| Preface |
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xix | |
| Acknowledgment |
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xxi | |
| About the Companion Site |
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xxii | |
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Part I Fundamentals of Electric Drives |
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1 | (162) |
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1 Electric Drives: Introduction And Motivation |
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3 | (18) |
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1-1 The Climate Crisis and the Energy-Saving Opportunities |
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4 | (1) |
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1-2 Energy Savings in Generation of Electricity |
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5 | (1) |
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1-2-1 Energy-Saving Potential in Harnessing of Wind Energy |
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6 | (1) |
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1-3 Energy-Saving Potential in the End-Use of Electricity |
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6 | (4) |
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1-3-1 Energy-Saving Potential in the Process Industry |
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7 | (1) |
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1-3-2 Energy-Saving Potential in the Residential and Commercial Sectors |
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8 | (2) |
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1-4 Electric Transportation |
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10 | (1) |
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1-5 Precise Speed and Torque Control Applications in Robotics, Drones, and the Process Industry |
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10 | (1) |
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1-6 Range of Electric Drives |
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11 | (1) |
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1-7 The Multidisciplinary Nature of Drive Systems |
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12 | (3) |
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1-8 Use of Simulation and Hardware Prototyping |
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15 | (1) |
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1-9 Structure of the Textbook |
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16 | (1) |
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17 | (1) |
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18 | (1) |
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18 | (1) |
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18 | (3) |
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2 Understanding Mechanical System Requirements For Electric Drives |
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21 | (30) |
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21 | (2) |
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2-2 Systems with Linear Motion |
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23 | (2) |
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25 | (8) |
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33 | (2) |
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35 | (1) |
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36 | (3) |
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39 | (4) |
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2-7-1 Conversion Between Linear and Rotary Motion |
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39 | (2) |
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41 | (2) |
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43 | (1) |
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2-9 Four-Quadrant Operation |
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44 | (1) |
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2-10 Steady-State and Dynamic Operations |
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45 | (1) |
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45 | (1) |
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45 | (1) |
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46 | (1) |
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46 | (5) |
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3 Basic Concepts In Magnetics And Electromechanical Energy Conversion |
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51 | (44) |
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51 | (1) |
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3-2 Magnetic Circuit Concepts |
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52 | (1) |
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3-3 Magnetic Field Produced by Current-Carrying Conductors |
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52 | (2) |
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52 | (2) |
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3-4 Flux Density B and the Flux φ |
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54 | (4) |
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3-4-1 Ferromagnetic Materials |
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54 | (2) |
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56 | (1) |
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57 | (1) |
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3-5 Magnetic Structures with air Gaps |
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58 | (3) |
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61 | (2) |
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3-7 Magnetic Energy Storage in Inductors |
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63 | (2) |
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3-8 Faraday's Law: Induced Voltage in a Coil due to Time-Rate of Change of Flux Linkage |
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65 | (3) |
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3-8-1 Relating e(t), φ (t), and i(t) |
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67 | (1) |
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3-9 Leakage and Magnetizing Inductances |
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68 | (3) |
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71 | (1) |
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3-11 Basic Principles of Torque Production and Voltage Induction |
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71 | (13) |
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3-11-1 Basic Structure of ac Machines |
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71 | (2) |
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3-11-2 Production of Magnetic Field |
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73 | (3) |
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3-11-3 Basic Principles of Torque Production and EMF Induction |
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76 | (4) |
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3-11-4 Application of the Basic Principles |
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80 | (1) |
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81 | (2) |
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3-11-6 Power Losses and Energy Efficiency |
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83 | (1) |
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84 | (3) |
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84 | (2) |
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3-12-2 Electromechanical Energy Conversion |
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86 | (1) |
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87 | (1) |
