Analog Pulse Modulation Modulation Continuous wave CW modulation
- Slides: 26
Analog Pulse Modulation
Modulation Continuous wave (CW) modulation AM Pulse Modulation Angle modulation FM Analog Pulse Modulation Digital Pulse Modulation PM PAM PPM PDM DM PCM
Introduction
Introduction
Introduction
Pulse Amplitude Modulation (PAM)
Pulse Amplitude Modulation (PAM)
Pulse Amplitude Modulation (PAM)
PDM and PPM
Digital Pulse Modulation
Digital Pulse Modulation �The digital pulse modulation has two types: q. Pulse Code Modulation(PCM) q. Delta Modulation(DM) �The process of Sampling which we have already discussed in initial slides is also adopted in digital pulse modulation
Pulse Code Modulation(PCM) �PCM is the most basic form of digital pulse modulation. �In PCM, a message signal is represented by a sequence of coded pulses, which is accomplished by representing the signal in discrete form in both time and amplitude. �The basic operations performed in the transmitter of a PCM system are sampling, quantizing, and encoding.
The basic elements of a PCM system § § Before we sample, we have to filter the signal to limit the maximum frequency of the signal as it affects the sampling rate. Filtering should ensure that we do not distort the signal, i. e. remove high frequency components that affect the signal shape.
Sampler �The sampler samples the input continuous-time analog signal at a sampling rate fs (= 1/Ts sec). �There are 3 sampling methods: �Ideal - an impulse at each sampling instant �Natural - a pulse of short width with varying amplitude �Flattop - sample and hold, like natural but with single amplitude value
Quantization Process �The analog signal has a continuous range of amplitudes and therefore its samples have a continuous amplitude range. �In the quantization, the signal with continuous amplitude can be approximated by a signal constructed of discrete amplitudes selected on a minimum error basis from an available set.
Quantizer �The sampling results is a series of pulses of varying amplitude values ranging between two limits: a min and a max. �The amplitude values are infinite between the two limits. �We need to map the infinite amplitude values onto a finite set of known values. �This is achieved by dividing the distance between min and max into L zones, each of height = (max - min)/L
Quantization Levels �The midpoint of each zone is assigned a value from 0 to L-1 (resulting in L values) �Each sample falling in a zone is then approximated to the value of the midpoint.
Quantization Zones �Assume we have a voltage signal with amplitutes Vmin=-20 V and Vmax=+20 V. �We want to use L=8 quantization levels. �Zone width = (20 - -20)/8 = 5 �The 8 zones are: -20 to -15, -15 to -10, -10 to -5, -5 to 0, 0 to +5, +5 to +10, +10 to +15, +15 to +20 �The midpoints are: -17. 5, -12. 5, -7. 5, -2. 5, 7. 5, 12. 5, 17. 5
Quantization Error �When a signal is quantized, we introduce an error - the coded signal is an approximation of the actual amplitude value. �The difference between actual and midpoint value is referred to as the quantization error. �The more zones, the smaller which results in smaller errors.
Encoding �In combining the process of sampling and quantization, the specification of the continuous-time analog signal becomes limited to a discrete set of values. �Representing each of this discrete set of values as a code called encoding process. �Code consists of a number of code elements called symbols. �In binary coding, the symbol take one of two distinct values. in ternary coding the symbol may be one of three distinct values and so on for the other codes.
Assigning Codes to Zones �Each zone is assigned a binary code. �The binary code consists of bits. �The number of bits required to encode the zones, or the number of bits per sample, is obtained as follows: nb = log 2 L �Given our example, nb = 3 �The 8 zone (or level) codes are therefore: 000, 001, 010, 011, 100, 101, 110, and 111 �Assigning codes to zones: � 000 will refer to zone -20 to -15 � 001 to zone -15 to -10, etc.
Line Coding �Any of several line codes can be used for the electrical representation of a binary data stream. �Examples of line coding : RZ, NRZ, and Manchester
10 x(t) 2 Consider the analog Signal x(t). t X(n. Ts) 10 Ts 2 n The signal is first sampled
10 8 6 4 2 2 dividing the range into 4 zones n 3 2 1 0 assign quantized values of 0 to 3 to the midpoint of each zone. n
3 2 1 0 approximating the value of the sample amplitude to the quantized values. 11 n 3 10 2 01 1 00 0 Each zone is assigned a binary code n
11 3 10 2 01 1 00 0 01 11 11 11 01 00 00 The sequence bits if the samples 01111111010000 Use one of the line code scheme to get the digital signal n
- Digital to analog modulation techniques
- Noise in analog modulation
- Modulation digital to analog
- Digital transmission advantages
- Pulse width modulation
- Ppolx
- Multiple pulse width modulation
- Hirst
- Pulse code modulation and demodulation
- Pulse code modulation conclusion
- Pulse code modulation conclusion
- Pulse code modulation and demodulation
- Amplitude modulation conclusion
- Pwm modulation definition
- Amplitude modulation vs frequency modulation
- Amplitude modulation vs frequency modulation
- Advantages of angle modulation
- Giant v wave in jvp
- Wave modulation
- Past simple future
- Future in the past continuous
- Earthquake p wave and swave travel time
- The wave chapter 10
- Transverse wave and longitudinal wave example
- Transverse and longitudinal waves both *
- Full wave rectified sine wave fourier series
- When does a wave posses a quarter wave symmetry?