V-6. APPENDIX. A. Center. Positions for IRAS. Sky Survey. Atlas .... D.6. Plot of points rejected by the global destriper for detector. 42 (25 #m) ... D-17. D.7.
0
iras
Sky Survey Atlas EXPLANATORYSUPPLEMENT
S. L. Wbeelock T. N. Gautier .L Chillemi D. Kester H. McCallon C Oken J. V/bite D. Gregoricb E Boulanger
J. good T. Chester
InfraredProcessing andAnalysis Center JetPropulsion Laboratory
May1994
TheInfrared Astronomical Satellite (IU,S)was a jointproject ofNASA (U.S.), NIVR (TheNetherlands) andSERC (U.K.).
PREFACE
This Atlas
Explanatory
(ISSA)
covers
and
completely
coverage
down
ecliptic plane
the
high
ecliptic
fields
are of reduced
Set.
reduced
residuals.
The
latitude
compared
care
is due
some
be
[_1 > 50°,
in 1991
with
down
rest
product,
of the
ISSA the the
ecliptic
fields
ISSA
by zodiacal using
some covers
to 1/31,_
20 ° of the
to the
when
Survey
in 1992
coverage within
IPAC taken
Sky
release
release
to contamination
should
IRAS
ISSA
ISSA
latitudes
as a separate
quality
first sky,
second
covering
the
and
Reject emission
ISSA
Reject
(§IV.F).
In addition provided File
Set.
The
quality
released
Special
images
to information
in this
(ZOHF),
release
data
Survey
For additional Investigator
S. Wheelock, Pasadena November
which
was
images,
on the described
some
IRAS in the
in this Supplement
Center reader Atlas
are available
(NSSDC) at the Goddard is referred to the NSSDC
1988
at the National Space Flight Cenfor access to the
(ISSA).
information
and
Gautier
concerning
ISSA,
please
Analysis
Center
and
T. Chester
1993
ii
''_tN_.'-_
December
is
History
H).
Institute of Technology CA 91125 T.N.
information
Zodiacal
Support
Infrared Processing Mail Code 100-22 California Pasadena,
3.0,
described
ISSA
Supplement
(Appendix
Space Science Data ter. The interested Sky
on the
Explanatory Version
memo
The
Guest
Reject
of 50 ° > 1/31 > 20 °, with
are
IRAS
ISSA
remaining
therefore The
accompanies
the
to 1/31 _ 40°.
latitudes
13 ° . The
Supplement
'4_- _:_Q_
i,_.e,_
._.;I
i_L_..' '."
contact:
TABLE
Preface
of Tables
Index
of Figures
ii
.....................................................................
vii
....................................................................
ix
INTRODUCTION A.
General
B.
The
C.
The
D.
Cautionary
Overview
.........................................................
I 1
IRAS
Survey
.........................................................
I-2
IRAS
Sky
Survey
Notes
D.1
Absolute
D.2
Point
D.3 D.4
Photometric Confirmation
D.5
Solar
D.6
Residual
D.7 D.8 E.
F.
A.
Ascending Caveats
Low
Responsivity
Due
Angles Scans
SURVEY
History
File
ATLAS
Improvements
A.2
Zodiacal
A.3
Destripers
I 8 I-8
Removal
to Permit
Detector
Coaddition
Baselines
the
Representation
Known Asteroid Removal from the Coadded Full-Sized Detectors ................................................
B.3
Detector
Effective
II .................
........................... of Spatial
Images
.................................................. Method
Response Solid
....................................
.........................................
Angles
...................................... ..°
nl
1
II-1 II-2
Information
Information ...................................... Removal .........................................
Calibration
Frequency
II-1
...............................
A.7 A.8
Source
I-9
......................................
Calibration
to Improve
of Calibration
I--9 I-9
............................................
Improved Particle
Spatial
I 8 I-8
A.5 A.6
B.2
I-7
.....................................
in Atlas
to Stabilize Pointing Radiation
I-7
OVERVIEW
in Relative
Foreground
I-6 I-6
in the
.................................... .....................................
Artifacts
Improvements
A.1
Point
.......................
.................................................
Frequency
SKY
B.1
........
I-7
Effects
to Improvements
Solid
Anomalies
Zodiacal
Overview
Set
.......................................................... Data ......................................................
Spatial
and
I-6 Reject
........................................................
IRAS
Changes
............................................
vs. Descending
Destriper
I- 6
.................................................
Change
A.40versampling
B.
Debris
of Detector
E.4
IRAS
Photometry
Calibration
E.3
I-6
................................................
Photon-Induced
Mosaicking Saturated
I-4
Errors in Low Latitude Images, ISSA of Sources .............................................
System
E.1 E.2
The
...............................................
.........................................................
Source
Processing
Atlas
Radiometry
Accuracy
II.
CONTENTS
..............................................................................
Index
I.
OF
. II-2 II 2 II-2
.................
II II
2 3
II--3 II-3 II--3 II-8
C. III.
B.4
Zero
B.5
Calibration
Product
Calibration
..............................................
Limitations
Description
for Extended
II-8
Sources
.......................
......................................................
II-8 II-9
PROCESSING A.
Time-Ordered
Detector
A.1
Positional
A.2
Calibration
Data
Improvements
Improvements
..............................
...........................................
Improvements
Detector Response Function ................................. Zero Point Calibration .......................................
III-2 III-3
A.2.c
Other
III-8
Calibration
Enhancements
C.
Image
Production
C.1
Empirical
C.2
Zodiacal
C.3
Destriping
Data
.......................
Removal
III-10
.....................................
III-11
........................................................
Global Local
Destriper
Image
Assembly
Destriper
Quality Checking D.1 Pre-Production
Overview
III-10 III-10 III-10
.............................................
Foreground
C.3.b
III-12
..................................
III-12
.............................................
III-13
..................................................
III-18
....................................................... ...................................................
III-21 III-21
.......................................................
III-21
D.2
Production
D.3
Post-Production
D.4
Types D.4.a
of Anomalies ............................................... Data Anomalies ............................................
III-22 III-23
D.4.b
Processing
III-23
Analysis
B.
Positional
C.
Point
D.
Photometric D.1 Point
Overview
Anomalies
III-21
......................................
.......................................................
Accuracy
Spread
IV-1
.....................................................
Function
IV-1
...................................................
IV-3
Consistency ............................................... Sources .....................................................
D.2
Extended
D.3
Absolute
Noise E.1
..................................................
RESULTS
A.
F.
.............................
...................................................... Corrections
C.3.a
ANALYSIS
E.
III-2
A.2.a A.2.b
A.3 Deglitching ....................................................... Time-Ordered to Position-Ordered Detector
D.
III-1 III-1
..........................................
B.
C.4
IV.
Point
Sources
.................................................
Photometry
Performance Cross-Scan
Noise Equivalent Residual Zodiacal
E.4
Quality
ISSA
Reject
Estimates Set
IV-15
.............................................
and Sensitivity vs. In-Scan Noise
E.2 E.3
IV-11 IV-11 IV-15
...................................... ......................................
IV--17 IV-17
Surface Brightness in ISSA ...................... Emission ....................................... From
Background
Scan-to-Scan Analysis
iv
Statistics
...................................
...................
IV-17 IV 18 IV
18
IV-19
V. VI. VII.
FORMATS
FOR
THE
REFERENCES
IRAS
ATLAS
(ISSA)
.........
.............................................
APPENDIX
A.
Center
APPENDIX
B.
Compression
APPENDIX
C.
Pre-Production
APPENDIX
D.
Global
Positions
for
IRAS
Algorithm
Sky
V
1
VI
1
VII-1
Survey
Atlas
............
A
....................................
Anomalies
1
B 1
.................................
C
1
Destriping
D.1
Introduction
D.2
Database
Generation
D.3
Database
Clean-Up
D.4
Intensity
Difference
............................................................
D-1
....................................................
D-1
..................................................... Fits
D--6
.................................................
D 8
D.4.a
Fits
at 12 ttm
.....................................................
D.4.b
Fits
at 25 ttm
....................................................
D
11
D.4.c
Fits
at 60 jml
....................................................
D
14
D.4.d
Fits
at
Monitoring
100 #m
E.
Gain
Errors
APPENDIX
F.
Gain
and
APPENDIX
G.
Zodiacal
G.1
Overview
G.2
Data
G.3
Description
..................................................
D-14 D-15
.................................................. Offset Dust
Corrections Cloud
E-1
...............................
Modeling
Using
...............................................................
.................................................................... of Model
G.3.a
Density
G.3.b
Temperature
....................................................
...........................................................
G.3.c
Emissivity
G.3.d
Cloud
G.3.e
Constant
G.3.f
Model
...................................................... ........................................................
Orientation
................................................
Background Parameters
............................................. .................................................
Fitting Procedure ....................................................... G.4.a Model Results ....................................................
APPENDIX
D 9
.............................................................
APPENDIX
G.4
SURVEY
..........................................................