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87 | (8) |
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4 Basic Understanding Of Switch-Mode Power Electronic Converters |
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95 | (34) |
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95 | (1) |
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4-2 Overview of Power Electronic Converters |
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95 | (9) |
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4-2-1 Switch-Mode Conversion: Switching Power-Pole as the Building Block |
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97 | (1) |
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4-2-2 PWM of the Switching Power-Pole (Constant fs) |
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98 | (1) |
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4-2-3 Bidirectional Switching Power-Pole |
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99 | (2) |
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4-2-4 PWM of the Bidirectional Switching Power-Pole |
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101 | (3) |
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4-3 Converters for dc Motor Drives (-- Vd < vo < Vd) |
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104 | (8) |
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4-3-1 Switching Waveforms in a Converter for dc Motor Drives |
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108 | (4) |
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4-4 Synthesis of Low-Frequency ac |
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112 | (1) |
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4-5 Three-Phase Inverters |
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113 | (5) |
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4-5-1 Switching Waveforms in a Three-Phase Inverter with Sine-PWM |
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117 | (1) |
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4-6 Power Semiconductor Devices |
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118 | (4) |
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119 | (1) |
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119 | (1) |
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4-6-3 Controllable Switches |
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120 | (1) |
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4-6-4 "Smart Power" Modules Including Gate Drivers and Wide Bandgap Devices |
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121 | (1) |
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4-7 Hardware Prototyping of PWM |
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122 | (2) |
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124 | (1) |
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125 | (1) |
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125 | (1) |
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126 | (3) |
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5 Control In Electric Drives |
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129 | (34) |
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129 | (1) |
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130 | (4) |
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5-2-1 Requirements Imposed by dc Machines on the PPU |
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134 | (1) |
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5-3 Designing Feedback Controllers for Motor Drives |
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134 | (9) |
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134 | (5) |
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5-3-2 Cascade Control Structure |
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139 | (1) |
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5-3-3 Steps in Designing the Feedback Controller |
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139 | (1) |
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5-3-4 System Representation for Small-Signal Analysis |
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140 | (3) |
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143 | (11) |
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5-4-1 Proportional-Integral Controllers |
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143 | (2) |
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5-4-2 Example of a Controller Design |
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145 | (6) |
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5-4-3 The Design of the Position Control Loop |
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151 | (3) |
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5-5 The Role of Feed-Forward |
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154 | (1) |
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154 | (1) |
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5-7 Anti-Windup (Non-Windup) Integration |
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155 | (1) |
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5-8 Hardware Prototyping of dc Motor Speed Control |
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156 | (1) |
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157 | (1) |
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158 | (1) |
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159 | (1) |
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159 | (4) |
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Part II Steady-State Operation of ac Machines |
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163 | (152) |
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6 Using Space Vectors To Analyze Ac Machines |
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165 | (38) |
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165 | (1) |
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6-2 Sinusoidally Distributed Stator Windings |
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166 | (9) |
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6-2-1 Three-Phase, Sinusoidally Distributed Stator Windings |
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173 | (2) |
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6-3 The Use of Space Vectors to Represent Sinusoidal Field Distributions in the Air Gap |
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175 | (5) |
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6-4 Space-Vector Representation of Combined Terminal Currents and Voltages |
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180 | (6) |
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6-4-1 Physical Interpretation of the Stator Current Space Vector rarr;is(t) |
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181 | (3) |
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6-4-2 Phase Components of Space Vectors →is(t) and →is(t) |
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184 | (2) |
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6-5 Balanced Sinusoidal Steady-State Excitation (Rotor Open-Circuited) |
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186 | (11) |
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6-5-1 Rotating Stator MMF Space Vector |
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187 | (2) |
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6-5-2 Rotating Stator MMF Space Vector in Multipole Machines |
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189 | (2) |
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6-5-3 The Relationship Between Space Vectors and Phasors in Balanced Three-Phase Sinusoidal Steady State (→vs|t = 0 ↔ Va and →ims|t = 0 ↔ Ima) |
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191 | (2) |
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6-5-4 Induced Voltages in Stator Windings |
