2. Verification of initial and final conditions (Figure #2) Prelab Part 2b: RL Initial and Final Condition Computations 1. For the circuit shown in figure 2 above, generate expressions for the initial inductor current, Ii(0) = (0+), and the inductor current for time tending towards infinity, it(o), in variable form. You must use the voltage and current polarities shown in figure 2 to receive credit for the prelab computations. 2. Calculate the theoretical numerical values for the initial inductor current, a=(0)=(0+), and the inductor current for time tending towards infinity, it(o), for the circuit shown in figure 2 above using the specified component values. To be thorough, you should also determine the inductor voltages (0) and (0) As you complete your computations, record the theoretical numerical values in the spaces provided below. Again note that all required equations must first be generated in variable form as indicated in prelab part 2b(1) above before substituting component values to receive credit. Note: The labelled spaces below are to be used to record your initial and final condition computation results from prelab part 2b(2) above. ILo= XL(0-)= ix(x)= XL(x)= 3 Vsi = 10[V] Vs2 = 5[V] + t=0 i1(t) R₁ = 1[k] ww v1(t) V2(t) + A i2(t) = IL (t) R₁ = 1[k2] VL(t) | iL(t) =iz(t) L=1[mH] 13(t) V3(t) R₁ = 1[k] B B Figure 2: RL circuit to be used for verifying initial and final conditions Verification of initial and final conditions (Figure #1) Prelab Part 2a: RC Initial and Final Condition Computations 1. For the circuit shown in figure 1 above, generate expressions for the initial capacitor voltage, Xco=xc(0)=xc(0+), and

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2. Verification of initial and final conditions (Figure #2) Prelab Part 2b: RL Initial and Final Condition Computations 1. For the circuit shown in figure 2 above, generate expressions for the initial inductor current, Ii(0) = (0+), and the inductor current for time tending towards infinity, it(o), in variable form. You must use the voltage and current polarities shown in figure 2 to receive credit for the prelab computations. 2. Calculate the theoretical numerical values for the initial inductor current, a=(0)=(0+), and the inductor current for time tending towards infinity, it(o), for the circuit shown in figure 2 above using the specified component values. To be thorough, you should also determine the inductor voltages (0) and (0) As you complete your computations, record the theoretical numerical values in the spaces provided below. Again note that all required equations must first be generated in variable form as indicated in prelab part 2b(1) above before substituting component values to receive credit. Note: The labelled spaces below are to be used to record your initial and final condition computation results from prelab part 2b(2) above. ILo= XL(0-)= ix(x)= XL(x)= 3

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Vsi = 10[V] Vs2 = 5[V] + t=0 i1(t) R₁ = 1[k] ww v1(t) V2(t) + A i2(t) = IL (t) R₁ = 1[k2] VL(t) | iL(t) =iz(t) L=1[mH] 13(t) V3(t) R₁ = 1[k] B B Figure 2: RL circuit to be used for verifying initial and final conditions Verification of initial and final conditions (Figure #1) Prelab Part 2a: RC Initial and Final Condition Computations 1. For the circuit shown in figure 1 above, generate expressions for the initial capacitor voltage, Xco=xc(0)=xc(0+), and