ACKNOWLEDGMENTS
D.5
SKY
H.
Zodiacal
History
File
IRAS
F
1
G
1
G
1
Data
G 3 G-3 G 6 G 6 G G-7 G 7 G-7 G-9
(ZOHF)
............................................................
H.1
Introduction
H.2
Production
H.3
Format
H.4
Processing
..............................................................
H-2
H.5
Calibration
..............................................................
H-3
Description
..................................................
..................................................................
V
7
H-1 H-1 t-I-2
H.6
Analysis Results H.6.a Gain and
........................................................ Offset ...................................................
H-3 H-3
H.6.b
Position
..........................................................
H-4
H.6.c
Calibration
H.7
Anomalies
H.8
Zodiacal
Verification
...........................................
............................................................... History
File
Version
3.1
........................................
vi
H-5 H-5 H-6
INDEX
II.
IRAS
SKY
SURVEY
A.1
Detectors
Used
B.1
Suggested
Correction
Between III.
ATLAS in IRAS
6' and
OF
TABLES
OVERVIEW
Sky
Factors
2 ° at 12 and
Survey
Atlas
for Spatial 25 pm
Images
........................
II 3
Frequencies
......................................
4
III
3
PROCESSING A.1
Hysteresis
A.2(a)
Equation
Time
....................................................
Constants,
12 pm
..............................................
III-4
A.2(b)
Time
Constants,
25 #m
..............................................
III
A.2(c)
Time
Constants,
60 pm
..............................................
III--5
A.2(d) Time Constants, 100 #m ............................................ A.3 TFPR Model Parameters ............................................... C.l(a)
Field-Groups
C.l(b)
for
Field-Groups
C.2
ISSA
C.3
Planet
and
12 and
25 ttm
for 60 and
ISSA
Reject
Positions
and
.....................................
100 pm
Fields
Corresponding
Comet
ISSA
and
III
Trails ISSA
.................
Reject
Amount
of Data
Removed
in Anomaly
Processing
(1_1 > 20°)
Amount
of Data
Removed
in Anomaly
Processing
of the
ISSA
IV.
Reject
and
Set
ISSA
ANALYSIS
(I/31 < 20 °)
Reject
Fields
....... .......
........................................
Affected
by Saturated
Data
15
III-19
Fields
D.l(b)
ISSA
6 9
III-14
....................................
Containing
4
III III
D.l(a)
D.2
V.
II
..............
III-21 III
22
III
22
III
27
RESULTS
B.1 B.2
Point Sources Used in the Position and Photometric Position Difference Statistics ............................................
C.1
Point
D.1
IRAS-DIRBE
E.1
In-Scan
E.2
Residual
Zodiacal
Emission
Discontinuities
E.3
Residual
Zodiacal
Emission
Gradients
F.1
Parallel
Error
Analysis,
Pixel
Size
= 0.5 °
F.2
Parallel
Error
Analysis,
Pixel
Size
= 2.0 °
F.3
Perpendicular
Error
Analysis,
Pixel
Size = 0.5 °
........................
IV
F.4
Perpendicular
Error
Analysis,
Pixel
Size = 2.0 °
........................
IV-25
Spread
FOR
THE
FITS
Header
1
A Sample
2 3
A Sample FITS FITS Keywords
Center
Dimensions
Transformation
vs. Cross-Scan
FORMATS
APPENDIX
Function
...........
......................................
in ISSA
SKY
for Intensity
16
398 .........................
IV
18
.............................
IV
19
IV
19
..............................
IV
22
..............................
IV-23
..................................
SURVEY Images
6
IV
Field
Header for Intensity Images ............................................................
IV-2 IV-3 IV
.........................................
Noise
IRAS
Analyses
ATLAS
24
(ISSA)
(4 byte
format)
................
V 2
(2 byte
format)
................
V 4 V-6
A Positions
for IRAS
Sky
Survey
Atlas vii
..................................
A-1
APPENDIX
B
B.1 Filter Kernels ........................................................... APPENDIX
B-2
C
C.1 Summary of Pre-Production Anomalies Removedfrom the ISSA Images .. C 1 APPENDIX
D
D.1 Detectors for which Global Destripe ParameterswereDerived ............ D.2 Relationship betweenNumber of DifferencePoints and Order of Fit, 12/tm .................................................... D.3 Relationship between Number of Difference Points and Order of Fit, 25 #m .................................................... D.4 RMS of Intensity Differencesas a Function of Iteration ................. APPENDIX
E-1 E-1 F-2 F-3
(3
G.1 Model Parameter Values and Uncertainties .............................. G.2 Correlation Coefl_icientsBetweenModel Parameters ..................... APPENDIX
D 12 D-15
F
F.1 Statistics of Correction Factors .......................................... F.2 Histogram of Gains ...................................................... APPENDIX
D 10
E
E.1 100 #m Gain Errors ..................................................... E.2 60 tim Gain Errors ...................................................... APPENDIX
D-2
G-9 G-13
H
H.1 Pixel Sizesfor ZOHF .................................................... H.2 Format of ZOHF Version 3.0 ............................................ H.3 Gain and Offset of eachVersion 3.0 Observation Comparedto each Version 2.0 Observation ................................................. H.4 Histograms of Comparison of ZOHF Positions with the Observation Parameter File .............................................
°°,
vln
H 1 H 2 H 3 H-4
INDEX
I.
II.
III.
FIGURES
INTRODUCTION B.1
Schematic
Drawing
of the
Orbital
B.2
Schematic
Drawing
of the
IRAS
IRAS
SKY
SURVEY
ATLAS
Geometry Focal
Plane
..............................
I 3
..............................
I-5
OVERVIEW
B.l(a)
Plots
of IRAS
detector
response
vs.
dwell
time,
12 and
25 itm
B.l(b)
Plots
of IRAS
detector
response
vs. dwell
time,
60 #m
................
B.l(c)
Plots
of IRAS
detector
response
vs.
time,
100 g.m
dwell
.........
II
5
II-6
...............
II
7
C.1
ISSA
Fields
for 1/31 > 50 ° in Equatorial
Coordinates
.....................
II
10
C.2
ISSA
Fields
for I/?1 > 20 ° in Equatorial
Coordinates
.....................
II
11
C.3
ISSA
Fields
for 1/31 < 20 ° in Equatorial
Coordinates
.....................
II
12
PROCESSING A.1
Point
C.l(a)
Source
Hysteresis
Field-Group Destriper
C.l(b)
Comparison
Boundaries
100 tm_ 25 #m
.........................
III
for 60 and
Processing
III
100/,nl
as Seen by IRAS Plane Anomalies
D.2
Distribution
of Mini-Streak
D.3
Distribution
of Local
D.4
Occurrence
of Saturated
and
Destripe Data
................................. .................................
Detector-Streak
Anomalies
Anomalies
for
for Entire
Sky
............
IL/I > 50 ° ................. ..........................
Histograms
of Position
Differences
in RA
Histograms
of Position
Differences
in DEC
C.l(a)
Contour
Plot
of Point
SI)read
Function
for a 12 /ml Source
C.l(b)
Contour
Plot
of Point
Spread
Fnnction
for a 25 ttm
Source
C.l(c)
Contour
Plot
of Point
Spread
Function
for a 60 t,m
Som'ce
...........
C.i(d)
Contour
Plot
of Point
Spread
Function
for a 100 ttm
Scatter
D.2
Flux
APPENDIX
III
17
III III
20 24
III
25
III
26
III
28
RESULTS
B.l(a) B.l(b)
D.1
16
Local
...............................................
Known Contet Trails Distribution of Focal
7
Local
...............................................
Boundaries
C.2 D.1
ANALYSIS
--
for 12 and
Processing
Field-Group Destriper
IV.
OF
Plots Density
of PSC
vs. ISSA
vs. Aperture
Point
Between
Source
Diameter
PSC
Between
Fluxes
and
PSC
ISSA
IV
4
IV
5
...........
IV
7
...........
IV
8
and
....
ISSA
Source
...
IV
.........
IV
..................
IV
...................................
9 10
12,13 IV
14
D
D.1
Distribution
D.2
Histogram
of boresight of boresight
intercepts crossing
for the counts
D.3 Proliferation D.4(a) Intensity
of detector intercepts residuals (HCON-1 and
D.4(b)
Intensity
residuals
D.5(a)
Intensity
differences
(HCON-3) along
per
focal
plane
fractional
100/an HCON-2)
crossings scan
..........
segnient
............................ at 12 ttm .................
12 mn ...............................
a single ix
detector-scan
track
with
.......
D 3 D 4 D 5 D 7
D 7 a
sixth D.5(b) Plot
D.7
Intensity
of points
class
along
differences
F
F.l(a)
Gain
and
destriper
a detector-scan
along
for detector
track
..........
