Cookbook for MIPS-916: 160micron Routine Scan Illumination Correction (IC)
Principal: Almudena Alonso
Deputy: David Frayer
Data Monkey(s): Almudena Alonso, Eiichi Egami, David
Frayer
Priority:
Downlink Priority: Normal
Analysis Time: 24-48 hours
Last
Updated:
Objective
To obtain a 160micron Routine Scan IC
Description
We will obtain IOC acceptable routine 160um SCAN mode
ICs (this task is repeated a number of times during different IOC campaigns)
to be used on a regular basis. This activity is a companion to the 160
um routine PHOTOMETRY task (MIPS-919). The pair of activities will allow
us to determine the relative efficiency and quality of ICs created using
scan and photometry AORs.
Since this task is repeated a number of times during IOC, we will observe
different regions of the sky each time. The task will check for possible
variations of quality of IC or saturation. This task will also be useful
for screening regions of the sky to obtain ICs in SIRTF routine operations.
This task together with MIPS-919 will determine whether routine ICs will
be obtained in photometry or scan mode.
NOTE: 24 and 70micron scan maps will also be observed. We will determine
whether different regions of the sky are suitable for obtaining flatfields/IC
at all three wavelengths. If that is the case, then MIPS-914 will be used
for all three wavelengths, and MIPS-915 and MIPS-916 will be redundant.
This task is executed in:
MIPS Campaign J
MIPS Campaign K
MIPS Campaign O
MIPS Campaign P
MIPS Campaign R
MIPS Campaign V
MIPS Campaign W
Data Collected
A 2 degree long (1 leg) scan map will be obtained using the fast scan AOT
in a region of the sky chosen to avoid bright point sources. This will
produce a total of 118 images to be median combined to produce a 160 um
IC. The map will require about 12.7 minutes of observing time.
# Please edit this file with care to maintain the
# correct format so that SPOT can still read it.
# Generated by SPOT on: 8/15/2002 14:6:39
HEADER: FILE_VERSION=6.1, STATUS = PROPOSAL
AOT_TYPE: MIPS Scan Map
AOR_LABEL: MIPS-916-Feb10-Mar25
AOR_STATUS: new
MOVING_TARGET: NO
TARGET_TYPE: FIXED SINGLE
TARGET_NAME: MIPS-916-Feb10-Mar25
COORD_SYSTEM: Equatorial J2000
POSITION: RA_LON=5h31m20.7928s, DEC_LAT=+3d15m00.6242s
OBJECT_AVOIDANCE: EARTH = YES, OTHERS = YES
REQUIRE_160: YES
SCAN_RATE: fast
FAST_RESET_160: NO
STEP_SIZE: TURNAROUND=35", FORWARD=35"
N_SCAN_LEGS: 1
N_MAP_CYCLES: 1
SCAN_LEG_LENGTH: 2.0
MAP_CENTER_OFFSET: CROSS_SCAN = 0, IN_SCAN = 0
SPECIAL_OVERHEAD: IMPACT = none, LATE_EPHEMERIS = NO
RESOURCE_EST: TOTAL_DURATION=762.52203, SLEW_TIME=3.0, SETTLE_TIME=5.222016, SLE
W_OVERHEAD=180.0, SPECIAL_OVERHEAD=0.0, UPLINK_VOLUME=653, DOWNLINK_VOLUME=94352
95, VERSION=S6.1.2
INTEGRATION_TIME: MIPS_24=15.7,MIPS_70=15.7,MIPS_160=3.1
COMMENT_START:
COMMENT_END:
Array Data Desired:
All Arrays
Data Reformatting Option:
-
NORMAL
1 FITS file per AOR per array.
Special Instructions:
Task Dependencies
-
CAID and title of Precedent Task #1 (or None)
-
etc.
Calibration Dependencies
Output and Deliverable Products
Mosaic of the observed region.
160micron IC obtained in SCAN mode.
We will apply an IC to a star observed at a grid of positions across
the array to check the quality of the IC. We will provide an array map
showing the location dependences -if any- of the photometric sensitivity.
Once the MIPS-919 task (Routine Photometry IC at 160micron) is executed,
we will provide a detailed comparison between ICs obtained in Photometry
and Scan modes at 160micron.
Data Analysis
-
Standard Pipeline reduction using the DAT and/or SSC Pipeline. If using
the DAT, we will run MIPS_SLOPER and then we will do the dark subtraction
with MIPS_CALER.
-
Produce a mosaic of the observed region using MIPS_ENHANCER. This will
be used to check for possible bright sources and/or regions of saturation.
-
Median combine 118 images obtained at 160micron (with some rejection algorithm)
using the IRAF "imcombine" task to create an IC. Alternatively, once the
IC DCEs are screened for possible saturation, etc, we can use the MIPS_ENHANCER
to create the flatfield frame using an appropriate rejection algorithm.
-
Apply the IC to star observations at different positions across the array
(NEED TO DETERMINE IOC TASKS ADEQUATE FOR THIS)
-
Aperture photometry on star using the IRAF "phot" task to measure flux
-
Comparison of star aperture photometry at different positions across the
array to determine IC accuracy.
-
Once the task is executed more than once:
-
we can look for possible IC variations with time/region of sky used
-
we can determine the number of DCEs necessary to construct a 'super' IC
(see J. Stansberry simulations; NEED TO ADD LINK TO FLATFIELD MODEL
WEBPAGE). NOTE: According to John's simulations we will need approximately
500 160micron DCEs to get an IC with an accuracy of 1% (rms, over the whole
array).
-
Once both this task and MIPS-919 are executed, we will carry out a detailed
comparison between ICs created in photometry and scan modes.
-
We will analyze the 24 and 70micron images in a similar fashion to determine
if the observed region of the sky is suitable to create flatfield/ICs at
all three wavelengths.
Software Requirements
Actions Following Analysis
If the IC S/N and quality requirements are met, then the flatfield frame
will be put in the calibration data archive.
If we find a sufficiently high number of regions of the sky are
good to create flatfields/ICs at all three wavelengths, we will only need
to observe MIPS-914. MIPS-915 and MIPS-916 can be replaced with other plug-and-play
tasks during IOC.
Failure Modes and Responses
If region of the sky used is saturated at one
or more wavelengths, this region will be removed from the list of flatfield
regions (Jeonghee Rho's list of flatfield regions), as ideally we would
like to use the same region of the sky to obtain flatfields and ICs at
all three wavelengths. If such region does not exist, then we will have
to keep MIPS-914, MIPS-915 and MIPS-916 and choose the appropriate region
of the sky for each wavelength.
Additional Notes