(c) X3(8): (d) X₁ (s): 8² +2 82-58-6' 23(t) is a two-sided signal 8-1 (8+2)(s² +8+1) • £₁(t) is a left-sided signal

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Only 2c and 2d needed. Thanks

**Problem Statement:**

Find the corresponding time function for each of the following rational Laplace transforms. For (a) and (b), use (at least) two different methods. Two suggested methods are provided below. For the remaining problems, using one method (of your choice) is adequate.

---

**(a) \(X_1(s) = \frac{s + 2}{s^2 - 2s + 2}\), \(\text{Re}\{s\} > 1\)**

- **Method 1**: Express \(X_1(s)\) as \(X_1(s) = \frac{A}{s - p_1} + \frac{B}{s - p_2}\) where \(p_1, p_2\) are the two poles and \(A, B\) are constants.

- **Method 2**: Express \(X_1(s)\) as:
  \[
  X_1(s) = \frac{C(s + \alpha)}{(s + \alpha)^2 + \omega_0^2} + \frac{D\omega_0^2}{(s + \alpha)^2 + \omega_0^2}
  \]
  for some properly chosen \(\alpha\) and \(\omega_0\), and constants \(C, D\).

---

**(b) \(X_2(s) = \frac{4s}{(s + 4)^2}\), \(\text{Re}\{s\} > -4\) (repeated poles)**

- **Method 1**: Express \(X_2(s)\) as \(X_2(s) = \frac{A}{s + 4} + \frac{B}{(s + 4)^2}\) for some constants \(A\) and \(B\).

- **Method 2**: Express \(X_2(s)\) as \(X_2(s) = \frac{C}{(s + 4)} + \frac{d}{ds}(s + 4)\) for some constants \(C\) and \(D\).

---

**(c) \(X_3(s) = \frac{s^2 + 2}{s^2 - 5s - 6}\); \(x_3(t)\) is a two-sided signal
Transcribed Image Text:**Problem Statement:** Find the corresponding time function for each of the following rational Laplace transforms. For (a) and (b), use (at least) two different methods. Two suggested methods are provided below. For the remaining problems, using one method (of your choice) is adequate. --- **(a) \(X_1(s) = \frac{s + 2}{s^2 - 2s + 2}\), \(\text{Re}\{s\} > 1\)** - **Method 1**: Express \(X_1(s)\) as \(X_1(s) = \frac{A}{s - p_1} + \frac{B}{s - p_2}\) where \(p_1, p_2\) are the two poles and \(A, B\) are constants. - **Method 2**: Express \(X_1(s)\) as: \[ X_1(s) = \frac{C(s + \alpha)}{(s + \alpha)^2 + \omega_0^2} + \frac{D\omega_0^2}{(s + \alpha)^2 + \omega_0^2} \] for some properly chosen \(\alpha\) and \(\omega_0\), and constants \(C, D\). --- **(b) \(X_2(s) = \frac{4s}{(s + 4)^2}\), \(\text{Re}\{s\} > -4\) (repeated poles)** - **Method 1**: Express \(X_2(s)\) as \(X_2(s) = \frac{A}{s + 4} + \frac{B}{(s + 4)^2}\) for some constants \(A\) and \(B\). - **Method 2**: Express \(X_2(s)\) as \(X_2(s) = \frac{C}{(s + 4)} + \frac{d}{ds}(s + 4)\) for some constants \(C\) and \(D\). --- **(c) \(X_3(s) = \frac{s^2 + 2}{s^2 - 5s - 6}\); \(x_3(t)\) is a two-sided signal
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