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Laplace Transform.

CHAPTER 3. Laplace Transform. EKT 232. Laplace Transform. 3 .1 Introduction. 3 .2 The Laplace Transform . 3.2.1 Generalization of the CTFT 3.2.2 The S-Plane 3.2.3 Poles and Zeros 3 .3 The Unilateral Laplace Transform and Properties. 3 .4 Inversion of the Unilateral.

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Laplace Transform.

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  1. CHAPTER 3 Laplace Transform. EKT 232

  2. Laplace Transform. 3.1 Introduction. 3.2 The Laplace Transform. 3.2.1 Generalization of the CTFT 3.2.2 The S-Plane 3.2.3 Poles and Zeros 3.3 The Unilateral Laplace Transform and Properties. 3.4 Inversion of the Unilateral. 3.5 Properties of Bilateral Laplace Transform 3.6 The Transfer Function of a System

  3. 3.1 Introduction. • In this Chapter 3 we are considering the continuous-time signal and system representation based on complex exponential signals. • The Laplace transform can be used to analyze a large class of continuous-time problems involving signal that are not absolutely integrable, such as impulse response of an unstable system. • Laplace transform come in two varieties; (i) Unilateral (one sided); is a tool for solving differential equations with initial condition. (ii) Bilateral (two sided); offer insight into the nature of system characteristic such as stability, causality, and frequency response.

  4. 3.1 Introduction.

  5. Pierre-Simon Laplace 3/23/1749 - 3/2/1827

  6. 3.2 Laplace Transform • H(s) is the Laplace Transform of h(t) and the h(t) is the inverse Laplace transform of H(s). • The Laplace transform of x(t) is • The Inverse Laplace Transform of X(s) is • We can express the relationship with the notation

  7. 3.2 Laplace Transform • Let estbe a complex exponential with complex frequency s = s +jw. We may write, • The real part of est is an exponential damped cosine • And the imaginary part is an exponential damped sine • The real part of s is the exponential damping factor s. • And the imaginary part of sis the frequency of the cosine and sine factor, w.

  8. 3.2 Laplace Transform • The condition for convergence of the Laplace transform is the absolute integrability of x(t)e-at , • The range of s for which the Laplace transform converges is termed the region of convergence (ROC)

  9. 3.2.1 Generalization of the CTFT • Laplace Transform is more general than Fourier Transform. • The FT is really just a special case of the LT.

  10. 3.2.1 Generalization of the CTFT The CTFT uses only complex sinusoids. The Laplace transform uses the more general complex exponentials.

  11. Generalization of the CTFT

  12. 3.2.2 The s-Plane. • It is convenience to represent the complex frequency s graphically in termed the s-plane. (i) the horizontal axis represents the real part of s (exponential damping factor s). (ii) The vertical axis represents the imaginary part of s (sinusoidal frequency w) • In s-plane, s =0 correspond to imaginary axis. • Fourier transfrom is given by the Laplace transform evaluated along the imaginary axis.

  13. Example 3.1:Laplace Transform of a Causal Exponential Signal. Determine the Laplace transform of x(t)=eatu(t). And Sketch the Zero and Pole. Solution: Step 1: Find the Laplace transform. To evaluate e-(s-a)t, Substitute s=s + jw

  14. Cont’d… Figure 3.5: The ROC for x(t) = eatu(t) is depicted by the shaded region. A pole is located at s = a. If s > a, then e-(s-a)t goes to zero as t approach infinity, *The Lapalce transform does not exist for s=<a because the integral does not converge. *The ROC is at s>a, the shade region of the s-plane in Figure below. The pole is at s=a. • .

  15. 3.2.3 Poles and Zeros. • Zeros. The ck are the root of the numeratorpolynomial and are termed the zeros of X(s). Location of zeros are denoted as “o”. • Poles. The dk are the root of the denominator polynomial and are termed the poles of X(s). Location of poles are denoted as “x”. • The Laplace transform does not uniquely correspond to a signal x(t) if the ROC is not specified. • Two different signal may have identical Laplace Transform, but different ROC. Below is the example. Figure 6.4a Figure 6.4b Figure 4.4a. The ROC for x(t) = eatu(t) is depicted by the shaded region. A pole is located at s = a. Figure 4.4b. The ROC for y(t) = –eatu(–t) is depicted by the shaded region. A pole is located at s = a.

  16. j s = -5 At s = -5 the denominator = 0 and X(s) goes to    j

  17. 3.3 Unilateral Laplace Transform and Properties Let g(t) and h(t) both be causal functions and let them form the following transform pairs, Linearity Time Shifting Complex-Frequency Shifting

  18. 3.3 Unilateral Laplace Transform and Properties Time Scaling Frequency Scaling Time Differentiation Once Nth Time Derivative

  19. Properties

  20. 3.3 The Unilateral Laplace Transform and Properties. • The Unilateral Laplace Transform of a signal x(t) is defined by • The lower limit of 0- implies that we do include discontinuities and impulses that occur at t = 0 in the integral. H(s) depends on x(t)for t >= 0. • The relationship between X(s) and x(t) as • The unilateral and bilateral Laplace transforms are equivalent for signals that are zero for time t<0.

  21. 3.4 Inversion of the Unilateral Laplace Transform. • We can determine the inverse Laplace transforms using one-to-one relationship between the signal and its unilateral Laplace transform.

  22. Example 3.3:Inversion by Partial-Fraction Expansion. Find the Inverse Laplace Transform of Solution: Step 1: Use the partial fraction expansion of X(s) to write Solving the A, B and C by the method of residues

  23. Cont’d…

  24. Cont’d… A=1, B=-1 and C=2 Step 2:Construct the Inverse Laplace transform from the above partial-fraction term above. - The pole of the 1st term is at s = -1, so - The pole of the 2nd term is at s = -2, so -The double pole of the 3rd term is at s = -2, so Step 3: Combining the terms. • .

  25. Example 3.4:Inversion An Improper Rational Laplace Transform. Find the Inverse Laplace Transform of Solution: Step 1: Use the long division to espress X(s) as sum of rational polynomial function. We can write,

  26. Cont’d… Use partial fraction to expand the rational function, Step 2:Construct the Inverse Laplace transform from the above partial-fraction term above. Refer to the Laplace transform Table. • .

  27. 3.5 Properties of Bilateral Laplace Transform. • The Bilateral Lapalace Transform is suitable to the problems involving no causal signals and system. • The properties of linearity, scaling, s-domain shift, convolution and differentiation in the s-domain is identicalfort the bilateral and unilateral LT, the operations associated of these properties may change the ROC. • ROC of the sum of the signals is an intersection of the individual ROCs.

  28. 3.6 Transfer Function of a System • The transfer function of an LTI system is defined as the Laplace transform of the impulse response. • Take the bilateral Laplace transform of both sides of the equation and use the convolution properties result in, • Rearrange the above equation result in the ratio of Laplace transform of the output signal to the Laplace transform of the input signal. (X(s) is nonzero)

  29. examples

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