from ..target.ATarget import ATarget from ..SpectralQty import SpectralQty import astropy.units as u from astropy.modeling.models import BlackBody from esbo_etc.lib.helpers import error class BlackBodyTarget(ATarget): """ This class models the spectral flux density of a star of given magnitude using as black body radiator """ # Bands from Handbook of Space Astronomy and Astrophysics # band_sfd = {"U": 1790*u.Jansky, "B": 4063*u.Jansky, "V": 3636*u.Jansky, "R": 3064*u.Jansky, # "I": 2416*u.Jansky, "J": 1590*u.Jansky, "H": 1020*u.Jansky, "K": 640*u.Jansky} _band = dict(U=dict(wl=366 * u.nm, sfd=4.175e-11 * u.W / (u.m ** 2 * u.nm)), B=dict(wl=438 * u.nm, sfd=6.32e-11 * u.W / (u.m ** 2 * u.nm)), V=dict(wl=545 * u.nm, sfd=3.631e-11 * u.W / (u.m ** 2 * u.nm)), R=dict(wl=641 * u.nm, sfd=2.177e-11 * u.W / (u.m ** 2 * u.nm)), I=dict(wl=798 * u.nm, sfd=1.126e-11 * u.W / (u.m ** 2 * u.nm)), J=dict(wl=1220 * u.nm, sfd=3.15e-12 * u.W / (u.m ** 2 * u.nm)), H=dict(wl=1630 * u.nm, sfd=1.14e-12 * u.W / (u.m ** 2 * u.nm)), K=dict(wl=2190 * u.nm, sfd=3.96e-13 * u.W / (u.m ** 2 * u.nm))) @u.quantity_input(wl_bins='length', temp=[u.Kelvin, u.Celsius], mag=u.mag) def __init__(self, wl_bins: u.Quantity, temp: u.Quantity = 5778 * u.K, mag: u.Quantity = 0 * u.mag, band: str = "V"): """ Initialize a new black body point source Parameters ---------- wl_bins : length-Quantity Wavelengths used for binning temp : Quantity in Kelvin / Celsius Temperature of the black body mag : Quantity in mag Desired apparent magnitude of the point source band : str Band used for fitting the planck curve to a star of 0th magnitude. Can be one of [U, B, V, R, I, J, H, K]. Returns ------- """ if band not in self._band.keys(): error("Band has to be one of '[" + ", ".join(list(self._band.keys())) + "]'") # Create blackbody model with given temperature bb = BlackBody(temperature=temp, scale=1 * u.W / (u.m ** 2 * u.nm * u.sr)) # Calculate the correction factor for a star of 0th magnitude using the spectral flux density # for the central wavelength of the given band factor = self._band[band]["sfd"] / (bb(self._band[band]["wl"]) * u.sr) * u.sr # Calculate spectral flux density for the given wavelengths and scale it for a star of the given magnitude sfd = bb(wl_bins) * factor * 10 ** (- 2 / 5 * mag / u.mag) # Initialize super class super().__init__(SpectralQty(wl_bins, sfd))