At t=0, the capacitor acts like a short circuit and the inductor acts like an open circuit, and we can simply the cicuit into:
V R 1 = 6.818 V {\displaystyle V_{R1}=6.818V}
V R 2 = 0 V {\displaystyle V_{R2}=0V}
V R 3 = V R 4 = 8.182 V {\displaystyle V_{R3}=V_{R4}=8.182V}
I R 1 = 13.64 m A {\displaystyle I_{R1}=13.64mA}
I R 2 = 0 A {\displaystyle I_{R2}=0A}
I R 3 = 5.455 m A {\displaystyle I_{R3}=5.455mA}
I R 4 = 8.182 m A {\displaystyle I_{R4}=8.182mA}
At t = ∞ {\displaystyle t=\infty } , the capacitor acts like an open circuit and the inductor acts like a short circuit. We can then simplify the circuit:
V R 1 = 9 V {\displaystyle V_{R1}=9V}
V R 2 = 36 V {\displaystyle V_{R2}=36V}
V R 3 = 0 V {\displaystyle V_{R3}=0V}
V R 4 = 6 V {\displaystyle V_{R4}=6V}
I R 1 = 18 m A {\displaystyle I_{R1}=18mA}
I R 2 = 12 m A {\displaystyle I_{R2}=12mA}
I R 3 = 0 A {\displaystyle I_{R3}=0A}
I R 4 = 6 m A {\displaystyle I_{R4}=6mA}
, the capacitor acts like an open circuit and the inductor acts like a short circuit. We can then simplify the circuit:
