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The Chapter includes: Pulse Amplitude Modulation Pulse Width Modulation Pulse Position Modulation

PULSE MODULATION. The process of transmitting signals in the form of pulses (discontinuous signals) by using special techniques. The Chapter includes: Pulse Amplitude Modulation Pulse Width Modulation Pulse Position Modulation Pulse Code Modulation.

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The Chapter includes: Pulse Amplitude Modulation Pulse Width Modulation Pulse Position Modulation

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  1. PULSE MODULATION The process of transmitting signals in the form of pulses (discontinuous signals) by using special techniques. • The Chapter includes: • Pulse Amplitude Modulation • Pulse Width Modulation • Pulse Position Modulation • Pulse Code Modulation Created by C. Mani, Principal, K V No.1, AFS, Jalahalli West, Bangalore

  2. Pulse Code (PCM) Pulse Amplitude (PAM) Pulse Width (PWM) Delta (DM) Pulse Position (PPM) Pulse Modulation Analog Pulse Modulation Digital Pulse Modulation Pulse Amplitude Modulation (PAM): * The signal is sampled at regular intervals such that each sample is proportional to the amplitude of the signal at that sampling instant. This technique is called“sampling”. * For minimum distortion, the sampling rate should be more than twice the signal frequency.

  3. Pulses at sampling frequency HF Carrier Oscillator Pulse Amplitude Modulator PAM AND Gate FM Modulator Analog Signal Pulse Shaping Network PAM - FM Analog Signal Amplitude Modulated Pulses

  4. Pulse Width Modulation (PWM or PLM or PDM): * In this type, the amplitude is maintained constant but the duration or length or width of each pulse is varied in accordance with instantaneous value of the analog signal. * The negative side of the signal is brought to the positive side by adding a fixed d.c. voltage. Analog Signal Width Modulated Pulses

  5. Pulse Position Modulation (PPM): * In this type, the sampled waveform has fixed amplitude and width whereas the position of each pulse is varied as per instantaneous value of the analog signal. * PPM signal is further modification of a PWM signal. It has positive thin pulses (zero time or width) corresponding to the starting edge of a PWM pulse and negative thin pulses corresponding to the ending edge of a pulse. * This wave can be further amended by eliminating the whole positive narrow pulses. The remaining pulse is called clipped PPM. PWM PPM

  6. PAM, PWM and PPM at a glance: Analog Signal Amplitude Modulated Pulses Width Modulated Pulses Position Modulated Pulses

  7. Pulse Code Modulation (PCM): * Analog signal is converted into digital signal by using a digital code. * Analog to digital converter employs two techniques: 1. Sampling: The process of generating pulses of zero width and of amplitude equal to the instantaneous amplitude of the analog signal. The no. of pulses per second is called “sampling rate”. 2. Quantization: The process of dividing the maximum value of the analog signal into a fixed no. of levels in order to convert the PAM into a Binary Code. The levels obtained are called “quanization levels”. * A digital signal is described by its ‘bit rate’ whereas analog signal is described by its ‘frequency range’. * Bit rate = sampling rate x no. of bits / sample

  8. Voltage Time 111 110 101 100 011 010 001 000 76543210 Binary Levels Codes Voltage Time 0 1 0 1 0 1 1 1 0 1 1 1 1 1 0 1 0 1 0 1 0 Time Sampling,QuantizationandCoding

  9. Merits of Digital Communication: END • Digital signals are very easy to receive. The receiver has to just detect whether the pulse is low or high. • AM & FM signals become corrupted over much short distances as compared to digital signals. In digital signals, the original signal can be reproduced accurately. • The signals lose power as they travel, which is called attenuation. When AM and FM signals are amplified, the noise also get amplified. But the digital signals can be cleaned up to restore the quality and amplified by the regenerators. • The noise may change the shape of the pulses but not the pattern of the pulses. • AM and FM signals can be received by any one by suitable receiver. But digital signals can be coded so that only the person, who is intended for, can receive them. • AM and FM transmitters are ‘real time systems’. i.e. they can be received only at the time of transmission. But digital signals can be stored at the receiving end. • The digital signals can be stored, or used to produce a display on a computer monitor or converted back into analog signal to drive a loud speaker.

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