Instrumental Properties

Even outside the SAA, observations show that "dark" counts tend to come in bursts. Approximately 15% of dark counts are produced by events that occur within a time of 8 ms or less. The CENSOR feature in Accumulation Mode allows you to ignore integrations with such high dark rates. CENSOR works by summing all 512 channels of the Digicon every 8 ms, and if that sum exceeds a threshold a coincident event is recorded. The flight software can reject and then repeat a single 8 ms time slice for which the coincidence sum exceeds a given level. Electronic noise in the analog summing circuit effectively limits the ability to discriminate events that produce less than about 8 simultaneous counts, so that only the high-amplitude tail of background events can be rejected. It is estimated that use of CENSOR can reduce the dark count rate by about 20%. Using CENSOR=YES is unlikely to degrade an observation (unless the object is bright enough to cause a consistently high count rate), but the benefit is also low: only about a 10% gain in S/N in favorable cases.

The dark count rate is highly uniform over the diodes, so that a mean dark count rate is an excellent representation of what happens at the detector.

Summary:

• The pre-flight noise specification was 0.01 counts diode-1 sec-1. The average measured value is 0.005 for D1 and 0.008 for D2.

• The background is sensibly constant between -20 and +20o geomagnetic latitude.

• At xb1 40o geomagnetic latitude, the extrema of HST's orbit, the rate is twice that at the geomagnetic equator.

• The background rate is correlated with the cosmic ray and trapped particle flux. Calculations show that the dark noise can be accounted for by cosmic-ray-induced Cerenkov radiation in the faceplates of the Digicons.

• The background due to the direct penetration of cosmic rays into diodes is very low (0.0004 counts diode-1 sec-1).

• Use the default STEP-TIME of 0.2 sec.

• Do not use CENSOR if the expected count rate exceeds about 100 counts per second per diode because real photon events will be rejected. In a severe case, all the data could be lost.

• Using CENSOR can drop the noise level by about 20%. The nominal Side 2 dark count rate is 0.012 counts per second per diode, so CENSOR=YES can lower it to 0.010.

• The following table shows the expected effects of using CENSOR. Rate is the target count rate per diode per second; the second column shows the standard S/N and the third column lists the S/N achieved with CENSOR=YES if the dark is 80% of its value without CENSOR. Signal-to-noise was calculated on a per diode basis for a nominal exposure time of 10,000 seconds (which is reduced to 9,800 if CENSOR is used because of the loss of 2% of the exposures).

Table 8.8:

Effects of CENSOR

FLYLIM may now be used as an Optional Parameter with an ACCUM. If users believe that FLYLIM may be of help in their science program they should note the following:

• The use of the FLYLIM parameter should be arranged in advance, i.e., before the Phase I proposal deadline, through consultation with a GHRS Instrument Scientist.

• At the time this is written FLYLIM has not been fully tested and its use is at the observer's risk.

If you decide you wish to use FLYLIM, we would suggest that you consider devoting one orbit of time as a first visit early in the cycle so that the true source count rate can be accurately and reliably determined.

For more information on using FLYLIM, we recommend that you read "Calibration of GHRS Burst Noise Rejection Techniques," by Beaver et al.in Calibrating Hubble Space Telescope, edited by J.C. Blades and S.J. Osmer (1993, STScI), p. 304.