1. نیمسال دوّم 93-92 افشین همّت یار دانشکده مهندسی کامپیوتر ارتباطات داده (883-40) مدولاسیون پالس

2. Pulse Modulation Introduction Sampling Process Pulse-Amplitude Modulation Other forms of Pulse Modulations Bandwidth-Noise Trade-off Quantization Process Pulse-Code Modulation Noise Consideration in PCM Systems Time-Division Multiplexing Digital Multiplexers Virtues, Limitations, and Modifications of PCM Linear Prediction Differential PCM Adaptive Differential PCM Delta Modulation 2

3. Introduction Continuous-Wave Modulation: Some parameter (amplitude, phase, or frequency) of a sinusoidal carrier wave is varied continuously in accordance with the message signal. Analog Pulse Modulation: Some parameter (amplitude, duration, or position) of each pulse (in a periodic pulse train) is varied in a continuous manner in accordance with the corresponding sample value of the message signal. (Information transmission in analog form, but transmission at discrete times.) Digital Pulse Modulation: The message signal is represented in a form that is discrete in both time and amplitude, thereby permitting its transmission in digital form as a sequence of coded pulses. 3

4. Sampling Process (1) f s = 2W T s = 1/(2W) 4

5. Sampling Process (2) Sampling theorem: A band-limited signal of finite energy, which has no frequency components higher than W Hertz, 1)is completely described by specifying the values of the signal at instants of time separated by 1/(2W) seconds. 2)may be completely recovered from a knowledge of its samples taken at the rate of 2W samples per second. f s < 2W f s > 2W 5

6. Pulse Amplitude Modulation (1) 6

7. Pulse Amplitude Modulation (2) Reconstruction filter  Aperture effect: Flat-top samples  Amplitude distortion and T/2 delay Equalizer  7

8. Other forms of Pulse Modulation Modulating signal  Carrier Pulse  Pulse Duration Modulation  (Pulse Width Modulation) Pulse Position Modulation  8

9. Bandwidth-Noise Trade-off (1) PPM is the optimum form of analog pulse modulation, and has similar noise performance as FM: 1)Both systems have a figure of merit proportional to the square of the transmission bandwidth normalized with respect to the message bandwidth. 2)Both systems exhibit a threshold effect as the signal-to-noise ratio is reduced. Can we produce a trade-off better than a square law? Yes, by Digital Pulse Modulation. 9

10. Bandwidth-Noise Trade-off (2) A basic form of DPM is Pulse Code Modulation: Discrete in both time and amplitude. Transmission of the message signal as a sequence of coded binary pulses. The effect of channel noise at the receiver output can be reduced to a negligible level simply by making the average power of the transmitted binary PCM wave large enough compared to the average power of the noise. Two fundamental processes are involved in the generation of a binary PCM wave: 1)Sampling: Discrete-time representation of the message signal 2)Quantization: Discrete –amplitude representation of the message signal Possibility to realize an exponential law for the bandwidth- noise trade-off. 10

11. Quantization Process (1) midtread midrise 11

12. Quantization Process (2) Quantization Noise 12

13. Quantization Process (3) Quantization Noise  (SNR) O Increases exponentially with the number of bits. 13

14. Quantization Process (4) Example: Sinusoidal Modulating Signal  SNR (dB) R (bits) L (levels) 49.88256 61.8101024 73.8124096 85.81416384 91.81665536 14

15. Pulse Code Modulation (1) Basic Elements 15

16. Pulse Code Modulation (2) Quantization (Compression & Expansion) μ Law A Law Typical used values: μ = 225, A = 87.6 16

17. Pulse Code Modulation (3) Line Codes: Unipolar NRZ  Polar NRZ  Unipolar RZ  Bipolar RZ  (AMI) Manchester  (Split Phase) 17

