Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Faraday’s Law of Induction If C is a stationary closed curve and S is a surface spanning C then The changing magnetic flux through S induces a non-electrostatic.

Published byCharleen Stafford Modified over 8 years ago

Similar presentations

Presentation on theme: "1 Faraday’s Law of Induction If C is a stationary closed curve and S is a surface spanning C then The changing magnetic flux through S induces a non-electrostatic."— Presentation transcript:

1 1 Faraday’s Law of Induction If C is a stationary closed curve and S is a surface spanning C then The changing magnetic flux through S induces a non-electrostatic electric field whose line integral around C is non-zero

2 2 Problem: Calculating Induced Electric Field Consider a uniform magnetic field which points into the page and is confined to a circular region with radius R. Suppose the magnitude increases with time, i.e. dB/dt > 0. Find the magnitude and direction of the induced electric field in the regions (i) r R. (iii) Plot the magnitude of the electric field as a function r.

3 3 W10D2 DC Circuits Today’s Reading Assignment W10D2 DC Circuits & Kirchhoff’s Loop Rules Course Notes: Sections 7.1-7.5

4 Announcements PS 8 due Week 11 Tuesday at 9 pm in boxes outside 32-082 or 26-152 Next Reading Assignment W10D3 PS07: PhET: Building a Circuit 7.1-7.5, 7.10 Exam 3 Thursday April 18 7:30 pm –9:30 pm 4

5 5 Outline DC Circuits Kirchoff’s Laws Electrical Power Measuring Voltage and Current

6 6 DC Circuits

7 7 Examples of Circuits

8 8 Symbols for Circuit Elements Battery Resistor Capacitor Switch Equipotential Junction Branch

9 9 Electromotive Force (EMF) The work per unit charge around a closed path done is called electromotive force EMF. This is a bad name because it is not a force. Let denote the force per unit charge, then the EMF is If a conducting closed path is present then

10 10 Ideal Battery 1)Inside Battery: chemical force non-zero inside battery (zero outside) moves charges through a region in which static electric field opposes motion 2) Ideal battery: net force on charges is zero 3) Potential difference between its terminals 4) Extend path through external circuit where

11 11 Sign Conventions - Battery Moving from the negative to positive terminal of a battery increases your potential

12 12 Sign Conventions - Resistor Moving across a resistor in the direction of current decreases your potential

13 Internal Resistance Real batteries have an internal resistance, r, which is small but non-zero Terminal voltage: (Even if you short the leads you don’t get infinite current)

14 14 Series vs. Parallel Series Parallel

15 15 Resistors In Series The same current I must flow through both resistors

16 16 Resistors In Parallel Voltage drop across the resistors must be the same

17 17 Measuring Voltage & Current

18 18 Measuring Potential Difference A voltmeter must be hooked in parallel across the element you want to measure the potential difference across Voltmeters have a very large resistance, so that they don’t affect the circuit too much

19 19 Measuring Current An ammeter must be hooked in series with the element you want to measure the current through Ammeters have a very low resistance, so that they don’t affect the circuit too much

20 20 Measuring Resistance An ohmmeter must be hooked in parallel across the element you want to measure the resistance of Here we are measuring R 1 Ohmmeters apply a voltage and measure the current that flows. They typically won’t work if the resistor is powered (connected to a battery)

21 P18 - 21 Concept Question: Bulbs & Batteries An ideal battery is hooked to a light bulb with wires. A second identical light bulb is connected in parallel to the first light bulb. After the second light bulb is connected, the current from the battery compared to when only one bulb was connected. 1.Is Higher 2.Is Lower 3.Is The Same 4.Don’t know

22 P18 - 22 Concept Question: Bulbs & Batteries An ideal battery is hooked to a light bulb with wires. A second identical light bulb is connected in series with the first light bulb. After the second light bulb is connected, the current from the battery compared to when only one bulb was connected. 1.Is Higher 2.Is Lower 3.Is The Same

23 23 Electrical Power Power is change in energy per unit time So power to move current through circuit elements:

24 24 Power - Battery I Moving from the negative to positive terminal of a battery increases your potential. If current flows in that direction the battery supplies power

25 25 Power – Resistor (Joule Heating) Moving across a resistor in the direction of current decreases your potential. Resistors always dissipate power

26 P18 - 26 Concept Question: Power An ideal battery is hooked to a light bulb with wires. A second identical light bulb is connected in parallel to the first light bulb. After the second light bulb is connected, the power output from the battery (compared to when only one bulb was connected) 1.Is four times higher 2.Is twice as high 3.Is the same 4.Is half as much 5.Is ¼ as much

27 P18 - 27 Concept Question: Power An ideal battery is hooked to a light bulb with wires. A second identical light bulb is connected in series with the first light bulb. After the second light bulb is connected, the light (power) from the first bulb (compared to when only one bulb was connected) 1.Is four times higher 2.Is twice as high 3.Is the same 4.Is half as much 5.Is ¼ as much

28 28 Kirchhoff’s Loop Rules

29 29 Current Conservation Sum of currents entering any junction in a circuit must equal sum of currents leaving that junction.

30 P18 - 30 Concept Question: Measuring Current If R 1 > R 2, compare the currents measured by the three ammeters: 1.A 1 > A 2 > A 3 2.A 2 > A 1 > A 3 3.A 3 > A 1 > A 2 4.A 3 > A 2 > A 1 5.A 3 > A 1 = A 2 6.None of the above 7.Not enough information is given.

