Chapter 3 Convolution Representation

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Presentation transcript:

Chapter 3 Convolution Representation

CT Unit-Impulse Response Consider the CT SISO system: If the input signal is and the system has no energy at , the output is called the impulse response of the system System System

Exploiting Time-Invariance Let x(t) be an arbitrary input signal with for Using the sifting property of , we may write Exploiting time-invariance, it is System

Exploiting Time-Invariance

Exploiting Linearity Exploiting linearity, it is If the integrand does not contain an impulse located at , the lower limit of the integral can be taken to be 0,i.e.,

The Convolution Integral This particular integration is called the convolution integral Equation is called the convolution representation of the system Remark: a CT LTI system is completely described by its impulse response h(t)

Block Diagram Representation of CT LTI Systems Since the impulse response h(t) provides the complete description of a CT LTI system, we write

Example: Analytical Computation of the Convolution Integral Suppose that where p(t) is the rectangular pulse depicted in figure

Example – Cont’d In order to compute the convolution integral we have to consider four cases:

Example – Cont’d Case 1:

Example – Cont’d Case 2:

Example – Cont’d Case 3:

Example – Cont’d Case 4:

Example – Cont’d

Properties of the Convolution Integral Associativity Commutativity Distributivity w.r.t. addition

Properties of the Convolution Integral - Cont’d Shift property: define Convolution with the unit impulse Convolution with the shifted unit impulse then

Properties of the Convolution Integral - Cont’d Derivative property: if the signal x(t) is differentiable, then it is If both x(t) and v(t) are differentiable, then it is also

Properties of the Convolution Integral - Cont’d Integration property: define then

Representation of a CT LTI System in Terms of the Unit-Step Response Let g(t) be the response of a system with impulse response h(t) when with no initial energy at time , i.e., Therefore, it is

Differentiating both sides Representation of a CT LTI System in Terms of the Unit-Step Response – Cont’d Differentiating both sides Recalling that it is and or