Mastering Engineering with Pearson eText -- Standalone Access Card -- for Electrical Engineering: Principles & Applications
7th Edition
ISBN: 9780134486970
Author: Allan R. Hambley
Publisher: PEARSON
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Chapter 2, Problem 2.64P
We have a cube with 1-
- Use MATLAB to solve the matrix equation GV=1 for the node voltages and determine the resistance.
Figure P2.64
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Find the equivalent resistance looking into terminals for the network shown in Figure P2.60. [Hint: First, connect a 1-A current source across terminals a and b. Then, solve the network by the node-voltage technique. The voltage across the current source is equal in value to the equivalent resistance.]
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Connect a 1-V voltage source across the terminals of the network shown in Figure P2.1(a). Then, solve the network by the mesh-current technique to find the current through the source. Finally, divide the source voltage by the current to determine the equivalent resistance looking into the terminals. Check your answer by combining resistances in series and parallel.
Chapter 2 Solutions
Mastering Engineering with Pearson eText -- Standalone Access Card -- for Electrical Engineering: Principles & Applications
Ch. 2 - Reduce each of the networks shown in Figure P2.1...Ch. 2 - A 4- resistance is in series with the parallel...Ch. 2 - Find the equivalent resistance looking into...Ch. 2 - Suppose that we need a resistance of 1.5 k and...Ch. 2 - Find the equivalent resistance between terminals a...Ch. 2 - Find the equivalent resistance between terminals a...Ch. 2 - What resistance in parallel with 120 results in...Ch. 2 - Determine the resistance between terminals a and b...Ch. 2 - Two resistances having values of R and 2R are in...Ch. 2 - A network connected between terminals a and b...
Ch. 2 - Two resistances R1 and R2 are connected in...Ch. 2 - Find the equivalent resistance for the infinite...Ch. 2 - If we connect n 1000- resistances in parallel,...Ch. 2 - The heating element of an electric cook top has...Ch. 2 - We are designing an electric space heater to...Ch. 2 - Sometimes, we can use symmetry considerations to...Ch. 2 - The equivalent resistance between terminals a and...Ch. 2 - Three conductances G1 G2, and G3 are in series....Ch. 2 - Most sources of electrical power behave as...Ch. 2 - The resistance for the network shown in Figure...Ch. 2 - Often, we encounter delta-connected loads such as...Ch. 2 - What are the steps in solving a circuit by network...Ch. 2 - Find the values of i1 and i2 in Figure P2.23....Ch. 2 - Find the voltages v1 and v2 for the circuit shown...Ch. 2 - Find the values of v and i in Figure P2.25. 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- Solve for the node voltages shown in Figure P2.59.arrow_forwardThe terminal voltage and terminal current were measured on thedevice shown in P2.14(a). The values of v and i are given in thetable of P2.14(b). Use the values in the table to construct a circuitmodel for the device consisting of a single resistor from Appendix H.arrow_forwardDetermine the value of in Figure P2.52 using node voltages to solve the circuit. Select the location of the reference node to minimize the number of unknown node voltages. What effect does the 20-Ω resistance have on the answer? Explain.arrow_forward
- Solve for the power delivered to the 8-Ω resistance and for the node voltages shown in Figure P2.58.arrow_forwardSolve for the power delivered by the voltage source in Figure P2.68, using the meshcurrent method.arrow_forwardA module with 40 cells has an idealized, rectangular I-V curve with ISC = 4 A and VOC = 20 V. If a single cell has a parallel resistance of 5 ohms and negligible series resistance, draw the I-V curve if one cell is completely shaded. What current would it deliver to a 12-V battery (vertical I-V load at 12 V)?arrow_forward
- Find the power delivered by each source in thecircuits of Figure P2.19.arrow_forwardFind the Thévenin and Norton equivalent circuits for the two-terminal circuit shown in Figure P2.80.arrow_forwardfollowing equation applies: V = IR. Outside of the linear range, V*IR, outside of the linear ranges where resistors are broken The resistor has a resistance of 100ohm, and a power rating of 250mW. 1) Sketch the plot (and label) of the i-v relationship for the resistor using only the linear range of the resistor. Determine the range of values for the voltage and current that the resistor operates as a linear element and note these simplified numerical values on the plot.arrow_forward
- Find the voltages v1 and v2 for the circuit shown in Figure P2.24 by combining resistances in series and parallel.arrow_forward4. Find the equivalent resistance Req for the circuit in Figure P.4, if R1 = 20 Ω, R2 = 10 Ω, R3 = 10 Ω, R4 = 5 Ω.arrow_forwardA battery can be modeled by a voltage source Vt in series with a resistance Rt. Assuming that the load resistance is selected to maximize the power delivered, what percentage of the power taken from the voltage source Vt is actually delivered to the load? Suppose that RL=9Rt; what percentage of the power taken from Vt is delivered to the load? Usually, we want to design battery-operated systems so that nearly all of the energy stored in the battery is delivered to the load. Should we design for maximum power transfer?arrow_forward
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