D-13
42 (25 #m)
illustrating
...
a
track
illustrating
a D-19
a detector-scan
track
illustrating
a
....................................................... that
offset
have
close
corrections
extreme
versus
D-17 D-19
a detector-scan
along
anomaly
segments
APPENDIX
global
13
a
.......................................................
differences
Scan
by the
track with algorithm
.......................................................
IB anomaly III
D
along a single detector-scan dual-hemisphere-with-overlap
rejected
differences
Intensity class
D.10
.......................................................
IA anomaly
Intensity class
D.9
fit
Intensity differences fit derived with the
D.6
D.8
order
D-20
point
pairs
elongation
and
for
100 #m
SOP,
fits
12 #m
.....
D-21
.........
F-4
F.l(b)
Gain
and
offset
corrections
versus
elongation
and
SOP,
25 #m
.........
F 5
F.l(c)
Gain
and
offset
corrections
versus
elongation
and
SOP,
60 #m
.........
F-6
APPENDIX
G
(3.1
ZIP
data
(3.2
The
scanning
(3.3
The
IRAS
(3.4
A typical
IRAS zodiacal
(3.5 (3.6
showing
bandpasses
Data
and
solar
elongation
Data
and
solar
elongation
APPENDIX
zodiacal
geometry
brightness of the
and dust
zodiacal
dust of 67 °
satellite
scan
cloud
with
model
the
of solar
elongation
prediction
dust
cloud
for a scan
model
prediction
(3-2 (3-4
........................... zodiacal
(3 5 model
fit
(3-10
at
................................................ cloud
...
.............................
a 200 K blackbody
pole-to-pole of 112 °
as a function
IRAS
(3-11 for a scan
at
.................................................
(3-12
H
H.1
Flux
H.2
Mean
ratio
at NEP
flux ratios
vs. time
from
vs. time at NEP
SAA
crossing
from
and
SAA
population
crossing standard
...........................................
.........................
H-7,8
deviations H-9,10
I.
INTRODUCTION
A. General Overview The
Infrared
low Earth a ten
month
produce from
Astronomical
orbit
in four
period
within
the
radiometry
original
extended
brightness
(IRAS
was
The
and
were
data now
products. the
IRAS
available Each spaced
are
1991,
completely
191_
40 °.
some
coverage
many
The
tor
destriping
the
SkyF1ux
features for
IRAS
spatial
Sky
solar
ISSA
system.
IRAS
survey
Catalog
1988, ed.
ecliptic 13°-
images.
Atlas
to
detectors data.
The surface
between
1984
C. A. Beichman
This
(§III.C.3)
result
at short at
are cannot
of the
be used
increase
25 #m.
region)
to give
relative
for determining I-1
the
is the latitude.
limiting
noise
photometry the
in
down
to
-20
because
° of
contaminated
by
Set
for
data
is usable
for photometric Supplement
infrared
combination
foreground
noise
are
calibrated
The
20 ° ecliptic
bands
release,
latitudes
Explanatory
is enough
Detector
above
with
Atlas.
of a factor
This
sky
coverage
Reject
Atlas
5'.
zodiacal
wavelengths.
locations
designed
than
the
so named
these
of the
(IPAC)
reprocessing
first
ecliptic
fields
consistently
larger
in a sensitivity
at 12 and most
Survey
Center
declination
some
ISSA
using
formats
is to present scales
of most
IRAS
when
original
covers The
Set,
These The
accuracy
of 50 ° > I/_l > 20 ° with
between
ISSA.
Sky
and
with
Reject
bands.
IRAS
analysis
for ISSA
fields
be taken
ISSA.
the
of the
of the
10 ° along
latitudes
ISSA
of the dust
should
at spatial
removal
invisible
rest
ISSA
(I/ 1 > 50°)
the
Analysis
The
every
ecliptic
photometric
results
of the
from
sensitivity.
analysis
The
releases
remaining
zodiacal
and and
(ISSA).
emission
unprecedented
and
centered
covers
The
§IV.F).
IRAS
two
product,
care
(§III.A.2),
They
Processing
latitudes
to the
and
motivation
images
Infrared
in 1992,
production,
scales
of infrared and
improved
are
20 ° of the ecliptic plane (the ISSA Reject bands and residual zodiacal emission. The
in the
Survey
There
high
and
sky from
view
resolution
the
_pecial
the
images
a broad
angular
to produce
compared
but
previously
small
infrared
Source
Accordingly,
residuals
(§I.D.3
improvements
Point
was
unobtainable
of 16.5 ° square
Supplement,
production
to I_1 _
quality
scientific
gave
high
as a separate
in detail
entire
the
during
survey
IRAS
consisting
in sensitivity
release,
down
applications
of the
IRAS
Explanatory
is a 12.5 ° x 12.5 ° region
second
emission
describes
with and
gained
covers
measurements
the
of the
improvements
10 ° apart.
released
reduced
zodiacal
with
images
large
data
field
The
20 ° are
sources
of the
at a sensitivity
knowledge
as the
which
their
along
with
that
using
430 fields.
to
system
however,
reprocessed are
solar
obtainable
IRAS
stability
100 #m
D.C.:GPO)).
the
clear,
good
of 98% of the sky from
purpose
sources
as SkyFlux
Atlases:
16.5 ° x 16.5 ° SkyFlux
Galaxy It was
known
released and
The
The
point
astronomical
atlas,
a survey
of 12, 25, 60 and
1983.
of infrared
atmosphere.
Catalogs
conducted
wavelengths
to November,
catalog
of extended
et al. (Washington
(IRAS)
effective
January
emission
images,
1986
with
reliable
Earth's
allowed
and
from
an extremely
Satellite
bands
absolute
images
of calibration
(§III.C.2), greater
and than
to reveal
detec-
five over
Galactic
limiting
noise
dust of ISSA
At latitudes is due
within
to zodiacal
for objects sky surface
dust
outside brightness.
the
Section §II.B gives important details about the calibration of IRAS. IRAS
results
with
the
Background
Explorer
quantitative
photometric
The
remainder
Diffuse
Infrared
Background
(COBE)
satellite
should
measurements
of this
for the
and
correct
Introduction
use of the
improvements
made
Chapter
III gives
presents
results
the
formats
B.
The
a description from
of the
IRAS
details
to as the
and
survey
IRAS Earth's allowed
the
pointed
exactly
to point
plane
are
and
was
An
released
used the
images
aspects
overview
of the
of the
is presented
to produce
ISSA
90 ° from
the
angles
long Main
Sun.
from
Reject
the
for
IRAS
changes
in Chapter
II.
Chapter
IV
Atlas.
images.
scans
Chapter
V details
by
polar of the
survey
to complete
of 75% of the
called
sky
survey
IRAS
instrument
used the
the ability surveys
ten month
in which
way
a double
the
centered
would
if it had
have
remained
of the satellite of 98% of the
operating
period
(Main
Supple-
CONfirmation
scans
In this
over
of circles geometry
two confirming
for Hours
scans.
orbit
six months
strategy
of Sun-centered
altitude
portions
This
sky within
an HCON
1/4 ° between
IRAS
at 900 km
along
sky in exactly
IRAS
the
extensive descriptions of the Supplement 1988, hereafter
orbit
the whole The
instruments,
reference.
§III.B).
was accomplished by scans separated from one scan to be correlated with HCONs (HCON-1 the IRAS mission,
and
of the
Supplement,
of a series
moved
telescope
descriptions
for easy
tile Sun
survey
survey,
consisted was
here
to view
confirming
§III.A),
IRAS
a Sun-synchronous
and
telescope
confirming
of the
Short
included into
I.B.1
IRAS
array
atlas
processing
designs
to facilitate
(Figure
sky and a third of the satellite.
ment,
on those
is also presented.
ISSA
Supplement.
launched
at varying
Each
a refresher
data processing system, along with contained in the IRAS Explanatory
Main
terminator Sun
images SkyF1ux
of the
of the
design
was
on the
ISSA
images.
and the IRAS products, are
referred the
ISSA
using
Cosmic
to understand the ISSA images. It will define the in this document. A collection of cautionary notes
of the
analysis
before
on the
of
Survey
Complete sky survey IRAS data
the
(DIRBE)
be understood
provides
ISSA
since
comparison
(§IV.D.3).
telescope and the IRAS survey needed terms and introduce the concepts used vital
Experiment
The
the
1/2°-wide
coverage
focal
of the
sky
by up to 36 hours, allowing point source detections other scans to confirm the reality of detections. Two
and HCON-2) were performed with the second HCON lagging
concurrently behind the
in the first six months of first by a few weeks. Solar
elongation HCON-1
angles, e, of the telescope line of sight were roughly confined to 80°-100 ° during and HCON-2. The third survey, HCON-3, was begun after the completion of the
first
and
two
cover
tile
when
it was
used
whole
sky
full available in less
terminated
A significant from
the
interplanetary
than
range
of solar
six months.
by exhaustion
feature
of the
IRAS
dust
in the
solar
of the survey system,
I-2
The IRAS
elongation
(60°-120
°) in an attempt
third
HCON
was
liquid
helium
supply.
strategy presented
is that
zodiacal
a constantly
only
75%
emission, changing
to
complete
arising source
of
NORTH PO LE
EARTH-SUN
SUN
3.85 ARCMIN PER SECOND SCAN RATE
LINE
1 DAY
DETECTOR ARRAY
EQUATOR/
LATER
\ \ \ \
\
Figure
I.B.1
900 km,
and
inclination,
a precession plane
A schematic of the
constantly
By pointing shielded
from
scanning
motion
confirming
foreground the
emission
celestial
surface through
sphere
brightnesses the
zodiacal
heat across
scans
on the
through separated because dust
of the
the
satellite
the
of tile orbital
99 °, combined
plane
faced the
drawing
with
orbit
the
of about
Sun as the satellite radially
loads
away
from
sky
celestial
sphere
which
IttAS
Sun
the and
in about
observed.
equatorial day.
near
the
Earth
cold
while
altitude,
bulge,
As a result, the Earth's
Earth,
Two
the
moved
This
orbital
led to
the
orbit
terminator. telescope
providing
A sequence
was
natural of hours-
is also shown.
as a few days
Earth
The
six months.
by as little cloud.
