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Cycle 22 STIS Calibration Plan

Hugues Sana
Justin Ely
&
COS/STIS Team

9/16/2014

1

Cycle 22 Instrument Usage Statistics Based on
Phase II Submissions*

· STIS orbits comprise almost 13% of all prime orbits in Cycle 22

Instruments
ACS
COS
STIS
WFC3
FGS

Prime Orbits Usage
17.4%
20.4%
12.6%
49.7%
0.0%

SNAP Orbit Usage
8.8%
9.8%
68.3%
13.2%
0.0%

* Include SNAP STIS program 13776 (450 orbits) for which Phase II still pending

STIS Cycle 22 Exposure Time Percentages as a Function of Configuration/Mode

Percentage of STIS Prime Exposure Time

C21

Configuration/Mode

Percentage of STIS SNAP Exposure Time
(0.9% of all STIS time)

C21
0.2%
0.2%
---
49.0%
---
49.0%
50.8%
---
50.8%

C22
26.4%
8.5%
17.9%
42.1%
1.5%
40.6%
31.5%
0.2%
31.3%

C22
100%
--
100%
--
--
--
--
--
--

3

CCD
CCD/Imaging
CCD/Spectroscopy
FUV
FUV/Imaging
FUV/Spectroscopy
NUV
NUV/Imaging
NUV/Spectroscopy

20.3%
4.3%
15.9%
38.5%
3.0%
35.5%
41.2%
0.06%
41.2%

STIS Cycle 22 Exposure Time Percentages as a Function of Configuration/Mode

Percentage of STIS Prime Exposure Time

C21

Configuration/Mode

Percentage of STIS SNAP Exposure Time
(0.9% of all STIS time)

C21
0.2%
0.2%
---
49.0%
---
49.0%
50.8%
---
50.8%

C22
26.4%
8.5%
17.9%
42.1%
1.5%
40.6%
31.5%
0.2%
31.3%

C22
100%
--
100%
--
--
--
--
--
--

4

CCD
CCD/Imaging
CCD/Spectroscopy
FUV
FUV/Imaging
FUV/Spectroscopy
NUV
NUV/Imaging
NUV/Spectroscopy

