Communications system laboratory /
| Main Author: | |
|---|---|
| Corporate Author: | |
| Format: | eBook |
| Language: | English |
| Published: |
Boca Raton :
CRC Press, Taylor & Francis Group,
[2016]
|
| Edition: | First edition. |
| Subjects: | |
| Online Access: | Connect to the full text of this electronic book |
Table of Contents:
- Machine generated contents note: 1. Types of Electronic Communication Systems
- 1.1. How the World Is Linked through Coaxial, Microwave, Satellite, Cable, and Cellular Technologies
- 1.2. Functional Layers in Modern Communication Systems
- 1.3. Path Loss in Communication Links
- 1.4. Introduction to MATLAB®/Simulink®
- 1.4.1. MATLAB® Basics
- 1.4.1.1. System Operating Commands
- 1.4.1.2. Numbers
- 1.4.1.3. Vectors and Matrices
- 1.4.1.4. Creating One-Dimensional and Two-Dimensional Spaces Using MATLAB®
- 1.4.1.5. Programming with Vectors
- 1.4.2. Simulink® Basics
- 1.4.2.1. General Simulink® Operations
- 1.4.2.2. Editing, Running, and Saving Simulink® Files
- 1.4.2.3. Demo Files
- 1.5. Introduction to Equipment Used in Communication Systems
- 1.5.1. Sources
- 1.5.2. Measurement Devices
- 1.5.3. Radio-Frequency Integrated Circuits
- Problem Solving
- Computer Laboratory
- Hardware Laboratory
- 2. Time/Frequency Analysis of Communication Signals and Systems
- Note continued: 2.1. Concept of Carrier in Communication Systems
- 2.2. Signal Spectrum and the Fourier Transform
- 2.2.1. Important Facts about the Fourier Transform
- 2.2.1.1. Continuous and Discrete Spectrum
- 2.2.2. Power and Energy Relations in the Fourier Domain
- 2.3. Important Communication Signals and Their Frequency Spectra
- 2.4. Frequency Analysis of Communication Systems
- 2.4.1. Linear Systems
- 2.4.2. Nonlinear Systems
- 2.5. Practical Methods of Spectrum Analysis: DFT and IDFT
- 2.6. Discrete-Time System Analysis: Circular Convolution
- 2.7. Fast Fourier Transform
- 2.8.Computation of Fast Fourier Transform with MATLAB®
- Problem Solving
- Computer Laboratory
- Hardware Laboratory
- 3. First-Generation Systems: Analog Modulation
- 3.1. Amplitude Modulation
- 3.1.1. Double Sideband Modulation
- 3.1.2. Single Sideband Modulation
- 3.2. Angle Modulation
- 3.2.1. Frequency Modulation
- 3.2.2. Phase Modulation
- Note continued: 3.3.Comparison of AM and FM Modulation Systems
- 3.4. Noise and Filtering in Analog Modulation Systems
- 3.4.1. Noise Performance of AM and FM Circuits
- 3.4.2. Filtering Techniques to Minimize Noise Effects in Communication Channels
- Problem Solving
- Computer Laboratory
- Hardware Laboratory
- 4. Second-Generation Systems: Digital Modulation
- 4.1. Pulse Code Modulation
- 4.1.1. Time Sampling
- 4.1.2. Amplitude Quantization
- 4.1.2.1. Uniform Quantizer
- 4.1.2.2. Nonuniform Quantizer
- 4.1.3. Digital Encoding
- 4.1.4. Transmission Rate and Shannon's Maximum Capacity Theorem
- 4.1.5. Line Coding and Pulse Shaping Technique
- 4.2. Digital Modulation Systems
- 4.2.1. Digital AM or Phase Shift Keying
- 4.2.2. Digital FM or Frequency Shift Keying
- 4.2.3. Differential Phase Shift Keying
- 4.3. BER and Bandwidth Performance in Digital Modulation Systems
- 4.3.1. Noise Correction and Filtering in Digital Modulation Systems
- Note continued: 4.3.1.1. Error-Detecting Codes
- 4.3.1.2. Error-Correcting Codes
- 4.3.2. Equalization and Channel Compensation
- Problem Solving
- Computer Laboratory
- Hardware Laboratory
- 5. Third-Generation Systems: Wideband Digital Modulation
- 5.1. Principle of Spread Spectrum Communications
- 5.2. Frequency-Hopping Spread Spectrum
- 5.2.1. FHSS Transmission and Reception
- 5.2.2. FHSS Bandwidth and BER Performance
- 5.3. Direct-Sequence Spread Spectrum
- 5.3.1. DSSS Transmission and Reception
- 5.3.2. DSSS Bandwidth and BER Performance
- 5.4. Advantages and Disadvantages of Spread Spectrum Systems
- Problem Solving
- Computer Laboratory
- 6. Capacity of Communication Systems and Higher Generations
- 6.1. Evolution of Capacity and Data Rate in Communication Systems
- 6.1.1. Frequency Division Multiple Access
- 6.1.2. Time Division Multiple Access
- 6.1.3. Code Division Multiple Access
- 6.2. Fourth-Generation Systems
- Note continued: 6.2.1. Multicarrier Approach to Modulation
