Jansky units are not a standard SI unit, so it may be necessary to convert the measurements made in the unit to the SI equivalent in terms of watts per square metre per hertz (W·m−2·Hz−1). However, other unit conversions are possible with respect to measuring this unit.
AB magnitude The flux density in janskys can be converted to a magnitude basis, for suitable assumptions about the spectrum. For instance, converting an
AB magnitude to a flux density in microjanskys is straightforward: S_v~[\mathrm{\mu}\text{Jy}] = 10^{6} \cdot 10^{23} \cdot 10^{-\tfrac{\text{AB} + 48.6}{2.5}} = 10^\tfrac{23.9 - \text{AB}}{2.5}.
dBW·m−2·Hz−1 The linear flux density in janskys can be converted to a
decibel basis, suitable for use in fields of telecommunication and radio engineering. 1 jansky is equal to −260
dBW·m−2·Hz−1, or −230
dBm·m−2·Hz−1: \begin{align} P_{\text{dBW}\cdot\text{m}^{-2} \cdot \text{Hz}^{-1}} &= 10 \log_{10}\left(P_\text{Jy}\right) - 260, \\ P_{\text{dBm}\cdot\text{m}^{-2} \cdot \text{Hz}^{-1}} &= 10 \log_{10}\left(P_\text{Jy}\right) - 230. \end{align}
Temperature units The
spectral radiance in janskys per
steradian can be converted to a
brightness temperature, useful in radio and microwave astronomy. Starting with
Planck's law, we see B_{\nu} = \frac{2h\nu^3}{c^2}\frac{1}{e^{h\nu/kT}-1}. This can be solved for temperature, giving T = \frac{h\nu}{k\ln\left (1+\frac{2h\nu^3}{B_\nu c^2}\right )}. In the low-frequency, high-temperature regime, when h\nu \ll kT, we can use the
asymptotic expression: T\sim \frac{h\nu}k\left(\frac{B_\nu c^2}{2h\nu^3}+\frac 12\right). A less accurate form is T_b = \frac{B_{\nu}c^2}{2k\nu^2}, which can be derived from the
Rayleigh–Jeans law B_{\nu} = \frac{2\nu^2 kT}{c^2}. == Usage ==