Problem 2.4 For the circuit shown in Fig. 2.4, N, - N,. Determine the voltage V...
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...
3-- Determine the peak load voltage for the circuit shown in Fig.1 i Determine the dc load voltage for the circuit shown in Fig.2 ii- Determine the dc load voltage and current values for the circuit shown in Fig.3 V-120V 1 R 10 ΚΩ Fig. 1 V-120V R-5.1 KS2 Fig. 2 10:1 V-120V R-5.1 Fig. 3
20. (a) Determine the equivalent resistance of the circuit in ▼Fig. 18.34 Find (b) the current in each resistor, (c) the voltage across each resistor, and (d) the total power delivered to the circuit. FIGURE 18.34 Power dissipation See Exercise 20. 10Ω 2.0 Ω 6.0 92 V 24 V 4,0Ω 12Ω 10Ω 5.0 Ω 시 r
20. (a) Determine the equivalent resistance of the circuit in ▼Fig. 18.34 Find (b) the current in each resistor, (c) the voltage across each...
The input to the circuit shown in Fig. 2 is the voltage source v(t). The output is the voltage across the capacitor, v(t). Determine the output of this circuit as a function of time t when the input is v.(t)-8+12u(t) V 40 18 s(t) 160 Fig. 2
2. Find the voltage v(t) for t 2 0 in the circuit of Fig. 2 3Ω 21 V 12Ω 1 F 6 6Ω Fig. 2
In the circuit shown in Fig. I, T is an ideal transformer whose turns ratio n/n is 2, where ni and n are the number of turns of the primary winding and the number of turns of the secondary winding, respectively; V is a sinusoidal voltage source whose phasor voltage is 240v2 L45 V; ZI and Z2 are two loads and their impedances are Z1-8Q, Z2-2p. Find phasor current i1, i2 and phasor voltage V1 and V2 Z1 V1 Fig.
4. For the circuit in Fig. 4, find the voltage volt) for t > 0. Determine the time necessary for the capacitor voltage to decay to 60% of its value at t=0. t=0 6 k2 W 40 V (+ - 4 kN 20 uF = " Fig. 4. Circuit for Problem 4.
Ouestion 1 (10%) The circuit shown in Fig. 1 is at steady state before t-0s. Determine v(t) and i(t) for>0. 3Ω 60 |(t) 12 u() 22 ) 12Ω Fig. 1
11.5 Determine the average power dissipated in the 4Ω resistor of the circuit in Fig. P11.5 2Ω j6Ω /4Ω 4Ω f-60 Hz Figure P11.5: Circuit for Problem 11.5
11.5 Determine the average power dissipated in the 4Ω resistor of the circuit in Fig. P11.5
2Ω j6Ω /4Ω 4Ω f-60 Hz Figure P11.5: Circuit for Problem 11.5
Problem V-B In the circuit shown in Fig. V-B, suppose RE = RG= Ru= Ri = R ohm. Determine the potential Vo at the output in terms of applied voltage Vin and the current supplied by Vin. (Answer hint: Use A- Y conversion on Rr. Rr and Re FIG. V-B RJ A Iin RG RF Vo Vin RH