- 6.2.2. Principle of Orthogonal Frequency Division Multiplexing
- 6.2.3. OFDM Transmission and Reception
- 6.2.4. Advantages and Disadvantages of OFDM
- 6.3. Multiple-Input Multiple-Output Technology
- 6.3.1. Principle of MIMO Systems
- 6.3.2. Analysis of Input
- Output Systems
- 6.4. Fifth-Generation Communication Systems
- Problem Solving
- Computer Laboratory
- 7. Long-Range and Short-Range Communication Networks
- 7.1. Wireless Local Area Networks (WLANs)
- 7.1.1. Types of WLAN Specifications
- 7.1.2. Wi-Fi Networks
- 7.1.2.1. Wi-Fi Hotspots and Network Types
- 7.1.2.2. Advantages of Wi-Fi
- 7.2. Personal Area Networks (PANs)
- 7.2.1. Bluetooth
- 7.2.1.1. Potential of Bluetooth Technology
- 7.2.1.2. Applications of Bluetooth
- 7.2.2. ZigBee
- 7.2.2.1. Potential of ZigBee Technology
- 7.2.2.2. Applications of ZigBee
- 7.3. Ultra-Wideband Systems
- 7.3.1. Frequency Bandwidth of UWB Systems
- Note continued: 7.3.2. UWB Transmission and Reception
- 7.3.3. UWB Pulse Generation
- 7.3.4. Potential Advantages and Disadvantages of UWB
- 7.3.5. Applications of UWB
- 7.4. Path Loss Calculations in Long-Range and Short-Range Networks
- 7.4.1. Line of Sight (LOS) Model
- 7.4.2. Practical Channel Models
- 7.4.3. Link Budget and Range Estimation in Wireless Links
- Problem Solving
- Computer Laboratory
- Appendix A Synthesized Waveform Generators
- A.1. Introduction
- A.2. Technical Specifications
- A.2.1. Waveforms
- A.2.2. Frequency Characteristics
- A.2.3. Sinewave Spectral Purity
- A.2.4. Signal Characteristics
- A.2.5. Output Characteristics
- A.2.6. Modulation
- A.2.7. Burst
- A.2.8. Sweep
- A.2.9. System Characteristics
- A.2.10. Trigger Characteristics
- A.2.11. Clock Reference
- A.2.12. Sync Output
- A.2.13. General Specifications
- A.3. Operating Instructions
- Appendix B RF Spectrum Analyzers
- B.1. Introduction
- B.2. Technical Specifications
- Note continued: B.2.1. Frequency Specifications
- B.2.2. Bandwidth Filters
- B.2.3. Amplitude Specifications
- B.3. General Specifications
- B.3.1. System Options
- B.3.2. General Options
- B.4. Operating Instructions
- Appendix C Dynamic Signal Analyzers
- C.1. Introduction
- C.2. Technical Specifications
- C.2.1. Frequency Specifications
- C.2.2. Single-Channel Amplitude
- C.2.3. FFT Dynamic Range
- C.2.4. Input Noise
- C.2.5. Window Parameters
- C.2.6. Single-Channel Phase
- C.2.7. Cross-Channel Amplitude
- C.2.8. Cross-Channel Phase
- C.2.9. Input
- C.2.10. Trigger
- C.2.11. Tachometer
- C.2.12. Source Output
- C.2.13. Digital Interfaces
- C.2.14.Computed Order Tracking: Option 1D0
- C.2.15. Real-Time Octave Analysis: Option 1D1
- C.2.16. Swept-Sine Measurements: Option 1D2
- C.2.17. Arbitrary Waveform Source: Option 1D4
- C.3. General Specifications
- C.4. Operating Instructions
- C.4.1. Single-Channel Mode Operation
- C.4.2. Dual-Channel Mode Operation
- Note continued: Appendix D Digital Storage Oscilloscopes
- D.1. Introduction
- D.2. Performance Characteristics of the Keysight 54600 Series Digitizing Oscilloscopes
- D.2.1. Acquisition: Analog Channels
- D.2.2. Acquisition: Digital Channels (54621D, 54622D, 54641D, and 54642D Only)
- D.2.3. Vertical System: Analog Channels
- D.2.4. Vertical System: Digital Channels (54621D, 54622D, 54641D, and 54642D Only)
- D.2.5. Horizontal
- D.2.6. Trigger System
- D.2.7. Analog Channel Triggering
- D.2.8. Digital (D15
- D0) Channel Triggering (54621D, 54622D, 54641D, and 54642D)
- D.2.9. External (EXT) Triggering
- D.2.10. Display System
- D.2.11. Measurement Features
- D.2.12. FFT
- D.2.13. Storage
- D.2.14.I/O
- D.2.15. General Characteristics
- D.2.16. Power Requirements
- D.2.17. Environmental Characteristics
- D.2.18. Other Information
- D.3. Operating Instructions
- Appendix E Integrated Circuits for Communication Systems
- Note continued: E.1. Introduction to Radio-Frequency Integrated Circuits
- E.2. RFIC Amplifier: TRF37B73 1
- 6000 MHz RF Gain Block
- E.3. RFIC Mixer: TRF37B32 700
- 2700 MHz Dual Downconverter
- E.4. RFICs for Transceiver Applications
- E.4.1. Texas Instruments CC2540 2.4 GHz Bluetooth® Transceiver
- E.4.2. Texas Instruments TRF2443 Integrated IF Transceiver
- E.4.3. Texas Instruments CC2520 ZigBee® RF Transceiver
- Appendix F Worldwide Frequency Bands and Terminology.