20.3%
4.3%
15.9%
38.5%
3.0%
35.5%
41.2%
0.06%
41.2%

STIS Cycle 22 Exposure Time Percentages as a Function of Grating/Mirror

Configuration/Mode
STIS/CCD
Grating/Mirror
G230LB
G230MB
G430L
G430M
G750L
G750M

MIRROR/CORON

Percentage of STIS Prime Exposure Time

C21
0.06%
0.12%
7.9%
0.4%
6.6%
1.0%
4.3%
12.4%
17.8%
5.3%
0.08%
3.0%
18.2%
10.5%
12.5%
0.06%

Percentage of STIS SNAP Exposure Time

C21
---
---
---
---
---
---
0.2%
---
---
44.12%
4.87%
---
32.42%
---
18.39%
---

C22
3.4%
0.03%
1.9%
1.7%
9.4%
1.5%
8.5%
4.2%
12.6%
17.4%
6.4%
1.5%
0.7%
13.1%
17.4%
0.2%

C22
---
--
52.1%
--
47.9%
--
--
--
--
--
--
--
--
--
--
--

5

STIS/FUV

E140H
E140M
G140L
G140M
MIRROR

STIS/NUV

E230H
E230M
G230L
MIRROR

STIS Cycle 22 Exposure Time Percentages as a Function of Grating/Mirror

Configuration/Mode
STIS/CCD
Grating/Mirror
G230LB
G230MB
G430L
G430M
G750L
G750M

MIRROR/CORON

Percentage of STIS Prime Exposure Time

C21
0.06%
0.12%
7.9%
0.4%
6.6%
1.0%
4.3%
12.4%
17.8%
5.3%
0.08%
3.0%
18.2%
10.5%
12.5%
0.06%

Percentage of STIS SNAP Exposure Time

C21
---
---
---
---
---
---
0.2%
---
---
44.12%
4.87%
---
32.42%
---
18.39%
---

C22
3.4%
0.03%
1.9%
1.7%
9.4%
1.5%
8.5%
4.2%
12.6%
17.4%
6.4%
1.5%
0.7%
13.1%
17.4%
0.2%

C22
---
--
52.1%
--
47.9%
--
--
--
--
--
--
--
--
--
--
--

6

STIS/FUV

E140H
E140M
G140L
G140M
MIRROR

STIS/NUV

E230H
E230M
G230L
MIRROR

STIS Calibration and Monitor Orbits Request by Cycle

Prog rams
Cycle 17
Cycle 18
Cycle 19
Cycle 20
Cycle 21
Cycle 22
25
20
18
20
20
19
External
Orbits
68
22
21
21
21
21

Parallel Orbits
0
0
0
0
0
0

Internal Orbits
1816
1370
1418
1391
1392*
1387*

Total
Orbits
1884
1392
1439
1412
1413
1408

External Orbit Requests have remained constant over the last 5 cycles.

* 5-orbit more in Cy 21 compared to Cy 22 due to execution of the special calibration program ("CCD Saturation Limits")

7

STIS Cycle 22 Calibration and Monitor Orbits Request

Prop. ID
Title
External
CCD Monitors
STIS CCD Performance Monitor
STIS CCD Dark Monitor
STIS CCD Bias and Readnoise Monitor
STIS CCD Hot Pixel Annealing
STIS CCD Spectroscopic Flat-Field Monitor
STIS CCD Imaging Flat-Field Monitor
STIS CCD Spectroscopic Dispersion Solution Monitor
STIS CCD Sparse Field CTE
STIS CCD Full Field Sensitivity
STIS Slit Wheel Repeatability
STIS CCD Spectroscopic Sensitivity Monitor
5
MAMA Monitors
STIS MAMA Spectroscopic Dispersion Solution Monitor
STIS MAMA Full Field Sensitivity
STIS MAMA Spectroscopic Sensitivity and Focus Monitor / COS Observations of Geocoronal Ly Emission
STIS FUV MAMA Dark Monitor
STIS NUV MAMA Dark Monitor
STIS MAMA FUV Flat-Field Monitor
STIS MAMA Fold Distribution
Contingency prog ram
STIS MAMA Anomalous Recovery
TOTAL
Cycle 22 orbit request
21
(6)
1387 + (6)
(6)
1392 + (6)
3
12
54
52
11*
2
7
7x1
1x3
3x1/L, 1x1/M, 4x2/E
9x6
26x2
11x1
1x2
7
3
12
54
52
11
2
1
1
14
730
369
39*
19
4
3
82
2x7
364+366
182+183+4
13x3
19x1
4x1
3x1
82x1
1x1
1x1
3x1/L, 1x2/M
14
730
369
39
19
4
3
82
1
1
5
External
Parallel
Internal
Frequency
Cycle 21
Allocation

Internal parallel orbits > 1800s.

Green means "executing on alternating cycle only"

() Indicates contingency orbits not included in Cycle 22 request.

*

8

STIS/CCD programs

9

STIS CCD Performance Monitor
P.I. JoTaylor

Purpose
To measure the baseline performance of the CCD detector.
This program monitors the performance of the CCD detector on orbit. Only primary amplifier D is used. Bias and Flat Field exposures Description
are taken in order to measure read noise, CTE (EPER test), spurious charge and gain. Full frame observations are made. Bias exposures are taken in sub-array readouts to check the bias level for ACQ and ACQ/PEAK observations. All orbits < 1800s.
Fraction GO/GTO 26% of STIS total exposure time.
Prog rams Supported
Resources Required: 14 internal orbits, performed in two groups of 7.
Observations
2 FTE weeks for analysis. Provides baseline measurements of gains, read noise, charge transfer efficiency, spurious charge and performance Resources Required: verification of binning and sub-array readout capabilities. Provides a rough assessment of changes in flat field features due to dust motes Analysis
or other particulates.
Possible update of the gain and read out noise values in ccdtab. This also provides a relative measure of CTI via the extended pixel edge Products
response test. Possible flight software updates of table CCDBiasSubtractionValue. Possible report in a STAN and a summary in the end of cycle ISR.
Accuracy Goals
Read-out noise error < 0.3 electrons. Gain error < 0.08 electrons./ADU
Scheduling & Special Visits will occur every 6 months (March and September).
Requirements
Changes from Cycle 21
No changes.

