Efnisyfirlit

• Title Page
• Copyright Page
• Brief Contents
• Contents
• Preface
• List of Videos
• Acknowledgements
• Publisher’s Acknowledgements
• Part 1 ELECTRICAL CIRCUITS AND COMPONENTS
• 1 Basic Electrical Circuits and Components
• 1.1 Introduction
• 1.2 Système International units
• 1.3 Common prefixes
• 1.4 Electrical circuits
• 1.5 Direct current and alternating current
• 1.6 Resistors, capacitors and inductors
• 1.7 Ohm’s law
• 1.8 Kirchhoff’s laws
• 1.9 Power dissipation in resistors
• 1.10 Resistors in series
• 1.11 Resistors in parallel
• 1.12 Resistive potential dividers
• 1.13 Sinusoidal quantities
• 1.14 Circuit symbols
• Further study
• Key points
• Exercises
• 2 Measurement of Voltages and Currents
• 2.1 Introduction
• 2.2 Sine waves
• 2.3 Square waves
• 2.4 Measuring voltages and currents
• 2.5 Analogue ammeters and voltmeters
• 2.6 Digital multimeters
• 2.7 Oscilloscopes
• Further study
• Key points
• Exercises
• 3 Resistance and DC Circuits
• 3.1 Introduction
• 3.2 Current and charge
• 3.3 Voltage sources
• 3.4 Current sources
• 3.5 Resistance and Ohm’s law
• 3.6 Resistors in series and parallel
• 3.7 Kirchhoff’s laws
• 3.8 Thévenin’s theorem and Norton’s theorem
• 3.9 Superposition
• 3.10 Nodal analysis
• 3.11 Mesh analysis
• 3.12 Solving simultaneous circuit equations
• 3.13 Choice of techniques
• Further study
• Key points
• Exercises
• 4 Capacitance and Electric Fields
• 4.1 Introduction
• 4.2 Capacitors and capacitance
• 4.3 Capacitors and alternating voltages and currents
• 4.4 The effect of a capacitor’s dimensions on its capacitance
• 4.5 Electric field strength and electric flux density
• 4.6 Capacitors in series and in parallel
• 4.7 Relationship between voltage and current in a capacitor
• 4.8 Sinusoidal voltages and currents
• 4.9 Energy stored in a charged capacitor
• 4.10 Circuit symbols
• Further study
• Key points
• Exercises
• 5 Inductance and Magnetic Fields
• 5.1 Introduction
• 5.2 Electromagnetism
• 5.3 Reluctance
• 5.4 Inductance
• 5.5 Self-inductance
• 5.6 Inductors
• 5.7 Inductors in series and in parallel
• 5.8 Relationship between voltage and current in an inductor
• 5.9 Sinusoidal voltages and currents
• 5.10 Energy storage in an inductor
• 5.11 Mutual inductance
• 5.12 Transformers
• 5.13 Circuit symbols
• 5.14 The use of inductance in sensors
• Further study
• Key points
• Exercises
• 6 Alternating Voltages and Currents
• 6.1 Introduction
• 6.2 Relationship between voltage and current
• 6.3 Reactance of inductors and capacitors
• 6.4 Phasor diagrams
• 6.5 Impedance
• 6.6 Complex notation
• Further study
• Key points
• Exercises
• 7 Power in AC Circuits
• 7.1 Introduction
• 7.2 Power dissipation in resistive components
• 7.3 Power in capacitors
• 7.4 Power in inductors
• 7.5 Power in circuits with resistance and reactance
• 7.6 Active and reactive power
• 7.7 Power factor correction
• 7.8 Three-phase systems
• 7.9 Power measurement
• Further study
• Key points
• Exercises
• 8 Frequency Characteristics of AC Circuits
• 8.1 Introduction
• 8.2 Two-port networks
• 8.3 The decibel (dB)
• 8.4 Frequency response
• 8.5 A high-pass RC network
• 8.6 A low-pass RC network
• 8.7 A low-pass RL network
• 8.8 A high-pass RL network
• 8.9 A comparison of RC and RL networks
• 8.10 Bode diagrams
• 8.11 Combining the effects of several stages
• 8.12 RLC circuits and resonance
• 8.13 Filters
