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Find the power delivered to the load resistor
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- 3b For the circuit in Figure Q3(b), solve for Ix, Iy and Vz using superposition method.arrow_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_forwardUsing mesh current analysis, find the currents i1 and i2 for the circuit of Figure P3.14.arrow_forward
- In the circuit shown in Figure P3.70, VS models thevoltage produced by the generator in a power plant,and RS models the losses in the generator, distributionwire, and transformers. The three resistances model thevarious loads connected to the system by a customer.How much does the voltage across the total loadchange when the customer connects the third load R3in parallel with the other two loads?VS = 110 V RS = 19 mΩR1 = R2 = 930 mΩ R3 = 100 mΩarrow_forwardUsing Kirchhoff's Rules, compute the current (mA) and voltage (V) values of the circuit if R1=2kΩ and R2=7kΩ.arrow_forwardThe circuit shown in Figure P3.35 is a simplifiedDC version of an AC three-phase electrical distributionsystem.VS1 = VS2 = VS3 = 170 VRW1 = RW2 = RW3 = 0.7Ω R1 = 1.9Ω R2 = 2.3Ω R3 = 11 ΩTo prove how cumbersome and inefficient (althoughsometimes necessary) the method is, determine, usingsuperposition, the current through R1.arrow_forward
- Using node voltage analysis in the circuit of FigureP3.4, find the current i through the voltage source.arrow_forwardUsing node voltage analysis in the circuit of FigureP3.3, find the voltage v across the 0.25-ohm resistancearrow_forwardAnswer the following if V1=8V, R1=9 Ω, R2=3 Ω, R3=4 Ω, R4=7 Ω and I1=10 A in the circuit in the figure i1=? Pv1=? PI1=? P5i1=?arrow_forward
- Find the voltage v across the 3- resistor in thecircuit of Figure P3.52 by replacing the remainder ofthe circuit with its Thévenin equivalentarrow_forwardUsing mesh current analysis, find the currents I1, I2, and I3 in the circuit of Figure P3.17 (assume polarity according to I2).arrow_forwardConstruct this circuit using the simulation: (simulation link: https://phet.colorado.edu/sims/html/circuit-construction-kit-dc/latest/circuit-construction-kit-dc_en.html ) Let: R1 = 2000 ohms R2 = 5000 ohms R3 = 3000 ohms R4 = 1000 ohms V1=24V 1. Total equivalent resistance of the circuit (using theoretical calculation) 2. Total current on the circuit (using simulation) 3. Total equivalent resistance of the circuit (using simulation) 4. % Error of #1 and #3 question.arrow_forward
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