الأربعاء، 27 يناير 2016

Controls

Modern Control Systems

Authors: Richard C. Dorf, Robert H. Bishop

Versions: 12 & 11 editions

Sizes: 12th: 32.5 MB 

            11th: 33.8 MB


Download link (12th): http://sh.st/mYIOU
Solution link (12th): http://sh.st/mYOq5

Download link (11th): http://sh.st/mYLXB 
Solution link (11th): http://sh.st/mYFtr


Overview

Global issues such as climate change, clean water, sustainability, waste management, and energy use have caused many engineers to re-think existing approaches to engineering design. Control systems in green engineering designs have led to products that minimize pollution, reduce the risk to human health, and improve the environment. An example is the use of wireless measurements on a robotic-controlled mobile sensing platform that measure key environmental parameters in a rain forest.

Table of Contents

Preface
About the Authors

Chapter 1 Introduction to Control Systems 1
1.1 Introduction 2
1.2 Brief History of Automatic Control 5
1.3 Examples of Control Systems 10
1.4 Engineering Design 17
1.5 Control System Design 18
1.6 Mechatronic Systems 21
1.7 Green Engineering 25
1.8 The Future Evolution of Control Systems 27
1.9 Design Examples 28
1.10 Sequential Design Example: Disk Drive Read System 32
1.11 Summary 34
Skills Check 35
Exercises 37
Problems 39
Advanced Problems 44
Design Problems 46
Terms and Concepts 48

Chapter 2 Mathematical Models of Systems 49
2.1 Introduction 50
2.2 Differential Equations of Physical Systems 50
2.3 Linear Approximations of Physical Systems 55
2.4 The Laplace Transform 58
2.5 The Transfer Function of Linear Systems 65
2.6 Block Diagram Models 79
2.7 Signal-Flow Graph Models 84
2.8 Design Examples 90
2.9 The Simulation of Systems Using Control Design Software 113
2.10 Sequential Design Example: Disk Drive Read System 128
2.11 Summary 130
Skill Check 131
Exercises 135
Problems 141
Advanced Problems 153
Design Problems 155
Computer Problems 157
Terms and Concepts 159

Chapter 3 State Variable Models 161
3.1 Introduction 162
3.2 The State Variables of a Dynamic System 162
3.3 The State Differential Equation 166
3.4 Signal-Flow Graph and Block Diagram Models 171
3.5 Alternative Signal-Flow Graph and Block Diagram Models 182
3.6 The Transfer Function from the State Equation 187
3.7 The Time Response and the State Transition Matrix 189
3.8 Design Examples 193
3.9 Analysis of State Variable Models Using Control Design Software 206
3.10 Sequential Design Example: Disk Drive Read System 209
3.11 Summary 213
SkillS Check 214
Exercises 217
Problems 220
Advanced Problems 227
Design Problems 230
Computer Problems 231
Terms and Concepts 232

Chapter 4 Feedback Control System Characteristics 234
4.1 Introduction 235
4.2 Error Signal Analysis 237
4.3 Sensitivity of Control Systems to Parameter Variations 239
4.4 Disturbance Signals in a Feedback Control System 242
4.5 Control of the Transient Response 247
4.6 Steady-State Error 250
4.7 The Cost of Feedback 253
4.8 Design Examples 254
4.9 Control System Characteristics Using Control Design Software 268
4.10 Sequential Design Example: Disk Drive Read System 273
4.11 Summary 277
Skills Check 279
Exercises 283
Problems 287
Advanced Problems 293
Design Problems 296
Computer Problems 300
Terms and Concepts 303