10

STIS CCD Dark Monitor (Parts 1 & 2)
P.I. Jo Taylor

Purpose
Monitor the darks for the STIS CCD.
Routine monitoring: obtain 2 visit per day comprising of 1 long (1100s) and 2 short (60s) darks exposures at GAIN=1 in order to monitor CCD behavior and chart growth of hot and bad pixels. Check how well the anneals work for the CCD. All exposures are internals and fit in occultation orbits.

Description
In addition to routine monitoring, one month of 60s daily darks will be taken with AMP=A to conduct a measure of the absolute CTI as a function of the number of transfers in the STIS CCD using warm pixels and a direct comparison to typical AMP=D 60s darks. We will schedule this month during periods when the STIS CCD is not being heavily used, thus mitigating any potential impact to GOs.

All orbits < 1800s.
Fraction GO/GTO 26% of STIS total exposure time.
Prog rams Supported
Resources Required: 364 (part1) + 366 (part2) internal orbits (twice per day)
Observations
Resources Required: 4 FTE weeks; Retrieve and construct superdarks. These superdarks are compared to previous superdarks and the image statistics are Analysis
checked to see if there are any anomalous statistical deviations. Analysis of CTE data.
Products
Weekly CDBS reference files (superdarks) and a summary in the end of cycle ISR.

Accuracy Goals
Superdark rms < 0.012 e-/s. S/N > 1.0
Scheduling & Special Two orbits per day.
Requirements
Changes from Cycle 21
No changes (including the data taken to support the CTI analysis).

11

STIS CCD Bias and Read Out Noise Monitor (Parts 1 & 2)
P.I. Jo Taylor

Monitor the bias in the 1x1 bin settings at GAIN=1 and at GAIN=4, to build up high S/N superbiases and track the evolution of hot Purpose
columns. Also acquire GAIN=1, 1x1 biases through AMPS A and C to use in combination with biases taken through AMP D for monitoring of the read noise.
Take full frame bias exposures in the 1x1 bin settings at GAIN=1, and 1x1 at GAIN = 4. Take full frame biases through AMPS A and C. All exposures are internals and fit in occultation orbits.

Description
In addition to routine monitoring, during one month we will use 4 orbits of GAIN=1, AMP=A biases in support of absolute CTI measurements using hot pixels in darks.

All orbits < 1800s.
Fraction GO/GTO 26% of STIS total exposure time.
Prog rams Supported
Resources Required: 182 (part1) + 183 (part2) internal orbits + 4 CTI internal orbits
Observations
2 FTE weeks. Retrieve and construct superbiases. These superbiases are compared to previous superbiases and the image statistics are Resources Required: checked to see if there are any anomalous statistical deviations. Furthermore, acquisition of biases through AMPS A and C will allow the Analysis
read noise monitor to be accomplished.
Products
Weekly CDBS reference files (superbiases) and a summary in the end of cycle ISR.
Accuracy Goals
Superbias rms < 0.95 e- at GAIN=1 1x1 and rms < 1.13 e- at GAIN=4 1x1. S/N > 1. Scheduling & Special One orbit per day for the routine monitor
Requirements
Changes from Cycle 21
No changes (including the data taken to support the CTI analysis).