31 31 Sum of Potential Differences Around a Closed Path Sum of potential differences across all elements around any closed circuit loop must be zero.

32 32 Sum of Potential Differences Around a Closed Path Sum of potential differences across all elements around any closed circuit loop must be zero.

33 33 Demonstration: Five Different Types of Resistance F13 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=F 13&show=0

34 34 Steps of Solving Circuit Problem 1. Straighten out circuit (make squares) 2. Simplify resistors in series/parallel 3. Assign current loops (arbitrary) 4. Write loop equations (1 per loop) 5. Solve

35 35 Worked Example: Circuit What is current through each branch of the circuit shown in the figure below?

36 36 Worked Example: Simple Circuit Upper Loop: Start at a and circulate clockwise. Then Current conservation at a: Lower Loop: Start at a and circulate clockwise. Then Solve for I 2 :and

37 37 Group Problem: Four Resistors Four resistors are connected to a battery as shown in the figure. The current in the battery is I, the battery emf is ε, and the resistor values are R 1 = R, R 2 = 2R, R 3 = 4R, R 4 = 3R. Determine the current in each resistor in terms of I.

38 38 Demonstration: Wheatstone Bridge F14 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=F 14&show=0

39 39 Group Problem: Wheatstone Bridge A circuit consisting of two resistors with R 1 =6.0 ohms and R 2 =1.5 ohms, a variable resistor, with resistance R var, a resistor of unknown value R u, and 9.0 volt battery, are connected as shown in the figure. When R var is adjusted to 12 ohms, there is zero current through the ammeter. What is the unknown resistance R u ?

Download ppt "1 Faraday’s Law of Induction If C is a stationary closed curve and S is a surface spanning C then The changing magnetic flux through S induces a non-electrostatic."

Similar presentations

Current Electricity & Ohm's Law.

Current Electricity & Ohm's Law.
Resistivity and Resistance

Resistivity and Resistance
Lecture 7 Circuits Ch. 27 Cartoon -Kirchhoff's Laws Topics –Direct Current Circuits –Kirchhoff's Two Rules –Analysis of Circuits Examples –Ammeter and.

Lecture 7 Circuits Ch. 27 Cartoon -Kirchhoff's Laws Topics –Direct Current Circuits –Kirchhoff's Two Rules –Analysis of Circuits Examples –Ammeter and.
Concept Questions with Answers 8.02 W10D2

Concept Questions with Answers 8.02 W10D2
Current. Current Current is defined as the flow of positive charge. Current is defined as the flow of positive charge. I = Q/t I = Q/t I: current in Amperes.

Current. Current Current is defined as the flow of positive charge. Current is defined as the flow of positive charge. I = Q/t I = Q/t I: current in Amperes.
Let us now use this realistic view of a battery in a simple circuit containing a battery and a single resistor. The electric potential difference across.

Let us now use this realistic view of a battery in a simple circuit containing a battery and a single resistor. The electric potential difference across.
Series and Parallel Circuits

Series and Parallel Circuits
Chapter 19 DC Circuits.

Chapter 19 DC Circuits.
Fundamentals of Circuits: Direct Current (DC)

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;

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;
Monday, Mar. 6, 2006PHYS 1444-501, Spring 2006 Dr. Jaehoon Yu 1 PHYS 1444 – Section 501 Lecture #12 Monday, Mar. 6, 2006 Dr. Jaehoon Yu EMF and Terminal.

Monday, Mar. 6, 2006PHYS , Spring 2006 Dr. Jaehoon Yu 1 PHYS 1444 – Section 501 Lecture #12 Monday, Mar. 6, 2006 Dr. Jaehoon Yu EMF and Terminal.
DC circuits Physics Department, New York City College of Technology.

DC circuits Physics Department, New York City College of Technology.
Fig 28-CO, p.858. Resistive medium Chapter 28 Direct Current Circuits 28.1 Electromotive “Force” (emf)

Fig 28-CO, p.858. Resistive medium Chapter 28 Direct Current Circuits 28.1 Electromotive “Force” (emf)
Copyright © 2009 Pearson Education, Inc. Lecture 7 – DC Circuits.

Copyright © 2009 Pearson Education, Inc. Lecture 7 – DC Circuits.
Electric Current and Direct-Current Circuits

Electric Current and Direct-Current Circuits
W12D1: RC and LR Circuits Reading Course Notes: Sections , , , ,

W12D1: RC and LR Circuits Reading Course Notes: Sections , , , ,
Electric current and direct-current circuits A flow of electric charge is called an electric current.

Electric current and direct-current circuits A flow of electric charge is called an electric current.
Internal Resistance Real batteries have a small internal resistance, r, which is small but non-zero Terminal voltage:  V  V b  V a P10 -    I r

Internal Resistance Real batteries have a small internal resistance, r, which is small but non-zero Terminal voltage:  V  V b  V a P10 -    I r
Monday, Oct. 10, 2005PHYS 1444-003, Fall 2005 Dr. Jaehoon Yu 1 PHYS 1444 – Section 003 Lecture #12 Monday, Oct. 10, 2005 Dr. Jaehoon Yu EMF and Terminal.

Monday, Oct. 10, 2005PHYS , Fall 2005 Dr. Jaehoon Yu 1 PHYS 1444 – Section 003 Lecture #12 Monday, Oct. 10, 2005 Dr. Jaehoon Yu EMF and Terminal.
Chapter 20: Circuits Current and EMF Ohm’s Law and Resistance

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

Similar presentations

Ads by Google