March 16, 2015
ece1229
137 , 138 Index , Ampere's law , antenna under test , aperture efficiency , aration , AUT , average , average power density , bivector , bold vectors , caligraphic vectors , captured power , circular polarization , complex , continuity equation , covariant , cross product , curl , curl of curl , dB , dBi , dipole , dipole current , dipole moment , directivity , divergence , divergence theorem , dot product , dual , Dual-Maxwell’s equation , Dual-Maxwell’s equations , duality , effective area , Effective Isotropic Receiving Power , EIRP , electic field , electric , electric charge density , electric current density , electric far field , electric field , electric four potential , electric potential , electric vector potential , far field , four current , four potential , four vector , free-space loss , Fresnel equations , Friis equation , Friis transmission equation , gain , Geometric Algebra , geometric product , gradient , Green's function , ground reflection , half power beamwidth , Helmholtz equation , horizontal dipole , horizontal electrical dipole , IERP , image theorem , impedance , impulse response , in terms of potentials , index of refraction , infinitesimal dipole , infinitesimal electric dipole , intrinsic impedance , isotropic radiator , Julia , line of sight , linear media , linear polarization , linear time invariant , Lorentz gauge , magnetic , magnetic and electric potential sep- , magnetic charge , magnetic charge density , magnetic current , magnetic current density , magnetic current source , magnetic field , magnetic four potential , magnetic vector potential , magnetization , matched load , Mathematica , Matlab , maximum directivity , Maxwell equation , Maxwell's equation , Maxwell's equations , Mie scattering , Minkowski space , near field , non-covariant GA form , non-homogeneous , notation , optical limit , ParametricPlot , ParametricPlot3D , permittivity , phasor , phasor sign , plane of incidence , plane of reflection , plane wave , PLF , polarization , polarization loss factor , polarization mismatch , polarization power loss , polarization vector , potential , power , power density , Poynting vector , pseudoscalar , radar cross section , radiated power density , radiation intensity , RCS , reciprocity theorem , reflection coefficient , relation to cross product , scalar potential , scattered power , scattered power density , signal to noise , spacetime gradient , spherical coordinates , spherical scattering , standard gain , Stokes' theorem , superposition , time average , transmitted power , transverse projection , triple product , vector potential , vertical dipole , wave vector , wavelength , wedge product , X-band

Facebook
Twitter
LinkedIn

I’ve now posted a first update of my notes for the antenna theory course that I am taking this term at UofT.

Unlike most of the other classes I have taken, I am not attempting to take comprehensive notes for this class. The class is taught on slides which go by faster than I can easily take notes for (and some of which match the textbook closely). In class I have annotated my copy of textbook with little details instead. This set of notes contains musings of details that were unclear, or in some cases, details that were provided in class, but are not in the text (and too long to pencil into my book), as well as some notes Geometric Algebra formalism for Maxwell’s equations with magnetic sources (something I’ve encountered for the first time in any real detail in this class).

The notes compilation linked above includes all of the following separate notes, some of which have been posted separately on this blog:

Like this:
Like Loading...

texttexttext`code`

more code

~~~~