Linear Integrated Circuits

This book provides (a) students with good in-depth and complete study material that is easy to learn and gain mastery of the subject of 'LIC', subscribing fully to university course syllabus and later in their professional career, (b) teaching faculty find complete subject material easy to...

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Detalles Bibliográficos
Autor principal:	Rao, B. Visvesvara (-)
Autor Corporativo:	B. Visvesvara Rao (-)
Formato:	Libro electrónico
Idioma:	Inglés
Publicado:	Noida : Pearson India 2015.
Edición:	1st ed
Colección:	Always learning.
Materias:	Linear integrated circuits > Textbooks.
Ver en Biblioteca Universitat Ramon Llull:	https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009820526706719

Tabla de Contenidos:

Cover
Copyright
Dedication
Contents
Preface
Acknowledgements
About the Author
Chapter 1: Fundamentals of Integrated Circuits
1.1 Introduction
1.2 History
1.3 Introduction to ICs
1.4 Classification of ICs
1.5 Advantages of IC Over Discrete Components
1.6 Basic Concepts of IC Fabrication Using Monolithic IC Technology
1.7 Fabrication Process of a Simple N-type MOSFET
1.8 Basic Structural Details of MOSFET (MOSFET Fabrication in IC Form)
1.9 Semiconductor Diode
1.10 Integrated Circuit (IC) Resistors and Capacitors
1.11 Junction Field Effect Transistor (n-Channel Fet)
1.12 Bipolar Junction Transistor
1.13 Application-specific IC
1.14 IC Assembly and Packaging
1.15 Overview and Interpretation of Data Sheets of Operational Amplifiers
1.16 Device Identification
1.17 Pin Identification and Temperature Ranges
Summary
Questions for Practice
Chapter 2: Fundamentals of Operational Amplifiers
2.1 Introduction
2.2 Introduction to Operational Amplifier
2.3 Block Diagram of an Operational Amplifier
2.4 BJT (Bipolar Junction Transistor) Differential Amplifier
2.5 Different Methods to Improve CMRR of Differential Amplifier
2.6 Basic Building Blocks of an Operational Amplifier
2.7 Analysis of Ideal Operational Amplifier
2.8 Pin Configuration of Operational Amplifiers μA 741 IC
2.9 Schematic Diagram of Operational Amplifier
2.10 Characteristic Features of an Ideal Operational Amplifier
2.11 Common-Mode Rejection Ratio (CMRR)
2.12 Input Bias and Offset Current
2.13 Output Offset Voltage
2.14 Minimization (Elimination) of Output Offset Voltage
2.15 Maximum Ratings of Operational Amplifier
2.16 Frequency Responses of Operational Amplifiers
2.17 Effect of Finite GBP on Integrated Circuits
2.18 Powering OP Amps.
2.19 Slew Rate and Methods of Improving Slew Rate
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 3: Linear Applications of Operational Amplifier
3.1 Introduction
3.2 Operational Amplifier IC
3.3 Sign Changer (Inverting Voltage Amplifier) (Current Shunt Feedback Amplifier)
3.4 Scale Changer
3.5 Non-inverting Amplifier (Current Series Feedback Amplifier)
3.6 Cascaded (Multistage Amplifier) Amplifier
3.7 Difference (Differential) Amplifier
3.8 Instrumentation Amplifier
3.9 Analog Computer to Solve Differential Equations Simulating a System Model
3.10 Four-quadrant Multiplier (IC Multiplier)
3.11 Current-to-voltage Converter (Transresistance Amplifier)
3.12 Voltage-to-current Converter with Floating Load
3.13 Grounded Load Voltage to Current (V-I) Converter
3.14 Sample and Hold Amplifier
3.15 Clipper Circuit
3.16 Clamper Circuit
3.17 Voltage to Frequency and Frequency to Voltage Converter IC
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 4: Non-Linear Applications of OP Amp
4.1 Introduction
4.2 Voltage Comparator
4.3 OP Amp Voltage Comparator
4.4 Different Types of Comparator ICs
4.5 Comparator Applications
4.6 Schmitt Trigger (Regenerative Comparator)
4.7 Inverting Schmitt Trigger
4.8 Wave Shaping of Output Signal Using Adjustable LTP and UTP
4.9 Non-inverting Schmitt Trigger
4.10 Adjustable UTP/LTP Schmitt Trigger
4.11 Multivibrators
4.12 Precision Rectifiers
4.13 Peak Detector Circuits