Chapter 5 The Performance of Feedback Control Systems 304
5.1 Introduction 305
5.2 Test Input Signals 305
5.3 Performance of Second-Order Systems 308
5.4 Effects of a Third Pole and a Zero on the Second-Order System Response 314
5.5 The s-Plane Root Location and the Transient Response 320
5.6 The Steady-State Error of Feedback Control Systems 322
5.7 Performance Indices 330
5.8 The Simplification of Linear Systems 339
5.9 Design Examples 342
5.10 System Performance Using Control Design Software 356
5.11 Sequential Design Example: Disk Drive Read System 360
5.12 Summary 364
Skills Check 364
Exercises 368
Problems 371
Advanced Problems 377
Design Problems 379
Computer Problems 382
Terms and Concepts 384

Chapter 6 The Stability of Linear Feedback Systems 386
6.1 The Concept of Stability 387
6.2 The Routh-Hurwitz Stability Criterion 391
6.3 The Relative Stability of Feedback Control Systems 399
6.4 The Stability of State Variable Systems 401
6.5 Design Examples 404
6.6 System Stability Using Control Design Software 413
6.7 Sequential Design Example: Disk Drive Read System 421
6.8 Summary 424
Skills Check 425
Exercises 428
Problems 430
Advanced Problems 435
Design Problems 438
Computer Problems 440
Terms and Concepts 442

Chapter 7 The Root Locus Method 443
7.1 Introduction 444
7.2 The Root Locus Concept 444
7.3 The Root Locus Procedure 449
7.4 Parameter Design by the Root Locus Method 467
7.5 Sensitivity and the Root Locus 473
7.6 PID Controllers 480
7.7 Negative Gain Root Locus 492
7.8 Design Examples 496
7.9 The Root Locus Using Control Design Software 510
7.10 Sequential Design Example: Disk Drive Read System 516
7.11 Summary 518
Skills Check 522
Exercises 526
Problems 530
Advanced Problems 539
Design Problems 543
Computer Problems 549
Terms and Concepts 551

Chapter 8 Frequency Response Methods 553
8.1 Introduction 554
8.2 Frequency Response Plots 556
8.3 Frequency Response Measurements 577
8.4 Performance Specifications in the Frequency Domain 579
8.5 Log Magnitude and Phase Diagrams 582
8.6 Design Examples 583
8.7 Frequency Response Methods Using Control Design Software 596
8.8 Sequential Design Example: Disk Drive Read System 602
8.9 Summary 603
Skills Check 608
Exercises 613
Problems 616
Advanced Problems 626
Design Problems 628
Computer Problems 631
Terms and Concepts 633

Chapter 9 Stability in the Frequency Domain 634
9.1 Introduction 635
9.2 Mapping Contours in the s-Plane 636
9.3 The Nyquist Criterion 642
9.4 Relative Stability and the Nyquist Criterion 653
9.5 Time-Domain Performance Criteria in the Frequency Domain 661
9.6 System Bandwidth 668
9.7 The Stability of Control Systems with Time Delays 668
9.8 Design Examples 673
9.9 PID Controllers in the Frequency Domain 691
9.10 Stability in the Frequency Domain Using Control Design Software 692
9.11 Sequential Design Example: Disk Drive Read System 700
9.12 Summary 703
Skills Check 711
Exercises 715
Problems 721
Advanced Problems 731
Design Problems 735
Computer Problems 740
Terms and Concepts 742

Chapter 10 The Design of Feedback Control Systems 743
10.1 Introduction 744
10.2 Approaches to System Design 745
10.3 Cascade Compensation Networks 747
10.4 Phase-Lead Design Using the Bode Diagram 751
10.5 Phase-Lead Design Using the Root Locus 757
10.6 System Design Using Integration Networks 764
10.7 Phase-Lag Design Using the Root Locus 767
10.8 Phase-Lag Design Using the Bode Diagram 772
10.9 Design on the Bode Diagram Using Analytical Methods 776
10.10 Systems with a Prefilter 778
10.11 Design for Deadbeat Response 781
10.12 Design Examples 783
10.13 System Design Using Control Design Software 796
10.14 Sequential Design Example: Disk Drive Read System 802
10.15 Summary 804
Skills Check 806
Exercises 810
Problems 814
Advanced Problems 823
Design Problems 826
Computer Problems 831
Terms and Concepts 833

