Polarization Calibration: Difference between revisions

Linear to Circular Conversion

At EOVSA’s linear feeds, in the electric field the linear polarization, X and Y, relates to RCP and LCP (R and L) as:

${\displaystyle R=X+iY}$

${\displaystyle L=X-iY}$

In terms of autocorrelation powers, we have the 4 polarization products XX*, YY*, XY* and YX*, where the * denotes complex conjugation. The quantities RR* and LL* are then

${\displaystyle RR^{*}=(X+iY)(X+iY)^{*}=XX^{*}-iXY^{*}+iYX^{*}+YY^{*}}$

${\displaystyle LL^{*}=(X-iY)(X-iY)^{*}=XX^{*}+iXY^{*}-iYX^{*}+YY^{*}}$

One problem is that there is generally a non-zero delay in Y with respect to X. This creates phase slopes in XY* and YX* from which we can determine the delay very accurately. As a check,

${\displaystyle StokesI={\frac {RR^{*}+LL^{*}}{2}}=XX^{*}+YY^{*}}$

${\displaystyle StokesV={\frac {RR^{*}-LL^{*}}{2}}=i(XX^{*}-YY^{*})}$

For completeness:

${\displaystyle StokesQ=XX^{*}-YY^{*}}$

${\displaystyle StokesU=XY^{*}-YX^{*}}$

${\displaystyle P_{linear}={\sqrt {U^{2}+Q^{2}}}}$

${\displaystyle \theta ={\frac {1}{2}}\arctan {\frac {U}{Q}}}$

Polarization Mixing Correction

Due to relative feed rotation between az-al mounted antennas and equatorial mounted antennas