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 5: Oscillators and Waveform Generators
5.1 Introduction
5.2 Oscillator Fundamentals
5.3 Oscillator Using OP Amp
5.4 RC Phase-shift Oscillator.
5.5 Wien Bridge Oscillator
5.6 High Frequency Oscillator Circuits
5.7 Quadrature Oscillator
5.8 Square Waveform Generator
5.9 Free-running Ramp Waveform Generator
5.10 Triangular Waveform Generator
5.11 Voltage-Controlled Oscillator
5.12 Waveform Generator IC L8038
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 6: 555 Timer and Its Applications
6.1 Introduction
6.2 555 IC Timer
6.3 Astable Multivibrator
6.4 Monostable Multivibrator
6.5 Ramp Generator
6.6 Bistable Mode (Schmitt Trigger) Operation of 555 Timer
6.7 Pulse-Width Modulator (PWM) Circuit
6.8 Pulse-Position Modulator (PPM) Circuit
6.9 Waveform Generator-IC 8038
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 7: Phase-Locked Loop and Its Applications
7.1 Introduction
7.2 Phase-Locked Loop
7.3 Frequency Multiplier (Frequency Synthesizer)
7.4 Analog Frequency Multiplier (AFM)
7.5 Amplitude Modulation Detector
7.6 Frequency Modulation Detector
7.7 Phase Shifter
7.8 Frequency Shift Keying Detector
7.9 Tracking Filter Using Phase-Locked Loop
7.10 Frequency (Signal) Synchronizer
7.11 Digital Phase-Locked Loop (DPLL)
7.12 Software or Discrete Time Signal Based Phase-Locked Loop
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 8: IC Voltage Regulator and DC Power Supply Circuits
8.1 Introduction
8.2 Basic Building Blocks of Linear IC Voltage Regulators
8.3 Series Voltage Regulator Circuit Using Operational Amplifier
8.4 Three-terminal Voltage Regulators (LM 7805 and LM 7905)
8.5 Voltage Regulators (LM 317 and LM 337)
8.6 Dual Power Supply Circuits
8.7 Precision Voltage Regulators
8.8 Switching Regulator and Switched-mode Power Supply.
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 9: Passive and Active Filters
9.1 Introduction
9.2 Concept of Filter Circuit Using Passive 'RCL' Components
9.3 Transfer Function Concept, Analysis, and Design
9.4 First-order Active Filters
9.5 Active Low-pass Butterworth Filter
9.6 Active High-pass Butterworth Filter
9.7 Switched Capacitor Filters
9.8 Active Band-pass Filter
9.9 Active Band Rejection (Stop) Filter
9.10 All-pass Filter
9.11 Multiple Feedback Filters (IGMF Filters)
9.12 State Variable Filters
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 10: Analog to Digital and Digital to Analog Data Converters
10.1 Introduction
10.2 Analog to Digital Data Converters
10.3 Parallel Comparator (Flash) Type Analog to Digital Converter
10.4 Counter or Tracking Type Analog to Digital Converter
10.5 Successive Approximation Type Analog to Digital Converter
10.6 Single Slope Type Analog to Digital Converter
10.7 Dual Slope Type Analog to Digital Converter
10.8 Digital to Analog Conversion Techniques
10.9 Binary Weighted Resistor Type Digital to Analog Converter
10.10 R-2R Ladder with Operational Amplifier Type Digital to Analog Converter
10.11 Inverted R-2R Ladder Digital to Analog Converter
10.12 Digital to Analog Converter with Memory
10.13 IC 1408/1508 Digital to Analog Converter
10.14 Specifications for Integrated Circuits Used in Digital to Analog Converters and Analog to Digital Converters
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 11: Introduction to Digital Integrated Circuits
11.1 Introduction to Integrated Circuits
11.2 Classification of Integrated Circuits
11.3 Classification of Logic Families.
11.4 Standard TTL Nand Gate: Analysis and Characteristics
11.5 Standard TTL Gate Circuit Parameters
11.6 TTL Open-collector Outputs
11.7 Tristate TTL Output Stage
11.8 Metal Oxide Semiconductor (MOS) FET Switches in Logic Gates
Points to Remember
Summary
Questions for Practice
Multiple-choice Questions
Chapter 12: Circuit Design and Simulation Using PSpice®
12.1 Introduction
12.2 PSPICE Workspace and Wiring the Circuit
Index.

Linear Integrated Circuits

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