12

STIS CCD Hot Pixel Annealing
P.I. Jo Taylor

Purpose
To anneal hot pixels. The effectiveness of the CCD hot pixel annealing is assessed by measuring the dark current behavior before and after annealing.
The characteristics of the CCD will first be defined by a series of bias, dark and flat-field exposures taken before the anneal. The CCD thermoelectric cooler will be turned off to allow the CCD detector temperature to rise from ~ -80 C to +5 C. The CCD will be left in the uncooled state for approximately 12 hours. At the end of this period the thermoelectric cooler is turned back on and the CCD is Description
cooled to its normal operating temperature. Since the CCD on Side-2 does not have thermistor, a 4 hour period, at a minimum, is necessary to ensure that the CCD is cool and stable. After the CCD has stabilized bias, dark and flat-field images will be repeated to check for changes in the CCD characteristics. The flat field exposures will permit evaluation of any window contamination acquired during the annealing period. All visits > 1800s. Pure parallel mode.
Fraction GO/GTO 26% of STIS total exposure time.
Prog rams Supported
Resources Required: 39 internal orbits and all orbits > 1800s.
Observations
Resources Required: 2 FTE weeks. By comparing the number of hot pixels before and after the anneal we see if the hot pixels decrease and estimate the Analysis
number of hot pixels that persist after the process.
Products
Hot pixel growth rate, median dark count rate, and a summary in the end of cycle ISR.

Accuracy Goals
Measure the growth rate of hot pixels to within 1% if possible.
Scheduling & Special Anneals will execute every 4th week using 3 orbits.
Requirements
Changes from Cycle 21
No changes.

13

STIS CCD Spectroscopic Flat-Field Monitor
PI: Hugues Sana

Purpose
Obtain medium resolution grating flats to determine the pixel-to-pixel variation for spectroscopic observations and produce the reference P-flat (M and L modes).

We will use the tungsten lamp and the medium resolution grating G430M to determine the pixel-to-pixel variations of the STIS CCD in Description
spectroscopic mode. The flat exposures will be taken with the 50CCD and 52x2 apertures at five offset positions to map, with a sufficient SNR, the entire sensitive area of the detector. The expected signal is 1.4e+6 ADU/pixel. The expected accuracy is 1.5%.

Fraction GO/GTO 26%
Prog rams Supported
Resources Required: 19 internal orbits
Observations
Resources Required: 2.5 FTE weeks
Analysis
Products
Reference files and an ISR as applicable. Summary in end of cycle ISR
Accuracy Goals
1.5%
Scheduling & Special 9 orbits for G430M with 50CCD spread across the cycle; 1 visit every ~40 days
Requirements
10 orbits for G430M with 52x2
Changes from Cycle 21
None

14

STIS CCD Imaging Flat-Field Monitor
PI: Hugues Sana

Purpose
Collect high SNR white light imaging flats (aperture=50CCD) for monitoring purposes and to create a new reference p-flat for chronographic and imaging observations.
3 months, obtain a series of imaging CCD flats using the MIRROR and the unfiltered allow us to keep monitoring possible (but unlikely) variations across the cycle; while the an average signal ~620000 ADU/pix (similarly to past cycles) and create a high accuracy ( orbit/visit will be used to monitor the stability of the CORON aperture due to the MSM 50CCD aperture. The 3 months combined observations will allow ~1%) imaging p-flat. The remaining limited reproducibility.

Once every cadence will Description
us to obtain time in each Fraction GO/GTO 26%
Prog rams Supported

Resources Required: 4 internal orbits
Observations
Resources Required: 4 FTE weeks
Analysis
Products
Reference p-flat, an ISR as relevant, summary in end of cycle ISR

Accuracy Goals
1%
Scheduling & Special 1 visit every 3 months
Requirements
Changes from Cycle 21
None

15

STIS CCD Spectroscopic Dispersion Solution Monitor
P.I. Paule Sonnentrucker

Purpose
To monitor the wavelength and spatial distortion maps for some configurations of the STIS/CCD.