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193 | (4) |
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197 | (2) |
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199 | (1) |
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199 | (1) |
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199 | (4) |
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7 Space Vector Pulse-Width-Modulated (Sv-Pwm) Inverters |
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203 | (14) |
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203 | (1) |
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7-2 Synthesis of Stator Voltage Space Vector →a vs |
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203 | (5) |
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7-3 Computer Simulation of SV-PWM Inverter |
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208 | (3) |
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7-4 Limit on the Amplitude Vs of the Stator Voltage Space Vector →a vs |
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211 | (2) |
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7-5 Hardware Prototyping of Space Vector Pulse Width Modulation |
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213 | (1) |
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214 | (1) |
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214 | (1) |
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214 | (1) |
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214 | (3) |
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8 Sinusoidal Permanent-Magnet Ac (Pmac) Drives In Steady State |
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217 | (24) |
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217 | (2) |
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8-2 The Basic Structure of PMAC MACHINES |
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219 | (1) |
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8-3 Principle of Operation |
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219 | (14) |
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8-3-1 Rotor-Produced Flux-Density Distribution |
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219 | (1) |
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220 | (4) |
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8-3-3 Mechanical System of PMAC Drives |
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224 | (1) |
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8-3-4 Calculation of the Reference Values i*a(t), i*b(t), and i*c(t) of the Stator Currents |
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225 | (3) |
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8-3-5 Induced EMFs in the Stator Windings During Balanced Sinusoidal Steady State |
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228 | (5) |
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8-3-6 Generator-Mode of Operation of PMAC Drives |
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233 | (1) |
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8-4 The Controller and the PPU |
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233 | (2) |
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8-5 Hardware Prototyping of PMAC Motor Hysteresis Current Control |
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235 | (3) |
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238 | (1) |
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239 | (1) |
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239 | (1) |
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239 | (2) |
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9 Induction Motors In Sinusoidal Steady-State |
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241 | (44) |
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241 | (1) |
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9-2 The Structure of Three-Phase, Squirrel-Cage Induction Motors |
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241 | (1) |
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9-3 The Principles of Induction Motor Operation |
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242 | (28) |
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9-3-1 Electrically Open-Circuited Rotor |
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243 | (2) |
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9-3-2 The Short-Circuited Rotor |
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245 | (20) |
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9-3-3 Per-Phase Steady-State Equivalent Circuit (Including Rotor Leakage) |
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265 | (5) |
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9-4 Tests to Obtain the Parameters of the Per-Phase Equivalent Circuit |
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270 | (2) |
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9-4-1 dc-Resistance Test to Estimate Rs |
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270 | (1) |
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9-4-2 The No-Load Test to Estimate Lm |
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271 | (1) |
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9-4-3 Blocked-Rotor Test to Estimate R'r and the Leakage Inductances |
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272 | (1) |
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9-5 Induction Motor Characteristics at Rated Voltages in Magnitude and Frequency |
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272 | (3) |
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9-6 Induction Motors of Nema Design A, B, C, and D |
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275 | (2) |
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277 | (1) |
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9-8 Hardware Prototyping of Induction Motor Parameter Estimation |
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277 | (1) |
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278 | (3) |
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281 | (1) |
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281 | (1) |
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281 | (4) |
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10 Induction-Motor Drives: Speed Control |
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285 | (30) |
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285 | (1) |
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10-2 Conditions for Efficient Speed Control Over a Wide Range |
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286 | (5) |
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10-3 Applied Voltage Amplitudes to Keep Bms = Bms, rated |
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291 | (5) |
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10-4 Starting Considerations in Drives |
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296 | (2) |
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10-5 Capability to Operate Below and Above the Rated Speed |
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298 | (3) |
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10-5-1 Rated Torque Capability Below the Rated Speed (With Bms, rated) |
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299 | (1) |
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10-5-2 Rated Power Capability Above the Rated Speed by Flux-Weakening |
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300 | (1) |
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10-6 Induction-Generator Drives |
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301 | (1) |
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10-7 Speed Control of Induction-Motor Drives |
