Sky Confusion Noise in the Far-Infrared: Cirrus, Galaxies and the Cosmic Far-Infrared Background
Abstract
We examined the sky confusion noise in 40 sky regions by analysing 175 far-infrared (90--200 μm) maps obtained with ISOPHOT, the photometer on-board the Infrared Space Observatory. For cirrus fields with < B > > 5 MJysr-1 the formula based on IRAS data (Helou & Beichman, Helou+Beichman90) predicts confusion noise values within a factor of 2 to our measurements. The dependence of the sky confusion noise on the surface brightness was determined for the wavelength range 90 λ 200 μm. We verified that the confusion noise scales as N ~ <B>1.5, independent of the wavelength and confirmed N ~ lambda2.5 for lambda >= 100um. The scaling of the noise value at different separations between target and reference positions was investigated for the first time, providing a practical formula. Since our results confirm the applicability of the Helou & Beichman (1990) formula, the cirrus confusion noise predictions made for future space missions with telescopes of a similar size can be trusted. At 90 and 170um a noise term with a Poissonian spatial distribution was detected in the faintest fields (<B> <= 3-5 MJysr-1), which we interpret as fluctuations in the Cosmic Far-Infrared Background (CFIRB). Applying ratios of the fluctuation amplitude to the absolute level of 10% and 7% at 90 and 170um, respectively, as supported by model calculations, we achieved a new simultaneous determination of the fluctuation amplitudes and the surface brightness of the CFIRB. The fluctuation amplitudes are 7(+/-)2 mJy and 15(+/-)4 mJy at 90 and 170um, respectively. We obtained a CFIRB surface brightness of B(0)=0.8(+/-)0.2 MJysr-1 (nuInu=14(+/-)3nWm-2sr-1) at 170um and an upper limit of 1.1 MJysr-1 (nuInu=37 nWm-2sr-1) at 90um.
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