Internal wavecals will be obtained with all 6 gratings (G230LB, G230MB, G430L, G430M, G750L, G750M) supported for use with the CCD. All observations will be obtained with the 52x0.1 aperture, which maps to 2 pixels at the CCD. The HITM1 lamp will be used, Description
rather than the LINE lamp. The HITM1 lamp has a more favorable spatial illumination pattern, dropping by only a factor of 3 at row 900, relative to the peak brightness at row 420. A comparison LINE lamp wavecal is however included with the G430L/4300 grating. All orbits < 1800s.
Fraction GO/GTO 26% of STIS total exposure time.
Prog rams Supported

Resources Required: 3 internal orbits
Observations

Resources Required: 4 FTE weeks
Analysis
Products
Update wavelength dispersion reference file as needed, ISR, and a summary in the end of cycle ISR.
0.2 pixels; wavelength accuracy for row 900. Wavelength coefficients are tabulated every 32 rows in the CCD dispersion (_dsp) reference file. Exposure times in this program have typically been chosen to yield a S/N ratio of at least 10 per pixel in row 900 after Accuracy Goals
combining 32 rows. This constraint must be satisfied in the left, middle, and right thirds of the image. Existing HITM1 wavecals were used to estimate exposure times assuming no significant degradation since Cycle 18.
Scheduling & Special These observations are taken once per cycle
Requirements
Changes from Cycle 21
No changes.

16

STIS CCD Sparse Field CTE
P.I. Sean Lockwood

Purpose
Re-establish an accurate correction for parallel register CTE losses that can be used for direct analysis of science data with negligible background. Do measurements for both GAIN settings (1 and 4).
The internal sparse field CTE will be measured via internal calibration lamp observations taken through narrow slits. The strategy of the test is as follows. Using the onboard tungsten lamp, narrow slit images are projected at different positions on the detector. At each position a series of exposures is taken alternating between the `A' and `C' amplifiers for readout. The further the charge needs to be Description
shifted to be read out, the more charge it will lose. For the parallel CTE measurement, the test will use the the cross disperser slits: 0.05x31NDB and 0.05x31NDA. In order to test the effects of different bias voltages the whole series of exposures are executed once for GAIN=1, and once for GAIN=4; this process requires a total of 74 orbits which includes various sets of biases. For the CTE pixel based correction, the test requires 8 orbits for darks read out with amplifier A. All orbits < 1800s.
Fraction GO/GTO 26% of STIS total exposure time.
Prog rams Supported
Resources Required: 82 internal orbits
Observations
Resources Required: 3 FTE weeks
Analysis
Products
Determine slope for time dependent correction of CTE, possible update of ccdtab reference file, and summary in the end of cycle ISR.
Accuracy Goals
CTE correction coefficients will be determined to a relative accuracy of 1%.
The whole set of calibration exposures is duplicated for GAIN=1 and GAIN=4. The first set should execute in November 2014 and Scheduling & Special includes visits 01-32; these must be done consecutively. The second set should be scheduled for December 2014 and includes visits Requirements
33-64, consecutively as well. Visits 75-82 should be scheduled within the month-long annealing period that the STIS "CCD Dark Monitor 2" program AMP=A darks are taken ~(June 1, 2015 - June 22, 2015).
Changes from Cycle 21
Re-arranging visit to help with analysis (cosmic rays)

17

STIS CCD Full Field Sensitivity
P.I. Hugues Sana

Purpose
To monitor CCD sensitivity over the whole field of view.
Observe a photometric standard star field in Omega Cen in 50CCD annually to monitor CCD sensitivity over the whole field of view. Keep the spacecraft orientation within a suitable range (+/- 5 degrees) to keep the same stars in the same part of the CCD for every measurement. This test will give a direct transformation of the 50CCD magnitudes to the Johnson-Cousins system for red sources. These Description
transformations should be accurate to 1%. The stability of these transformations will be measured to the sub-percent level. These observations also provide a check of the astrometric and PSF stability of the instrument over its full field of view. Although this test is done using CCD imaging mode, the confirmation of detector stability and uniformity provided by this monitor is important for spectroscopic observations as well. All orbits > 1800s.
Fraction GO/GTO 26% of STIS total exposure time.
Prog rams Supported
Resources Required: 1 external orbit
Observations
Resources Required: 1 FTE week
Analysis
Products
Summary in the end of cycle ISR.

