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100   $a20131107d2014      uy             0
101 0 $aeng
135   $aurcnu||||||||
181   $ctxt
182   $cc
183   $acr
200 10$aElectromechanical motion systems $edesign and simulation /$fFrederick G.F. Moritz
210  1$aChichester, England :$cWiley,$d2014.
210  4$dİ2014
215   $a1 online resource (310 p.)
300   $aDescription based upon print version of record.
311   $a1-119-99274-5 
320   $aIncludes bibliographical references at the end of each chapters and index.
327   $aElectromechanical Motion Systems; Contents; Acknowledgements; 1 Introduction; 1.1 Targeted Readership; 1.2 Motion System History; 1.3 Suggested Library for Motion System Design; Reference; 2 Control Theory Overview; 2.1 Classic Differential/Integral Equation Approach; 2.2 LaPlace Transform-the S Domain; 2.3 The Transfer Function; 2.4 Open versus Closed Loop Control; 2.4.1 Transient and Frequency Response; 2.5 Stability; 2.6 Basic Mechanical and Electrical Systems; 2.6.1 Equations and Constants; 2.6.2 Power Test; 2.6.3 Retardation Test; 2.7 Sampled Data Systems/Digital Control; 2.7.1 Sampling
327   $a2.7.2 Quantization 2.7.3 Computational Delay; 2.7.4 System Analysis; References; 3 System Components; 3.1 Motors and Amplifiers; 3.1.1 Review of Motor Theory; 3.1.2 The Brush Motor; 3.1.3 The "H" Drive PWM Amplifier; 3.1.4 The Brushless Motor [2, 3]; 3.1.5 Speed/Torque Curves; 3.1.6 Thermal Effects; 3.1.7 Motor Constant; 3.1.8 Linear Motor [7-10]; 3.1.9 Stepper Motors [12]; 3.1.10 Induction Motors; 3.2 Gearheads; 3.2.1 Spur Gearhead; 3.2.2 Planetary Gearhead; 3.2.3 Hybrid Gearhead; 3.2.4 Worm Gearhead; 3.2.5 Harmonic Gearhead; 3.2.6 Gearhead Sizing - Continuous Operation
327   $a3.2.7 Gearhead Sizing - Intermittent Operation 3.2.8 Axial and Radial Load; 3.2.9 Backlash and Stiffness; 3.2.10 Temperature/Thermal Resistance; 3.2.11 Planetary/Spur Gearhead Comparison; 3.3 Leadscrews and Ballscrews; 3.3.1 Leadscrew Specifications; 3.3.2 Ball Screw Specifications; 3.3.3 Critical Speed; 3.3.4 Column Strength; 3.3.5 Starts, Pitch, Lead; 3.3.6 Encoder Lead; 3.3.7 Accuracy; 3.3.8 Backdrive - Self-Locking; 3.3.9 Assemblies; 3.4 Belt and Pulley; 3.4.1 Belt; 3.4.2 Guidance/Alignment; 3.4.3 Belt and Pulley versus Ball Screw; 3.5 Rack and Pinion; 3.5.1 Design Highlights
327   $a3.5.2 Backlash 3.5.3 Dynamics; 3.6 Clutches and Brakes; 3.6.1 Clutch/Brake Types; 3.6.2 Velocity Rating; 3.6.3 Torque Rating; 3.6.4 Duty Cycle/Temperature Limits; 3.6.5 Timing; 3.6.6 Control; 3.6.7 Brake/System Timing; 3.6.8 Soft Start/Stop; 3.7 Servo Couplings; 3.7.1 Inertia; 3.7.2 Velocity; 3.7.3 Torque; 3.7.4 Compliance; 3.7.5 Misalignment; 3.7.6 Coupling Types; 3.8 Feedback Devices; 3.8.1 Optical Encoders; 3.8.2 Magnetic Encoders; 3.8.3 Capacitive Encoders; 3.8.4 Magnetostrictive/Acoustic Encoders; 3.8.5 Resolvers; 3.8.6 Inductosyn; 3.8.7 Potentiometer; 3.8.8 Tachometers; References
327   $aAdditional Readings 4 System Design; 4.1 Position, Velocity, Acceleration, Jerk, Resolution, Accuracy, Repeatability; 4.1.1 Position; 4.1.2 Velocity; 4.1.3 Acceleration; 4.1.4 Jerk; 4.2 Three Basic Loops - Current/Voltage, Velocity, Position; 4.2.1 Current Voltage Loop; 4.2.2 Velocity Loop; 4.2.3 Position Loop; 4.3 The Velocity Profile; 4.3.1 Preface; 4.3.2 Incremental Motion; 4.3.3 Constant Motion; 4.3.4 Profile Simulation; 4.4 Feed Forward; 4.5 Inertia; 4.5.1 Preface; 4.5.2 Motor Selection; 4.5.3 Reflected Inertia - Gearhead; 4.5.4 Torque versus Optimum Ratio - Gearhead
327   $a4.5.5 Power versus Optimum Ratio - Gearhead
330   $aAn introductory reference covering the devices, simulations and limitations in the control of servo systems  Linking theoretical material with real-world applications, this book provides a valuable introduction to motion system design. The book begins with an overview of classic theory, its advantages and limitations, before showing how classic limitations can be overcome with complete system simulation. The ability to efficiently vary system parameters (such as inertia, friction, dead-band, damping), and quickly determine their effect on performance, stability, efficiency
606   $aServomechanisms
606   $aRobotics
615  0$aServomechanisms.
615  0$aRobotics.
676   $a629.8/323
686   $aTEC046000$2bisacsh
700   $aMoritz$b Frederick G. F$01706528
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910828944503321
996   $aElectromechanical motion systems$94094003
997   $aUNINA