Pulse Amplitude Modulation and Pulse Code Modulation

1. Pulse Amplitude Modulation andPulse Code Modulation oleh Warsun Najib

2. t 0 T t 0 t 0 T 0 t t 0 Pulse Amplitude Modulation PAM-PCM

3. Low Pass Band Pass 0 0 *make sure that Sinc function is big and flat by reduce time By using very narrow Demodulation of PAM PAM-PCM

4. PAM1 LPF PAM-TDM before filtering Pulse generator PAM-TDM to the transmission line LPF switch Clock Pulse generator PAM2 LPF Sampler Sampler Switch : determining the synchronization and sequence of the channels Clock : determine the timing of the overall system Pulse generator : produces narrow rectangular pulses to drive the sampler Multiplexing PAM-TDM PAM-PCM

5. T Two signal are sampled equally Tx=the time interval between adjacent channels or samples Nyquist interval for one signal For n channel Nyquist Sampling PAM-PCM

6. Tx Tx 0 -BF BF S1 S2 S3 S4 With condition of equal BW and sampling equally therefore the Total BW Requirement is n x BW If BW of each channel is not equal Therefore the Total BW Requirement is n x largest BW Bandwidth Requirement PAM-PCM

7. Transmitting Analog signal in Digital format • Advantages • Immunity to noise : with some amount of noise digital can withstand while analog failed to provide virtually error free transmission. • Reduce signal to noise ratio • Error control coding ; parity check, Hamming code make more reliable • Signal can be completely regenerated at intermediate regenerator for long haul system. • More compatible with computer system for signal processing and digital memories for data storage. • More elaborate code can be used. • Ideal for integrated services digital network (ISDN) PAM-PCM

8. Pulse Code Modulation • m(t) is sampled, each sample value is rounded off to the nearest allowable value. This value is digitally encoded as a sequence of binary digits • There are three process of Digitization 1. Sampling 2. Quantization (devide into level of voltage) The approximation of amplitude value of sinal m(t) into one of M discrete quantized values 3. Encoding Each quantization level is encoded into N binary digits Where N is the number of binary digit per code word M is the number of quantization level PAM-PCM

9. Where M = no. of steps = quantization step V 0 M Steps -V t Sampling Signal Quantization PAM-PCM

10. V 111 110 101 100 0 011 010 001 000 -V 1 1 1 1 1 0 1 0 0 0 1 1 0 1 0 1 0 0 1 0 1 1 1 t Encoding PAM-PCM

11. Quantization Noise 0 Quantization Error Uniform distribution PAM-PCM

12. time Signal to Noise Ratio The average power Time average Continuous RV PAM-PCM

13. where Signal to Noise Ratio[1] PAM-PCM

14. In dB Encoding : each quantization level is encoded into N binary digit No.of level No.of binary digit per code word Signal to Noise Ratio[2] PAM-PCM

15. MAN WOMAN voice time 0 300 500 800 3.4k 3.1k Nyquist 300 3.4k (2x3.4k=6.8k) Each sample is quantized and encoded into 8 bits Bit rate = x 8 = 64kbps ; with 32 channels 1channel = 8 bits therefore 8 x 488.25nsec = 3.9 sec Total bit length = 8 bit x 32 channels = 256 bits TDM-PCM (E1 standard) PAM-PCM