Accuracy Goals
1%
Scheduling & Special ORIENT 310.0D TO 310.0 D; BETWEEN 15-JAN-2015:00:00:00 AND 20-MAR-2015:00:00:00
Requirements
Changes from Cycle 21
No changes.

18

STIS Slit Wheel Repeatability
P.I. Audrey DiFelice

Purpose
To test the repeatability of slit wheel motions.

Description
A sequence of lamp spectra taken using grating G230MB and the three smallest long slits 52X0.1, 52X0.2, and 52X0.05.
Fraction GO/GTO 90%
Prog rams Supported
Resources Required: 1 internal orbit (24 exposures, ~40 minutes total)
Observations
Resources Required: 2FTE days
Analysis

Products
The average and maximum shifts observed in the dispersion and the spatial direction. Summary in end of cycle ISR

Accuracy Goals
Shifts should be smaller than 0.5 pixels.
Scheduling & Special None.
Requirements
Changes from Cycle 21
Update the valid observation window to 2014

19

STIS CCD Spectroscopic Sensitivity Monitor
P.I. Hugues Sana

Purpose
Monitor the spectroscopic sensitivity of the STIS CCD using the low and medium resolution gratings to reveal contamination issues that may affect the spectroscopic throughput.

This program will monitor the STIS CCD spectroscopic sensitivity using a high-declination spectroscopic calibration star (AGK+81D266). Description
The results will be compared to previous observations to detect trends. The L modes will be observed at the nominal and E1 positions every four months with one orbit per visit. The M modes will be monitored once per year with two orbits per visit.
Fraction GO/GTO 26%
Prog rams Supported
Resources Required: 5 external orbits
Observations
Resources Required: 3 FTE weeks (1 week for analysis, 2 weeks for ISR)
Analysis

Products
Updated STIS TDSTAB file, an ISR on STIS sensitivity monitoring, summary in end of cycle ISR

Accuracy Goals
Minimum signal to noise of 50 per resolution element at the least sensitive wavelength.
Scheduling & Special Visits need to be approximately equally spaced throughout the cycle
Requirements
Changes from Cycle 21
None

20

STIS/MAMA programs

21

STIS MAMA Spectroscopic Dispersion Solution Monitor
P.I. Paule Sonnentrucker

Purpose
To monitor the wavelength dispersion solutions of some STIS MAMA configurations.
Internal wavecals will be obtained in all gratings at primary and secondary central wavelengths chosen to cover cycle use. There is also overlap with choices of configurations used with previous calibration programs which will enable long-term monitoring. This program Description
uses the LINE lamp for a total of approximately 8 hours, typically at a lamp current of 10 mA, consuming about 0.5% of the 15000 mAhour lifetime. Extra-deep wavecals are included for some echelle modes and for some first order modes to ensure detection of weak lines. All orbits < 1800s.
Fraction GO/GTO 74% of STIS total exposure time.
Prog rams Supported
Resources Required: 7 internal orbits
Observations

Resources Required: 4 FTE weeks
Analysis

Products
Update reference file as needed, ISR, and summary in the end of cycle ISR.

Accuracy Goals
0.1 pixels internal wavelength precision.
Scheduling & Special These observations are taken once per cycle
Requirements
Changes from Cycle 21
No changes

22

MAMA Full Field Sensitivity
P.I. Hugues Sana

Purpose
To monitor the sensitivity of the FUV-MAMA and NUV-MAMA over the full field.
By observing the globular cluster NGC6681 once every year at roughly the same orientation, we will monitor the full-field sensitivity of the MAMA detectors and their astrometric and PSF stability. These observations will be used to look for contamination, throughput Description
changes, or formation of color centers in the photocathode and window that might be missed by spectroscopic monitoring or difficult to interpret in flat-fielding. Although this test is done using MAMA imaging modes, the confirmation of detector stability and uniformity provided by this monitor is important for spectroscopic observations as well. All orbits > 1800s.
Fraction GO/GTO 74% of STIS prime exposure time.
Prog rams Supported
Resources Required: 3 external orbits
Observations
Resources Required: 1 FTE week
Analysis
Products
summary in the end of cycle ISR.

