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Chapter 2 System Models – Time Domain

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1 Chapter 2 System Models – Time Domain
ELEC 2120 Fri. May 17, 2013 Roppel Chapter 2 System Models – Time Domain

2 Model of a System Mathematical equation that describes the relationship between input x(t) or x[n] and the output y(t) or y[n]. Drawing or diagram that illustrates the input – output relationship Words that define the inputs, outputs, and their relationship.

3 Time Domain Voltage “Hello” Time

4 Frequency Domain Voltage “Hello” Frequency

5 Chapter 2 2.1 – 2.3: Discrete time 2.4 – 2.6: Continuous time

6 Convolution is Most Important Model
Discrete Time: 3 Models Input / Output Convolution Difference Equation Convolution is Most Important Model

7 Why Convolution is Important
Leads most directly to frequency domain. Most signal analysis is performed in the frequency domain. Most system analysis is performed in the frequency domain.

8 INPUT/OUTPUT REPRESENTATION OF DISCRETE-TIME SYSTEMS
N-point moving average filter:

9 INPUT/OUTPUT REPRESENTATION OF DISCRETE-TIME SYSTEMS
Generalization: The weights, wi , define the system.

10 INPUT/OUTPUT REPRESENTATION OF DISCRETE-TIME SYSTEMS
Further Generalization: Any causal linear time-invariant discrete-time system with the input x[n] equal to zero for all n < 0 can be expressed in this form!

11 UNIT-PULSE RESPONSE Denote by h[n] Set x[n] = δ[n]

12 UNIT-PULSE RESPONSE The unit-pulse response lets you “see” everything inside the system. It’s like kicking the tires and slamming the doors on a used car to see what rattles.

13 CONVOLUTION REPRESENTATION
Rewriting the I/O equation using h[n] yields CONVOLUTION

14 CONVOLUTION EXAMPLE More about computing convolution later…
>> x=[ ]; % input unit pulse >> h=[ ]; % unit pulse response >> y=conv(x,h); % output >> y y = >> More about computing convolution later…

15 DIFFERENCE EQUATION MODEL (Sect. 2.3)
Nth-Order Input/Output Difference Equation: Present output, y[n], depends on previous inputs and outputs, and present input, x[n]. Solve recursively, or find a closed-form solution.

16 DIFFERENTIAL EQUATION MODELS (Sect. 2.4 / 2.5)
R-C circuit example (1st order) Mass-spring-damper example (2nd order) …solve using standard techniques from diff. eq.

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