AP Physics. Capacitors in Series C3C3 C2C2 C1C1 Capacitors in series share the same charge magnitude.

Slides:

Advertisements

Similar presentations

Circuits Electromotive Force Work, Energy and emf

Advertisements

Unit 3 Day 5: EMF & Terminal Voltage, & DC Resistor Circuits Electromotive Force (EMF) Terminal Voltage Internal Resistance Series, Parallel, and Series-

Q26.1 Which of the two arrangements shown has the smaller equivalent resistance between points a and b? A. the series arrangement B. the parallel arrangement.

Which of the two cases shown has the smaller equivalent resistance between points a and b? Q Case #1 2. Case #2 3. the equivalent resistance is.

© 2012 Pearson Education, Inc. Which of the two arrangements shown has the smaller equivalent resistance between points a and b? Q26.1 A. the series arrangement.

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.

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 that.

Fundamentals of Circuits: Direct Current (DC)

Chapter 19 DC Circuits. Units of Chapter 19 EMF and Terminal Voltage Resistors in Series and in Parallel Kirchhoff’s Rules EMFs in Series and in Parallel;

DC circuits Physics Department, New York City College of Technology.

Ch 26 – Capacitance and Dielectrics The capacitor is the first major circuit component we’ll study…

Dr. Jie ZouPHY Chapter 28 Direct Current Circuits.

Fig 28-CO, p.858. Resistive medium Chapter 28 Direct Current Circuits 28.1 Electromotive “Force” (emf)

Additional Questions (Direct Current Circuits)

Chapter 26 Capacitance and Dielectrics. Concept Question 1.

Capacitance (II) Capacitors in circuits Electrostatic potential energy.

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.

Electric current and direct-current circuits A flow of electric charge is called an electric current.

DC Electrical Circuits Chapter 28 Electromotive Force Potential Differences Resistors in Parallel and Series Circuits with Capacitors.

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

Resistors in Series and Parallel Circuits. Resistors in circuits To determine the current or voltage in a circuit that contains multiple resistors, the.

Chapter 20: Circuits Current and EMF Ohm’s Law and Resistance

Direct Current When the current in a circuit has a constant direction, the current is called direct current Most of the circuits analyzed will be assumed.

Series Circuits AKA Voltage Dividers Cardinal Rules for Series Circuits Potential difference is divided proportionately amongst each of the resistors placed.

Copyright © 2009 Pearson Education, Inc. Chapter 28: DC Circuits (Ch. 26 in the Giancoli Book!)

Lecture 6 Direct Current Circuits Chapter 18 Outline Energy Source in Circuits Resistor Combinations Kirchhoff’s Rules RC Circuits.

Chapter 28 Direct Current Circuits 1.R connections in series and in parallel 2.Define DC (direct current), AC (alternating current) 3.Model of a battery.

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

In conclusion, there are two requirements which must be met in order to establish an electric circuit. The requirements are: 1.There must.

Chapter 19 DC Circuits. Objectives: The student will be able to: Determine the equivalent capacitance of capacitors arranged in series or in parallel.

Chapter 28: Direct Current Circuits

Physics Chapter 20: Circuits and Circuit Elements.

Capacitance, Capacitors and Circuits. Start with a review The capacitance C is defined as To calculate the capacitance, one starts by introduce Q to the.

Lecture 17 Problems & Solution(1). [1] What is the magnitude of the current flowing in the circuit shown in Fig. 2? [2] A copper wire has resistance 5.

10/9/20151 General Physics (PHY 2140) Lecture 10  Electrodynamics Direct current circuits parallel and series connections Kirchhoff’s rules Chapter 18.

Physics 2102 Circuits Circuits Physics 2102 Gabriela González b a.

-Combinations of Capacitors -Energy Stored in a Charged Capacitor AP Physics C Mrs. Coyle.

AP Physics C Electric Circuits III.C. III.C.1 Current, Resistance and Power.

Schematic Diagrams & Circuits

DC Circuits. EMF and Terminal Voltage Electric circuit needs a battery or generator to produce current – these are called sources of emf. Battery is a.

Series and Parallel Circuits. Series Circuit Current must pass through all resistors.

Capacitors in a Circuit emf Resistors series parallel Circuit problems Capacitors in a circuit.

Fall 2008 Physics 121 Practice Problem Solutions 08A: DC Circuits Contents: 121P08 - 4P, 5P, 9P, 10P, 13P, 14P, 15P, 21P, 23P, 26P, 31P, 33P, Kirchoff’s.

Series wiring means that the devices are connected in such a way that there is the same electric current through each device. One loop only for the flow.

Chapter 20 Capacitors in Series and Parallel Capacitors in Circuits Like resistors, capacitors in circuits can be connected in series, in parallel, or.

Phys 102 – Lecture 7 Series and parallel circuits 1.

