1- Find the currents Ii and I2 and the voltage VAB 2Ω 6 V 2- Initially the capacitor is charged with 20 uC. At t-0 the switch is closed. Find the time constant, the initial current in the circuit (at t-0), and the time needed for the current to drop to 1/3 of its initial value. Veキ104F
e: Two Loop Circuit 07-10.0 pts possible Consider the circuit 7Ω -i3 4 V 2Ω i2- 6 V 10 V 1Ω 3 2 1- Find i1. Answer in units of A.
Q8. Plot the waveform of Vo(t), assuming ideal op amp in Fig. 8 0 V 2Ω 2Ω X-12%-time (s) 0 4 +15V 2Ω -10 V Vo(t) 2Ω 12 V Fig. 8
Determine Vx in the circuit of Figure 3. 4Ω 2/ 2Ω 6Ω ΙΩ +8 V 1Ω Figure 3
1. For the circuit shown in figure P-01, determine a. Coupling coefficient of coupled inductors! b. The voltage, Vx as shown in the circuit! C. Energy stored inside the coupled inductors! ML 2Ω Figure P-01 2. For the ideal transformer circuit shown in figure P-02, determine a. Primary and secondary currents, Ii and I2! b. Primary and secondary voltages, Yi and V2! C. Complex power supplied by the source 1, 2Ω 1:2 6090V ms svo 12Ω Figure P-02 1. For...
Please Solve all questions with full steps 2Ω Find Z if Vi-Sz-120 V: 0.25 Ω We were unable to transcribe this imageDetermine the frequency so that the current I, and the voltage V, are in phase. R= 120 L = 19 mH C= 220 pF
015 10.0 points Consider the circuit 23 3 V 3 S 2 V 5 V 2Ω 1Ω Find i1 Answer in units of A 016 (part 1 of 2) 10.0 points Consider the following circuit. 5.2 Ω 3.0 Ω 3.0 Ω 4.3 Ω 1.8 Ω 3.0 Ω Find the equivalent resistance. Answer in units of Ω
solve 10.38 10.38 Find the current ix in the following ideal transformer r 20 2Ω 1:3 12 cos 2t + 6 Q Figure P10.38
Find all the currents in the following circuit. 2Ω 2 V 3Ω 7Ω 4Ω 10 V 10Ω 6Ω 5Ω 6V 2Ω 5Ω 11Ω 3 V
Palred Quiz) 3 For ideal transformer as shown in figure P.3, determine: a. The currents I1, I2 and I3! b. The primary and secondary voltage Vu V, Vg and Va C. The complex power supplied by the source! d. The effective power dissipated by the load impedance, Zioad 812-20 Ω 1:3 18 Ω Zload 40200 v ( 45 Figure P.3 Ideal Transformer Circuit