Earth's
1 ° per orbited
from
the
tile entire
geometry.
in its orbit
variation I
observations
would
3
produced
measure and steep
of the same significantly
changed gradients
the
point
on
different line
of sight
in individual
HCON images where adjacent locations on the sky were scannedat different times. This prevented direct co-addition of separateHCONs. The variation in zodiacalforegroundwas most troublesome at 12 and 25 #m (15%to 30%dependingon the HCON) which fall near the peak wavelengthof the zodiacal emission. At the longer wavelengths,diffuse Galactic emission becomesnmch stronger than zodiacal emission, reducing the effects of zodiacal variation. The focal plane array of the IRAS survey instrument consistedof 62 detectors with either 15 or 16detectorsat eachof the four IRAS wavelengths(Figure I.B.2). The telescope wasoriented sothat, during survey scans,the imageof the skymovedacrossthe array in the long direction at 3.85' s-1, producing complete coverageof a 0.5°-wide swath of sky. The four staggeredrows of detectors in eachwavelengthband weredesignedto provide slightly more than 100%overlap of the detectorsduring a single scan. This provides slightly more than two samplesper detector in the cross-scandirection, which substantially undersamples the telescopepoint spread function at the shorter wavelengths. Sampling rates of 16, 16, 8 and 4 samplesper secondof the 12, 25, 60 and 100#m detectors, respectively,combined with the 3.85' s-1 scanrate and the detector widths of 0.75', 0.75', 1.5' and 3.0', givesabout a 50% oversamplingin the in-scan direction. All 62 detectorsdid not operate correctly in orbit. Two nearly adjacent dead 25 pm detectors and one dead 60 pm detector left holes in tile focal arrays C.
plane
(Figure
The
swath.
Sky
IRAS
Sky
Survey Survey
12.5 ° x 12.5 °, with zodiacal Fields
emission were
every
The
IRAS
requirements, to
an
in the
The data,
survey
array
in-scan
the data field and
first
detectors
step
resolution
affected
the
12 and
the
same
processing the
in the
25 #m
process
Separate examined
point
4.7'
of this
Section
with
higher
spatial
To reduce the
ISSA
time-ordered FWHM
at
processing
images
detector 12, 25,
60
independently
to rephase
centered
rest
was
data and
100
for each
the
data
streams
the
smoothed
to
streams #m,
detector to sample
sky.
emission stability
direction.
introduced
in order
line on the
a zodiacal zero
were
the
a sky.
images.
to produce
second, and
The
measurements
cross-scan
(minus
field on the
12.5 ° x 12.5 ° regions
ISSA
brightness
3.6'
delays
cross-scan
removed detector
into images. were visually
3.5',
430
images,
brightness
a specific
10 ° apart.
of the
reduction
per
sky surface within
into
spaced
in the
data
samples
B). Time
sky
sky
than
resampling
entire are
sky surface-brightness the
wavelength
processing
produced
of 3.5',
represents
IRAS
which
in the
at two
and
the
direction
(Appendix
refined
image
bands,
features
smoothing
simultaneously
Each
at a particular
salient
resample,
in-scan
respectively
blind
is a set of machine-readable
by partitioning
the
and
pixels.
declination
in the
smooth
1.5'
defined the
resolution
or partially
Atlas Atlas
model)
10 ° along
summarizes
noisy
I.B.2).
IRAS
The
Four
model
with
two
from
destriping
algorithms
and and
rephased binned
images of the individual HCONs were produced for each to allow identification and removal of artifacts (§III.D.3).
After removal of artifacts by editing the time-ordered for each HCON and all HCONs were then co-added.
I-4
data, new images Known asteroids
were produced remain in the
WAVELENGTH BANDS, ,um
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\
I
I
I
IMAGE
I_ [ Fv,s,B,._
DIRECTION
STAR SENSORS Figure
I.B.2
rectangles filter the
and
Y direction
individual ISSA
Auxiliary Due
statistical available The
noise upon
dust artifact
images
of sky coverage
were
removed
images
not
are
image
filled-in
but
included
some
These
features
include
planets,
unknown
process. objects, sources.
of a source detectors
from
the
noise
numbered
of a detector,
the focal
inoperative,
prior
utility
The
of view
during
data
released
plane.
crossed were
statistical
limited
in the
contain
nonconfirming
field
the
plane while
the
mission.
to producing were
in
the
co-added
also produced
(§III.C.4),
the
set of images.
for each
sky coverage
They
are,
and
however,
at IPAC.
images
nonconfirming
focal
the
performance
and
and
IRAS
represent
degraded
images
for instance),
removal
The
showed
constraints
HCONs.
bands,
The
as indicated.
request
of the
each
combination.
to volume
co-added
individual
drawing
portion
detectors
HCON
field.
central
field lens
cross-hatched
images.
A schematic
in the
The both
remaining
individual
to avoid
features
fine structure asteroids HCON
confusion
I-5
with
that
do not
in the zodiacal
confirm cloud
among (the
and
orbital
debris
that
images
enable
users
to identify
confirming
sources
and
the
zodiacal
escaped to study
the these the
D.
Cautionary
D.1
Absolute ISSA
Radiometry
was
emission, sky
Notes
over
surface
25 #m
designed
to provide
spatial
scales
brightness.
100 #m
bands
are
in the
(§II.B.4
affected
above
correction,
§II.B
scales (§IV.D.3). the IRAS-DIRBE
data,
the
accuracy
of the
of this
comparison.
D.2
Point
Source
Photometry
with
this
Survey See
is designed
to study for sources
(Moshir
§IV.C
Photometric
rest
The images of the ISSA
bands. ten
The
times
images
D.4
et al. 1992)
should
than
the
in the
to
or anomalies
the
residual
(§III.C.4). examined
offsets.
25 #m,
background useful
at the
in the
Catalog
in the at
frequency
spatial
scales
region.
If special
reject
data
2, and
and
the
images
errors
are smaller
longer
wavelengths.
Faint
with
been
Source sources.
ISSA.
Set
reject
compared to the the zodiacal dust
region
is taken
remain than
not
by
analyzed
on point
measured
in the care
has
IRAS
information
Reject
work. IRAS
not be impacted
are of reduced quality emission residuals and 25 #m
of this in the
are not optimally
sources
ISSA
at 12 and the
All
measurements.
will
survey
for survey
Images,
and
sources
Version
of point
ecliptic plane by zodiacal
errors
at
when
can
estimating
scientifically
at 12 and
be up to the
useful.
25 #m,
At 60
making
the
of Sources increased
are
visible
objects that appear satellites, asteroids image.
Latitude
12 and
G) and
detector
for quantitative
is not
5 _. Point
accuracy
nonreject
at 12 and
especially
Confirmation Due
background
than
be consulted
of expected in Low
calibration
Source
within 20 ° of the due to contamination
(§IV.F)
100 #m,
reject
Point
Errors
worse
of the
measurements
images
structures
smaller
IRAS
residual
background and
The
for discussion
D.3
at
Appendix
scientists to understand the calibration diffor measurements of sky brightness on large
source
extended
absolute
is dominated and
60% at 100 #m exists
ISSA
zodiacal
sources.
brightness
using
point
for accuracy product.
relative
with COBE DIRBE data
IRAS
results
ISSA
the
point
IPAC newsletters will contain any updated results comparison indicates an uncalibrated nonlinearity
the
optimized
at 60 #m and
before
There is an ongoing effort ferences between the IRAS and
error
of the
for determining
(§III.C.2
knowledge
of these
removal
be used
zero
model
by imperfect
as 30%
after
cannot
absolute
by both
affects
Read
5 t. ISSA emission
III.A.2)
which
photometry,
of the
extent
of as much
a few degrees.
spatial Unless
than
zodiacal
and
to some
An uncertainty response
larger
Uncertainty
by uncertainties
60 and
differential
No confirmation
sensitivity than
in the
of the
ISSA
SkyFlux
images,
images.
more
nonconfirming
Nonconfirming
objects
in only one HCON intensity image. These objects or space debris. If not removed, they can appear co-adder
was
implemented
in producing
the
are
those
may be orbiting in the co-added
co-added
Therefore, for each ISSA field, all individual HCON intensity visually to identify objects appearing in only one HCON image. I-6
objects
ISSA
image
images were When found,
the contaminated portion of the offending scanwasidentified and removed.Lessthan 1%of the entire survey databasewas removedby this visual inspection process(§III.D.3). Even though great care was taken to remove anomalies, some remain in the co-addedimage. Individual HCON imagesshould be examined to verify the reality of unusual features in the co-addedimage. D.5
Solar
System
Emission
from
includes
some
This Some
asteroids
publication
some
remain
Both
comet
tails
by either
radiation
pressure,
418).
