Presentation is loading. Please wait.

Presentation is loading. Please wait.

EEE340Lecture 081 Example 3-1 Determine the electric field intensity at P (-0.2, 0, -2.3) due to a point charge of +5 (nC) at Q (0.2,0.1,-2.5) Solution.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "EEE340Lecture 081 Example 3-1 Determine the electric field intensity at P (-0.2, 0, -2.3) due to a point charge of +5 (nC) at Q (0.2,0.1,-2.5) Solution."— Presentation transcript:

1 EEE340Lecture 081 Example 3-1 Determine the electric field intensity at P (-0.2, 0, -2.3) due to a point charge of +5 (nC) at Q (0.2,0.1,-2.5) Solution

2 EEE340Lecture 082 Example 3-2 Determine electric field intensity at an arbitrary point inside the shell. (We’ll do it by Gauss’ Law)

3 EEE340Lecture 083 Example 3-3 Velocity uniform electric field over a width w. Find the vertical deflection z=L. Solution

4 EEE340Lecture 084 3-3.1 E-Field due to Discrete Charges We can use the principle of superposition.

5 EEE340Lecture 085 The resultant force on charge q located at point is the vector sum of the forces exerted on q by each of the charges q 1, q 2, …, q N. or The electric field intensity (electric field strength) is in the direction of and is measured in N/C or V/m (force per unit charge)

6 EEE340Lecture 086 The electric field intensity at point due to a point charge q at. For N point charges q 1, q 2, … q N located at Practice exercise: Point charge 5nC is located at (2,0,4) point charge -2nC is located at (-3,0,5) Find at (1,-3,7)

7 EEE340Lecture 087 The total E-field Electric dipole: a pair of equal and opposite charges +q and –q separated by a small distance, d<< observation location, r. (3.23) +q0 -q0 0d P

8 EEE340Lecture 088 Approximation under d<<r Similarly Hence (3.26)

9 EEE340Lecture 089 Define the dipole moment where vector distance is from -q to +q Then In spherical coordinates, by using Eq. (2-77) or

10 EEE340Lecture 0810 3-3.2: E-field due to distributed charges The differential charge  dv’ that contributes to the electric field intensity at the observation (field) point P is where Hence for volume distribution of charges For a surface distribution with charge density  s (3.34) (3.35) (3.32)

11 EEE340Lecture 0811 For a line charge Example 3-4: Infinitely long straight line with uniform charge density, find Solution. Because of the symmetry, we select a cylinder coordinate system. where Hence (3.36)

Download ppt "EEE340Lecture 081 Example 3-1 Determine the electric field intensity at P (-0.2, 0, -2.3) due to a point charge of +5 (nC) at Q (0.2,0.1,-2.5) Solution."

Similar presentations

The divergence of E If the charge fills a volume, with charge per unit volume . R Where d is an element of volume. For a volume charge:

The divergence of E If the charge fills a volume, with charge per unit volume . R Where d is an element of volume. For a volume charge:
Electricity. Electrostatic The Electric Field Electric charge. Conductors and Insulators Coulomb´s Law The Electric field. Electric Field Lines Calculating.

Electricity. Electrostatic The Electric Field Electric charge. Conductors and Insulators Coulomb´s Law The Electric field. Electric Field Lines Calculating.
Electric Potential AP Physics Montwood High School R. Casao.

Electric Potential AP Physics Montwood High School R. Casao.
Sources of the Magnetic Field

Sources of the Magnetic Field
Phys 102 – Lecture 3 The Electric field 1. Today we will... Learn about the electric field Apply the superposition principle Ex: Dipole, line of charges,

Phys 102 – Lecture 3 The Electric field 1. Today we will... Learn about the electric field Apply the superposition principle Ex: Dipole, line of charges,
Copyright © 2009 Pearson Education, Inc. Chapter 21 Electric Charge and Electric Field.

Copyright © 2009 Pearson Education, Inc. Chapter 21 Electric Charge and Electric Field.
Chapter 2 Electrostatics 2.0 New Notations 2.1 The Electrostatic Field 2.2 Divergence and Curl of Electrostatic Field 2.3 Electric Potential 2.4 Work and.

Chapter 2 Electrostatics 2.0 New Notations 2.1 The Electrostatic Field 2.2 Divergence and Curl of Electrostatic Field 2.3 Electric Potential 2.4 Work and.
EE3321 ELECTROMAGENTIC FIELD THEORY

EE3321 ELECTROMAGENTIC FIELD THEORY
Real Insulators (Dielectrics)

Real Insulators (Dielectrics)
Lecture 10EEE 3401 For a line charge Example 3-4: Infinitely long straight line with uniform charge density, find Solution. Because of the symmetry, we.

Lecture 10EEE 3401 For a line charge Example 3-4: Infinitely long straight line with uniform charge density, find Solution. Because of the symmetry, we.
Chapter 23 Summer 1996, Near the University of Arizona Chapter 23 Electric Fields.

Chapter 23 Summer 1996, Near the University of Arizona Chapter 23 Electric Fields.
3-6. Conductors in Static Electric Field

3-6. Conductors in Static Electric Field
EEE340Lecture 231 6-5: Magnetic Dipole A circular current loop of radius b, carrying current I makes a magnetic dipole. For R>>b, the magnetic vector potential.

EEE340Lecture : Magnetic Dipole A circular current loop of radius b, carrying current I makes a magnetic dipole. For R>>b, the magnetic vector potential.
EEE340Lecture 131 3-8. Electric flux density and dielectric constant Where the electric flux density (displacement) Absolute permittivity Relative permittivity.

EEE340Lecture Electric flux density and dielectric constant Where the electric flux density (displacement) Absolute permittivity Relative permittivity.
EEE340Lecture 161 Solution 3: (to Example 3-23) Apply Where lower case w is the energy density.

EEE340Lecture 161 Solution 3: (to Example 3-23) Apply Where lower case w is the energy density.
Principle of Superposition (revisited) The presence of other charges does not change the force exerted by point charges. One can obtain the total force.

Principle of Superposition (revisited) The presence of other charges does not change the force exerted by point charges. One can obtain the total force.
Day18: Electric Dipole Potential & Determining E-Field from V

Day18: Electric Dipole Potential & Determining E-Field from V
Group of fixed charges exert a force F, given by Coulomb’s law, on a test charge q test at position r. The Electric Field The electric field E (at a given.

Group of fixed charges exert a force F, given by Coulomb’s law, on a test charge q test at position r. The Electric Field The electric field E (at a given.
Example Problem Solution:

Example Problem Solution:
Physics. ELECTROSTATICS - 2 Electric field due to a point charge Electric field due to a dipole Torque and potential energy of a dipole Electric lines.

Physics. ELECTROSTATICS - 2 Electric field due to a point charge Electric field due to a dipole Torque and potential energy of a dipole Electric lines.

Similar presentations

Ads by Google