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302 | (3) |
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10-7-1 Limiting of Acceleration/Deceleration |
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303 | (1) |
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303 | (1) |
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304 | (1) |
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304 | (1) |
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10-8 Pulse-Width-Modulated PPU |
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305 | (1) |
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10-9 Harmonics in the PPU Output Voltages |
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305 | (3) |
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10-9-1 Modeling the PPU-Supplied Induction Motors in Steady State |
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308 | (1) |
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10-10 Reduction of Bms at Light Loads |
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308 | (1) |
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10-11 Hardware Prototyping of Closed-Loop Speed Control of Induction Motor |
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309 | (3) |
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10-12 Summary/Review Questions |
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312 | (1) |
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313 | (1) |
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313 | (1) |
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314 | (1) |
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Part III Vector Control of ac Machines |
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315 | (108) |
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11 Induction Machine Equations In Phase Quantities: Assisted By Space Vectors |
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317 | (24) |
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317 | (1) |
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11-2 Sinusoidally Distributed Stator Windings |
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318 | (2) |
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11-2-1 Three-Phase, Sinusoidally Distributed Stator Windings |
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319 | (1) |
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11-3 Stator Inductances (Rotor Open-Circuited) |
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320 | (4) |
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11-3-1 Stator Single-Phase Magnetizing Inductance Lm, one-phase |
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320 | (2) |
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11-3-2 Stator Mutual-Inductance Lmutual |
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322 | (1) |
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11-3-3 Per-Phase Magnetizing-Inductance Lm |
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323 | (1) |
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11-3-4 Stator-Inductance Ls |
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324 | (1) |
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11-4 Equivalent Windings in a Squirrel-Cage Rotor |
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324 | (2) |
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11-4-1 Rotor-Winding Inductances (Stator Open-Circuited) |
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325 | (1) |
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11-5 Mutual Inductances Between the Stator and the Rotor Phase Windings |
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326 | (1) |
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11-6 Review of Space Vectors |
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327 | (3) |
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11-6-1 Relationship Between Phasors and Space Vectors in Sinusoidal Steady State |
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329 | (1) |
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330 | (3) |
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11-7-1 Stator Flux Linkage (Rotor Open-Circuited) |
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330 | (1) |
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11-7-2 Rotor Flux Linkage (Stator Open-Circuited) |
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331 | (1) |
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11-7-3 Stator and Rotor Flux Linkages (Simultaneous Stator and Rotor Currents) |
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332 | (1) |
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11-8 Stator and Rotor Voltage Equations in Terms of Space Vectors |
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333 | (1) |
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11-9 Making a Case for a dq-Winding Analysis |
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334 | (4) |
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338 | (1) |
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339 | (2) |
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12 Dynamic Analysis Of Induction Machines In Terms Of Dq-Windings |
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341 | (36) |
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341 | (1) |
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12-2 dq-Winding Representation |
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341 | (6) |
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12-2-1 Stator dq-Winding Representation |
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342 | (3) |
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12-2-2 Rotor dq-Windings (Along the Same dq-Axes as in the Stator) |
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345 | (1) |
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12-2-3 Mutual Inductance Between dg-Windings on the Stator and the Rotor |
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346 | (1) |
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12-3 Mathematical Relationships of the dq-Windings (at an Arbitrary Speed ωd) |
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347 | (8) |
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12-3-1 Relating dq-Winding Variables to Phase Winding Variables |
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349 | (1) |
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12-3-2 Flux Linkages of dq-Windings in Terms of Their Currents |
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350 | (1) |
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12-3-3 dq-Winding Voltage Equations |
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351 | (4) |
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12-3-4 Obtaining Fluxes and Currents with Voltages as Inputs |
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355 | (1) |
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12-4 Choice of the dq-Winding Speed ωd |
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355 | (2) |
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12-5 Electromagnetic Torque |
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357 | (3) |
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12-5-1 Torque on the Rotor d-Axis Winding |
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357 | (1) |
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12-5-2 Torque on the Rotor q-Axis Winding |
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358 | (1) |
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12-5-3 Net Electromagnetic Torque Tem on the Rotor |
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359 | (1) |
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360 | (1) |
