All of the supported slits for this Cycle are available on the ETCs. The pull-down menu gives the supported slits and filters for the chosen grating/prism. Since the filters and the slits are in the same wheel, you can choose either a slit or a filter. In case of the neutral density filters, the pull-down menu gives the density of the filter in "log10" units, i.e. ND=1 corresponds to an attenuation factor of 10, ND=2 corresponds to an attenuation factor of 100, etc. In the case of the slits, the pull-down menu gives the slit height and slit width in arcsec. To choose the best slit width, you may need to know the number of detector pixels corresponding to the slit-width. The table below gives the plate scales for different gratings.
|
Grating |
Plate Scale (arcsec/pixel) |
|
|
Along Dispersion |
Along Slit |
|
|
First Order CCD |
0.051 |
0.051 |
|
G140L, G230L |
0.025 |
0.025 |
|
G140M, G230M |
0.029 |
0.025 |
|
E230M |
0.035 |
0.029 |
|
E140M |
0.036 |
0.029 |
|
E230H |
0.047 |
0.029 |
|
E140H |
0.047 |
0.029 |
Detector Countrate
Restrictions
The
ETC uses the current MAMA countrate
restrictions, which are taken from the STIS
Instrument Handbook. If the observation will exceed any of the countrate restrictions, a warning message will be given in
the output page. This is particularly useful to check if the observations will
exceed the bright-object protection (BOP) limit of the MAMA detector. The countrate restrictions for the detectors are as follows:
CCD Saturation Limits
|
Gain |
Saturation Level |
Full Well |
||
|
(electrons) |
(ADU) |
(electrons) |
(ADU) |
|
|
1 |
30,000 |
30,000 |
120,000 |
120,000 |
|
4 |
120,000 |
30,000 |
120,0001 |
30,000 |
1The fullwell limit for gain=4 is 144,000 near the
center of the chip and only 120,000 near the edges.
MAMA Countrate Restrictions for Different
Modes
|
Detector |
Target |
Local Limit |
Global Limit |
||
|
(First-order +
Prism Modes) |
(Echelle Modes) |
(Imaging Mode) |
|||
|
(counts/sec/pixel) |
(counts/sec) |
(counts/sec) |
(counts/sec) |
||
|
NUV-MAMA |
Non-variabe |
75 |
30,000 |
200,000 |
200,000 |
|
FUV-MAMA |
Non-variable |
75 |
30,000 |
200,000 |
|
|
NUV-MAMA |
Irregularly Variable |
75 |
12,000 |
80,000 |
|
|
FUV-MAMA |
Irregularly Variable |
75 |
12,000 |
80,000 |
|
In
the case of the echelle modes, there is some extra
noise because of the scattered light which runs across the orders. The updated
version of the ETC takes this extra noise into account (to a first
approximation) in the calculation of the S/N ratio. The global countrate estimates take the scattering into account.
For
imaging mode the peak countrates mentioned in the
output need some explanation. The peak countrates are
used only to check for the MAMA
bright object protection issues. Since the health of the detector sometimes
relies on our ability to predict the peak countrate
in a given observation, and since the dependence of the NUV- and FUV-MAMA PSF
on the filter/spectral shape is still being investigated, we have been a bit
conservative in our estimates of peak countrates,
particularly for the MAMAs. At present, the calculation
of peak count rates for the point sources assume that the encircled energy in
the central pixel is 30% in case of the CCD, and 25% in case of the MAMAs. This can be sometimes over conservative and can be
slightly larger than a factor of 2 for some MAMA modes. A more accurate
algorithm will be added in the future, which will take the spectral shape of a
given source and the filter combination into account to calculate the
appropriate percentage of enclosed energy in the central pixel.
Detector Binning
The
CCD has 3 binning factors: x1, x2 and x4. In Imaging
mode the binning factors must be the same in each detector dimension, but for
spectroscopy the factors can be different. Since the readnoise
of the CCD applies only to a 'binned' pixel, using a binning factor greater
than one can reduce the overall noise in some cases. However, this comes at the
price of degraded spatial (or spectral) resolution. The readnoise
and saturation characteristics of the CCD are given in the Table below. (Note
that the MAMA detectors have no readnoise, so the
binning option is ignored in these cases.)
Detector Background
STIS ACQ and ACQ/PEAK
observations are always done using an unbinned subarray and a CCD gain setting of 4. For these parameters,
the expected dark current is about 0.007 e-/s, and the expected read noise is
about 7.75 e-.
|
Detector |
Dark |
Read Noise |
|
CCD (Gain=1) |
9.0 * 10 -3 electron/pixel/s |
5.4 e- |
|
CCD (Gain=4) |
9.0 * 10 -3 electron/pixel/s |
7.7 e- |
|
NUV-MAMA |
1.3 * 10 -3 count/pixel/s |
0. |
|
FUV-MAMA |
0.07 - 3.0 * 10 -4 count/pixel/s |
0. |
Setting
the CCD gain to 4 is useful if you are expecting a large number of counts. For
faint sources, where the counts are expected to be lower, gain=1 may be
preferable since the readnoise in that case is lower.
To
avoid an excessive number of cosmic ray detections with the CCD, longer
exposures should be split (CR-split) in order to:
1.
keep
the number of detected cosmic rays low
2.
be
able to remove the cosmic rays during data reduction
Using
CR-split increases the effective readnoise, which is taken into account in the exposure time calculations.
The default CR-split is 2.
Selecting
a Checkbox Size for STIS Target Acquisitions
For extended source acquisitions, the user sets CHECKBOX=n, where n must be an odd number between 3 and 105: the checkbox will then have dimension n x n pixels. CHECKBOX should be set to the minimum size which ensures that the brightest checkbox will be the one centered on the region of interest (i.e., if your object is peaked within a region of 1 arcsecond, set CHECKBOX=21 [= (1 arcsecond) / (0.05 arcsecond pixel-1) + 1]. The maximum checkbox is 105 pixels on a side, or ~5 x 5 arcseconds. The used for a diffuse-source acquisition target image is CHECKBOX+101 pixels on a side. The STIS Target Acquisition Simulator can be used to determine the optimal CHECKBOX size.
