Luminosity distance DL is defined in terms of the relationship between the absolute magnitude M and apparent magnitude m of an astronomical object.
M=m-5log10{
DL | |
10pc |
which gives:
DL=
| |||||
10 |
where DL is measured in parsecs. For nearby objects (say, in the Milky Way) the luminosity distance gives a good approximation to the natural notion of distance in Euclidean space.
The relation is less clear for distant objects like quasars far beyond the Milky Way since the apparent magnitude is affected by spacetime curvature, redshift, and time dilation. Calculating the relation between the apparent and actual luminosity of an object requires taking all of these factors into account. The object's actual luminosity is determined using the inverse-square law and the proportions of the object's apparent distance and luminosity distance.
Another way to express the luminosity distance is through the flux-luminosity relationship,
F=
L | ||||||||
|
where is flux (W·m−2), and is luminosity (W). From this the luminosity distance (in meters) can be expressed as:
DL=\sqrt{
L | |
4\piF |
The luminosity distance is related to the "comoving transverse distance"
DM
DL=(1+z)DM
DA
DL=(1+z)2DA
where z is the redshift.
DM
\delta\theta
DM\delta\theta
DM
DC