Comet
along
the
images
orbit
visible
Residual
tion
due
that
are
Point
expected source
At 60 and Galactic
change
depending
plane.
photon-induced
Compared
scan
responsivity
Improved
image
The
Change solid angle
functions §II.D.2). products, to Main
trails
and
The
tails, blown
tail
pole
of comet
(fields
416
pressure,
of time.
is found
will
comet
particles
and
spread
In the
perpendicular
sky,
sources
enhancement,
Some
ISSA
to the
in §III.C.4.
scan
Planets
§III.C.4.
remain
of the
data. due
around
photon-induced See Main
than
at less than
the
images
in the
ISSA
or hysteresis
brighter
sources from
effects
direction.
period
nearly
latitude
point
co-added
effect
sun.
1986
plane at ecliptic ISSA Reject Set. with
ecliptic
a long
comet
Sources
removed
hysteresis
HCONS
to radiation
image
lower
around
tails. not
in the
on the
Calibration
response 2 1992,
source
100 #m,
as the
were
north
planets.
removed.
or neutral
to the
and
as of the
were
associated
wind
confusion.
Effects
background.
to have
tails
over
the
responsivity and
the
the
by known
appear
asteroids
1986)
Dust
insensitive
crossing
Responsivity tails
near
debris
cover
trails
in different
is closest
accumulate
affected
fields
strength
from a single point several directions.
nal
fields
in ISSA
to a photon-induced
at 25 #m
D.7
and
can cause
comet
known
(Matson
by solar
comet
images
as streaks
resembling
of source
tails.
comet
appear
only
data.
blown
the
tails,
aspects
in the
of larger
Photon-Induced
Artifacts are
of the
since
and
bands parallel to the ecliptic by the dust bands are in the
particles
in some
comet
in different
seen
in the data
Survey
emission affected
are
composed
trails
Comet
seen
when
is visible
A list of ISSA
also
trails ionized
bands,
images
and
are
appear
trails,
comet
direction.
and
charged
IRAS-Araki-Alcock
D.6
bands
remains
dust
co-added
Asteroid
dust
material
zodiacal
as nonconfirming extended less than 15 °. The images
caused
are
system
in the
IRAS
zodiacal
appear latitudes
solar
asteroids,
of the
The
by
Debris
effect,
The
that
these than
to point
sources
bright
and
thresholds one
areas
tail being
around
§IV.A.8
20 Jy
may may
have
radiate
scanned
(within
brightness
tails
is a func-
15 Jy at 12 pm
More
Supplement
images.
in
_ 6 °) such sources
will
for explanation
of
enhancement. Due
to Improvements
estimates
in the Accuracy
were derived
for each
detector
of Detector based
Solid
Angle_
on two-dimensional
(see Explanatory Supplement to the IRAS Faint Source Survey Version The improved solid angles differ from those used in making the origie.g.,
SkyFlux
Supplement
and Table
IRAS IV.A.1 I-7
Zodiacal the
average
History of new
File
(ZOHF)
effective
Version solid
angles
2.0. for
full
size
detectors
decreased
values.
100 #m
D.8
Several the
vs.
with
Earth
is about
2%
north
ecliptic
pole
at
asymmetry
angles
ZOHF
2.0 and
Version
(scans
has
100 #m,
an inverse
Version
slightly
while
ascending 60 #m, the
is a real feature
and
respectively,
effect
and
on calculated
3.1 will be fainter
brighter
at
12, 25
at 60 #m.
3.0 (§I.F
and
with
decreasing
progress
plane
In the
12 and
between
2.0
which
than
IRAS
the
ascending
orbit,
scans 1.5%
look
25 #m,
and
Appendix
4%
descending
scans.
sky cannot
be ruled
1/31 > 50° can be mosaicked
without
are
progress
look
behind
magnitude
100 #m
of the
as seen
Analysis
part of the ascending-descending drifts. However, the possibility
of the
which
always
The at
found
latitude)
(scans
scans
ahead.
and
H) have
ecliptic
scans
descending
always at
ascending
in Appendix H shows that a large attributed to uncorrected calibration of the
at 12, 25 and
Scans
latitude).
in its orbit
effect
in the
Version
at the ecliptic
ecliptic
6%
in the solid
values
ZOHF
scans
brighter
increasing
the
of the
descending
systematically
the
to ZOHF Descending
users
8% and
A change
Therefore,
compared
Ascending
that
by 13%,
by 3% at 60 #m.
intensity and
increased
at
the
as described
asymmetry can be that some small part
out (Dermott
1994,
submitted
to Nature). E.
Processing
E.1
Caveats
Mosaicking All images
to
an
accuracy
destriping
the
where
accuracy of 1-2
Saturated An error
well as the
entire
images occurs
it is not
latitude
MJy
sky,
(§III.C.3.b).
as those
was found
the
effect
This
capability
brought
all
is due
confirming
offset
to the
adjustments
use
coverages
of a global
of the
sky
to a
1/31 < 50°,
Fields
in the
in the
I/3t > 50°
1/31 < 50 ° sky join.
sr -1 at 60 #m
and
were
latitude
sky except
At these 3-5
processed
lower
MJy
near
differently sky can
from
the
the
be mosaicked
Galactic
two locations,
ISSA
plane
and
field boundary
sr -1 at 100 #m are
measurable.
Data
eliminated in the
sr -1. which
lower sky
I/3t > 50 ° sky and
discrepancies E.2
the
1/31 > 50°
same
the
MJy
additional
level.
covering
in the
0.1
(§III.C.3.a),
background
Fields with
of about
algorithm
Common
fields
covering
wrong
set of ISSA
while mainly
considered
in the algorithm
detector some in the
when images.
for handling
saturation
As a result,
nonsaturated Galactic
a significant
intensity plane
where
problem
since
values
intensity affects
values.
the SkyF1ux
intensity
were
60 and
it affects
8
and
saturated the
(§III.D.4.b).
I
saturated
occurred
values
erroneously 0.1%
error
images
were
as
included
eliminated.
100 #m detectors less than
The
saturate, of detector
This but data
E.3
Destriper
Anomalies
An error
was found
algorithms 50 ° sky.
This
removed
in the
13).
Low
magnitude
of the
Frequency
zodiacal model.
part
25 #m
around
discontinuity. marks
The
the the
60 ° point.
Thus
part
of the
this
longitude effect
year.
change
The
at
destriper
destriper
0.5 MJy The
were
remain
is about 0.5 °.
1/3[ >
problems
anomalies
location than
destriper
in the
at 4h31m46.5s:-63d40m15s
in the (ISSA
sr -1
software
An
example This
at
12 and
was
part
of the The
sky was peak
° ecliptic
by looking
fixed
for
is roughly
viewed
and
of the
where
later
discrepancy
dust
band
sr -1 at 12 #m,
local intensity prior to zodiacal emission removal. For 12 #m is roughly 5% of local intensity prior to zodiacal
overlap
240 ° point leg
through
in the
to the
a different
intensity
along
is enhanced
at
by a
a different
which
a
Six months
ascending
change
the
the
survey.
the
ISSA
at 12 and
mission
leg and
in
through
occurs
HCON-2 and
in the
observed
to as the
six months
a zodiacal
2.0 MJy
were
descending
240 ° point
latitude,
to imperfections
of a discontinuity
magnitude
through
sky
is referred
HCON-1
to the
due
or gradients
of the
of the
leg of the
images
discontinuities
the beginning
cloud.