Accuracy Goals
Percent level; counting statistics signal-to-noise on bright stars
Scheduling & Special Should roughly match most common orient from previous observations.
Requirements
ORIENT 260.0D TO 266.0 D; BEFORE 16-JUN-2015:00:00:00
Changes from Cycle 21
No changes.

23

STIS MAMA Spectroscopic Sensitivity & Focus Monitor (& COS Observations of Geocoronal Lyman- Emission)
PI: Hugues Sana

Purpose
Monitor the sensitivity of each STIS MAMA grating mode to detect any changes due to contamination or other effects, and monitor the STIS focus in spectroscopic and imaging modes

- SENSITIVITY: Obtain exposures in each of the two low-resolution MAMA spectroscopic modes every 4 months, in each of the 2 medium-resolution modes once a year, and in each of the 4 echelle modes every 3 months, using unique calibration standards for each mode (L: GRW+70D5824, M: AGK+81D266,E: BD+28D4211), and compare the results to the first observations to detect any trends.
- FOCUS: For this cycle we will enhance the monitoring of the STIS focus (PSF across the dispersion as a function of UV wavelength) Description
by including a direct comparison between the G230LB 0.1X0.09 and 50CCD throughput as well as a narrow band OII CCD image during each L-Mode visit. These exposures can be added without requiring extra orbits if the G230L wavecal is shifted into the occultation. We will continue to also include an OII image with the M-mode visit.
- AIRGLOW: Whenever possible, COS/FUV airglow spectra will be obtained in parallel (see COS slides)
Fraction GO/GTO 74% of STIS prime exposure time
Prog rams Supported
Resources Required: 12 external orbits
Observations
Resources Required: 3 FTE weeks
Analysis
Products
Updated STIS TDSTAB file and ISRs on STIS sensitivity monitoring and focus monitoring. Summary in end of cycle ISR

Accuracy Goals
Minimum signal to noise of 50 per resolution element at the least sensitive wavelength. 10% for focus changes.
Scheduling & Special Visits need to be approximately equally spaced throughout the cycle.
Requirements
Changes from Cycle 21
Enhanced focus monitoring strategy.

24

STIS FUV MAMA Dark Monitor
P.I. Colin Cox

Purpose
To monitor the dark rate in the STIS FUV detector to provide information for data analysis, IHB and ETC updates.
Also to detect any large changes in instrument behavior which might indicate a problem.

Description

Six 1300s dark images are taken every six weeks. The exposures are distributed over about six hours from initial turn-on to characterize the rate increase as a function of turn-on time and temperature.

Fraction GO/GTO 42%
Prog rams Supported
Resources Required: 54 internal orbits
Observations
Resources Required: 2.5 FTE week
Analysis
Individual and cumulative dark images. Update dark rates in ETC and IHB. Text file giving full rate history plus graphical representation. All maintained on STIS monitor web page. Summary in end of cycle ISR

Products

Accuracy Goals
Each measurement will give a statistical uncertainty of less than 1% for the global dark rate

Scheduling & Special All measurements taken in SAA free periods in six sequential orbits. This matches time-on range of typical GO observations
Requirements

Changes from Cycle 21
None

25

STIS NUV MAMA Dark Monitor
P.I. Colin Cox

Purpose
Monitor the dark rate in the STIS NUV MAMA to provide values for image processing, to detect any large changes which might indicate instrumental problems and to update IHB and ETC.

Description

Two 1300 second dark images are taken every two weeks. The images are taken about 6 hours apart to discriminate between long and short term changes.