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12-7 d- and q-Axis Equivalent Circuits |
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360 | (1) |
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12-8 Relationship Between the dq-Windings and the Per-Phase Phasor-Domain Equivalent Circuit in Balanced Sinusoidal Steady State |
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361 | (2) |
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363 | (2) |
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12-9-1 Calculation of Initial Conditions |
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364 | (1) |
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365 | (8) |
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373 | (1) |
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373 | (1) |
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373 | (2) |
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375 | (2) |
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13 Mathematical Description Of Vector Control In Induction Machines |
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377 | (24) |
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377 | (1) |
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13-2 Motor Model With the d-Axis Aligned Along the Rotor Flux Linkage →λr-Axis |
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378 | (6) |
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13-2-1 Calculation of ωdA |
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379 | (1) |
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13-2-2 Calculation of Tem |
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380 | (1) |
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13-2-3 d-Axis Rotor Flux-Linkage Dynamics |
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380 | (1) |
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381 | (3) |
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384 | (9) |
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13-3-1 Speed and Position Control Loops |
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385 | (3) |
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388 | (1) |
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13-3-3 Calculating the Stator Voltages to be Applied |
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388 | (3) |
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13-3-4 Designing the PI Controllers |
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391 | (2) |
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13-4 Hardware Prototyping of Vector Control of Induction Motor |
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393 | (5) |
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398 | (1) |
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398 | (1) |
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399 | (2) |
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14 Speed-Sensorless Vector Control Of Induction Motor |
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401 | (22) |
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401 | (1) |
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14-2 Open-Loop Speed Estimator |
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402 | (2) |
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14-3 Model-Reference Adaptive System (MRAS) Estimator |
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404 | (12) |
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14-3-1 Rotor Speed Estimation |
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407 | (3) |
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14-3-2 Stator d- and q-Axis Current Reference |
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410 | (1) |
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14-3-3 Estimation of ωdA and θda |
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411 | (3) |
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14-3-4 Designing the PI controller |
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414 | (2) |
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14-4 Parameter Sensitivity of Open-Loop Estimator and MRAS Estimator |
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416 | (1) |
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14-5 Practical Implementation |
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417 | (4) |
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421 | (1) |
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422 | (1) |
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423 | (1) |
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423 | (1) |
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423 | (46) |
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14-A-1 MRAS Linearized Error Function |
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423 | (4) |
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15 Analysis Of Doubly Fed Generators (Dfigs) In Steady State And Their Vector Control |
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427 | (26) |
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427 | (3) |
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15-2 Steady-State Analysis |
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430 | (6) |
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15-3 Understanding DFIG Operation in dq Axis |
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436 | (7) |
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437 | (1) |
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15-3-2 Flux Linkages and Currents |
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437 | (1) |
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438 | (1) |
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15-3-4 Stator and Rotor Power Inputs |
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438 | (1) |
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15-3-5 Electromagnetic Torque |
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439 | (1) |
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15-3-6 Relationships of Stator and Rotor Real and Reactive Powers |
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439 | (4) |
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15-4 Dynamic Analysis of DFIG |
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443 | (1) |
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15-5 Vector Control of DFIG |
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443 | (6) |
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15-5-1 Rotor Current Controller |
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443 | (2) |
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15-5-2 Rotor Speed Controller |
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445 | (1) |
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15-5-3 Stator Reactive Power Controller |
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446 | (1) |
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15-5-4 Rotor Position Estimator |
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446 | (3) |
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449 | (1) |
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450 | (1) |
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450 | (1) |
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450 | (3) |
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16 Direct Torque Control (Dtc) And Encoder-Less Operation Of Induction Motor Drives |
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453 | (16) |
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453 | (1) |
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453 | (2) |
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16-3 Principle of Encoder-Less DTC Operation |
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455 | (1) |