ISSA
regions
longitude.
progressed
in intensity
in the
sharp
cloud.
marks
-15
caused
remain
ascending
same dust
occurs
geometric
dust
leg had
the
scans
is visible less
adjacent
240 ° ecliptic
of the
zodiacal
short,
Although
some
at this
as either
where
60 ° point
descending
effect
is seen
zodiacal
beginning
anomaly
effects
occur
60 ° and
data.
for one of the
for some
Artifacts
This
of the
the parameters corrections
(§III.D),
is very
emission
Discontinuities
derived in poor
1% of the
process
anomaly
Spatial
different
later
the
I/3[ < 50 ° sky.
zodiacal
images.
than
destriper
the
Residual the
less
that
resulting
checking
A typical
Typically
processing E.4
affects
quality
The
25 #m.
for ISSA,
error
[/_[ > 50 ° images. field
in the software
implemented
is about
time
of
7% of the
1/31 > 50 °, the worst discrepancy at emission removal and about 2% at
25 #m. In addition
to discontinuities,
Galaxy
remain
and
zodiacal
F.
the The
IRAS
The produce and
all
ZOHF
Version error
found
History
and
and
The
in each ISSA
band
3.1 of the in Version
images
IRAS
ISSA
artifacts
not attributable
between
the
zodiacal
to the emission
(§IV.E.3).
time-ordered
data Version
is a time-ordered
of the
survey
is that
standard
ZOHF
3.0.
problem
the
For
ZOHF
additional
was
I-9
have
been
important
retains
the
intensities
1990
were
used
in December
of the
An
in May the
in §I.C
released
information
released
affected
described 3.0, record
array
a 0.5 ° x 0.5 ° beam.
survey.
The
scale
to differences
File (ZOHF)
ZOHF
to produce the
due the
rephased
versions.
the
are
angular
File
History
intervals
large
in producing
Zodiacal
detectors
as observed during Appendix H.
These
used
resampled
IRAS
all subsequent
eight-second
images.
model Zodiacal
same the
in which the
in the
other
entire added
IRAS
zodiacal on
and
the
dust ZOHF
corrected
of a very
survey
together
difference
small
to
1988, over
between emission refer
to
a single number
of ZOHF samples in Version 3.0: none at 12 #m, one at 25 _m, one at 60 #m and 382 (0.03%) at 100#m. The affected sampleswere lowered 23% on the average,with a maximum decreaseof 45%. The description and analysespresentedin the IRAS circular accompanyingVersion 3.0 and in Appendix H of this Supplementare not changedby this correction. The ZOHF is also available with the zodiacal emissionremoved. This product was made by subtracting the zodiacal emissionas predicted by the J. Good model (Appendix G). The Zodiacal Emission RemovedZOHF is available from IPAC by special request. In responseto requestsby IPAC General Investigators, two additional versionsof the ZOHF wereproduced and releasedby IPAC. A version of the ZOHF was generatedgiving eachpixel the maximum in-scanresolution of 2_while maintaining the 0.5° resolution crossscan. This product is known as the 2t In-scan ZOHF and was produced for the purpose of studying the zodiacal dust bands near the ecliptic plane. The Bright Point Source Removed (BPSR) ZOHF was produced in responseto a user request and was generated by removing flux contribution due to bright point sourcesand associatedtails. Point sourceswere identified using the IRAS Point SourceCatalog. Detector samples within a 10' radius of the known source and along the sourcetail were removed from the scan data prior to computing an eight-secondintensity average. Under certain conditions this algorithm produced a nonphysical increasein a 0.5° x 0.5° pixel brightness compared to the brightness in the ZOHF Version 3.0. This can occur in areaswhere sourcesare fainter than surrounding structure. Due to this discrepancy,IPAC recommends that special care be taken
when
All released Coordinated
using
the BPSR
ZOHF
products
Request
and
ZOHF. as well as the User
Support
ISSA
Office
NASA/GSFC Code 633.4 Greenbelt,
MD
20771.
I-
10
are
available
(CRUSO)
through:
II. A.
Changes The
that the
and
limited
the
electronic
60 #m
bands,
The intrinsic The
images.
making
interpretation
detector
removal
HCON resolution
of the
and
largely
zodiacal
faint
without reduced
emission
increased reduced
factors similar
of 2-3 at 12 and 25 #m and 1.5 2.0 for 60 and noise in the in-scan and cross-scan directions. of v_
faint
improvement
structure
quality A.1
over
at 12, 25 and
of the
ISSA
images
in Relative
When
at uniform
measurements
due
calibration,
these
perfections
a factor
images.
No
pendix
G was
of the
individual
removed
or better
artifacts
due
effects
of the
is not
perfect,
moved
the
compared
0.5 MJy
foreground
sr -l
and
images
zodiacal
of the
foreground.
over
the
SkyFlux noise
by
in images with an additional
co-added
images
reveal
Details
of the
images.
of the
reduced the IRAS
appear
different
With
perfect
uniform.
in the
images.
Any
used
source
im-
Calibration
detector-to-detector calibration
model
detector
subtraction
data,
of the
stripes in the
by
SkyFlux
calibration.
described
was
removal
survey.
data.
Since
the
zodiacal
errors
1.0 MJy 1
data, IRAS
in some
places
and
for ]/31 > 50 ° are sr -1
at 25 ttm
over
and
Ap-
co-addition
resulted
the
removed
II-
useflfl
model
during
in the
foreground
in §III.C.2
permitting
zodiacal
non-zodiacal-removed
foreground
and
sky
point
emission
to the
12 #m
will give
Coaddition
zodiacal
remain
the
to the
a band
responsivities.
striping
relative
foreground at
within
baselines
affected
The
in zodiacal
Residual
level
IV.
detectors
time-ordered
images.
insufficient
to the
the sensitivity
The
to Permit
reduction,
in others.
background,
have
to changes zodiacal
images 12, 25 and
the detector-to-detector
SkyFlux
and
25 #m
by the
from
the
in the
in §III.A.2,
Removal
HCON
from
images.
equal-sized
removed
12 and
predicted
stripes
HCON
in detector-to-detector
changes
Foregro'and
A foreground
fold
are
at
co-
interpolation.
invisible
in detector
described
of ten
calibration
Zodiacal
sky,
result
for ISSA,
roughly
A.2
variations
SkyF1ux for the
100 #m. This results Coaddition provides
in Chapter
artificial
prevented
Calibration
to variations
in calibration
enhancements
totally
will be found
Improvements looking
individual
60 #m
and spatial
steep,
data
residual
destripers
by roughly
regions
and
and
of the
detector
interference
images
factor
The
2' pixels
the
bright
images;
features
further
include §IV.A.8),
responsivity
producing
sky
the
difficult
problems
around
SkyF1ux
foreground
problems
Supplement
in detector
in the
Finally,
several
These
(Main accuracy
time-ordered
eliminated
of five.
to correct
images.
variations
of the
foreground
a factor
#m;
obscured
of all improvements noise
SkyFlux
zodiacal
which
designed
striping
observed
images,
the
was
photometric
100
prominent
of the
OVERVIEW
enhancement
degraded
produced
individual
images of the
60 and
sampled
combination
ISSA
responsivity at
SkyFlux
ATLAS
Atlas
usability
which
variations
of the
the
and
plane
that
in the
critically
in
photon-induced
Galactic
temporal
addition just
sensitivity
offsets
gradients
SURVEY
created
as hysteresis,
as the
and
that
of the
known
such
SKY
Improvements
processing
effects
also
IRAS
in a five-
in gradients However, emission too
much
3 5% of the scales
and some model was
re-
original
of 10 ° . For
50° > 1/31 > 20*, the residualsare 1.0 MJy sr-1 at 12/am and 2.0-2.5 MJy sr-lat 25 #m over scalesof 10°. The zodiacal emission model assumeda physical dust distribution which did not inelude the dust bands. The dust band emissionremains in the data and produces artifacts in the images at low ecliptic latitudes, the ISSA Reject Set. A.3
Destripers Stripe
noise
uncalibrated globally
to Stabilize due
1988).
average
of all other
At each
varying
destriping
of a particular to the only
a 10%
A.4
on
1.5'
scan
of every
best
detector.
to make
further The
left
for the
used
after
(Emerson
each
The
and
detector
to the
by applying
a
assumption
of global
foreground
removal,
brightness
at that
comparison
adjustments.
destriper global
sky
and
destriper
zodiacal
a similar
baseline
local
the
first
was accomplished
after
estimate
on
foreground The
to match
This
measurements,
destriper,
RMS
points
attempted
wavelength.
zodiacal
destripers.
was
This
able
destriping.
point.
of each
The
detector
destriper
used
to accomplish
The
two
about
destripers
are
Signal
noise
noise
from
Known
Asteroid
Known
asteroids
removed
from
contributor
in the
the
images need
improves
to further
reconstruction
ISSA
on board due
ISSA
images
Information
the
sampling
smooth
the
interval
by 25% over
time-ordered
data.
for the
IRAS
survey
contribute
slightly
(§III.A.1).
listed
HCON
IRAS
satellite
to high-energy
spikes
Removal
data
the
images
attempted
protons
remained
in the
and
to remove
electrons.
