7. 4.4-2. Consider the circuit shown below. Use Laplace transform techniques to solve the following: (a) Determine the standard-form, constant-coefficient differential equation description of this circuit. (b) Letting RC = 1, determine the total response y(t) to input z(t) = 3e-¹tu(t) and initial capacitor voltage of v. (0) = 5. x(1) y(t)

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**Analysis of RC Circuit Using Laplace Transform Techniques** Consider the circuit depicted below. This analysis involves determining the response of the circuit using Laplace transform techniques. **Problem 7.4.4-2** (a) **Determine the standard-form, constant-coefficient differential equation description of this circuit.** (b) **Given** \( R = 1 \) and \( C = 1 \), **determine the total response \( y(t) \) to input \( x(t) = 3e^{-t}u(t) \) and initial capacitor voltage of** \( v_c(0^-) = 5 \). **Circuit Diagram Explanation:** The diagram shows a simple RC series circuit which consists of: - A resistor \(R\) in series with a capacitor \(C\). - An input voltage source \(x(t)\). - An output voltage across the capacitor \(y(t)\). The circuit is configured as follows: 1. The voltage source \(x(t)\) is connected in series with a resistor \(R\). 2. The resistor \(R\) is connected in series with a capacitor \(C\). 3. The voltage \(y(t)\) is measured across the capacitor \(C\). Students are instructed to apply Laplace transform techniques to derive the differential equation that governs the circuit's behavior and to find the total response of the system given specific initial conditions and the input function.