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Refer to Figure P3.44 and use the principle of super position to determine the current i through
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Principles and Applications of Electrical Engineering
- Refer to the given circuit below. Using Superposition Theorem, determine the percent contribution of E₁ to the current through R3 (lbc)- 1 R3E1 % contribution = - x 100 R3E2 + 1 R1 R2 R3 R4 E₁ E2 I 3 Ω 70 4 Ω 3 Ω 7 V 8 V 5 A I R3E1 +1 R31 + R₁ E₁ a ↑ R₂ C b R3 R4 E₂ +arrow_forwardWith reference to Figure P3.43, usingsuperposition, determine the component of the currentthrough R3 that is due to VS2.VS1 = VS2 = 450 VR1 = 7Ω R2 = 5Ω R3 = 10Ω R4 = R5 = 1 Ωarrow_forwardFind the Thévenin equivalent of the circuitconnected to RL in Figure P3.58, where R1 = 10Ω ,R2 = 20 Ω, Rg = 0.1 Ω, and Rp = 1 Ω.arrow_forward
- Write the Loop-current equations for the circuit below. Then, determine the values of i, iz and i3. 50 10 30 V 15 V wwarrow_forwardThe input to the circuit in Figure P 3.6-25 is the voltage of the voltage source vs. The output is the current measured by the meter i.. Show that the output of this circuit is proportional to the input. Determine the value of the constant of proportionality. ww Us 2Ω Figure P 3.6-25 40 Ω www 10 92 ia 20 Ω Ammeter iof 40 Ω 50 iaarrow_forwardUsing KCL, perform node analysis on the circuitshown in Figure P3.24, and determine the voltageacross R4. Note that one source is a controlled voltagesource! Let VS = 5 V; AV = 70; R1 = 2.2 kΩ;R2 = 1.8 kΩ; R3 = 6.8 kΩ; R4 = 220Ωarrow_forward
- 3.16 plz solve and explain this examplestep by step plz avoid direct solutionarrow_forwardDetermine the branch currents, using KVL andloop analysis in the circuit of Figure P3.35.VS2 = VS3 = 110V VS1 = 90 VR1 = 7.9 ΩR2 = R3 = 3.7 ΩRW1 = RW2 = RW3 = 1.3 Ωarrow_forwardRefer to the given circuit below. Using Superposition Theorem, determine the percent contribution of I to the current through R3 (lbc). IR31 % contribution = x 100 1 +1 +1 R3E1 "R3E2 R3 R4 E1 E2 I 6Q 1Q 9 V 7V 3A a R31 R1 2Q R1 R2 1Q E₁ R2 C b R3 R4 E2arrow_forward
- Q3) For the network shown in the figure below, determine the following: a) fe b) Zinl and Zin2 c) Zo1 and Zo2 d) Avı, Av2, and AVT +20 V 6.8 kQ 30 ka 6.8 ka 30 ka 0.5 F 0.5 uF P-150 B- 150 1.5 ka 50 uF 1.5 ka 50 uFarrow_forward(b) Prove the circuit in Figure Q.5 can perform the operation of adder/subtractor by completing Table Q.5. -Sub FA FA FA FA Figure Q.5 Table Q.5 B[3:0] Sub A[3:0] C4 S[3:0] Operation 0111 1000 1 0111 1000arrow_forwardUse the Principle of Superposition to determine the current i through R3 in the Figure. Let R1 = 100, R2 = 40, R3 = 20, R4 = 20, R5= 20, Vs 10 V, Is = 2A. ww VS R3 ww wwwarrow_forward
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