SkyFlux
from
However,
images.
the
IRAS
many
small
A deglitcher
removed
(§III.A.3). from
in the
prior
of nonconfirming
individual
the
of Spatial
Removal
of large
the
ISSA
pointing
spikes
vestiges
Representation
obviates
Radiation
data
in the
in the
processing
and
the
Information
resolution
Particle
detector
and
Pointing
to improved
in the
destriper
12.5 ° field.
spacing
images
Improved
A.7
local
to Improve
Improvements
this
global
sky is the
as the
two
at 1.2 million
to every
in cross-scan
pixel
SkyFlux
spikes
the
residual
with
in §III.C.3.
The
A.6
data
of all IRAS
of all detectors
reduction
reduced
in the same
in a single
Oversampling
A.5
the
fluctuations,
was
correction
known
data
described
the
point
average the
point,
the average
destriper,
baseline
survey
detectors
baseline
is that
Baselines
variations
all of the
Griives
second
to residual
responsivity compared
slowly
Detector
the IRAS
to making sources
Coadded Asteroid the
Images and
co-added
(§III.C.4)
images.
II -2
in the
Comet images. co-added
Survey This images.
(Matson
1986)
eliminated Asteroids
were
a major remain
A.8
Full-Sized When
Detectors
flux measurements
by undersized
detectors
sociated
combining
with
are converted
appear
too
different
to surface
bright.
Thus,
detector
sizes,
(Table II.A.1) were used in making as well as full-sized detectors.
the
ISSA
Table Detectors
Wavelength
B.
the
operative,
The
SkyFlux
in IRAS
Sky
Survey
Atlas
Detectors 29
30
48
49
50
51
52
25
16
18
19
21
22
40
41
42
43
44
45
60
08
09
10
13
14
15
32
33
34
35
37
100
01
02
03
04
05
06
07
56
57
58
59
was
set
Source
Calibration
brightness source
process
scale
of the
IRAS
of the
detectors
12 #m
calibration
presented
to the IRAS
IRAS
by Rieke
were
used
source
survey
in a three-step
detectors
et al. (1984)
Frequency
As mentioned
response
across to the
point
long
flashes,
exposure term
source
(DC)
calibration
source
calibration
was
maintenance VI of the Main
of the
model
were
detectors
made
and
for
to the
ground-
of c_ Tau.
This
No
changes
have
been
ISSA. standard,
of the
point
NGC6543, source
Supplement.
between are
tied
First,
The extrapolation from of asteroids. Details of
Supplement.
to a secondary
in Chapter
internal
calibration.
A model
internal
detailed
and
Details
was used
stimulators.
to track
A number
of
in §III.A.2.
Response the
which
a detector
in Chapter
Longer and
61
process.
via measurements
Main
for short-term
above,
stimulators,
VI of the
transferred
responsivity to this
as discussed
point
then
are found
improvements
scanning
in Chapter
absolute was
of this process
internal
60
Method
calibration
absolute
are
Spatial
53
of Calibration
stimulators
B.2
_-sized
Images
28
point
as-
detectors
used
25
Calibration
the
images
24
10 #m
made
problems
II.A.1
calibration was extrapolated to 25 and 60 #m using stellar models. 60 to 100 #m was based on observations and model calculations this
measured
full-sized
23
point
based
photometric
the
images.
sources
12
Point The
point
to eliminate only
(#m)
Overview
B.1
Used
brightness,
IRAS
flashed
at the
survey
VI of the thus
Main
accurately
to point
sources
responsivity was
detector
were
needed
responsivities
for
a duration
rate.
These
Supplement. calibrating revealed
of the
II - 3
flashes
to the
a difference
by
point
that
photometry.
the
of a point
calibrated
were
between
suggesting source
monitored to that
were
All data data
detectors,
for extended
were similar
scaled
to the
frequency.
short
term
a correction This
of
to NGC6543 relative
source the
use
source
correction
(AC) to
the was
obtained by measuring detector responseas a function of dwell time during the IRAS mission in an attempt to define the frequency responseof the IRAS detectors. Point sources were scanned across the detectors at 2, 1 4, 1 s1 and _ of the survey scan rate. Measurementswere extended to longer periods, with flashesof the internal stimulators lasting tens of secondsfor 12 and 25 #m and by extended stares at point sourcesfor 60 and 100 #m. Some of these measurementsare shown in Figures II.B.l(a)-(c), which is reproducedfrom Figure IV.A.4 of the Main Supplement. The temporal response shown in Figures II.B.l(a)-(c) is translated scan rate of 3.85 _ s -1 . No attempt data.
was
Instead,
in order 25 #m
the
to best and
60 and of these
factors
Suggested
surface
100 #m).
brightness
should spatial
corrections
can
to the be
for 12 and
total
25 #m
Correction Between
sistent
measurement
was
suggest a nonlinearity on brightness. The long
wavelengths
sources
at 60 #m
and
12 and
0.92
The 25 #m
in Table
ISSA
in each 2 ° at
and
1.00 DC
band 12 and
at 12, 25, calibrated.
sources),
the
correction from
survey
for the
(>
therefore
(point
inverse
factors
Figure
for
II.B.l(a).
II.B.1.
II.B.1 for
2 ° at
Spatial
12 and
Frequencies
25
pm
(deg)
12/_m
25 #m
0.1
1.15
1.10
0.2
1.18
1.13
0.5
1.25
1.18
1.0
1.28
1.20
1.5
1.28
1.23
2.0
1.28
1.23
Scale
factors
photometry
response
of the
obtained
for
the
detectors
60
in photometric 100 #m,
to recover
from
which makes the uncertainty in the
results
are
Factors*
scale frequency
0.82,
scales
IRAS
factor
scales
measured.
for
Factors
* Multiplication
the
0.78,
Multiplication Spatial
While
flux
are found
6 r and
spatial
products spatial
determined
Table Suggested
were
ZOHF
the
correction
by a single
at large
factors the
using
response
multiplied
on the smallest
be applied scales
was
and
response
frequency
brightness The
ISSA
frequency
a true
calibration
the
respectively. correct
a spatial
to perform
source
> 5 ° at 60 and the
intermediate
point represent
100 #m,
To recover
made
into
and
100
small-
ISSA at #m.
data.
12 and
25 #m
Figures
was
II.B.l(b)
clear, and
no
con-
II.B.l(c)
frequency response at 60 and 100 #m dependent overall linearity of the photometric scale at the uncertainties
respectively. II - 4
of about
30_
and
60_
for extended
SPATIALSCALE(degrees) 0.5
0.10.2 I
I
1.0
I
1.5
I
1.3
ASSUMED
I
DC/SURVEY
RATE
RESPONSE
rl A ¢_z
1.2
n
1.1
tu ev
1.0
,
I 10
0
i
DWELL •
1/2 SURVEY
13 STARING
RATE
J 20
TIME
CALIB
OBSERVATION
3O
(seconds)
OBS
aLYR
aLYR
DET
DET
29
29
•
1, 1/2, 1/4, 1/8, 1/16 SURVEY RATE CALIB MEAN OF ALL SOURCES DET 53 aLYR
OBS
&
REFERENCE
FLASH-MEAN
SOURCE
OF COLOR
BAND
LONG
DURATION
NORMALIZED
AT 3.2 sec
SPATIALSCALE(degrees) 0.10.2 1.3
I
0.5
1.0
I
I
ASSUMED z
1.5
]
1.2
I
DC/SURVEY
RATE
RESPONSE
& A
z_
2'"
1.1 -0
25 _m ,
1.¢
I 10
0
J
DWELL •
&
1, 1/2, 1/4, 1/8, 1/16
SURVEY
FLORA,
45
aLYR
REFERENCE OF COLOR
Figure
II.B.l(a)
dependence ments
were
by viewing translated scan
of the
rate
made
DET
SOURCE BAND
Measurements detectors either
by
of the
CALIB
DURATION
OBS
FLASH-MEAN
AT 3.2 sec
response
panel)
a source
long flashes of the internal the dwell time of the lower of 3.85'
LONG
3O
(seconds)
RATE
NORMALIZED
at 12 (top crossing
TIME
I 20
and
vs. dwell
time
25 (bottom
at scan
rates
to measure
panel) less
than
#m. the
frequency
The
measure-
survey
rates
or
reference source. The upper horizontal scale has scale to spatial frequency using the IRAS survey
s -1 . II
5
SPATIAL SCALE (degrees) 0.51.0 II
_
2.0
5.0
I
I
8.0
1.4 ASSUMED 1.0 rl
DC/SURVEY
RATE RESPONSE
o
o
o
ALPHA LYRAE
O
0.8
J 2O
0
I 40
I 60
I 80
I 100
120
DWELL TIME (seconds) SPATIAL SCALE (degrees) 0.5 1.0 I
w
1.4
0
1.2
2.0
5,0
I
I
I
&
f,oLU
8.0
o
[]
,.°
n"
NGC 6543
0.8
I 20
0
I 40
I 60
I 80
,I , 100
120
DWELL TIME (seconds) SPATIAL SCALE (degrees) 2.0 5.0
0.5 1.0 I
_uJ _co rr z _O
I
I
1.4 [] 1.2
_0tll Za:
1.1>
er
0,8
8.0
I
[]
I
[]
[]
IRC + 10216 I 20
0
I 40
I 60
I 80
I 100
120
DWELL TIME (seconds) 60 gm O SURVEY RATE OBS DET 14 •
1, 1/2, 1/4, 1/8, 1/16 SURVEY RATE DET37
•
1/2 SURVEY
RATE CALIB OBS DET 37
•
1/8 SURVEY
RATE DEE 14
[]
STARING OBS DET 14
A STARING OBS DET 37 o
Figure
II.B.l(b)
dependence
at scan
reference
source.
scale
Measurements
of the
a source
to spatial
1/2 SURVEY RATE OBS DET 14
detectors
rates
at 60 #m.
less than
The frequency
of the
upper using
the the
The
survey
horizontal IRAS
response
vs. dwell
measurements rates
scale
were
or by viewing has
survey II - 6
translated scan
rate
time
to measure
made
long the
of 3.85'
either
flashes
dwell s -1.
time
frequency by
crossing
of the
internal
of the
lower
SPATIAL 1.0 1.4
_0 z o3o.
