Engineering Circuit Analysis
9th Edition
ISBN: 9780073545516
Author: Hayt, William H. (william Hart), Jr, Kemmerly, Jack E. (jack Ellsworth), Durbin, Steven M.
Publisher: Mcgraw-hill Education,
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Chapter 5, Problem 52E
(a)
To determine
Find the power absorbed by the
(b)
To determine
Replace the
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Chapter 5 Solutions
Engineering Circuit Analysis
Ch. 5.1 - For the circuit of Fig. 5.4, use superposition to...Ch. 5.2 - For the circuit of Fig. 5.7, use superposition to...Ch. 5.2 - For the circuit of Fig. 5.18, compute the current...Ch. 5.2 - For the circuit of Fig. 5.20, compute the voltage...Ch. 5.3 - Using repeated source transformations, determine...Ch. 5.3 - Use Thvenins theorem to find the current through...Ch. 5.3 - Determine the Thvenin and Norton equivalents of...Ch. 5.3 - Find the Thvenin equivalent for the network of...Ch. 5.3 - Find the Thvenin equivalent for the network of...Ch. 5.4 - Consider the circuit of Fig. 5.43. FIGURE 5.43...
Ch. 5.5 - Prob. 11PCh. 5 - Linear systems are so easy to work with that...Ch. 5 - Prob. 2ECh. 5 - Prob. 3ECh. 5 - (a) Employ superposition to determine the current...Ch. 5 - (a) Using superposition to consider each source...Ch. 5 - (a) Determine the individual contributions of each...Ch. 5 - (a) Determine the individual contributions of each...Ch. 5 - After studying the circuit of Fig. 5.53, change...Ch. 5 - Consider the three circuits shown in Fig. 5.54....Ch. 5 - (a) Using superposition, determine the voltage...Ch. 5 - Employ superposition principles to obtain a value...Ch. 5 - (a) Employ superposition to determine the...Ch. 5 - Perform an appropriate source transformation on...Ch. 5 - (a) For the circuit of Fig. 5.59, plot iL versus...Ch. 5 - Determine the current labeled I in the circuit of...Ch. 5 - Verify that the power absorbed by the 7 resistor...Ch. 5 - (a) Determine the current labeled i in the circuit...Ch. 5 - (a) Using repeated source transformations, reduce...Ch. 5 - Prob. 19ECh. 5 - (a) Making use of repeated source transformations,...Ch. 5 - Prob. 21ECh. 5 - (a) With the assistance of source transformations,...Ch. 5 - For the circuit in Fig. 5.67 transform all...Ch. 5 - Prob. 24ECh. 5 - (a) Referring to Fig. 5.69, determine the Thevenin...Ch. 5 - (a) With respect to the circuit depicted in Fig....Ch. 5 - (a) Obtain the Norton equivalent of the network...Ch. 5 - (a) Determine the Thevenin equivalent of the...Ch. 5 - Referring to the circuit of Fig. 5.71: (a)...Ch. 5 - Prob. 30ECh. 5 - (a) Employ Thvenins theorem to obtain a...Ch. 5 - Prob. 32ECh. 5 - Determine the Norton equivalent of the circuit...Ch. 5 - For the circuit of Fig. 5.75: (a) Employ Nortons...Ch. 5 - (a) Obtain a value for the Thvenin equivalent...Ch. 5 - Prob. 36ECh. 5 - Obtain a value for the Thvenin equivalent...Ch. 5 - With regard to the network depicted in Fig. 5.79,...Ch. 5 - Determine the Thvenin and Norton equivalents of...Ch. 5 - Determine the Norton equivalent of the circuit...Ch. 5 - Prob. 41ECh. 5 - Determine the Thvenin and Norton equivalents of...Ch. 5 - Prob. 43ECh. 5 - Prob. 44ECh. 5 - Prob. 45ECh. 5 - (a) For the simple circuit of Fig. 5.87, find the...Ch. 5 - For the circuit drawn in Fig. 5.88, (a) determine...Ch. 5 - Study the circuit of Fig. 5.89. (a) Determine the...Ch. 5 - Prob. 49ECh. 5 - Prob. 50ECh. 5 - With reference to the circuit of Fig. 5.91, (a)...Ch. 5 - Prob. 52ECh. 5 - Select a value for RL in Fig. 5.93 such that it...Ch. 5 - Determine what value of resistance would absorb...Ch. 5 - Derive the equations required to convert from a...Ch. 5 - Convert the - (or "-") connected networks in Fig....Ch. 5 - Convert the Y-(or T-) connected networks in Fig....Ch. 5 - For the network of Fig. 5.97, select a value of R...Ch. 5 - For the network of Fig. 5.98, select a value of R...Ch. 5 - Prob. 60ECh. 5 - Calculate Rin as indicated in Fig.5.100. FIGURE...Ch. 5 - Employ Y conversion techniques as appropriate to...Ch. 5 - Prob. 63ECh. 5 - (a) Use appropriate techniques to obtain both the...Ch. 5 - (a) For the network in Fig. 5.104, replace the...Ch. 5 - Prob. 66ECh. 5 - Prob. 67ECh. 5 - A 2.57 load is connected between terminals a and...Ch. 5 - A load resistor is connected across the open...Ch. 5 - A backup is required for the circuit depicted in...Ch. 5 - (a) Explain in general terms how source...Ch. 5 - The load resistor in Fig. 5.108 can safely...Ch. 5 - Prob. 74ECh. 5 - As part of a security system, a very thin 100 ...Ch. 5 - With respect to the circuit in Fig. 5.90, (a)...