Electric Circuits.

Capacitors, Batteries. Capacitors Create a difference in Potential based upon how much charge is stored V = q/C (V) C : Capacitance C = k ε o A /d k :

111/16/2015 ELECTRICITY AND MAGNETISM Phy 220 Chapter 4: Capacitors.

Unfortunate book names:. A circuit must contain a source of potential difference, and a path for the flow of charge. It will probably also contain.

Chapter 25 Lecture 20: Capacitor and Capacitance.

Chapter 27: Circuits Introduction What are we going to talk about in chapter 28: What is an electromotive force ( E : emf)? What is the work done by an.

Series and Parallel Wiring GET A CALCULATOR!!!!!.

Today’s agenda: Capacitance. You must be able to apply the equation C=Q/V. Capacitors: parallel plate, cylindrical, spherical. You must be able to calculate.

Chapter 27 Lecture 23: Circuits: I. Direct Current When the current in a circuit has a constant direction, the current is called direct current Most of.

What is the equivalent resistance of this circuit? What is the current running through the first resistor? What is the potential difference drop across.

Electric Potential: Charged Conductor

Circuits Series vs Parallel. Electric Circuit Path of current flow As electrons move through a circuit, they transfer potential energy from the source.

CURRENT AND RESISTANCE LECTURE 8 DR. LOBNA MOHAMED ABOU EL-MAGD.

Electric Current and Circuits Ch. 18. Electric Current A net flow of charge Variable = I Unit = Ampere (A) I = Δq/Δt Conventional current is the direction.

12/4/2016 Advanced Physics Capacitance  Chapter 25 – Problems 1, 3, 8, (17), 19, (33), 39, 40 & 49.

Phys102 Lecture 10 & 11 DC Circuits Key Points EMF and Terminal Voltage Resistors in Series and in Parallel Circuits Containing Resistor and Capacitor.

Phys 102 – Lecture 7 Series and parallel circuits.

Circuits. The Basics The Symbols Wire Resistor Light Bulb Plug Battery Open Switch Closed Switch Capacitor.

Consider a charged capacitor whose plates are separated by air (dielectric constant 1.00 ). The capacitor is electrically isolated from its surroundings.

Capacitance (II) Capacitors in circuits Electrostatic potential energy.

Capacitors A capacitor is a device that has the ability “capacity” to store electric charge and energy.

Capacitors, Batteries.

Resistors & Capacitors in Series and Parallel

Chapter 28 Problems 2,6,8,9,15,20,21,36,40.

Presentation transcript:

AP Physics

Capacitors in Series C3C3 C2C2 C1C1 Capacitors in series share the same charge magnitude.

If C 1 = 6 μ F, C 2 = 2 μ F, and C 3 = 3 μ F, what is the equivalent capacitance C eq of the circuit? For capacitors connected in series the reciprocal of the equivalent capacitance is equal to the sum of the reciprocals of the individual capacitances: Notice that the equivalent capacitance is less than any of the individual capacitances. This is true any time capacitors are connected in series. Capacitors in Series C3C3 C2C2 C1C1

Capacitors in parallel share the same potential difference. Parallel Circuit C3C3 C2C2 C1C1

For capacitors connected in parallel the equivalent capacitance of the system is the sum of the capacitances of all the capacitors: If C 1 = 6 μ F, C 2 = 2 μ F, and C 3 = 3 μ F, what is the equivalent capacitance C eq of the circuit? The equivalent capacitance of capacitors connected in parallel is always more than the capacitance of any one capacitor. Parallel Circuit C3C3 C2C2 C1C1

1.Find the charge stored and the voltage across each capacitor in the following circuit. 30 µF 180 V 60 µF 90 µF

2.Find the energy stored in the circuit at equilibrium. 30 µF 180 V 60 µF 90 µF

2.Find the energy stored in the circuit at equilibrium. Find the equivalent capacitance. 30 µF 180 V 60 µF 90 µF 180 V

 Why do the charges flow?  When can they flow?  If the charges are always flowing from high potential to low potential how do they get at a higher potential to begin with?

Emf is not a force. It is an “energy per unit charge” quantity (just like potential). Symbol: Units are _____________________________________ What supplies the emf? Batteries, generators, power supplies These objects are like a water pump in a continuously flowing fountain

Ideal sources of emf have no internal resistance. Most sources of emf are not ideal and have some internal resistance r. R ε = V tot I V tot I R r ε

As a flashlight battery ages, its emf stays approximately constant, but its internal resistance increases. A fresh battery has an emf of 1.5 V and negligible internal resistance. When the battery needs replacement, its emf is still 1.5 V, but its internal resistance has increased to 1000 Ω. If this old battery is supplying 1.0 mA to a lightbulb, what is its terminal voltage? V tot I R r ε