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Chapter 9

1. The Laplace Transform "Here I come to save the day!"

$ X(s) = \int_{-\infty}^{+\infty}x(t)e^{-st}\, dt $

s is a complex number of the form $ \sigma + j\omega $ and if $ \sigma = 0 $ then this equation reduces to the Fourier Transform of $ x(t) $. Indeed, the LT can be viewed as the FT of the signal $ x(t)e^{-\sigma t} $ as follows:

$ \mathcal{F}\lbrace x(t)e^{-\sigma t} \rbrace = \mathcal{X}(\omega) = \int_{-\infty}^{+\infty}x(t)e^{-\sigma t}e^{-j\omega t}\, dt $

2. The Region of Convergence for Laplace Transforms (To Infinity or Converge!)

Definitions

A signal x(t) is:

  1. right sided if there exists a t_0 such that x(t) = 0 for t < t_0
  2. left sided if there exists a t_0 such that x(t) = 0 for t > t_0
  3. two sided if it extends infinitely for both t > 0 and t < 0
  4. of finite duration if there exist two values of t, T_1 and T_2 such that x(t) = 0 for t < T_1 and t > T_2

From 4: A two sided signal can be represented as the sum of a right sided signal and a left sided signal if the signal is divided at any arbitrary T_0. The two sided signal conver

A Laplace transform is rational if it is of the form X(s) = \frac{N(s)}{D(s)} Property

  1.  : The ROC of X(s) consists of strips parallel to the $ j\omega $-axis in the s-plane.
  2.  : For rational Laplace transforms, the ROC does not contain any poles.
  3.  : If x(t) is of finite duration and is absolutely integrable, then the ROC is the entire s-plane.
  4.  : If x(t) is right sided, and if the line Re{s} = $ \sigma_0 $ is in the ROC, then all values of s for which Re{s} > $ \sigma_0 $ will also be in the ROC.
  5.  : If x(t) is left sided, and if the line Re{s} = \sigma_0 is in the ROC, then all values of s for which Re{s} < \sigma_0 will also be in the ROC.
  6.  : If x(t) is two sided, and if the line Re{s} = \sigma_0 is in the ROC, then the ROC will consist of a strip in the s-plane that includes the line Re{s} = \sigma_0.
  7.  : If the Laplace transform X(s) of x(t) is rational, then its ROC is bounded by poles or extends to infinity. In addition, no poles of X(s) are contained in the ROC.
  8.  : If the Laplace Transform X(s) of x(t) is rational, then if x(t) is right sided, the ROC is the region in the s-plane to the right of the rightmost pole. If x(t) is left sided, the ROC is the region in the s-plane to the left of the leftmost pole.

Notes:

  1. If giving a Laplace Transform for an answer to a question, the definition is incomplete without providing a ROC.
  2. In order to determine the inverse Laplace transform of a LT X(s), one must consider its ROC. The ROC coupled with properties 1-8 will be used to distinguish between the signals that produce the same LT X(s)

Partial Fraction Expansion

Any rational function $ X(s) = \frac{N(s)}{D(s)} $ can be expressed as a linear combination of LOWER ORDER terms.

Example
$ X(s) = \frac{(s - z_1)(s-z_2)}{(s-p_1)(s-p_2)^2} = \frac{A}{s-p_1} + \frac{B}{s-p_2} + \frac{C}{(s-p_2)^2} $
z_1 and z_2 are referred to as the zeroes of the function because X(z_1) = 0;
p_1 and p_2 are referred to the poles of the function because X(p_1) is infinity creating a large "pole" on the graph
p_2 is a second order pole because it occurs twice
To obtain the coefficients you can use the relationship:
$ R = (s-p_R)X(s) \Bigg|_{s=p_{r}}\,\,\, $for this example the 2nd order pole creates a special case
The coefficient B cannot be computed directly because (s-p_2)X(s) still leaves a pole at p_2 and therefore cannot be
evaluated at s=p_2. A and C can be computed easily however, and once those are computed there is only one unknown left
in the equation and can clearly be obtained through direct algebraic manipulation.
If that method proves fruitless or too hard to compute, then a system of equations can be obtained by acquiring a
common denominator for the RHS of the equation resulting in $ A(s-p_2)^2 + B(s-p_2)(s-p_1) + C(s-p_1) $. This equation is
precisely equal to the numerator of the LHS of the equation therefore, after algebraically expanding all the terms. You
can obtain a system of 3 equations and 3 unknowns which may be solved using a variety of methods, including those
learned in linear algebra, like Kramer's(need to double check that name) rule. Methods learned in high school algebra
also apply.


3. The Inverse Laplace Transform

$ x(t) = \frac{1}{2\pi}\int_{\sigma - j\infty}^{\sigma + j\infty} X(s)e^{st}\,ds $

for values of $ s = \sigma + j\omega $ in the ROC. The formal evaluation of the integral requires contour integration in the complex plane which is beyond the scope of this course.

3.1 The Laplace Transforms we will consider will fall into several categories that can be inverted using tables.
$ X(s) = \sum_{i=1}^{m} \frac{A_i}{s+a_i} $

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