• 8.14 Stray capacitance and inductance
• Further study
• Key points
• Exercises
• 9 Transient Behaviour
• 9.1 Introduction
• 9.2 Charging of capacitors and energizing of inductors
• 9.3 Discharging of capacitors and de-energising of inductors
• 9.4 Generalised response of first-order systems
• 9.5 Second-order systems
• 9.6 Higher-order systems
• Further study
• Key points
• Exercises
• 10 Electric Motors and Generators
• 10.1 Introduction
• 10.2 A simple AC generator
• 10.3 A simple DC generator
• 10.4 DC generators or dynamos
• 10.5 AC generators or alternators
• 10.6 DC motors
• 10.7 AC motors
• 10.8 Universal motors
• 10.9 Stepper motors
• 10.10 Electrical machines – a summary
• Further study
• Key points
• Exercises
• Part 2 ELECTRONIC SYSTEMS
• 11 Electronic Systems
• 11.1 Introduction
• 11.2 A systems approach to engineering
• 11.3 Systems
• 11.4 System inputs and outputs
• 11.5 Physical quantities and electrical signals
• 11.6 System block diagrams
• Further study
• Key points
• Exercises
• 12 Sensors
• 12.1 Introduction
• 12.2 Describing sensor performance
• 12.3 Temperature sensors
• 12.4 Light sensors
• 12.5 Force sensors
• 12.6 Displacement sensors
• 12.7 Motion sensors
• 12.8 Sound sensors
• 12.9 Sensor interfacing
• 12.10 Sensors – a summary
• Further study
• Key points
• Exercises
• 13 Actuators
• 13.1 Introduction
• 13.2 H eat actuators
• 13.3 Light actuators
• 13.4 Force, displacement and motion actuators
• 13.5 Sound actuators
• 13.6 Actuator interfacing
• 13.7 Actuators – a summary
• Further study
• Key points
• Exercises
• 14 Amplification
• 14.1 Introduction
• 14.2 Electronic amplifiers
• 14.3 Sources and loads
• 14.4 Equivalent circuit of an amplifier
• 14.5 Output power
• 14.6 Power gain
• 14.7 Frequency response and bandwidth
• 14.8 Differential amplifiers
• 14.9 Simple amplifiers
• Further study
• Key points
• Exercises
• 15 Control and Feedback
• 15.1 Introduction
• 15.2 Open-loop and closed-loop systems
• 15.3 Automatic control systems
• 15.4 Feedback systems
• 15.5 Negative feedback
• 15.6 The effects of negative feedback
• 15.7 Negative feedback – a summary
• Further study
• Key points
• Exercises
• 16 Operational Amplifiers
• 16.1 Introduction
• 16.2 An ideal operational amplifier
• 16.3 Some basic operational amplifier circuits
• 16.4 Some other useful circuits
• 16.5 Real operational amplifiers
• 16.6 Selecting component values for op-amp circuits
• 16.7 The effects of feedback on op-amp circuits
• Further study
• Key points
• Exercises
• 17 Semiconductors and Diodes
• 17.1 Introduction
• 17.2 Electrical properties of solids
• 17.3 Semiconductors
• 17.4 pn junctions
• 17.5 Diodes
• 17.6 Semiconductor diodes
• 17.7 Special-purpose diodes
• 17.8 Diode circuits
• Further study
• Key points
• Exercises
• 18 Field-effect Transistors
• 18.1 Introduction
• 18.2 An overview of field-effect transistors
• 18.3 Insulated-gate field-effect transistors
• 18.4 Junction-gate field-effect transistors
• 18.5 FET characteristics
• 18.6 FET amplifiers
• 18.7 Other FET applications
• 18.8 FET circuit examples
• Further study
• Key points
• Exercises
• 19 Bipolar Junction Transistors
• 19.1 Introduction
• 19.2 An overview of bipolar transistors
• 19.3 Bipolar transistor operation
• 19.4 A simple amplifier
• 19.5 Bipolar transistor characteristics
• 19.6 Bipolar amplifier circuits
• 19.7 Bipolar transistor applications
