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Innovative Cosmic Ray Rejection in ISOCAM Data Next: Compression of Mosaic CCD Images with CompFITS2
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Ott, S., Metcalfe, L., Pollock, A., & Tuffs, R. 2000, in ASP Conf. Ser., Vol. 216, Astronomical Data Analysis Software and Systems IX, eds. N. Manset, C. Veillet, D. Crabtree (San Francisco: ASP), 543

Innovative Cosmic Ray Rejection in ISOCAM Data

S. Ott, L. Metcalfe, A. Pollock
ISO Data Centre, Astrophysics Division, Space Science Dept. of ESA, Villafranca, P.O. Box 50727, 28080 Madrid, Spain

R. Tuffs
Max-Planck-Institut für Kernphysik, Heidelberg, Germany


Abstract:

Cosmic ray rejection (deglitching) is one of the challenging data analysis problems for ISOCAM, the infrared camera on board ESA's Infrared Space Observatory (ISO).

Artifacts, caused by undetected glitches, limit the calibration accuracy and sensitivity, and directly influence the quality of the final data products.

We present five new deglitching algorithms suited for different types of ISOCAM data and discuss their applicability.

We also show examples demonstrating the improvements gained by these deglitching techniques.


1. Introduction


Glitches (remnants of cosmic ray impacts) have been found to be a powerful (and often dominant) limiting factor for all aspects of the data analysis of ISOCAM (Cesarsky et al. 1996), the infrared camera on board ESA's Infrared Space Observatory (ISO) (Kessler et al. 1996)1.

Standard deglitching techniques2 like multi-resolution (Starck et al. 1998) or sigma clipping work ``blindly'' on a data vector only and therefore ignore valuable information about:

Therefore the standard deglitchers have often to rely on badly chosen thresholds, which consequently result in:

2. MMMS (Multi-Method, Multi-Step)

field of application:
dark current calibration with highly redundant data. The signal (trends) are buried in the noise, and the value of the final result is known, as a perfectly dark-corrected dark must be zero
algorithm:
repeated application of multi-resoltution deglitching and conventional sigma clipping
result:
reduction of the noise level by a factor of five and of the standard error by a factor of four. The number of rejected pixels is a strong indicator of deviations due to hidden features and trends
caveats:
true features are partially clipped out. To avoid this, iterations are necessary

3. Sky-Cube Deglitching

field of application:
all datasets with stabilised and highly redundant data (especially faint source data)
algorithm:
after conventional deglitching, each detector pixel, for each raster position, is projected into the sky to generate a ``sky cube''. Afterwards sigma-clipping is performed for each sky-cube-pixel
result:
excellent rejection of remaining faders and dippers (Siebenmorgen et al. 1999) not caught by earlier deglitching
caveats:
none known yet
annotation:
as sky-cube deglitching relies on the comparison between detector- and sky-pixel, the actual ISO pointing and the distortion corrections for ISOCAM have to be accurately known. Correction for ISOCAM's long and short term drift will result in further improvements

Figure 1: CAM survey data after multiresolution deglitching (left) and after sky-cube deglitching (right).
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4. BISC (Best Iterative Sigma Clipping)



field of application:
all datasets with relatively well stabilised data
algorithm:
iterative method; the data-cube is normalised by estimations of flux level per state3
result:
stringent deglitching, including a very good rejection of faders and dippers. The low residual noise permits additional treatments for faint sources
caveats:
pixels with a high gradient (e.g. due to cross-talk in the neighbourhood of strong extended sources) or strong point sources with high noise can be masked out and have to be recovered by a NOSC post-processing step (see Section 5 below)
annotation:
Overruling of the on-target-flag (normally set to bad during slews of the satellite) enables the recovery of a significant amount of otherwise ignored data for raster observation of a flat sky

Figure 2: CAM survey data after multiresolution deglitching (left) and after BISC deglitching (right).

Figure 3: BISC deglitched CAM survey data with additional faint source processing.

5. NOSC (Normalised Sigma Clipping)


field of application:
all datasets with stabilised data and very few (down to four!) read-outs
algorithm:
per step, 25% of the read-outs (alternately with the highest and then with the lowest signal within a state) are ignored. On the remaining sample, sigma clipping is performed using modified values for mean and variance
result:
spectacular results for CAM parallel, on its own and as BISC postprocessor
caveats:
imperfect glitch rejection in case of higher than expected number of strong glitches during a state

Figure 4: CAM paralled exposure with six readouts after multiresolution deglitching (left) and after NOSC deglitching (right).
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6. Clipper



field of application:
in principle, all datasets
algorithm:
Currently, there are two algorithms under evaluation:


result:
promising examples on data with high gradients
caveats:
still under development

References

Cesarsky, C., et al. 1996, A&A, Vol. 315, L32

Kessler, M., Steinz, J.A. et al. 1996, A&A, Vol. 315, L27

Siebenmorgen, R. et al. 1999, ISO Handbook Volume III (CAM), Version 1.0, ESA Document, Reference Number SAI-99-057/Dc

Starck, J-L., Murtagh, F. & Bijaoui, A., 1998, Image Processing and Data Analysis: The Multiscape Approach, Cambridge Univeristy Press, Cambridge (GB)



Footnotes

... 1996)1
ISO is an ESA project with instruments funded by ESA member states (especially the PI countries: France, Germany, the Netherlands and the United Kingdom) and with the participation of ISAS and NASA.
... techniques2
See Siebenmorgen et al. 1999 for the effects of cosmic ray impacts and a description of conventional deglitchers.
... state3
state: the finest division time division of ISOCAM activities. All CAM and satellite (pointing) parameters are fixed during a state.

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