Chapter 11 The Design of State Variable Feedback Systems 834
11.1 Introduction 835
11.2 Controllability and Observability 835
11.3 Full-State Feedback Control Design 841
11.4 Observer Design 847
11.5 Integrated Full-State Feedback and Observer 851
11.6 Reference Inputs 857
11.7 Optimal Control Systems 859
11.8 Internal Model Design 869
11.9 Design Examples 873
11.10 State Variable Design Using Control Design Software 882
11.11 Sequential Design Example: Disk Drive Read System 888
11.12 Summary 890
Skills Check 890
Exercises 894
Problems 896
Advanced Problems 900
Design Problems 903
Computer Problems 906
Terms and Concepts 908

Chapter 12 Robust Control Systems 910
12.1 Introduction 911
12.2 Robust Control Systems and System Sensitivity 912
12.3 Analysis of Robustness 916
12.4 Systems with Uncertain Parameters 918
12.5 The Design of Robust Control Systems 920
12.6 The Design of Robust PID-Controlled Systems 926
12.7 The Robust Internal Model Control System 932
12.8 Design Examples 935
12.9 The Pseudo-Quantitative Feedback System 952
12.10 Robust Control Systems Using Control Design Software 953
12.11 Sequential Design Example: Disk Drive Read System 958
12.12 Summary 960
Skills Check 961
Exercises 965
Problems 967
Advanced Problems 971
Design Problems 974
Computer Problems 980
Terms and Concepts 982

Chapter 13 Digital Control Systems 984
13.1 Introduction 985
13.2 Digital Computer Control System Applications 985
13.3 Sampled-Data Systems 987
13.4 The z-Transform 990
13.5 Closed-Loop Feedback Sampled-Data Systems 995
13.6 Performance of a Sampled-Data, Second-Order System 999
13.7 Closed-Loop Systems with Digital Computer Compensation 1001
13.8 The Root Locus of Digital Control Systems 1004
13.9 Implementation of Digital Controllers 1008
13.10 Design Examples 1009
13.11 Digital Control Systems Using Control Design Software 1018
13.12 Sequential Design Example: Disk Drive Read System 1023
13.13 Summary 1025
Skill Check 1025
Exercises 1029
Problems 1031
Advanced Problems 1033
Design Problems 1034
Computer Problems 1036
Terms and Concepts 1037

Appendix A Matlab Basics 1038
References 1056
Index 1071
Appendix B MathScript RT Module Basics
Appendix C Symbols, Units, and Conversion Factors
Appendix D Laplace Transform Pairs
Appendix E An Introduction to Matrix Algebra
Appendix F Decibel Conversion
Appendix G Complex Numbers
Appendix H z-Transform Paris Preface
Appendix I Discrete-Time Evaluation of the Time Response

الثلاثاء، 26 يناير 2016

Digital Circuits

Digital Integrated Circuits: Analysis and Design 

Author: John E. Ayers

Version: 1st edition

Size: 10.9 MB



Download link: http://sh.st/mnoEa







Overview

Focusing on underlying principles rather than the details of current technologies that will soon be obsolete, Ayers (University of Connecticut) provides broad coverage of the field of digital integrated circuits for students interested in designing circuits and designing with integrated circuits. Stressing computer tools throughout, with SPICE examples and exercises in every chapter, the book covers principles of digital circuits and their attributes, including bipolar, MESFET, MOS, and BiCMOS circuits, and their manufacture, testing, interfacing, and packaging. Readers are assumed to have a core engineering science background. Annotation ©2004 Book News, Inc., Portland, OR