• 19.8 Circuit examples
• Further study
• Key points
• Exercises
• 20 Power Electronics
• 20.1 Introduction
• 20.2 Bipolar transistor power amplifiers
• 20.3 Classes of amplifier
• 20.4 Power amplifiers
• 20.5 Four-layer devices
• 20.6 Power supplies and voltage regulators
• Further study
• Key points
• Exercises
• 21 Internal Circuitry of Operational Amplifiers
• 21.1 Introduction
• 21.2 Bipolar operational amplifiers
• 21.3 CMOS operational amplifiers
• 21.4 BiFET operational amplifiers
• 21.5 BiMOS operational amplifiers
• Further study
• Key points
• Exercises
• 22 Noise and Electromagnetic Compatibility
• 22.1 Introduction
• 22.2 Noise sources
• 22.3 Representing noise sources within equivalent circuits
• 22.4 Noise in bipolar transistors
• 22.5 Noise in FETs
• 22.6 Signal-to-noise ratio
• 22.7 Noise figure
• 22.8 Designing for low-noise applications
• 22.9 Electromagnetic compatibility
• 22.10 Designing for EMC
• Further study
• Key points
• Exercises
• 23 Positive Feedback, Oscillators and Stability
• 23.1 Introduction
• 23.2 Oscillators
• 23.3 Stability
• Further study
• Key points
• Exercises
• 24 Digital Systems
• 24.1 Introduction
• 24.2 Binary quantities and variables
• 24.3 Logic gates
• 24.4 Boolean algebra
• 24.5 Combinational logic
• 24.6 Boolean algebraic manipulation
• 24.7 Algebraic simplification
• 24.8 Karnaugh maps
• 24.9 Automated methods of minimisation
• 24.10 Propagation delay and hazards
• 24.11 Number systems and binary arithmetic
• 24.12 Numeric and alphabetic codes
• 24.13 Examples of combinational logic design
• Further study
• Key points
• Exercises
• 25 Sequential Logic
• 25.1 Introduction
• 25.2 Bistables
• 25.3 Monostables or one-shots
• 25.4 Astables
• 25.5 Timers
• 25.6 Memory registers
• 25.7 Shift registers
• 25.8 Counters
• 25.9 Design of sequential logic circuits
• Further study
• Key points
• Exercises
• 26 Digital Devices
• 26.1 Introduction
• 26.2 Gate characteristics
• 26.3 Logic families
• 26.4 TTL
• 26.5 CMOS
• 26.6 Interfacing TTL and CMOS or logic using different supply voltages
• 26.7 Power dissipation in digital systems
• 26.8 Noise and EMC in digital systems
• Further study
• Key points
• Exercises
• 27 Implementing Digital Systems
• 27.1 Introduction
• 27.2 Array logic
• 27.3 Microprocessors
• 27.4 System-on-a-chip (SOC) devices
• 27.5 Programmable logic controllers (PLCs)
• 27.6 Single-board computers and microcontrollers
• 27.7 Selecting an implementation method
• Further study
• Key points
• Exercises
• 28 Data Acquisition and Conversion
• 28.1 Introduction
• 28.2 Sampling
• 28.3 Signal reconstruction
• 28.4 Data converters
• 28.5 Sample and hold gates
• 28.6 Multiplexing
• Further study
• Key points
• Exercises
• 29 Communications
• 29.1 Introduction
• 29.2 The communications channel
• 29.3 Modulation
• 29.4 Demodulation
• 29.5 Multiplexing
• 29.6 Radio receivers
• 29.7 Microwave communication
• 29.8 Fibre-optic communication
• Further study
• Key points
• Exercises
• 30 System Design
• 30.1 Introduction
• 30.2 Design methodology
• 30.3 Choice of technology
• 30.4 Electronic design tools
• Further study
• Key points
• Exercises
• Appendices A Symbols
• B SI units and prefixes
• C Op-amp circuits
• D Complex numbers
• E Answers to selected exercises
• Index
• A
• B
• C
• D
• E
• F
• G
• H
• I
• J
• K
• L
• M
• N
• O
• P
• Q
• R
• S
• T
• U
• V
• W
• X
• Z