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16-4 Calculation of →λs, →λr, Tem, and ωm |
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456 | (4) |
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16-4-1 Calculation of the Stator Flux →λs |
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456 | (1) |
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16-4-2 Calculation of the Rotor Flux →λr |
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456 | (2) |
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16-4-3 Calculation of the Electromagnetic Torque Tem |
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458 | (1) |
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16-4-4 Calculation of the Rotor Speed ωm |
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459 | (1) |
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16-5 Calculation of the Stator Voltage Space Vector |
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460 | (4) |
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16-6 Direct Torque Control Using dq-Axes |
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464 | (1) |
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464 | (3) |
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467 | (1) |
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467 | (1) |
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468 | (1) |
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468 | (1) |
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469 | (29) |
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16-A-1 Derivation of Torque Expressions |
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469 | (4) |
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17 Vector Control Of Permanent-Magnet Synchronous Motor Drives |
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473 | (25) |
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473 | (1) |
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17-2 dq-Analysis of Permanent-Magnet Synchronous Machines |
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473 | (4) |
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475 | (1) |
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17-2-2 Stator dq-Winding Voltages |
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475 | (1) |
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17-2-3 Electromagnetic Torque |
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476 | (1) |
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476 | (1) |
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17-3 Non-Salient Pole Synchronous Machines |
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477 | (4) |
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17-3-1 Relationship Between the dq Circuits and the Per-Phase Phasor-Domain Equivalent Circuit in Balanced Sinusoidal Steady State |
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477 | (1) |
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17-3-2 dq-Based Dynamic Controller for "Brush-less dc" Drives |
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478 | (3) |
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17-4 Salient-Pole Synchronous Machines |
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481 | (14) |
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17-4-1 Rotor Position Estimation Using High-Frequency Injection |
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483 | (3) |
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17-4-2 Speed-Sensorless Dynamic Controller for IPM Motor |
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486 | (2) |
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17-4-3 Designing PID Controller |
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488 | (3) |
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17-4-4 Electromagnetic Torque |
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491 | (4) |
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17-5 Hardware Prototyping of Vector Control of SPM Synchronous Motor |
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495 | (1) |
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495 | (2) |
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497 | (1) |
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498 | (1) |
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498 | (29) |
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17-A-l Transformation of Stator Flux-Linkage From Rotating dq Frame to Stationary Frame |
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498 | (3) |
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18 Reluctance Drives: Stepper-Motors And Switched-Reluctance Drives |
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501 | (26) |
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501 | (1) |
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18-2 The Operating Principle of Reluctance Motors |
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502 | (4) |
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18-3 Stepper-Motor Drives |
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506 | (8) |
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18-3-1 Variable-Reluctance Stepper-Motors |
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506 | (1) |
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18-3-2 Permanent-Magnet Stepper-Motors |
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507 | (2) |
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18-3-3 Hybrid Stepper-Motors |
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509 | (2) |
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18-3-4 Equivalent-Circuit Representation of a Stepper-Motor |
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511 | (1) |
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18-3-5 Half-Stepping and Micro-Stepping |
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512 | (1) |
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18-3-6 Power Electronic Converters for Stepper-Motors |
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513 | (1) |
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514 | (4) |
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18-4-1 Switched-Reluctance Motor |
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514 | (1) |
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18-4-2 Electromagnetic Torque Tem |
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515 | (3) |
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18-4-3 Induced Back-EMF ea |
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518 | (1) |
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18-5 Instantaneous Waveforms |
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518 | (3) |
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18-6 Role of Magnetic Saturation |
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|
521 | (1) |
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18-7 Power Electronic Converters for SRM Drives |
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522 | (1) |
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18-8 Determining the Rotor Position for Encoder-LESS Operation |
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523 | (1) |
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18-9 Control in Motoring Mode |
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523 | (1) |
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18-10 Summary/Review Questions |
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524 | (1) |
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525 | (1) |
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525 | (1) |
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525 | (2) |
| Index |
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527 | |
