1. |
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1. Introduction to Electromagnetics
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Introduction to Electromagnetics
Review of Calculus |
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2. |
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2. Vector Analysis (1)
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2-1 Overview
2-2. Vector addition and subtraction
2-3. Vector multiplication
2-4.1 Cartesian coordinates |
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3. |
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2. Vector Analysis (2)
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2-4.2 Cylindrical coordinates
2-4.3 Spherical coordinates |
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4. |
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2. Vector Analysis (3)
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2-5. Gradient of a scalar field
2-6. Divergence of a vector field
2-7. Divergence theorem |
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5. |
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2. Vector Analysis (4)
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2-8. Curl of a vector field
2-9. Stokes's theorem
2-10. Two null of identities |
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6. |
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3. Static Electric Fields (1)
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3-2. Fundamental postulates of electrostatics in free space
3-3. Coulomb's law |
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7. |
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3. Static Electric Fields (2)
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3-4. Gauss's law and applications |
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8. |
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3. Static Electric Fields (3)
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3-5. Electric potential
3-6. Material media in static electric field |
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9. |
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3. Static Electric Fields (4)
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3-7. Electric flux density and dielectric constant
3-8. Boundary conditions for electrostatic fields |
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10. |
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3. Static Electric Fields (5)
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3-9. Capacitances and capacitors |
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11. |
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3. Static Electric Fields (6)
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3-11. Solution of electrostatic boundary-value problems
3-11.1 Poisson's and Laplace's Equations
3-11.2 Boundary-value problems in Cartesian coordinates
3-11.5 Method of Images |
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12. |
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4. Steady Electric Currents (1)
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4-2. Current Density and Ohm's Law |
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13. |
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4. Steady Electric Currents (2)
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4-3. Equation of Continuity and Kirchhoff's Current Law
4-6. Resistance Calculations |
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