Fraction GO/GTO 31%
Prog rams Supported
Resources Required: 52 internal orbits
Observations
Resources Required: 0.05 FTE year
Analysis
ETC and IHB dark rate updates. Individual and cumulative dark rates. Master dark reference file. Refinements to model describing Products
temporal and temperature effects. Text file giving continuously updated dark rate history and graphical representation. Both maintained on STIS monitoring web page. Summary in end of cycle ISR
Accuracy Goals
Statistical accuracy of mean rate will be better than 1%.

Scheduling & Special SAA free orbits covering a 6-hour period.
Requirements

Changes from Cycle 21
None

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STIS FUV MAMA Flat-Field Monitor
PI: Hugues Sana

This program is aimed at obtaining FUV-MAMA flat-field observations to create new p-flats with a SNR of ~100 per (low resolution) Purpose
pixel. The flats are obtained with the Krypton lamp and the MR grating G140M, similar to the cycle 17 and 18 programs. However the exact instrument setup (slit width and central wavelength) might change depending on the desired count level (which will be close to the internally allowed global rate limit).
Past experience and observations have shown that ~11 visits are sufficient to create a cumulative image with ~2500 counts/pixel (high resolution mode, equivalent to ~10000 count/pixel in low resolution mode). We will start taking exposures with the setup G140M/52x0.1/1470 as in cycles 18 & 20 programs. We will move to G140M/52x0.1/1420 if/when the global rate has decreased below Description
180000-190000 counts/sec (maximum allowed is ~280000 counts/sec). On the basis of past experience exposures will be at least 4740 sec long. Hence, all orbits exceed the 1800 s execution time. Different visits will have different slit offsets in order to illuminate the pixels which are normally shadowed by the slit bars.
Fraction GO/GTO 42% of STIS total exposure time.
Prog rams Supported
Resources Required: 11 internal orbits and all orbits > 1800s.
Observations
Resources Required: 4 FTE weeks
Analysis
Products
This cycle p-flat is for monitoring purposes. The achievable SNR is limited by the Poisson noise. If applicable a new reference p-flat will be created combining cycle 17, 18, 20 and 22 FUV flats. ISR as applicable.

Accuracy Goals
1.0%: Accuracy is per low-res pixel (2x2 high-res pixels).
Scheduling & Special Similar to the NUV flat program, the observations are executed on alternate cycles, to save lamp lifetime.
Requirements
Changes from Cycle 20
None. This program is run on even-numbered cycles.

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STIS MAMA Fold Distribution P.I. Thomas Wheeler

Purpose
The fold analysis provides a measurement of the distribution of charge cloud sizes incident upon the anode providing some measure of changes in the pulse-height distribution of the MCP and, therefore, MCP gain.

Description

While globally illuminating the detector with a flat field, the valid event (VE) rate counter is monitored, while various combinations of row and column folds are selected.

Fraction GO/GTO 74% of STIS prime orbits
Prog rams Supported
Resources Required: 2 internal orbits
Observations
Resources Required: 0.5 FTE day.
Analysis
Products
The results will be sent to the COS/STIS Team and V. Argabright of Ball Aerospace.

Accuracy Goals
Scheduling & Special This proposal is executed annually.
Requirements
Changes from Cycle 21
None

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Contingency program

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STIS MAMA Recovery from Anomalous Shutdown P.I. Thomas Wheeler

Purpose
Safe and orderly recovery of either MAMA detector from an anomalous shutdown.

The recovery procedure consists of three separate tests (i.e. visits) to check the MAMA's health after an anomalous shutdown. Description
Each must be successfully completed before proceeding onto the next. They are: (1) signal processing electronics check, (2) slow, intermediate voltage high-voltage ramp-up, and (3) ramp-up to full operating voltage.

Fraction GO/GTO 74% of STIS prime orbits
Prog rams Supported
Resources Required: 6 internal orbits
Observations
Resources Required: If activated, 0.5 FTE day per test.
Analysis
Products
For tests 1-3, only a Go/No-Go to proceed will be given.

Accuracy Goals

Scheduling & Special This is a contingency proposal activated only in the event of an anomalous shutdown. This proposal is usually followed by the Requirements
STIS MAMA Fold Distribution proposal.

Changes from Cycle 21
None

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