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Chapter 8 Chapter 8 Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Voltage sources Principles of Electric Circuits - Floyd 4 Current (A) An ideal voltage source plots a vertical line on the VI characteristic as shown for the ideal 6.0 V source. Actual voltage sources include the internal source resistance, which can drop a small voltage under load. The characteristic of a nonideal source is not vertical. 5 3 2 1 0 0 2 6 4 Voltage (V) 8 10 © Copyright 2006 Prentice-Hall Chapter 8 Summary Voltage sources A practical voltage source is drawn as an ideal source in series with the source resistance. When the internal resistance is zero, the source reduces to an ideal one. RS VS + Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Voltage sources If the source resistance of a 5.0 V power supply is 0.5 W, what is the voltage across a 68 W load? RS Use the voltage-divider equation: VS + 5.0 V RL VL VS RL RS 68 W 5 V = 4.96 V 68 W 0.5 W Principles of Electric Circuits - Floyd VOUT 0.5 W RL 68 W © Copyright 2006 Prentice-Hall Chapter 8 Summary Current sources Principles of Electric Circuits - Floyd 4 Current (A) An ideal current source plots a horizontal line on the VI characteristic as shown for the ideal 4.0 mA source. Practical current sources have internal source resistance, which takes some of the current. The characteristic of a practical source is not horizontal. 5 3 2 1 0 0 2 6 4 Voltage (V) 8 10 © Copyright 2006 Prentice-Hall Chapter 8 Summary Current sources A practical current source is drawn as an ideal source with a parallel source resistance. When the source resistance is infinite, the current source is ideal. IS Principles of Electric Circuits - Floyd RS © Copyright 2006 Prentice-Hall Chapter 8 Summary Current sources If the source resistance of a 10 mA current source is 4.7 kW, what is the voltage across a 100 W load? Use the current-divider equation: IS 10 mA RS IL IS RL RS 4.7 kW 10 mA = 9.8 mA 100 W 4.7 kW Principles of Electric Circuits - Floyd RS 4.7 kW RL 100 W © Copyright 2006 Prentice-Hall Chapter 8 Summary Source conversions Any voltage source with an internal resistance can be converted to an equivalent current source and viceversa by applying Ohm’s law to the source. The source resistance, RS, is the same for both. To convert a voltage source to a current source, I S VS RS To convert a current source to a voltage source, VS IS RS Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Superposition theorem The superposition theorem is a way to determine currents and voltages in a linear circuit that has multiple sources by taking one source at a time and algebraically summing the results. R3 R1 + - VS2 18 V R2 6.8 kW - - VS1 12 V 6.8 kW I2 + Principles of Electric Circuits - Floyd 2.7 kW + What does the ammeter read for I2? (See next slide for the method and the answer). © Copyright 2006 Prentice-Hall Chapter 8 Summary + +1.56 mA - Source 1: Source 2: VS1 12 V 6.8 kW I2 VS2 18 V R2 6.8 kW - 2.7 kW Set up a table of pertinent information and solve for each quantity listed: R3 R1 + What does the ammeter read for I2? RT(S1)= 6.10 kW I1= 1.97 mA I2= 0.98 mA RT(S2)= 8.73 kW I3= 2.06 mA I2= 0.58 mA Both sources I2= 1.56 mA The total current is the algebraic sum. Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Thevenin’s theorem Thevenin’s theorem states that any two-terminal, resistive circuit can be replaced with a simple equivalent circuit when viewed from two output terminals. The equivalent circuit is: RTH VTH Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Thevenin’s theorem VTH is defined as the open circuit voltage between the two output terminals of a circuit. RTH is defined as the total resistance appearing between the two output terminals when all sources have been replaced by their internal resistances. RTH VTH Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Thevenin’s theorem What is the Thevenin voltage for the circuit? 8.76 V What is the Thevenin resistance for the circuit? 7.30 kW Output terminals R1 VS 12 V 10 kW R2 27 kW Principles of Electric Circuits - Floyd RL 68 kW Remember, the load resistor has no affect on the Thevenin parameters. © Copyright 2006 Prentice-Hall Chapter 8 Summary Thevenin’s theorem Thevenin’s theorem is useful for solving the Wheatstone bridge. One way to Thevenize the bridge is to create two Thevenin circuits - from A to ground and from B to ground. The resistance between point R1 R2 V A and ground is R1||R3 and the S + RL A B resistance from B to ground is R2||R4. The voltage on each R3 R4 side of the bridge is found using the voltage divider rule. Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Thevenin’s theorem For the bridge shown, R1||R3 = 165 W and R2||R4 = 179 W . The voltage from A to ground (with no load) is 7.5 V and from B to ground (with no load) is 6.87 V . VS +15 V + - R1 R2 330 W 390 W RL A B 150 W R3 R4 330 W 330 W The Thevenin circuits for each of the bridge are shown on the following slide. Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Thevenin’s theorem RTH A RL VTH 7.5 V 165 W 150 W B RTH' 179 W VTH' 6.87 V Putting the load on the Thevenin circuits and applying the superposition theorem allows you to calculate the load current. The load current is: 1.27 mA Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Norton’s theorem Norton’s theorem states that any two-terminal, resistive circuit can be replaced with a simple equivalent circuit when viewed from two output terminals. The equivalent circuit is: IN Principles of Electric Circuits - Floyd RN © Copyright 2006 Prentice-Hall Chapter 8 Summary Norton’s theorem IN is defined as the output current when the output terminals are shorted. RN is defined as the total resistance appearing between the two output terminals when all sources have been replaced by their internal resistances. IN Principles of Electric Circuits - Floyd RN © Copyright 2006 Prentice-Hall Chapter 8 Summary Norton’s theorem What is the Norton current for the circuit? 