Introduction to Analog and Digital Communication.
This book primarily focuses on the design of analog and digital communication systems; and has been structured to cater to the second year engineering undergraduate students of Computer Science, Information Technology, Electrical Engineering and Electronics and Communication departments. For better...
Clasificación: | Libro Electrónico |
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Autor principal: | |
Otros Autores: | , |
Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
Aalborg :
River Publishers,
2016.
©2016 |
Colección: | River Publishers series in communications.
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Temas: | |
Acceso en línea: | Texto completo Texto completo |
Tabla de Contenidos:
- Cover; Half Title Page; River Publishers Series Page; Title Page
- Introduction to Analog and Digital Communication; Copyright Page; Contents; Preface; Acknowledgments; List of Figures; List of Tables; List of Abbreviations; PART I
- Analog Communication; Chapter 1
- Analog Modulation; 1.1 Introduction; 1.1.1 Types of Signals; 1.2 Types of Communication; 1.2.1 Basic Blocks of Communication Systems; 1.2.2 Detailed View of Communication Systems; 1.3 Need for Modulation; 1.4 Modulation; 1.4.1 Amplitude Modulation; 1.4.1.1 Modulation index (m); 1.5 Modulation of Complex Modulating Signal.
- 1.6 Importance of Modulation Index1.6.1 Depth of Modulation or Percent Modulation; 1.6.2 Transmission Efficiency of AM Modulation; 1.6.3 AM Power Calculation; 1.6.4 DSB-SC-Double Sideband Suppressed Carrier; 1.6.5 SSB-Single Sideband Modulation; 1.6.6 VSB-Vestigial Sideband Modulation; 1.7 Comparison of Various AM Modulation Technique; 1.8 Solved Problems; 1.3 Need for Modulation; Chaper 2
- Angle Modulation; 2.1 Mathematical Analysis; 2.1.1 Bandwidth Calculation of FM; 2.1.2 Types of FM; 2.2 Mathematical Analysis of PM; 2.3 Noises; 2.3.1 Types of Internal Noises; 2.4 Solved Problems.
- 2.5 Points to RememberPART II
- Digital Communication; Chapter 3
- Digital Modulation; 3.1 Introduction; 3.2 Binary Modulation Techniques; 3.2.1 Amplitude Shift Keying; 3.2.2 Mathematical Representation; 3.2.3 Signal Space Representation or Constellation Diagram; 3.2.4 Probability of Error; 3.2.5 ASK Generation; 3.2.6 ASK Reception or Demodulation; 3.3 Phase Shift Keying; 3.3.1 Mathematical Representation; 3.3.2 Signal Space Representation of PSK; 3.3.3 Probability of Error; 3.3.4 PSK Generation; 3.3.5 PSK Reception; 3.4 Frequency Shift Keying; 3.4.1 Mathematical Representation.
- 3.4.2 Signal Space Representation of FSK3.4.3 Probability of Error; 3.4.4 FSK Generation; 3.4.5 FSK Reception; 3.5 Comparison of Binary Modulation Techniques; 3.6 Quadrature Phase Shift Keying; 3.6.1 Mathematical Representation; 3.6.2 Signal Space Representation; 3.6.3 Probability of Error; 3.6.4 QPSK Generation; 3.6.5 QPSK Reception; 3.7 Minimum Shift Keying; 3.7.1 Mathematical Representation; 3.7.2 Signal Space Representation; 3.7.3 Probability of Error; 3.7.4 MSK Generation; 3.7.5 MSK Demodulation; 3.8 M-ary Modulation Techniques; 3.8.1 M-ASK; 3.9 M-PSK; 3.9.1 Mathematical Representation.
- 3.9.2 Receiver Circuit for M-PSK3.10 M-QAM; 3.10.1 M-ary QAMTransmitter; 3.10.2 M-ary QAM Receiver; 3.11 M-FSK; 3.12 Comparison of Various M-ary Modulation Techniques; 3.13 Points to Remember; PART III
- Pulse and Data Communication; Chapter 4
- Pulse Modulation; 4.1 Introduction; 4.2 Pulse Amplitude Modulation; 4.2.1 Generation of PAM Signals/Sampling Process; 4.2.2 Detection of PAM Signal; 4.3 Pulse Width Modulation; 4.3.1 Generation of PWM Signal; 4.3.2 Detection of PWM; 4.4 Pulse Position Modulation; 4.4.1 Generation of PPM; 4.4.2 Detection of PPM; 4.5 Pulse Code Modulation.
- Chapter 5
- Data Communication.