2. The switch has been closed a long time before opening att0. Find the initial and...
5. If the switch has been closed for a long time before opening at t = 0: a) What is i, () for <0? b) What is i, (t) for t> 0? 3 (kS2) 10(V) E1 () 6(k2) Figure 5. Circuit for problem 5.
7. (15 Points) If the switch has been closed a long time before opening, find the inductor current for t20. 202 t=0 1 mH w 2 A } 812 16 Ω
3. The switch has been open a long time before closing at t = 0. Find the initial and final energy stored in the inductor. Determine i(t) and v(t) fort > 0*. t = 0 1092 to i(t) 2A @ 500 FT VIC 30.4 mH 2.503 14 4. The switch has been closed a long time before opening at t = 0. Find il(t) and vc(t) fort > 0*. 2012 t = 0 vc(t) 4092 4uF 60V 3 10 mH...
for t20. switch in the cireuit has been open for a long time before closing at co, rind iC) 3K (30 points) ISV
In the circuit the switch has been closed for a long time before opening at & (Figure 1)
Problem 7.10 In the circuit the switch has been closed for a long time before opening at t=0. (Figure 1) Part A Find the value of L so that v. (t) equals 0.5v. (0+) when t= 2 ms. Take R = 11 12 Express your answer with the appropriate units. TH TA ? L = 9 H Submit Previous Answers Request Answer * Incorrect; Try Again; 9 attempts remaining Part B Find the percentage of the stored energy that has...
7) (12 pts): The switch in caircuit has been closed for a long time before opening att-0. Find i(t), vt) and islt) for t 20 20 is. 40 Ω 120Ç 600 250 mH v, 1000 60Ω
AP 7.8 The switch in the circuit have been open for a long time. The initial charge on the capacitor is 0. At t=0, switch is closed. Find the expression for i(t), v(t) for t> 0+. 0.1 µF X1%3D0% i(1) 7.5 mA( v(t) 20 k2 30 kn
5. The switch has been open for a long time before closing at t0. Find v(t) and 1802 t 0 Wi 10 mH
Part 2: In the circuit shown, the switch has been in position a for a long time. At t=0, the switch moves to b a. Find the current i(t) for t20 b. Find the voltage v(t) for t0 t=0b a + 1522 8 A a 100 v(t) 1012 M i(1) $100 mH