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32 Cards in this Set
- Front
- Back
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Derive differential form of Gauss Law from the integral form |
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Derive the differential form of Faraday Lenz law from integral form |
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Define electric potential |
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What is the general solution of Poisson's equation? |
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Derive the differential form of Ampère's law (non Maxwell) |
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Derive the Maxwell correction for Ampere's law |
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Derive Coulomb's Law |
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Derive Biot-Savart Law |
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What is the electromagnetic energy density u? |
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State the two identities of grad/div/curl that =0 |
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What is the approximation of an electric field if r >> r' ? |
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What are the required conditions for an approximation that returns a magnetic monopole? |
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Give the approximation of the E field of the Electric Dipole |
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Give the approximation of the B field when r >> r' |
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Give the Coulomb Gauge condition and state why we can use it for all cases |
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State the Lorenz guage condition and why it can be used in all cases |
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State the E and B fields in terms of potentials in both static and time dependent worlds |
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State (and name) the potential guage conditions for both the static and time dependent worlds |
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State Poisson's equation for statics and the equivalents for the time dependent world |
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Derive the Maxwell form of Ohms law from the empirical form |
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What form of guass' law would you use for dielectric/ capacitor problems? |
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Define capacitance and the energy stored in a capacitor in terms of capacitance |
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Calculate the inductance of a solenoid using Maxwell's equations |
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What are the components of the total charge for dielectrics and total current density for magnets |
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Derive Gauss' law in terms of the displacement vector |
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Give the B and E fields in terms of H and D respectively |
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What is continuous over the boundary for the E and B fields |
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How would I calculate the bound current density |
Curl of Magnetisation (M) |
