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Flat-field accuracy (LW)

Flat-field accuracy can be as good as 5 when the signal is stabilized. The flat-field was found to be very stable all along the calibration; this allows the use of a library flat-field, instead of loosing observing time by making flat-field calibration with the ICD linked with each observation. However, a limitation comes from the differential stabilization times between the pixels. It would be prohibitive in flight to wait for a full stabilization of the array, and the observer will have to make use of the images obtained in still unstable configurations. Usually, stabilization is quantified by comparing the mean pixel signal to the stabilized value. In our case, it is better to determine the stabilization by measuring the pattern noise on flat-fielded images. The differential stabilization generates a pattern across the images which increases the spatial noise. Low level effects can be observed for several minutes after a flux step. The main problems are located on the pixels at the edges of the array, and on a line of pixels in the lower left hand side quadrant of the array which has a slightly lower responsivity than the average. They appear in dark on Figure gif.

A good way to remove these effects, as well as the low frequency noise mentioned earlier (which in fact may be related to these effects), is to use a beam-switching procedure switching the pointing from the source field to an adjacent reference field, as is done with ground-based telescopes. Alternatively, a micro- scanning procedure can be used, displacing the field of view by a few arcsec on the sky every few exposures; this can be realised using the raster pointing mode of ISO (see also section gif).



ISOCAM Observer's Manual - V1.0
Tue Oct 31 12:06:23 MET 1995