Homework 2 SJTU233. Part A. Part B. Problem 2. Part A. Problem 1. Find the impedance Zab in the circuit seen in the figure. Suppose that R = 5 Ω.

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1 Homework 2 SJTU233 Problem 1 Find the impedance Zab in the circuit seen in the figure. Suppose that R = 5 Ω. Express Zab in polar form. Enter your answer using polar notation. Express argument in degrees. Express Zab in rectangular form. Express your answer in complex form using three significant figures. Problem 2 The circuit in has an impedance of 40+j20Ω at a frequency of 4500rad/s. Determine R and L.

2 Express your answers using three significant figures separated by a comma. The circuit in has an impedance of 40 j20ω at a frequency of 4500rad/s. Determine R and C. Express your answers using three significant figures separated by a comma. Problem 3 Find the steady-state expression for vo in the circuit of if ig=90cos10000tma. Suppose that vo(t)=v0cos(ωt+ϕ), where 180 <ϕ 180. Determine the values V0, ω, ϕ. Express your answers using three significant figures separated by commas. Problem 4

3 Use the node-voltage method to find Vo in the circuit in the figure when Vs= V. Enter your answer using polar notation. Express argument in degrees. Problem 5 Use the mesh-current method to find the steady-state expression for vo(t) in the circuit in if va=18sin(4000t)v, vb=12cos(4000t)v. Write the steady-state expression for vo(t) as vo=vocos(ωt+ϕ), where 180 <ϕ 180. Suppose that R = 750 Ω. Find the numerical value of Vo.

4 Find the numerical value of ϕ. Express your answer using three significant figures. Problem 6 The parameters in the circuit shown in the figure are R1=0.1Ω, ωl1=0.8ω, R2=24Ω, ωl2=32ω, and VL= 320 +j0v. Calculate the phasor voltage Vs. Enter your answer using polar notation. Express argument in degrees. Connect a capacitor in parallel with the inductor, hold VL constant, and adjust the capacitor until the magnitude of I is a minimum. What is the capacitive reactance? Express your answer in complex form. Connect a capacitor in parallel with the inductor, hold VL constant, and adjust the capacitor until the magnitude of I is a minimum. What is the value of Vs? Enter your answer using polar notation. Express argument in degrees. Part D Find the value of the capacitive reactance that keeps the magnitude of I as small as possible and that at the same time makes Vs = VL = 320 V.

5 Problem 7 A load consisting of a 480 Ω resistor in parallel with a (5/9)μF capacitor is connected across the terminals of a sinusoidal voltage source vg, where vg=160 cos5000tv. What is the peak value of the instantaneous power delivered by the source? What is the peak value of the instantaneous power absorbed by the source? What is the average power delivered to the load? Part D What is the reactive power delivered to the load? Part E Does the load absorb or generate magnetizing vars? Part F What is the power factor of the load? Part G What is the reactive factor of the load? Problem 8 A personal computer with a monitor and keyboard requires 60 W at 115 V (rms). Calculate the rms value of the current carried by its power cord. A laser printer for the personal computer is rated at 90 W at 115 V (rms). If this printer is plugged into the same wall outlet as the computer, what is the rms value of the current drawn from the outlet?

6 Problem 9 The periodic current shown in the figure dissipates an average power of 1050 W in a resistor. (This is a fun question, think clearly!) What is the value of the resistor? Problem 10 The two loads shown in can be described as follows: Load 1 absorbs an average power of 10 kw and delivers 4 kvar of reactive power; load 2 has an impedance of (60+j80) Ω. The voltage at the terminals of the loads is cos100πtv. Find the rms value of the source voltage.

7 Express your answer to four significant figures and include the appropriate units. Determine by how many time is the load voltage out of phase with the source voltage by finding the value of (θvl θvg)/ω, where θvl and θvg are the phase angles of the voltages VL and Vg respectively, and ω is the angular frequency of the voltages. Does the load voltage lead or lag the source voltage? Problem 11 A factory has an electrical load of 1600 kw at a lagging power factor of 0.8. An additional variable power factor load is to be added to the factory. The new load will add 360 kw to the real power load of the factory. The power factor of the added load is to be adjusted so that the overall power factor of the factory is 0.97 lagging. Specify the reactive power associated with the added load. Does the added load absorb or deliver magnetizing vars? What is the power factor of the additional load? Part D Assume that the voltage at the input to the factory is 2100 V (rms). What is the rms magnitude of the current into the factory before the variable power factor load is added? Part E What is the rms magnitude of the current into the factory after the variable power factor load has been added?

8 Problem 12 The variable resistor R in the circuit shown in is adjusted until the average power it absorbs is maximum. Suppose that Vs=350 0 V (rms). Find the value of the resistor R required for the maximum average power absorbed by it. Find the maximum average power for the resistor R. Find a resistor from the table shown in that would have the most average power delivered to it.

= 32.0\cis{38.7} = j Ω. Zab = Homework 2 SJTU233. Part A. Part B. Problem 2. Part A. Problem 1

= 32.0\cis{38.7} = j Ω. Zab = Homework 2 SJTU233. Part A. Part B. Problem 2. Part A. Problem 1 Homework 2 SJTU233 Problem 1 Find the impedance Zab in the circuit seen in the figure. Suppose that R = 5 Ω. Express Zab in polar form. Enter your answer using polar notation. Express argument in degrees.

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