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EEE241: Fundamentals of Electromagnetics

EEE241: Fundamentals of Electromagnetics. Introductory Concepts, Vector Fields and Coordinate Systems Instructor: Dragica Vasileska. Outline. Class Description Introductory Concepts Vector Fields Coordinate Systems. Class Description. Prerequisites by Topic: University physics

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EEE241: Fundamentals of Electromagnetics

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  1. EEE241: Fundamentals of Electromagnetics Introductory Concepts, Vector Fields and Coordinate Systems Instructor: Dragica Vasileska

  2. Outline • Class Description • Introductory Concepts • Vector Fields • Coordinate Systems

  3. Class Description Prerequisites by Topic: • University physics • Complex numbers • Partial differentiation • Multiple Integrals • Vector Analysis • Fourier Series

  4. Class Description • Prerequisites: EEE 202; MAT 267, 274 (or 275), MAT 272; PHY 131, 132 • Computer Usage: Students are assumed to be versed in the use MathCAD or MATLAB to perform scientific computing such as numerical calculations, plotting of functions and performing integrations. Students will develop and visualize solutions to moderately complicated field problems using these tools. • Textbook: Cheng, Field and Wave Electromagnetics.

  5. Class Description • Grading: Midterm #1 25% Midterm #2 25% Final 25% Homework 25%

  6. Class Description

  7. Why Study Electromagnetics?

  8. Examples of Electromagnetic Applications

  9. Examples of Electromagnetic Applications, Cont’d

  10. Examples of Electromagnetic Applications, Cont’d

  11. Examples of Electromagnetic Applications, Cont’d

  12. Examples of Electromagnetic Applications, Cont’d

  13. Research Areas of Electromagnetics • Antenas • Microwaves • Computational Electromagnetics • Electromagnetic Scattering • Electromagnetic Propagation • Radars • Optics • etc …

  14. Why is Electromagnetics Difficult?

  15. What is Electromagnetics?

  16. What is a charge q?

  17. Fundamental Laws of Electromagnetics

  18. Steps in Studying Electromagnetics

  19. SI (International System) of Units

  20. Units Derived From the Fundamental Units

  21. Fundamental Electromagnetic Field Quantities

  22. Three Universal Constants

  23. Fundamental Relationships

  24. Scalar and Vector Fields • A scalar field is a function that gives us a single value of some variable for every point in space. • Examples: voltage, current, energy, temperature • A vector is a quantity which has both a magnitude and a direction in space. • Examples: velocity, momentum, acceleration and force

  25. Example of a Scalar Field

  26. Scalar Fields e.g. Temperature: Every location has associated value (number with units) 26

  27. Scalar Fields - Contours • Colors represent surface temperature • Contour lines show constant temperatures 27

  28. Fields are 3D • T = T(x,y,z) • Hard to visualize  Work in 2D 28

  29. Vector Fields Vector (magnitude, direction) at every point in space Example: Velocity vector field - jet stream 29

  30. Vector Fields Explained

  31. Examples of Vector Fields

  32. Examples of Vector Fields

  33. Examples of Vector Fields

  34. Choice is based on symmetry of problem VECTOR REPRESENTATION 3 PRIMARY COORDINATE SYSTEMS: • RECTANGULAR • CYLINDRICAL • SPHERICAL Examples: Sheets - RECTANGULAR Wires/Cables - CYLINDRICAL Spheres - SPHERICAL

  35. Orthogonal Coordinate Systems: (coordinates mutually perpendicular) Cartesian Coordinates z P(x,y,z) y Rectangular Coordinates x P (x,y,z) z z P(r, θ, z) Cylindrical Coordinates P (r, Θ, z) y r x θ z Spherical Coordinates P(r, θ, Φ) θ r P (r, Θ, Φ) y x Φ Page 108

  36. Parabolic Cylindrical Coordinates (u,v,z) • Paraboloidal Coordinates (u, v, Φ) • Elliptic Cylindrical Coordinates (u, v, z) • Prolate Spheroidal Coordinates (ξ, η, φ) • Oblate Spheroidal Coordinates (ξ, η, φ) • Bipolar Coordinates (u,v,z) • Toroidal Coordinates (u, v, Φ) • Conical Coordinates (λ, μ, ν) • Confocal Ellipsoidal Coordinate (λ, μ, ν) • Confocal Paraboloidal Coordinate (λ, μ, ν)

  37. Parabolic Cylindrical Coordinates

  38. Paraboloidal Coordinates

  39. Elliptic Cylindrical Coordinates

  40. Prolate Spheroidal Coordinates

  41. Oblate Spheroidal Coordinates

  42. Bipolar Coordinates

  43. Toroidal Coordinates

  44. Conical Coordinates

  45. Confocal Ellipsoidal Coordinate

  46. Confocal Paraboloidal Coordinate

  47. z z Cartesian Coordinates P(x,y,z) P(x,y,z) P(r, θ, Φ) θ r y x y x Φ Cylindrical Coordinates P(r, θ, z) Spherical Coordinates P(r, θ, Φ) z z P(r, θ, z) y r x θ

  48. Coordinate Transformation • Cartesian to Cylindrical (x, y, z) to (r,θ,Φ) (r,θ,Φ)to (x, y, z)

  49. Coordinate Transformation • Cartesian to Cylindrical Vectoral Transformation

  50. Coordinate Transformation • Cartesian to Spherical (x, y, z) to (r,θ,Φ) (r,θ,Φ)to (x, y, z)

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