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- Don't use ai to answer I will report you answerarrow_forwardQ1. Consider the unity feedback control system whose open-loop transfer function is: G(s) = = 40(S + 2) s(s+3)(s + 1)(s + 10) hod of Ziegler-Nichols. By using second method of Ziegler- Nichols, calculate the PID, PI-D and I-PD parameters and make tuning for this for this parameters to get accepting response for the following system, then compare your results for all types controllers? GINarrow_forward1) Use the method of source transformation to find Ix in the following circuit. ΖΩ j4Ω wwwm -j20 60/0° V(+ 602 www 492 -j30 wwwarrow_forward
- Don't use ai to answer I will report you answerarrow_forward3) The sinusoidal voltage source in the following circuit is given by vg = 22.36 cos(5000t + 26.565°) V. Obtain the Thevenin equivalent of the circuit with respect to the terminals a, b. 50 mH Vg 250 Ω 400 nF 50 mH a barrow_forward2) Use the method of source transformation to find Vo in the following circuit. 102 w j30 0.202 10.6 Ω w m ΦΩΣ 10 Ω 40/0° V Vo -j352 -j19arrow_forward
- The distribution function for a random variable X is - F(x) = { 1 − e−²x² x ≥ 0 .Find a) the density function b)the probability x 2 and c) the probability that -3arrow_forward1. Tests of a 10 kVA, 230/2300 V single-phase transformer have yielded the following results: Vacuum test low voltage side: current = 0.45A Po = 70WLow side short circuit test: voltage = 11.6V Pcc = 224.3WDetermine: a. Parameters Rcc and Xcc of the equivalent circuit referring to the secondary.b. Transformer voltage regulation, if feeding a load of 4kVA, fp = 0.75 in delayc. Efficiency if the load is 7kVA, fp = 0.8 inductivearrow_forwardDon't use ai to answer I will report you answerarrow_forwardThe short-circuit test has been carried out on a single-phase transformer of 2500kVA,50kV/10kV, with the following results: 4000V, 50A , 50000 WIt is known that the transformer has a vacuum current equal to 2% and its efficiency at full load fp=1 is 97.5%. Calculate: A. Parameters of the excitation branch. Rfe, JXm, Pob. Relative voltage drops. εcc, εrcc, εxccarrow_forwardMagnetic Field Analysis of a Helical Coil In this lab you will analyse the inductive coil structure shown in Figure 1. It comprises a solid round copper wire of radius a = 0.8mm, wound into a cylindrical spiral having N = 20 turns, major radius R = 10mm and an axial pitch p = 2mm. The coil is excited by a dc current of 1A. R P 1 (a) Analytic Calculations Figure 1: Helical Air-cored Coil Using the expressions developed in the class, estimate the magnetic flux density B at the centre of the coil. Recall from EN1216 that for a long solenoid, the flux density is given by: HONI B l As we saw in the class (see section 4) a modified expression can also be derived that eliminates the need for the 'long' solenoid assumption: R α1 Р â B = HONI 2l (cosa₂-cosα1) 1 Compare the results obtained using equations (1) and (2) and state which solution you would expect to give the best approximation to the real coil behaviour.arrow_forwardI need immediate help with my SIMULINK model. I don't know why but no matter how much a increase or decrease Kc or TI, the graphs are the same. C'A0(s) is the disturbance going through G'D(s). Please check my transfer function blocks by taking the laplace transform of the equations. Any suggestions is welcome greatly! thanksarrow_forwardarrow_back_iosSEE MORE QUESTIONSarrow_forward_ios
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