Peculiar velocity In real observations, the movement of the Earth with respect to the
Hubble flow has an effect on the observed redshift. There are actually two notions of redshift. One is the redshift that would be observed if both the Earth and the object were not moving with respect to the "comoving" surroundings (the
Hubble flow), defined by the cosmic microwave background. The other is the actual redshift measured, which depends both on the
peculiar velocity of the object observed and on their peculiar velocity. Since the
Solar System is moving at around 370 km/s in a direction between
Leo and
Crater, this decreases 1+z for distant objects in that direction by a factor of about 1.0012 and increases it by the same factor for distant objects in the opposite direction. (The speed of the motion of the Earth around the Sun is only 30 km/s.)
Comoving distance The comoving distance d_C between fundamental observers, i.e. observers that are both moving with the
Hubble flow, does not change with time, as comoving distance accounts for the expansion of the universe. Comoving distance is obtained by integrating the proper distances of nearby fundamental observers along the line of sight (
LOS), whereas the proper distance is what a measurement at constant cosmic time would yield. In
standard cosmology,
comoving distance and
proper distance are two closely related distance measures used by cosmologists to measure distances between objects; the comoving distance is the proper distance at the present time. The comoving distance (with a small correction for our own motion) is the distance that would be obtained from parallax, because the parallax in degrees equals the ratio of an
astronomical unit to the circumference of a circle at the present time going through the sun and centred on the distant object, multiplied by 360°. However, objects beyond a
megaparsec have parallax too small to be measured (the
Gaia space telescope measures the parallax of the brightest stars with a precision of 7 microarcseconds), so the parallax of galaxies outside our
Local Group is too small to be measured. There is a
closed-form expression for the integral in the definition of the comoving distance if \Omega_r=\Omega_m=0 or, by substituting the scale factor a for 1/(1+z), if \Omega_\Lambda=0. Our universe now seems to be closely represented by \Omega_r=\Omega_k=0. In this case, we have: d_C(z) = d_H \Omega_m^{-1/3}\Omega_\Lambda^{-1/6}[f((1+z)(\Omega_m/\Omega_\Lambda)^{1/3})-f((\Omega_m/\Omega_\Lambda)^{1/3})] where f(x)\equiv\int_0^x \frac{dx}{\sqrt{x^3+1}} The comoving distance should be calculated using the value of that would pertain if neither the object nor we had a peculiar velocity. Together with the scale factor it gives the proper distance of the object when the light we see now was emitted by the it, and set off on its journey to us: d = a d_C
Proper distance Proper distance roughly corresponds to where a distant object would be at a specific moment of
cosmological time, which can change over time due to the
expansion of the universe.
Comoving distance factors out the expansion of the universe, which gives a distance that does not change in time due to the expansion of space (though this may change due to other, local factors, such as the motion of a galaxy within a cluster); the comoving distance is the proper distance at the present time.
Transverse comoving distance Two comoving objects at constant redshift z that are separated by an angle \delta\theta on the sky are said to have the distance \delta\theta d_M(z), where the transverse comoving distance d_M is defined appropriately. (Peebles confusingly calls the transverse comoving distance the "angular size distance", which is not the angular diameter distance.)
Angular diameter distance An object of size x at redshift z that appears to have angular size \delta\theta has the angular diameter distance of d_A(z)=x/\delta\theta. This is commonly used to observe so called
standard rulers, for example in the context of
baryon acoustic oscillations. When accounting for the earth's peculiar velocity, the redshift that would pertain in that case should be used but d_A should be corrected for the motion of the solar system by a factor between 0.99867 and 1.00133, depending on the direction. (If one starts to move with velocity towards an object, at any distance, the angular diameter of that object decreases by a factor of {{nowrap|\sqrt{1 - \beta^2},}} where
Luminosity distance If the intrinsic
luminosity L of a distant object is known, we can calculate its luminosity distance by measuring the flux S and determine d_L(z) = \sqrt{L/4\pi S}, which turns out to be equivalent to the expression above for d_L(z). This quantity is important for measurements of
standard candles like
type Ia supernovae, which were first used to discover the acceleration of the
expansion of the universe. When accounting for the earth's peculiar velocity, the redshift that would pertain in that case should be used for d_M, but the factor (1+z) should use the measured redshift, and another correction should be made for the peculiar velocity of the object by multiplying by \sqrt{(1+v/c) / (1-v/c)}, where now v is the component of the object's peculiar velocity away from us. In this way, the luminosity distance will be equal to the angular diameter distance multiplied by (1+z)^2, where z is the measured redshift, in accordance with
Etherington's reciprocity theorem (see below).
Light-travel distance (also known as "
lookback time" or "
lookback distance") This distance d_T is the time that it took light to reach the observer from the object multiplied by the
speed of light. For instance, the radius of the
observable universe in this distance measure becomes the age of the universe multiplied by the speed of light (1 light year/year), which turns out to be approximately 13.8 billion light years. There is a closed-form solution of the light-travel distance if \Omega_r = \Omega_m = 0 involving the
inverse hyperbolic functions \text{arcosh} or \text{arsinh} (or involving
inverse trigonometric functions if the cosmological constant has the other sign). If \Omega_r = \Omega_\Lambda = 0 then there is a closed-form solution for d_T(z) but not for z(d_T). Note that the comoving distance is recovered from the transverse comoving distance by taking the limit \Omega_k \to 0, such that the two distance measures are equivalent in a
flat universe. There are websites for calculating light-travel distance from redshift. The age of the universe then becomes \lim_{z\to\infty} d_T(z)/c, and the time elapsed since redshift z until now is: t(z) = d_T(z)/c.
Etherington's distance duality The Etherington's distance-duality equation is the relationship between the luminosity distance of standard candles and the angular-diameter distance. It is expressed as follows: d_L = (1+z)^2 d_A ==See also==