Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 20 Pretest Circuits. 1. If the batteries in a portable CD player provide a terminal voltage of 12 V, what is the potential difference across.

Published byEric Beasley Modified over 8 years ago

Similar presentations

Presentation on theme: "Chapter 20 Pretest Circuits. 1. If the batteries in a portable CD player provide a terminal voltage of 12 V, what is the potential difference across."— Presentation transcript:

1 Chapter 20 Pretest Circuits

2

3 1. If the batteries in a portable CD player provide a terminal voltage of 12 V, what is the potential difference across the entire player? A. 3.0 VB. 4.0 V C. 6.0 VD. 12 V

4

5 2. Three resistors with values of 3.0 Ω, 6.0 Ω, and 12 Ω are connected in series. What is the equivalent resistance of this combination? A. 0.58 ΩB. 1.7 Ω C. 7.0 ΩD. 21 Ω

6

7 3. Three resistors connected in parallel carry currents labeled I 1, I 2, and I 3. Which of the following expresses the total current I T in the combined system? A. I T = I 1 + I 2 + I 3 B. I T = (1/I 1 + 1/I 2 + 1/I 3 ) C. I T = I 1 = I 2 = I 3 D. I T = (1/I 1 + 1/I 2 + 1/I 3 ) -1

8

9 4. What is the equivalent resistance for the resistors in the figure above? A. 25 ΩB. 10 Ω C. 7.5 Ω D. 5.0 Ω

10 WOW, no figure! Sorry!

11 1. What are the two formulas for calculating equivalent resistance?

12 Series: R T = R 1 + R 2 + R 3 Parallel: 1/R T = 1/R 1 + 1/R 2 + 1/R 3

13 2a. What is the equivalent resistance in the circuit shown above? b. If the battery is 12V, what is the current in the circuit? c. What is the current in the 6Ω resistor? d. What is the rate of energy dissipation for the 6Ω resistor? e. What is the rate of energy dissipation for the entire circuit?

14 2a. The 8 Ω and 4 Ω resistors are replaced with a 12 Ω resistor. This 12 and the other 12 are in parallel, so they can be replaced with a 6 Ω resistor. The 6 Ω and 4 Ω resistors are in parallel, so they can be replaced with a 2.4 Ω resistor. This 2.4 Ω resistor is in series with the 6 Ω resistor, so the total resistance is 8.4 Ω.

15 b. If the battery is 12V, what is the current in the circuit? V = IR 12 V = I x 8.4 Ω I = 1.43 A

16 c. What is the current in the 6Ω resistor? The 6 Ω resistor is in series with the source, so it gets all the current. I = 1.43 A

17 d. What is the rate of energy dissipation for the 6Ω resistor? The current I is 1.43 A. The voltage drop is V = IR, V = 1.43 x 6 = 8.58 V. P = IV P = 1.43 x 8.58 P = 12.3 W

18 e. What is the rate of energy dissipation for the entire circuit? P = IV P = 1.43 x 12 P = 17.16 W

19 3. A student is provided with a 12.0-V battery of negligible internal resistance and four resistors with the following resistances: 100 Ω, 30 Ω, 20 Ω, and 10 Ω. The student also has plenty of wire of negligible resistance available to make the connections as desired. (a)Using all of these components, draw a circuit diagram in which each resistor has nonzero current flowing through it, but in which the current from the battery is as small as possible.

20 A series circuit would make the resistance highest, so the current would be lowest.

21 3. A student is provided with a 12.0-V battery of negligible internal resistance and four resistors with the following resistances: 100 Ω, 30 Ω, 20 Ω, and 10 Ω. The student also has plenty of wire of negligible resistance available to make the connections as desired. (b) Using all of these components, draw a circuit diagram in which each resistor has nonzero current flowing through it, but in which the current from the battery is as large as possible (without short circuiting the battery).

22 A parallel circuit would make the resistance lowest, so the current would be as high as possible.

23 The battery and resistors are now connected in the circuit shown above. (c) Determine the equivalent resistance in the circuit.

24 (c) Determine the equivalent resistance in the circuit. The 20 Ω and 30 Ω resistors are in series, so they are equal to a 50 Ω resistor. This 50 is in parallel with the 100 Ω resistor, so they can be replaced with a 33 Ω resistor. This 33 is in series with the 10, so the total resistance is 43 Ω.

25 (d) Determine the current in the 10-Ω resistor. This resistor is in series with the source, so it gets all the current. V = IR 12 V = I x 43 Ω. I = 0.28 A

26 4. Three resistors with values of 16 Ω, 19 Ω, and 25 Ω, respectively, are connected in parallel. What is their equivalent resistance?