Table of Contents

1Introduction to Digital Integrated Circuits1
2Semiconductor Materials45
3Diodes61
4Bipolar Junction Transistors89
5Transistor-Transistor Logic115
6Emitter-Coupled Logic207
7Field-Effect Transistors255
8NMOS Logic287
9CMOS Logic321
10Low-Power CMOS Logic391
11BiCMOS Logic423
12GaAs Direct-Coupled FET Logic449
13Interfacing between Digital Logic Circuits481
14Interconnect509
15Bistable Circuits543
16Digital Memories577
17Design and Layout607
18Integrated Circuit Packages635
App. AProperties of Si and GaAs at 300 K663
App. BDesign Rules, Constants, Symbols, and Definitions665
Index673

الاثنين، 25 يناير 2016

Electrical Machines

Brushless Permanent-Magnet Motor Design

Author: Duane C. Hanselman

Version: 2nd edition

size: 70.3 MB



download link: http://sh.st/mkN73







Overview

Written for electrical, electronics, and mechanical engineers responsible for designing and specifying motors, the book provides details of brushless DC and synchronous motors, as well as both radial and axial motor topologies. Beginning with a discussion of the fundamentals of generic motor design, it logically progresses to a set of more advanced, yet easily understandable, concepts for designing brushless permanent-magnet motors. In addition, the author fully explains techniques for magnetic modeling and circuit analysis, shows how magnetic circuit analysis applies to motor design, describes all major aspects of motor operation and design in simple mathematical terms, develops rigourous design equations for radial flux and axial flux motors, and illustrates basic motor drive schemes. All common motor design terms are clearly defined and a wealth of charts, tables and equations are included. 

Table of Contents

Chapter 1 Basic Concepts
1.1 Scope
1.2 Shape
1.3 Torque
1.4 Motor Action
1.5 Magnet Poles and Motor Phases
1.6 Poles, Slots, Teeth, and Yokes
1.7 Mechanical and Electrical Measures
1.8 Motor Size
1.9 Units
1.10 Summary

Chapter 2 Magnetic Modeling
2.1 Magnetic Circuit Concepts
Basic Relationships
Magnetic Field Sources
Air Gap Modeling
Slot Modeling
Example
2.2 Magnetic Materials
Permeability
Ferromagnetic Materials
Core Loss
Permanent Magnets
Permanent Magnet Magnetic Circuit Model
2.3 Example
2.4 Summary

Chapter 3 Electrical and Mechanical Relationships
3.1 Flux Linkage and Inductance
Self inductance 
Mutual Inductance 
Mutual Flux Due to a Permanent Magnet 
3.2 Induced voltage 
Faraday's Law 
Example 
3.3 Energy and Coenergy 
Energy and Coenergy in Singly-Excited Systems 
Energy and Coenergy in Doubly-Excited Systems 
Coenergy in the Presence of a Permanent Magnet 
3.4 Force, Torque and Power 
Basic Relationships 
Fundamental Implications 
Torque From a Macroscopic Viewpoint 
Force From a Microscopic Viewpoint 
Reluctance and Mutual Torque 
Example 
3.5 Summary 

Chapter 4 Brushless Motor Fundamentals 
4.1 Assumptions 
Rotational Motion 
Surface-Mounted Magnets 
4.2 Fundamental Concepts 
Magnetic Circuit Model 
Magnetic Circuit Solution 
Flux Linkage 
Back EMF and Torque 
Multiple Coils 
4.3 Multiple Phases 
4.4 Design Variations 
Fractional Pitch Coils 
Fractional Pitch Magnets 
Fractional Slot Motor 
4.5 Coil Resistance 
4.6 Coil Inductance 
Air Gap Inductance 
Slot Leakage Inductance 
End Turn Inductance 
4.7 Series and Parallel Connections 
4.8 Armature Reaction 
4.9 Slot Constraints 
Slot Fill Factors 
Slot Resistance 
Wire Gage Relationships 
Constancy of Ni 
4.10 Torque Constant, Back EMF Constant, and Motor Constant 
4.11 Torque per Unit Rotor Volume 
4.12 Cogging Torque 
4.13 Summary 

