(b) The switch-capacitor-inductor network shown in Figure 4.2 is placed across the terminals of a Thévenin equivalent circuit with an open circuit voltage of 10 V and Thévenin equivalent resistance of 10 N. There is no energy stored in either the capacitor or inductor at time t = 0. For the resulting circuit, give the following values, assuming the switch is closed at t = 0: (i) the initial voltage across the capacitor (t = 0) (ii) the final steady state voltage across the capacitor (t >> 0) (ii) the initial current through the inductor (t = 0) (iv) the final steady state current through inductor (t >> 0)

I am looking for a solution to Q4. (b) please. I assumed this all fell under the same question as these are all interlinked? Thanks in advance

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Question 4 4. (a) Construct a Thévenin equivalent circuit across the terminals a, b for the circuit shown in Figure 4.1. 25 N a 8 V 1 A 30 Ω b Figure 4.1 (b) The switch-capacitor-inductor network shown in Figure 4.2 is placed across the terminals of a Thévenin equivalent circuit with an open circuit voltage of 10 V and Thévenin equivalent resistance of 10 0. There is no energy stored in either the capacitor or inductor at time t = 0. For the resulting circuit, give the following values, assuming the switch is closed at t = 0: (i) the initial voltage across the capacitor (t = 0) (ii) the final steady state voltage across the capacitor (t >> 0) (ii) the initial current through the inductor (t = 0) (iv) the final steady state current through the inductor (t >> 0) t = 0 a b 10 nF 100 µH Figure 4.2 Question 4 is continued on the next page