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Signal Operations. 2 Basic Operation of the Signals. Basic Operation of the Signals. 1.3.1. Time Shifting 1.3.2 Reflection and Folding. 1.3.3. Time Scaling.

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Presentation on theme: "Signal Operations. 2 Basic Operation of the Signals. Basic Operation of the Signals. 1.3.1. Time Shifting 1.3.2 Reflection and Folding. 1.3.3. Time Scaling."— Presentation transcript:

1 Signal Operations

2 2 Basic Operation of the Signals. Basic Operation of the Signals. 1.3.1. Time Shifting 1.3.2 Reflection and Folding. 1.3.3. Time Scaling 1.3.4 Precedence Rule for Time Shifting and Time Scaling.

3 Time Shifting Time shifting is, as the name suggests, the shifting of a signal in time. This is done by adding or subtracting the amount of the shift to the time variable in the function. Subtracting a fixed amount from the time variable will shift the signal to the right (delay) that amount, while adding to the time variable will shift the signal to the left (advance).

4 4 delayadvances  A time shift delay or advances the signal in time by a time interval +t 0 or –t 0, without changing its shape. y(t) = x(t - t 0 ) right  If t 0 is positive the waveform of y(t) is obtained by shifting x(t) toward the right, relative to the tie axis. (Delay) left  If t 0 is negative, x(t) is shifted to the left. (Advances) 1.3.3 Time Shifting.

5 5 Example 1: Continuous Signal. A CT signal is shown in Figure below, sketch and label each of this signal; a) x(t -1) 3 2 t x(t)

6 6 Solution: (a) x(t -1) 04 t x(t-1) 2

7 Quiz 1: Time Shifting. Given the rectangular pulse x(t) of unit amplitude and unit duration. Find y(t)=x (t - 2)

8 8 Ans Quiz 1: Time Shifting. Given the rectangular pulse x(t) of unit amplitude and unit duration. Find y(t)=x (t - 2) Solution: t 0 is equal to 2 time units. Shift x(t) to the right by 2 time units. Figure 1.16: Time-shifting operation: (a) continuous-time signal in the form of a rectangular pulse of amplitude 1.0 and duration 1.0, symmetric about the origin; and (b) time-shifted version of x(t) by 2 time shifts.

9 9 Discrete Time Signal. A discrete-time signal x[n] is shown below, Sketch and label each of the following signal. (a) x[n – 2] x[n] n 5353 0 1 2 3

10 10 (a) A discrete-time signal, x[n-2].  A delay by 2 5 3 0 1 2 3 4 5 n x[n-2]Cont’d…

11 Quiz 2 Quiz 2 Discrete Time Signal. A discrete-time signal x[n] is shown below, Sketch and label each of the following signal. (a)x[n – 3] x[n] n 5353 0 1 2 3

12 Quiz 2 Quiz 2 Ans 5 3 0 1 2 3 4 5 n x[n-2] 6

13 13 replacing  Let x(t) denote a continuous-time signal and y(t) is the signal obtained by replacing time t with –t;  y(t) is the signal represents a refracted version of x(t) about t = 0. special cases  Two special cases for continuous and discrete-time signal; (i) Even signal; x(-t) = x(t) an even signal is same as reflected version. (ii) Odd signal; x(-t) = -x(t) an odd signal is the negative of its reflected version. 1.3.2 Reflection and Folding.

14 14 Example :. A CT signal is shown in Figure 1.17 below, sketch and label each of this signal; a) x(-t) 3 2 t x(t)

15 15 Solution: (c) x(-t) -31 2 t

16 16  The continuous-time version of the unit-step function is defined by,  The discontinuity exhibit at t = 0 and the value of u(t) changes instantaneously from 0 to 1 when t = 0. That is the reason why u(0) is undefined.Cont’d…

17 STEPS To Remember Reflection) If you have Time shifting and Reversal ( Reflection) together Do 1 st Shifting Then Reflection

18 Question 1 Question 1

19 Solution

20 20 Question 2: Discrete Time Signal. A discrete-time signal x[n] is shown below, Sketch and label each of the following signal. (a) x[-n+2](b) x[-n] x[n] n 6464 0 1 2 3

21 21 (a) A discrete-time signal, x[-n+2]. Time shifting and reversal 6 4 -1 0 1 2n x(-n+2)Cont’d…

22 22 (b) A discrete-time signal, x[-n].  Time reversal 6 4 -3 -2 -1 0 1 n x(-n)Cont’d…

23 Question 2 Continuous Signal A continuous signal x(t) is shown in Figure. Sketch and label each of the following signals. a) x(t)= u(t -1) b) x(t)= [u(t)-u(t-1)] c) x(t)=  (t - 3/2)

24 24Solution: (a) x(t)= u(t -1) (b) x(t)= [u(t)-u(t-1)] (c) x(t)=d(t - 3/2)

25 25 multiplication  Time scaling refers to the multiplication of the variable by a real positive constant. acompressed  If a > 1 the signal y(t) is a compressed version of x(t). aexpanded  If 0 < a < 1 the signal y(t) is an expanded version of x(t). Time Scaling.

26 Example

27 27  In the discrete time,  It is defined for integer value of k, k > 1. Figure below for k = 2, sample for n = +-1, Figure 1.12: Effect of time scaling on a discrete-time signal: (a) discrete-time signal x[n] and (b) version of x[n] compressed by a factor of 2, with some values of the original x[n] lost as a result of the compression.Cont’d…

28 28  The discrete-time version of the unit-step function is defined by, 1.4.5 Step Function.

29 29 Tutorial 1 Q 1A continuous-time signal x(t) is shown below, Sketch and label each of the following signal (a) x(t – 2)(b) x(2t) (c.) x(t/2)(d) x(-t) x(t) t 4 04

30 Tutorial 1 Q3 Q3

31 Tutorial 1

32 32 discrete-time  The discrete-time version of the unit impulse is defined by, 1.4.6 Impulse Function.

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