Chapter 5 Motor Design Possibilities 
5.1 Radial Flux Motors 
Inner Rotor 
Outer Rotor 
5.2 Axial Flux Motors 
5.3 Li near Mo tor s 
5.4 Summary 

Chapter 6 Windings 
6.1 Assumptions 
6.2 Coil Span 
6.3 Valid Pole and Slot Combinations 
6.4 Winding Layout 
Example 
Example 
Winding Layout Procedure 
6.5 Coil Connections 
6.6 Winding Factor 
6.7 Inductance Revisited 
Single Tooth Coil Equivalence 
Air Gap Inductance 
Slot Leakage Inductance 
6.8 Summary 

Chapter 7 Magnetic Design
7.1 Air Gap Magnetic Field Distribution
Air Gap Region Solution 
Magnet Region Solution 
Symmetry 
7.2 Influence of Stator Slots 
7.3 Tooth Flux 
7.4 Stator Yoke Flux 
7.5 Influence of Skew 
7.6 Influence of Ferromagnetic Material 
7.7 Back EMF 
7.8 Slotless Motor Construction 
Concentrated Winding 
Sinusoidally-Distributed Winding 
7.9 Summary 

Chapter 8 Electrical Control 
8.1 Fundamentals of Torque Production 
8.2 Brushless DC Motor Drive 
Ideal Torque Production 
Motor Constant
Torque Ripple 
8.3 AC Synchronous Motor Drive 
Ideal Torque Production 
Motor Constant 
Torque Ripple 
8.4 General Drive 
Ideal Torque Production 
Torque Ripple 
Motor Constant 
8.5 Motor Drive Topologies 
Half Bridge 
Full H-Bridge 
Y-Connection 
zl-Connection 
8.6 Summary 

Chapter 9 Performance 
9.1 Motor Constant 
General Sizing 
Motor Constant Maximization 
9.2 Cogging Torque Relationships 
9.3 Radial Force Relationships 
9.4 Core Losses 
Basic Concepts 
Core Loss Modeling 
Application to Motor Design 
Conclusion 
9.5 AC Winding Resistance 
9.6 Summary 

Chapter 10 Examples 
Common Characteristics 
Presented Results 
Notes 
Two Pole Motors 
Four Pole Motors 
Six Pole Motors 
Eight Pole Motors
Ten Pole Motors 
Twelve Pole Motors 
Fourteen Pole Motors 
Sixteen Pole Motors 
Twenty Pole Motors 
Twenty-Four Pole Motors 
Thirty-Two Pole Motors 

Appendix A Fourier Series 
A.l Definition 
A.2 Coefficients 
A.3 Symmetry Properties 
A.4 Mathematical Operations 
Addition 
Scalar Multiplication 
Function Product 
Phase Shift 
Differentiation 
Mean Square Value and RMS 
A.5 Computing Coefficients 
Procedure 
A.6 Summary 

Appendix B Magnetic Field Distributions in Polar Coordinates 
B.l Problem Formulation 
B.2 Polar Coordinate Application 
B.3 Air Gap Region Solution 
B.4 Magnet Region Solution
B.5 Summary 
B.6 Magnetization Profiles 
Radial Magnetization 
Parallel Magnetization 
Radial Sinusoidal Amplitude Magnetization 
Sinusoidal Angle Magnetization 
B.7 Examples 
B.8 Summary 

Appendix C Magnetic Field Distributions in Rectangular Coordinates 
C.l Rectangular Coordinate Application 
Single Magnet and Single Air Gap Case 
Two Magnet, Single Air Gap Case 
One Magnet, Two Air Gap Case 
C.2 Magnetization Profile 
C.3 Summary 

Appendix D Symbols, Units, and Abbreviations 
Appendix E Glossary 
Bibliography
Books 
Articles 
Index 

