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UNIT-III Signal Transmission through Linear Systems

UNIT-III Signal Transmission through Linear Systems. Introduction. A system can be characterized equally well in the time domain or the frequency domain, techniques will be developed in both domains The system is assumed to be linear and time invariant.

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UNIT-III Signal Transmission through Linear Systems

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  1. UNIT-IIISignal Transmission through Linear Systems

  2. Introduction • A system can be characterized equally well in the time domain or the frequency domain, techniques will be developed in both domains • The system is assumed to be linear and time invariant. • It is also assumed that there is no stored energy in the system at the time the input is applied

  3. Impulse Response • The linear time invariant system or network is characterized in the time domain by an impulse response h (t ),to an input unit impulse (t) • The response of the network to an arbitrary input signal x (t )is found by the convolution of x (t )with h (t ) • The system is assumed to be causal, which means that there can be no output prior to the time, t =0,when the input is applied. • The convolution integral can be expressed as:

  4. Transfer Function of LTI system • The frequency-domain output signal Y (f )is obtained by taking the Fourier transform • Frequency transfer function or the frequency response is defined as: • The phase response is defined as:

  5. Distortion less Transmission • The output signal from an ideal transmission line may have some time delay and different amplitude than the input • It must have no distortion—it must have the same shape as the input. • For ideal distortion less transmission: Output signal in time domain Output signal in frequency domain System Transfer Function

  6. What is the required behavior of an ideal transmission line? • The overall system response must have a constant magnitude response • The phase shift must be linear with frequency • All of the signal’s frequency components must also arrive with identical time delay in order to add up correctly • Time delay t0 is related to the phase shift  and the radian frequency  = 2f by: t0 (seconds) =  (radians) / 2f (radians/seconds ) • Another characteristic often used to measure delay distortion of a signal is called envelope delay or group delay:

  7. Ideal Filter Characteristics • Filter • A frequency-selective system that is used to limit the spectrum of a signal to some specified band of frequencies • The frequency response of an ideal low-pass filter condition • The amplitude response of the filter is a constant inside the pass band -B≤f ≤B • The phase response varies linearly with frequency inside the pass band of the filter

  8. Ideal Filters • For the ideal band-pass filter transfer function • For the ideal high-pass filter transfer function Figure1.11 (c) Ideal high-pass filter Figure1.11 (a) Ideal band-pass filter

  9. Bandwidth • Theorems of communication and information theory are based on the assumption of strictly band limited channels • The mathematical description of a real signal does not permit the signal to be strictly duration limited and strictly band limited.

  10. (a) Half-power bandwidth. (b) Equivalent rectangular or noise equivalent bandwidth. (c) Null-to-null bandwidth. (d) Fractional power containment bandwidth. (e) Bounded power spectral density. (f) Absolute bandwidth. Different Bandwidth Criteria

  11. Causality and Stability • Causality : It does not respond before the excitation is applied • Stability • The output signal is bounded for all bounded input signals (BIBO) • An LTI system to be stable • The impulse response h(t) must be absolutely integrable • The necessary and sufficient condition for BIBO stability of a linear time-invariant system

  12. Paley-Wiener Criterion • The frequency-domain equivalent of the causality requirement

  13. Spectral Density • The spectral density of a signal characterizes the distribution of the signal’s energy or power in the frequency domain. • This concept is particularly important when considering filtering in communication systems while evaluating the signal and noise at the filter output. • The energy spectral density (ESD) or the power spectral density (PSD) is used in the evaluation.

  14. Energy Spectral Density (ESD) • Energy spectral density describes the signal energy per unit bandwidth measured in joules/hertz. • Represented as ψx(f), the squared magnitude spectrum • According to Parseval’s theorem, the energy of x(t): • Therefore: • The Energy spectral density is symmetrical in frequency about origin and total energy of the signal x(t) can be expressed as:

  15. Power Spectral Density (PSD) • The power spectral density (PSD) function Gx(f ) of the periodic signal x(t) is a real, even, and nonnegative function of frequency that gives the distribution of the power of x(t) in the frequency domain. • PSD is represented as: • Whereas the average power of a periodic signal x(t) is represented as: • Using PSD, the average normalized power of a real-valued signal is represented as:

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