סילבוס לקורס חשמל ומגנטיות: הבדלים בין גרסאות בדף

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(3 גרסאות ביניים של אותו משתמש אינן מוצגות)
שורה 1: שורה 1:
Electrostatics: Coulomb's law; electric field and potential; flux and Gauss' law (integral and differential forms); capacitive* conductors and electrostatic energy; method of mirror charges; electric field in matter, electric dipole, polarization, dielectric materials, boundary conditions
[[86-120 חשמל ומגנטיות תשע"ג ב'|חזרה לעמוד הקורס]]


Electric current: charge conservation; Ohm's law; DC circuits*
'''הנושאים שיילמדו במהלך הקורס הם:'''


Magnetic field: Lorentz force; Ampere's law (integral and differential forms); Biot-Savart's law; vector potential*
* Electrostatics: Coulomb's law; electric field and potential; flux and Gauss' law (integral and differential forms); capacitive conductors and electrostatic energy; method of mirror charges; electric field in matter, electric dipole, polarization, dielectric materials, boundary conditions


Inductance: inductance and time-dependent effects; Faraday's and Lenz's laws of inductance; magnetic energy*
* Electric current: charge conservation; Ohm's law; DC circuits


Maxwell's equations: displacement current; consequences*
* Magnetic field: Lorentz force; Ampere's law (integral and differential forms); Biot-Savart's law; vector potential


Magnetic field in matter: magnetic dipole; diamagnetic, paramagnetic and ferromagnetic materials*
* Inductance: inductance and time-dependent effects; Faraday's and Lenz's laws of inductance; magnetic energy
 
* Maxwell's equations: displacement current; consequences
 
* Magnetic field in matter: magnetic dipole; diamagnetic, paramagnetic and ferromagnetic materials

גרסה אחרונה מ־23:54, 2 בפברואר 2013

חזרה לעמוד הקורס

הנושאים שיילמדו במהלך הקורס הם:

  • Electrostatics: Coulomb's law; electric field and potential; flux and Gauss' law (integral and differential forms); capacitive conductors and electrostatic energy; method of mirror charges; electric field in matter, electric dipole, polarization, dielectric materials, boundary conditions
  • Electric current: charge conservation; Ohm's law; DC circuits
  • Magnetic field: Lorentz force; Ampere's law (integral and differential forms); Biot-Savart's law; vector potential
  • Inductance: inductance and time-dependent effects; Faraday's and Lenz's laws of inductance; magnetic energy
  • Maxwell's equations: displacement current; consequences
  • Magnetic field in matter: magnetic dipole; diamagnetic, paramagnetic and ferromagnetic materials