السبت، 23 يناير 2016

Electrical Machines

 Design of Rotating Electrical Machines

Authors: Juha Pyrhonen, Tapani Jokinen, Valeria Hrabovcova

Version: 1st edition

size: 14.8 MB



Download link: http://sh.st/melsj







Overview

In one complete volume, this essential reference presents an in-depth overview of the theoretical principles and techniques of electrical machine design. This book enables you to design rotating electrical machines with its detailed step-by-step approach to machine design and thorough treatment of all existing and emerging technologies in this field.
Senior electrical engineering students and postgraduates, as well as machine designers, will find this book invaluable. In depth, it presents the following:
  • Machine type definitions; different synchronous, asynchronous, DC, and doubly salient reluctance machines.
  • An analysis of types of construction; external pole, internal pole, and radial flux machines.
  • The properties of rotating electrical machines, including the insulation and heat removal options.
Responding to the need for an up-to-date reference on electrical machine design, this book includes exercises with methods for tackling, and solutions to, real design problems. A supplementary website hosts two machine design examples created with MATHCAD: rotor surface magnet permanent magnet machine and squirrel cage induction machine calculations. Classroom tested material and numerous graphs are features that further make this book an excellent manual and reference to the topic.

Table of Contents

1 Principal Laws and Methods in Electrical Machine Design 1
2 Windings of Electrical Machines 47
3 Design of Magnetic Circuits 153
4 Flux Leakage 225
5 Resistances 255
6 Main Dimensions of a Rotating Machine 281
7 Design Process and Properties of Rotating Electrical Machines 301
8 Insulation of Electrical Machines 429
9 Heat Transfer 457
Appendix A 497
Appendix B 501
Index 503

Electrical Machines

Electric Machinery Fundamentals

Author: Stephen J.chapman 

Version: 5th edition

Size: 37.3 MB


Download link: http://sh.st/meaH2









Overview

Electric Machinery Fundamentals continues to be a best-selling machinery text due to its accessible, student-friendly coverage of the important topics in the field.
In the fifth edition, the use of MATLAB® continues to be incorporated in examples and problems, where applicable. The targeted and thought-provoking problems you've come to appreciate have been retained in this edition.
Chapman continues to share his up-to-date knowledge and experiences in the field in an engaging and understandable style.


Table of Contents

1Introduction to Machinery Principles1
2Transformers56
3Introduction to Power Electronics140
4AC Machinery Fundamentals215
5Synchronous Generators250
6Synchronous Motors324
7Induction Motors357
8DC Machinery Fundamentals448
9DC Motors and Generators506
10Single-Phase and Special-Purpose Motors604
App. AReview of Three-Phase Circuits652
App. BCoil Pitch and Distributed Windings674
App. CSalient-Pole Theory of Synchronous Machines694
App. DTables of Constants and Conversion Factors704
Index705

الأربعاء، 20 يناير 2016

ELECTROMAGNETIC | كهرومغناطيسية

Engineering Electromagnetics

Author: Nathan Ida

Version: 1st edition

Size: 45.6 MB


Download link: http://sh.st/n3QB9






Overview

The book is a comprehensive two semester textbook. It is written with all details of derivations included and all steps in solutions listed. It requires little beyond basic calculus and can be used for self-study. The wealth of examples and alternative explanations makes it approachable by students.

Table of Contents

1Vector algebra1
2Vector calculus57
3Coulomb's law and the electric field121
4Gauss's law and the electric potential173
5Boundary value problems : analytic methods of solution281
6Boundary value problems : numerical (approximate) methods351
7The steady electric current415
8The static magnetic field469
9Magnetic materials and properties523
10Faraday's law and induction629
11Maxwell's equations687
12Electromagnetic waves and propagation725
13Reflection and transmission of plane waves807
14Theory of transmission lines877
15The Smith chart, impedance matching, and transmission line circuits955
16Transients on transmission lines999
17Waveguides and resonators1043
18Antennas and electromagnetic radiation1121