Total Count Limits
During observations, the spacecraft is dithered in a Lissajous figure
to average out pixel-to-pixel response variations and to eliminate the
gaps in the spectral coverage when using the LETG/HRC-S combination
(see the three HRC-S segments here).
A 450,000 count limit for an on-axis source has been imposed over the course of the dither
pattern to limit the adverse affects on gain and QE due to the total
amount of charge extracted from the MCP at the point of extraction.
If a target is thought to exceed this value, make a note in the
comments section of the RPS form. The CXC may offset the pointing to
limit the accumulated count to a given region of the MCP.
Count Rate Limits
The count rate limits vary the total count rate over the full FOV
(telemetry limit) and the count rate for a single source within the
frame (linearity limit). The two are discussed below.
Telemetry Limits
Over the whole FOV, the maximum telemetered count rate is 184 cts
s^-1. It is possible to exceed this limit and use the valid rate (the
rate of triggers that pass on-board validity tests) to correct
for primary rate saturation.
Linearity Limits
The linearity limits refer to the limited count rate for an on-axis
point source. This means that avoiding the telemetry limit does not
guarantee the linearity limits are not exceeded. The HRC-I linearity
is verified in the laboratory at ~5 cts s^-1 and is ≈10% at 20
counts s^1. The HRC-S limit is ~25 cts s^-1.
A few methods are listed below to eliminate the effects of count rate limits:
1. Inserting a transmission grating (LETG or HETG) to reduce flux and
analyze zeroth-order image.
2. Offsetting the aimpoint will smear the image out, thereby reducing
the number of counts for one part of the detector. To avoid the
telemetry limit, significant offsetting is a possibilty which will
greatly reduce the spatial resolution.
To avoid telemetry limits specifically, windowing is available to
reduce the flux from nearby bright objects.
HRC-I
The HRC-I uses an anti-coincidence shield to reduce the detector's
exposure to cosmic rays and lowers the valid event rate to ~100 cts
s^1. After standard processing, this rate drops to 1.7x10^-5 cts s^-1
arcsec^-2. For point source observations of 100 ks or less the background
is negligible, but the low rate can become significant for extended
low surface brightness objects.
HRC-S
The anti-coincidence shield for the HRC-S does not work due to an
uncorrectable timing error. This leads to a background rate that exceeds
the telemetry rate limit of 184 cts s^-1. To overcome this issue, a
"spectroscopy region" as been designated using the edge blanking
feature, which like windowing, ignores the events occuring outside
ofthe designated edges. The new region extends the full length of the
detector but only 3.4 arcmin in the cross dispersion direction. This
arrangement creates a quiescent background rate of 120 cts s^1. More
can be read about the spectroscopy region in Sec 9.3.6 of the POG.
Background Fluctuations
As with most all detectors on space-based telescopess, the HRC-I and HRC-S
experience background fluctuations due to charged particles. These
occurrences will usually last from 3-10 minutes and can range from a
factor of 2 to 10 over the quiescent background rates. These events
affect about 20% of observing time and can be easily recognized and
removed from observations.
SpectroscopyEven though the HRC-S is optimized for
spectroscopy, both the HRC-S and HRC-I can be used with the LETG for
spectroscopic studies. Read about LETG detector choices
here.
HRC-S
The HRC-S is primarily designed for spectroscopy. Also, the QE is smaller
than ACIS-S in the 1.2-20 Å range, but is larger at longer
wavelengths. The HRC-S can also be configured to have the highest time
resolution of any detector on Chandra. Therefore, observations that are interested in spectral
information longer than 25 Å or require high time resolution
should utilize the LETG/HRC-S combination.
HRC-I
Although the HRC-I is optimized for imaging, it can still be used for
spectroscopy. Coupled with the LETG, the HRC-I detector provides
wavelength coverage from 1.2-73 Å. Also, because of its size
(30x30 arcmin), it can be used if a large detector in the
cross-dispersion direction is required. Therefore, observations of
very weak sources with interesting spectral features beyond the limit
of LETG/ACIS-S or observations requiring a detector with a very large
cross-dispersion area should utilize the LETG/HRC-I.
Be sure to check if the ACIS-S detector can better fulfill specific
spectroscopic goals.
Imaging
The best HRC imaging is done with the HRC-I due to its lower
background (
Sec
7.10 of the POG) and large field of view (30x30 arcmin). The
instrinsic PSF FWHM is ~0.4 arcsec but the resolution degrades as the
target moves off-axis due to the increasing width of the HRMA PSF and
the increasing deviation between the curved HRMA focal surface and the flat HRC-I detector. The center
of the HRC-I FOV yields the best focus and the best image quality.
Timing Studies
The HRC-S has three segments that are normally used for
spectroscopy. But when put into timing mode, only the middle segment
of the MCP is used to generate event triggers. The detector is not
edge-blanked like with normal spectroscopic studies. This way, even
though the active detector area is decreased to 6x30 arcmin, every event is telemetered
(assuming that the count rate is below the telemetry saturation). This
yields the fastest time resolution aboard Chandra of 1.6 ms.