27 1/R T = 1/R 1 + 1/R 2 + 1/R 3 1/R T = 1/16 + 1/19 + 1/25 1/R T = 0.0625 + 0.053 + 0.04 1/R T = 0.15513 R T = 6.45 Ω

28

29 1/R P = 1/R 1 + 1/R 2 + 1/R 3 1/R P = 1/3 + 1/4 + 1/5 1/R P = 0.33 + 0.25 + 0.2 1/R P = 0.78 R P = 1.28 Ω

Download ppt "Chapter 20 Pretest Circuits. 1. If the batteries in a portable CD player provide a terminal voltage of 12 V, what is the potential difference across."

Similar presentations

Capacitors and/or TV (not Emf). 1. An empty capacitor does not resist the flow of current, and thus acts like a wire. 2. A capacitor that is full of charge.

Capacitors and/or TV (not Emf). 1. An empty capacitor does not resist the flow of current, and thus acts like a wire. 2. A capacitor that is full of charge.
Worksheet: Circuits and Ohm’s Law

Worksheet: Circuits and Ohm’s Law
Dr. Jie ZouPHY 13611 Chapter 28 Direct Current Circuits.

Dr. Jie ZouPHY Chapter 28 Direct Current Circuits.
Circuits Series and Parallel. Series Circuits Example: A 6.00 Ω resistor and a 3.00 Ω resistor are connected in series with a 12.0 V battery. Determine.

Circuits Series and Parallel. Series Circuits Example: A 6.00 Ω resistor and a 3.00 Ω resistor are connected in series with a 12.0 V battery. Determine.
Parallel Resistors Checkpoint

Parallel Resistors Checkpoint
Direct Current Circuits

Direct Current Circuits
If current is disrupted through one element (e.g. the light goes out) If current is disrupted through one element (e.g. the light goes out) then they.

If current is disrupted through one element (e.g. the light goes out) If current is disrupted through one element (e.g. the light goes out) then they.
Announcements Master of Exam I is available in E-learning. The scores will be posted soon. Class average of 12.46 and standard deviation 3.42 QUESTIONS?

Announcements Master of Exam I is available in E-learning. The scores will be posted soon. Class average of and standard deviation 3.42 QUESTIONS?
Lecture 2 Basic Circuit Laws

Lecture 2 Basic Circuit Laws
Basic Electronics II Series and Parallel Circuits.

Basic Electronics II Series and Parallel Circuits.
Series Circuits Series circuit: a circuit in which all parts are connected end to end to provide a single path for the current. Ammeters are always placed.

Series Circuits Series circuit: a circuit in which all parts are connected end to end to provide a single path for the current. Ammeters are always placed.
Series Circuits Circuits in which there is only one path for current to flow through All elements of the circuit (resistors, switches etc…) are in the.

Series Circuits Circuits in which there is only one path for current to flow through All elements of the circuit (resistors, switches etc…) are in the.
Series, Parallel, and Series- Parallel Circuits

Series, Parallel, and Series- Parallel Circuits
MHS Physics Department AP Unit III C 2 Steady state direct current circuits with batteries and resistors only.

MHS Physics Department AP Unit III C 2 Steady state direct current circuits with batteries and resistors only.
Unit 6 Series Circuits.

Unit 6 Series Circuits.
Preview Objectives Schematic Diagrams Electric Circuits Chapter 18 Section 1 Schematic Diagrams and Circuits.

Preview Objectives Schematic Diagrams Electric Circuits Chapter 18 Section 1 Schematic Diagrams and Circuits.
Twenty Questions Electricity 1. Twenty Questions 12345 678910 1112131415 1617181920.

Twenty Questions Electricity 1. Twenty Questions
Electric Circuits. What is an Electric Circuit? Electric Circuit: is a closed loop through which charges can continuously move. Need to have complete.

Electric Circuits. What is an Electric Circuit? Electric Circuit: is a closed loop through which charges can continuously move. Need to have complete.
CHAPTER 18 Direct Current Circuits. Sources of emf  The source that maintains the current in a closed circuit is called a source of emf.  Any devices.

CHAPTER 18 Direct Current Circuits. Sources of emf  The source that maintains the current in a closed circuit is called a source of emf.  Any devices.
Basic Electric Circuits Chapter 18. Circuit Components.

Basic Electric Circuits Chapter 18. Circuit Components.

Similar presentations

Ads by Google