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A Test for Weak Cosmic Ray Events on CCD Exposures



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Astronomical Data Analysis Software and Systems IV
ASP Conference Series, Vol. 77, 1995
Book Editors: R. A. Shaw, H. E. Payne, and J. J. E. Hayes
Electronic Editor: H. E. Payne

A Test for Weak Cosmic Ray Events on CCD Exposures

J. Bland-Hawthorn
Anglo-Australian Observatory, P.O. Box 296, Epping, N.S.W. 2121 Australia

S. Serjeant
Department. of Astrophysics, University of Oxford, Oxford OX1 3RH, UK

P. L. Shopbell
Department. of Space Physics & Astronomy, Rice University, P.O. Box 1892, Houston, TX 77251

 

Abstract:

It is notoriously difficult to identify weak cosmic ray events in long exposure observations. The majority of ``de-glitch" programs have little difficulty in identifying the bright events. The faint events---either individual or ``splatter'' around bright events---are rather more problematic. We propose a simple test to evaluate the effectiveness of a de-glitch program in removing weak events. The method is to compare the probability distribution function (PDF) of cosmic ray events between an observation and a dark frame matched in exposure time. We illustrate the basic idea using dark exposures from a Tek 10241024 CCD with varying exposure lengths and read-out times.

             

Observations

We have obtained dark frames using the Tek 10241024 CCD at the AAT 3.9m with varying exposure lengths (15, 30, 60, and 120min) and read-out times (FAST, SLOW, XTRASLOW). The histogram of each frame shows the contribution from the bias, read and dark noise. A millisecond exposure was used to remove the bias and read noise contribution to each histogram. The additional contribution from the dark noise is well calibrated at 0.11countspixksec. It is assumed that the remaining events are related to cosmic rays. Only half the CCD frame was used because long exposures revealed a weak intensity gradient in the dark response on the other half.

  
Figure: Histogram of cosmic ray events in a two hour dark frame. The monotonic curve is the cumulative histogram of these events. The error bars are Poissonian and not independent. Original PostScript figure (78 kB)


Method

We define to be the number of cosmic ray events with energies (expressed in counts) in the range . The cumulative distribution is then

When , the slope of the plot vs is proportional to . In Figure gif, the noisy histogram is the bias/dark/read noise subtracted dark frame. The monotonic curve is a plot of vs. which is found to be rather well defined and reproducible over the different exposures. We propose that de-glitch programs should compute the PDF in this way for both the data and a matched dark frame (same exposure, same read-out time). The PDF for the data is determined from all events identified by the de-glitch algorithm. Since the energetic events are easier to find, the bright end of both PDFs will be well matched. In Figure gif, where the de-glitch PDF turns over at low energy---presumably but not necessarily at an energy greater than or equal to the turnover in the dark PDF---gives some idea as to how effective the algorithm has been in removing the weaker events.

  
Figure: The cumulative histogram from Figure gif with which to compare the performance of a de-glitch algorithm. Three cases are illustrated: algorithm A is too conservative, algorithm B more reliable, and algorithm C has mistaken real data with faint cosmic rays. Original PostScript figure (16 kB)




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