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XuetangX

Electromagnetic Field

Shandong University via XuetangX

Overview

Electromagnetic phenomenon is one of the most important phenomena in nature, which has always been an important issue for ancient scientists or the present scientists. For the students of electrical and electronic information engineering, the core of their major courses is the embodiment of electromagnetic phenomena in a specific range and under specific conditions.

Using the qualitative process and quantitative method to analyze electromagnetic phenomena is the necessary professional knowledge and skills for an electrical engineering student. The electromagnetic field analyzing principle and method also are the theoretical base of electrical application disciplines. The electromagnetic field theory is the theoretical base of electrical, electronic and information technology, the most essential description of macro electromagnetic phenomenon, the" key” to open the door of electrical engineering castle.

Electromagnetic Field is the prerequisite course for Electrical MachineElectrical Engineering Theory and other specialized courses of electrical engineering. 

Electromagnetic Field needs the prerequisite courses such as Advanced MathematicsCollege Physics, Vector Analysis and Field Theory.  The course asks the students to establish the viewpoint of "field" and provide theoretical and technical support for the follow-up professional courses. The course would lead students to understand the theorem and the physical meaning of the Maxwell equations and mathematical expressions, to master the vector analysis method of  basic electromagnetism phenomenon, to describe the essential physical concept of electromagnetic field based on summarizing the basic law of experiment. 

After learning this course, students will have completely knowledge about the theorem and the physical meaning of the Maxwell equations and mathematical expressions. It includes the static and time-varing electromagnetic fields. The common question representation methods and solving methods for electromagnetic field  are known. The main objective is to lay the ground work for future intensive study in electromagnetic field.



Syllabus

  • Chapter I
    • [1.1]Development of Electromagnetic field
    • [1.2] Learning method
  • Chapter 2
    • [2.1] Source of Electrostatic Field
    • [2.2] Electric Field Intensity
    • [2.3] Nature of Dielectric Material
    • [2.4] Electric Displacement
    • [2.5] Gauss's Law and its Application
    • [2.6] Potential and Potential Gradient
    • [2.7] Poisson's and Laplace's equations
    • [2.8] Boundary Conditions
    • [2.9] Condutor Properties and Boundary Condtions
    • [2.10] Theorem of Uniqueness of Solution
    • [2.11.1] Image Method 1
    • [2.11.2] Image Method 2
    • [2.12] Electric Axis Method
    • [2.13] Capacitance
    • [2.14] Enegry in Electrostatic Field
    • [2.15] Virtual Displacement Method
    • [2.16] Electrostatic Shielding
  • Chapter 3
    • [3.1] Current and Current Density
    • [3.2] Field in Meatallic Conductor
    • [3.3] Boundary Problem of Steady Electric Field 1
    • [3.4] Electrostatic Match Method
    • [3.5] Conductance
    • [3.6] Grounding Resistance 1
  • Chapter 4
    • [4.1] Biot-Savart Law
    • [4.2] Application of Biot-Savart Law
    • [4.3] Ampere's circuital Law
    • [4.4] Law of conservation of magnetic flux
    • [4.5] magnetic force
    • [4.6] Magnetic scalar potential
    • [4.7] Magnetic material
    • [4.8] Magnetic circuit
    • [4.9] Inductor
    • [4.10] Magnetic energy
  • Chapter 5
    • [5.1] Gauss’s law for electric fields 1
    • [5.2] Gauss’s law for electric fields 2
    • [5.3] Gauss’s law for electric fields 3
    • [5.4] Gauss’s law for electric fields 4
    • [5.5] Gauss’s law for electric fields 5
    • [5.6] Gauss’s law for electric fields 6
    • [5.7] Gauss's law for magnetic fields 1
    • [5.8] Gauss's law for magnetic fields 2
    • [5.9] Faraday’s law 1
    • [5.10] Faraday’s law 2
    • [5.11] Faraday’s law 3
    • [5.12] Faraday’s law 4
    • [5.13] Faraday’s law 5
    • [5.14] The Ampere-Maxwell law 1
    • [5.15] The Ampere-Maxwell law 2
    • [5.16] The Ampere-Maxwell law 3
    • [5.17] The Ampere-Maxwell law 4
    • [5.18] The Ampere-Maxwell law 5
    • [5.19] From Maxwell’s Equations to the wave equation 1
    • [5.20] From Maxwell’s Equations to the wave equation 2
  • Final Exam

    Taught by

    Hui Zhong

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