATIONS1.5 TWO- AND THREE-PHASE STATORSTwo-Phase StatorThree-Phase StatorLine-to-Line Voltage1.6 PROBLEMS1.7 REFERENCECHAPTER 2 ANALYSIS OF THE SYMMETRICAL STATOR2.1 INTRODUCTION2.2 TESLA'S ROTATING MAGNETIC FIELDTwo-Pole Two-Phase StatorTwo-Pole Three-Phase Stator2.3 REFERENCE FRAME THEORYTwo-Phase TransformationThree-Phase Transformation2.4 STATOR VOLTAGE AND FLUX LINKAGE EQUATIONS IN THE ARBITRARY REFERENCE FRAME AND THE INSTANTANEOUS PHASORTwo-Phase StatorThree-Phase StatorInstantaneous and Steady-State Phasors2.5 PROBLEMS2.6 REFERENCESCHAPTER 3 SYMMETRICAL INDUCTION MACHINE3.1 INTRODUCTION3.2 SYMMETRICAL MACHINES3.3 SYMMETRICAL TWO-POLE ROTOR WINDINGSTwo-Phase Rotor WindingsThree-Phase Rotor Windings3.4 SUBSTITUTE VARIABLES FOR SYMMETRICAL ROTATING CIRCUITS AND EQUIVALENT CIRCUITTwo-Phase MachineThree-Phase Machine3.5 ELECTROMAGNETIC FORCE AND TORQUE3.6 P-POLE MACHINES3.7 FREE ACCELERATING VARIABLES VIEWED FROM DIFFERENT REFERENCE FRAMES3.8 STEADY-STATE EQUIVALENT CIRCUIT3.9 PROBLEMS3.10 REFERENCESCHAPTER 4 SYNCHRONOUS MACHINES4.1 INTRODUCTION4.2 ANALYSIS OF THE PERMANENT-MAGNET ac MOTORTorqueUnequal Direct- and Quadrature-Axis InductancesThree-Phase Machine4.3 WINDINGS OF THE SYNCHRONOUS MACHINE4.4 EQUIVALENT CIRCUIT - VOLTAGE AND TORQUE EQUATIONSTorqueRotor Angle4.5 DYNAMIC AND STEADY-STATE PERFORMANCES4.6 ANALYSI OF STEADY-STATE OPERATION4.7 TRANSIENT STABILITYThree-Phase Fault4.8 PROBLEMS4.9 REFERENCECHAPTER 5 DIRECT CURRENT MACHINE AND DRIVE5.1 INTRODUCTION5.2 COMMUTATION5.3 VOLTAGE AND TORQUE EQUATIONS5.4 PERMANENT-MAGNET dc MACHINE5.5 DC DRIVEAverage-Value Time-Domain Block DiagramTorque Control5.6 PROBLEMS5.7 REFERENCECHAPTER 6 BRUSHLESS dc AND FIELD ORIENTED DRIVES6.1 INTRODUCTION6.2 THE BRUSHLESS dc DRIVE CONFIGURATION6.3 COMMON MODE OF BRUSHLESS dc DRIVE OPERATION6.4 OTHER MODES OF BRUSHLESS dc DRIVE OPERATIONMaximum-Torque Per Volt Operation of a Brushless dc DriveMaximum-Torque Per Ampere Operation of a Brushless dc DriveTorque Control6.5 FIELD ORIENTED INDUCTION MOTOR DRIVE6.6 PROBLEMS6.7 REFERENCESCHAPTER 7 SINGLE-PHASE INDUCTION MOTORS7.1 INTRODUCTION7.2 SYMMETRICAL COMPONENTS7.3 ANALYSIS OF UNBALANCED MODES OF OPERATIONUnbalanced Stator VoltagesUnbalanced Stator ImpedancesOpen-Circuited Stator Phase7.4 SINGLE-PHASE AND CAPACITOR-STATOR INDUCTION MOTORSSingle-Phase Induction MotorCapacitor-Start Induction Motor7.5 DYNAMIC AND STEADY-STATE PERFORMANCE OF A CAPACITOR-START SINGLE-PHASE INDUCTION MOTOR7.6 SPLIT-PHASE INDUCTION MOTOR7.7 PROBLEMS7.8 REFERENCESCHAPTER 8 STEPPER MOTORS8.1 INTRODUCTION8.2 BASIC CONFIGURATIONS OF MULTISTACK VARIABLE-RELUCTANCE STEPPER MOTORS8.3 EQUATIONS FOR MULTSTACKVARIABLE-RELUCTANCE STEPPER MOTORS8.4 OPERATING CHARACTERISTICS OF MULTISTACK VARIABLE-RELUCTANCE STEPPER MOTORS8.5 SINGLE-STACK VARIABLE-RELUCTANCE STEPPER MOTORS8.6 BASIC-CONFIGURATION OF PERMANENT-MAGNET STEPPER MOTORS8.7 EQUATIONS FOR PERMANENT-MAGNET STEPPER MOTORS8.8 PROBLEMS8.9 REFERENCES

Paul C. Krause, PhD, started PC Krause and Associates, Inc. in 1983. He was a Professor in the School of Electrical and Computer Engineering at Purdue University for 39 years. He is a Life Fellow of the IEEE and has authored or co-authored over 100 technical papers and three textbooks on electric machines. He was the recipient of the IEEE Nikola Tesla Award in 2010.Thomas C. Krause received the B.S degree in electrical engineering from Purdue University, West Lafayette, IN, USA, in 2019 and the M.S. degree in electrical engineering and computer science from the Massachusetts Institute of Technology, Cambridge, MA, USA, in 2021. He is currently pursuing the PhD degree with the Massachusetts Institute of Technology.