17.9 mA What is the Norton resistance for the circuit? 359 W R1 VS + 10 V Output terminals 560 W R2 1.0 kW RL 820 W The Norton circuit is shown on the following slide. Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Norton’s theorem The Norton circuit (without the load) is: IN 17.9 mA Principles of Electric Circuits - Floyd RN 359 W © Copyright 2006 Prentice-Hall Chapter 8 Summary Maximum power transfer The maximum power is transferred from a source to a load when the load resistance is equal to the internal source resistance. RS VS + RL The maximum power transfer theorem assumes the source voltage and resistance are fixed. Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Summary Maximum power transfer What is the power delivered to the matching load? RS The voltage to the load is 5.0 V. The power delivered is V 2 5.0 V PL = 0.5 W RL 50 W 2 Principles of Electric Circuits - Floyd VS + 10 V 50 W RL 50 W © Copyright 2006 Prentice-Hall Chapter 8 Summary D-to-Y and Y-to-D conversion The D-to-Y and Y-to-D conversion formulas allow a three terminal resistive network to be replaced with an equivalent network. RC For the D-to-Y conversion, each resistor in the Y is equal to the product of the resistors in the two adjacent D branches divided by the sum of all three D resistors. Principles of Electric Circuits - Floyd R1 RA R2 R3 RB © Copyright 2006 Prentice-Hall Chapter 8 Summary D-to-Y and Y-to-D conversion The D-to-Y and Y-to-D conversion formulas allow a three terminal resistive network to be replaced with an equivalent network. R C For the Y-to-D conversion, each R1 resistor in the D is equal to the sum of all products of Y resistors, taken RA two at a time divided by the opposite Y resistor. Principles of Electric Circuits - Floyd R2 R3 RB © Copyright 2006 Prentice-Hall Chapter 8 Key Terms Current source A device that ideally provides a constant value of current regardless of the load. Maximum power Transfer of maximum power from a source transfer to a load occurs when the load resistance equals the internal source resistance. Norton’s A method for simplifying a two-terminal theorem linear circuit to an equivalent circuit with only a current source in parallel with a resistance. Superposition A method for analysis of circuits with more theorem than one source. Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Key Terms Terminal The concept that when any given load is equivalency connected to two sources, the same load voltage and current are produced by both sources. Thevenin’s A method for simplifying a two-terminal theorem linear circuit to an equivalent circuit with only a voltage source in series with a resistance. Voltage source A device that ideally provides a constant value of voltage regardless of the load. Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz 1. The source resistance from a 1.50 V D-cell is 1.5 W. The voltage that appears across a 75 W load will be a. 1.47 V RS b. 1.50 V c. 1.53 V d. 1.60 V Principles of Electric Circuits - Floyd VS + 1.5 V VOUT 1.5 W RL 75 W © Copyright 2006 Prentice-Hall Chapter 8 Quiz 2. The internal resistance of an ideal current source a. is 0 W b. is 1 W c. is infinite d. depends on the source Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz 3. The superposition theorem cannot be applied to a. circuits with more than two sources b. nonlinear circuits c. circuits with current sources d. ideal sources Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz 4. A Thevenin circuit is a a. resistor in series with a voltage source b. resistor in parallel with a voltage source c. resistor in series with a current source d. resistor in parallel with a current source Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz 4. A Norton circuit is a a. resistor in series with a voltage source b. resistor in parallel with a voltage source c. resistor in series with a current source d. resistor in parallel with a current source Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz 5. A signal generator has an output voltage of 2.0 V with no load. When a 600 W load is connected to it, the output drops to 1.0 V. The Thevenin resistance of the generator is a. 300 W b. 600 W c. 900 W d. 1200 W. Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz 6. A signal generator has an output voltage of 2.0 V with no load. When a 600 W load is connected to it, the output drops to 1.0 V. The Thevenin voltage of the generator is a. 1.0 V b. 2.0 V c. 4.0 V d. not enough information to tell. Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz 7. A Wheatstone bridge is shown with the Thevenin circuit as viewed with respect to ground. The total Thevenin resistance (RTH + RTH’) is R1 R2 a. 320 W VS + 1.0 kW A - b. 500 W R3 1.0 kW RL 100 W 1.0 kW B R4 470 W c. 820 W d. 3.47 kW. RTH VTH Principles of Electric Circuits - Floyd RL ' RTH VTH' © Copyright 2006 Prentice-Hall Chapter 8 Quiz 8. The Norton current for the circuit is R1 a. 5.0 mA b. 6.67 mA c. 8.33 mA VS + 10 V 1.0 kW R2 1.0 kW RL 1.0 kW d. 10 mA Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz 9. The Norton resistance for the circuit is R1 a. 500 W b. 1.0 kW c. 1.5 kW VS + 10 V 1.0 kW R2 1.0 kW RL 1.0 kW d. 2.0 kW Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz 10. Maximum power is transferred from a fixed source when a. the load resistor is ½ the source resistance b. the load resistor is equal to the source resistance c. the load resistor is twice the source resistance d. none of the above Principles of Electric Circuits - Floyd © Copyright 2006 Prentice-Hall Chapter 8 Quiz Answers: Principles of Electric Circuits - Floyd 1. a 6. b 2. c 7. c 3. b 8. d 4. d 9. a 5. b 10. b © Copyright 2006 Prentice-Hall