18. Pulse Code Modulation (4) Line Codes: Unipolar NRZ   Polar NRZ Unipolar RZ   Bipolar RZ Manchester  18

19. Pulse Code Modulation (5) Line Codes: Unipolar NRZ  DC component and thus waste of DC power Nonzero spectrum near zero frequency Lack of synchronization Polar NRZ  High spectrum near zero frequency Lack of synchronization Unipolar RZ  DC component and high Spectrum near zero frequency Need for more power than Polar NRZ and twice bandwidth Good for timing recovery Bipolar RZ  No DC component Low spectrum near zero frequency (if equal probability for “1”s and “0”s) Good for timing recovery Manchester  No DC component Low spectrum near zero frequency (regardless of signal statistics) Very good for timing recovery Twice bandwidth 19

20. Pulse Code Modulation (6) Differential Encoding 20

21. Pulse Code Modulation (6) Regeneration: 1)Channel noise and interference  Wrong decisions  Bit errors 2)Deviation of spacing between received pulses  Jitter  Distortion Decoding: Generating a pulse the amplitude of which is the weighted sum of all the pulses in the code word. Filtering: Low-pass reconstruction filter whose cutoff frequency is equal to the message bandwidth. 21

22. Noise Considerations in PCM Systems (1) Two major sources of Noise: Channel Noise Is introduced anywhere between the transmitter output and the receiver input. Always present, once the equipment is switched on. Quantization Noise Is introduced in transmitter and is carried all the way along to the receiver output. Is signal-dependent. It disappears when the message signal is switched off. Measure for fidelity of PCM transmission: Average probability of symbol error  Bit Error Rate (BER) 22

23. Noise Considerations in PCM Systems (2) Error Threshold: E b /N 0 : The ratio of the transmitted signal energy per bit, to the noise spectral density. Time between errors (Bit Rate = 10 5 bps) PePe E b /N 0 (dB) 10 -3 Second10 -2 4.3 10 -1 Second10 -4 8.4 10Seconds10 -6 10.6 20Minutes10 -8 12 1 Day10 -10 13 3 Months10 -12 14 23

24. Time-Division Multiplexing Block Diagram of TDM System 24

25. Digital Multiplexer MultiplexerDemultiplexer High-speed Transmission Line 1 2 N 1 2 N Data Sources Destinations T1 Digital Hierarchy DS0: 64 Kbps one voice channel DS1: 1.544 Mbps (twenty four DS0) {(1+24x8)x8 KSamples/Sec} DS2: 6.312 Mbps (four DS1) DS3: 44.736 Mbps (seven DS2) DS4: 274.176 Mbps (six DS3) DS5: 560.160 Mbps (two DS4) 25

26. Virtues, Limitations and Modifications of PCM (1) Advantages: 1) Robustness to channel noise and interference 2) Efficient regeneration of the coded signal along the transmission path. 3) Efficient exchange of increased channel bandwidth for improved signal-to-noise ratio, obeying an exponential law. 4) A uniform format for the transmission of different kinds of baseband signals, hence their integration with other forms of digital data in a common network. 5) Comparative ease with which message sources may be dropped or reinserted in a time-division multiplex system. 6) Secure communication through the use of special modulation scheme or encryption. 26

27. Virtues, Limitations and Modifications of PCM (2) Limitations: 1) Increased system complexity >> Cost effective fashion using VLSI 2) Increased channel bandwidth >> Availability of wideband channels (satellite, fiber optics) >> Data compression techniques Modifications: 1) Differential PCM(DPCM) 2) Adaptive Differential PCM(ADPCM) 27

28. Linear Prediction Linear Adaptive Prediction (Finite-duration Impulse Response (FIR) Discrete-time Filter) 28

29. Differential Pulse Code Modulation Transmitter Receiver 29

30. Adaptive Differential Pulse Code Modulation Adaptive Quantization with: Forward estimation (AQF) Backward estimation (AQB) Adaptive Prediction with: Forward estimation (APF) Backward estimation (APB) AQB APB 30

31. Delta Modulation (1) Sampling at higher rates One bit for each sample 31

32. Delta Modulation (2) Transmitter Receiver 32

33. Delta Modulation (3) Required condition: (for no overload) Slope Overload 33

34. Delta Modulation (4) Delta-Sigma Modulation Simplification of the receiver Pre-emphasis of low-frequency content of the input signal Increasing correlation between adjacent samples  reduction the variance of the error signal 34