Example 1a. Assume Initial conditions Zero. Use Laplace Transform to solve the following circuit and find Vo(s). 10eu(t) V 10 Ω www 10et (1) V 1022 10 Ω www + (t) = 0.1 F Example 1b. Use Laplace Transform to solve the following circuit and find Vo(s). Consider initial condition in the capacitor vo(0) = 5 volts. 1022 T + (1) 0.1 F +28(t) A - 28(1) A

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**Example 1a:** Assume initial conditions are zero. Use the Laplace Transform to solve the following circuit and find \( V_o(s) \). ### Circuit Description: - The circuit is driven by a voltage source \( 10e^{-t}u(t) \, \text{V} \), where \( u(t) \) is the unit step function. - The circuit contains two resistors, each with a resistance of \( 10 \, \Omega \). - A capacitor is present, with a capacitance of \( 0.1 \, \text{F} \), where \( v_o(t) \) is the voltage across the capacitor. - There is also a current source \( 2\delta(t) \, \text{A} \), where \( \delta(t) \) is the Dirac delta function. ### Diagram: The voltage source is on the left, connected in series with a \( 10 \, \Omega \) resistor. The right side branches into a parallel connection: another \( 10 \, \Omega \) resistor and a capacitor. The capacitor has an additional path going through a current source that injects a current of \( 2\delta(t) \, \text{A} \). --- **Example 1b:** Use the Laplace Transform to solve the following circuit and find \( V_o(s) \). Consider the initial condition in the capacitor \( v_o(0^-) = 5 \, \text{volts} \). ### Circuit Description: - The setup is identical to that in Example 1a, including the \( 10e^{-t}u(t) \, \text{V} \) voltage source, two \( 10 \, \Omega \) resistors, and a \( 0.1 \, \text{F} \) capacitor. - The current source remains \( 2\delta(t) \, \text{A} \). - The initial voltage across the capacitor is \( 5 \, \text{volts} \). ### Diagram: The second circuit matches the configuration of the first, with a similar layout and components. The main difference is the initial voltage condition on the capacitor.