Q4: Using souce transformation, find i in the circuit of Fig. 4. 1 30 5 mH...
Q4. Find the Norton's equivalent circuit with respect to the terminals a and b, and write the answer in polar form. 20 | | 11/30°A 1 40 403 200 4240° v bom 32 22-20°v Q5. Find i(t) in the network. (t) 22 AM 1s(t) = 4 sin(2kt) A 0 4mH3 = 3 mF vs(t) = 10 cos(2kt+30°) V 422 Q6. Find the i(t). 212 is(t) = 10 sin(1kt + 10) A W ΔΩ ans I. 2 mF vs(t) = 10...
Q.: Findi, in circuit of Fig 1 20 mH TIT 50 00S 4000/ V W 8092 40 4F 1002 2 sin 20001 A 6002 24 V Figure 1
sool9 (10 Mark Question 4 Calculate vo in the circuit of Figure Q4 using mesh analysis 22 ww 50 ww + FO 2vo 32 8V Figure Q4 Question 5 1) Determinei for the circuit in Fig. Q5 using the superposition principle. ria af tt (10 M
4. Use the mesh-current method to find i, iandi in the circuit shown in Figure 4. W 1.50 Fig. 4 5. Use the mesh-current method to find i, toi, in the circuit shown in Figure 5. 250 m . 1000 200 V +) 500 10 Fig. 5 6. Use the mesh-current method to find the power that the current source delivers to the circuit shown in Figure 6. 5.60 0.80 30 A Fig. 6
Find Io using source transformation in the following circuit: (5 points) 2 Ω j1 Ω οδο I, 4Ω 8/90° A j5 Ω ell 1 Ω W -j3 Ω -j2 Ω
a. For the circuit shown in Fig. 1, find i(t) and vi(t) for all t. b. For the circuit shown in Fig. 2, find vclt) and ic(t) for all t. 10 kΩ 20 kΩ ic 10 mH 18 V 100u(-1) V 40u(C) V F, 13 a. For the circuit shown in Fig. 1, find i(t) and vi(t) for all t. b. For the circuit shown in Fig. 2, find vclt) and ic(t) for all t. 10 kΩ 20 kΩ ic...
For Prob 9.5 9.47 In the circuit of Fig 9.54, determine the value of i,Cr If V.-8/30" V in the circuit of Fig. 959. find l," 9.52 2miH ら(n20 115 cos 2,000, v C Figure 9.59 For Prob. 9.52 Figure 9.54 For Prob. 9.47 9.53 Find I, in the circuit of Fig. 9.60 9.48 Given that v,(,) = 20 sin( 100,-40") in Fig. 9,55. determine i,) 4Ω ML 10 Ω 3052 , tn) ( 10Ω 160 430 V 8Ω Figure...
Q4. (a) Using nodal analysis, determine the voltage in the circuit shown in Figure Q4(a). (b) (i) Find the transmission parameters for the two-port network shown in Figure Q4(b). 20 Ω 30 Ω 10 Ω 60Ω 4 A 0.01v1A 2v1V Figure Q4(a) 21, V 24 Ω 2 2 1 V. 2 20 Ω Figure Q4(b) 20 Ω 30 Ω 10 Ω 60Ω 4 A 0.01v1A 2v1V Figure Q4(a) 21, V 24 Ω 2 2 1 V. 2 20 Ω Figure...
The circuit shown in Figure Q4-1 includes an audio source and the equivalent circuit of a loudspeaker that you have been asked to analyse. 4. a) Assuming the speaker is to operate at a single frequency of 200 Hz and is5 driven by a cosinusoidal signal with peak amplitude of 20 V; determine the equivalent impedance of the speaker When connected to the audio source, calculate the current flow i() When testing the loudspeaker detailed in Q4a) i), you can...
4. (10.6) Find the output voltage (as a phasor) in the circuit below. j1 Ω 2Ω W 2020° 192 5/20 5. (10.42) Find the currents and voltages (as phasors) in the circuit below containing an ideal transformer. WW th ot 20 7602 20200 & 10 6. (10.43) Find the voltage (as phasor) in the circuit below containing an ideal transformer. 2:1 2:1 rün 402 W W of 22 2020 -120 lllll j622 lo 7. If Li - 30 mH, L2...