SCALE
3.0
I
(degrees)
5.0
t
8.0
1
I
1.2
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II.B.l(c)
dependence a source reference scale
to spatial
1 SURVEY
•
1/2 SURVEY
RATE RATE
OBS
DET
6
•
1/8 SURVEY
RATE
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n
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Measurements
of the at scan source.
•
detectors
OBS
DET
DET
6
6
of the
at 100 #m.
response
The
vs. dwell
measurements
time were
to measure made
either
frequency by crossing
rates less than the survey rates or by viewing long flashes of the internal The upper horizontal scale has translated the dwell time of the lower frequency
using
the
IRAS
survey II - 7
scan
rate
of 3.85 _ s -1.
B.3
Detector
Effective
After
data
tronics the
were
as discussed
average
solid are
the
surface
angle
values
discussed
Zero The
of sky
the
brightness
over
zero
free
point
from
the
each
difference
of the
The
the value
observed
position
of the
of the
source 0.2%
assumed B.5
was
this
The
in 1986
and
Survey.
The
not
intended
to provide
are found
in §III.A.2.
As discussed
in §II.B.2,
in the 100/tm
Suggested
for the
electrical
offset
used
IRAS
secondary
CS-15.
The
total
signal
TFPR
(§III.A.2.b)
and
signal
was
for correction
zero
slightly
point
ascribed
of the
is dependent
position
of/3
throughout
NGC6543
at/3
in the
in flux among 100 #m,
Extended was
of the
ISSA
to an area
(the
to the
zero
point
in
on the
accuracy
= 89.2 ° and
_ = 94.6 °
the
mission.
However, the actual
The
observed
/3 = 89.2 °, A = 95.0 °
= 89.8 °, A = 150.3 °. NGC6543 transfer
standard
derived the
offsets,
TFPR
respectively,
(Main it is not
locations of the
considered
is roughly
absolute
was
Supplement a
0.03%,
zero
point
as
§III.A.2.b.
calibration
variation
predicted
discrepancies
for
are
in §II.B.2.
The
Source
NGC6543
observation model
as a secondary
variation
Limitations point
past
model,
annual
Features
to yield
release
by reference
and
/3 = 88.8 °, A = 268.9 ° and
at 12, 25, 60 and
TFPR
maintained pole
on a TFPR
varied
between
caused
the
5 ° at 60 and
Faint
used
§IV.A.3).
latitude and ecliptic longitude, respectively. CS-15 calibration observations were executed,
calibration
and
cies.
SkyFlux
to the
calibration
of the
based
direction
1.9%
Calibration
model
was
elec-
(§III.A.2.b).
TFPR
source
of error. and
zero
detector
their
by linear interpolation between offsets obtained during This process is described in more detail in §VI.B.3 of
derived
varied
scan
point
by the
The
and
which was accessible throughout the entire Flux Photometric Reference or TFPR. The
brightness
and
accuracy
as the
Although
0.5%,
detectors
Supplement
the
ecliptic
electronic
prediction
TFPR
on the
major
special
measured
The
model
position
§VI.B).
since
was set and north
to the
was obtained of the TFPR.
brightness
in the
(Main
Supplement
the
the
where /3 and _ represent ecliptic due to the method by which the
used
of each
of view
improved
calibration near
using
The
TFPR
depending
angle
of the
in §III.A.2.c.
compared
between
Supplement.
TFPR
IRAS
daily was
offset.
Main
have
Explanatory
sources
survey observations these measurements the
solid
field
Main Supplement §VI.B), area was called the Total
detector
electronic
ISSA
the
is given
of the
point
was observed
from
effective
response
Calibration
calibration standard IRAS mission. This TFPR
for
of the
difference
Point
for frequency
in §II.B.2, used
of the
Angles
corrected
in §II.D.2
magnitude B.4
Solid
Sources
severely
TFPR.
limited
This
is not
accurate
absolute
the
scan
with
appear correction
too
IRAS spatial faint. factors
The
were
less than correction
for intermediate
II-
knowledge problem
photometry.
data
scales
by our a major
8
not
of the since
the
Uncertainties
corrected
spatial
25 #m
flux
ISSA
images
for the
TFPR
for all spatial
2 ° at 12 and factors
absolute
and
for point
sources
scales
are found
frequenless than are
given
in Table
II.B.1. Large uncertainties, 30% and 60% at 60 and 100 #m, respectively, exist in the factors for spatial scalecorrections. This uncertainty in the frequencyresponseof IRAS at long wavelengthsis the major sourceof uncertainties in the absolute calibration of ISSA. The user is directed to a careful reading of §II.B.2 and examination of Figures II.B.l(b) and (c) before attempting to perform photometric corrections for spatial scalesat 60 and I00 #m. C.
Product
Description
ISSA, Flexible
combined Image
along
varies
in Figures
SkyFlux fields. field centers. For image
for
image and
of all
The
small
FITS
that
any
number The
and
upon
noise
size of each
ISSA
range The
(12,
standard
range
deviation down
down
16 bits
The
through: Request
to that
requires
image
Reject
MD
the
there
images
fields
spacing
equatorial
with
HCON-3)
deviation
Set
and
User
mean
threshold per
pole
from
the
corresponding
is an plus
were
about
Support
20771.
II - 9
The
intensity
a co-added
also
number
comparing of each noise
produced
is used.
of bits
per
it to 5% of median
pixel. level,
If 16 bits
then
the
is too
number
In FITS-formatted
of
images,
sample.
0.5 or 1.0 Mbytes,
set of ISSA
comprises
sample.
and
5% of median
32 bits
is either
entire
range
of the
to the
633.4
Greenbelt,
Set
in
consists
is different
100 #m), and
16 or 32 bits per
the intensity
NASA/GSFC Code
Reject
25, 60 and HCON-2
ascension,
at the south scheme
ISSA
image
size of 1.5 t. The
In right starts
numbering and
(HCON-1,
standard
of signal.
is available Coordinated
ISSA
are either
intensity
ISSA
the
Each
a pixel
images
at IPAC.
images
than
10 ° apart.
that
and
et al. 1981).
numbering
entire
Coverage
information
greater
dynamic
4.2 Gbytes.
the
by examining
is the
will carry
Note
wavelength
request
intensity
(Wells
of sky with
spaced Field
coverage
intensity
to hold the
bits
IRAS
coverages.
was determined where
II.C.3.
confirming
the
is a set of 430 machine-readable
format
are
poles.
A lists
and
are available
sample noise,
each
which
II.C.1
field
Set,
(FITS)
at the
Appendix
each
Reject
a 12.5 ° x 12.5 ° field
bands
to convergence
as shown
ISSA
System
covering
declination
due
the
Transport
of 500 x 500 pixels are
with
plus
ISSA
depending Reject
1.4 Gbytes.
Office
(CRUSO)
images
on noise has
level
a size of
/
/,
/ t
5. Most
due
Faint
Events
the
re-ordered based on sky position. All scans one database called an ISSA field. A field IRAS
The
Image
SNR
Position-Ordered
reprocessing
into segments were grouped
C.
with
than
compressing.
were
for the
IRAS
data
> 5).
priately to signal downstream processors that deglitching data were used in creating the ISSA images. The deglitch of the
and
detector
threshold
interpolation
Even
typically
§II.C.2.a).
of five (SNR
frequency
a quality
for the
to phasing
by a factor
linear
used
Survey,
over
were
hits. of less
§IV.A.6).
as that
Source
of radiation
an amplitude
artifacts
Supplement
Faint
source
with
These
same
data
noise point
data.
is the
of a high-pass
the
artifacts
(Main
to the
detector
greater
by the removal
many
in the
detector
output
improved
detectors
by the
time-ordered
the
a frequency
remained
Supplement
monitored
were
deglitcher,
the
used
(Explanatory
cessor that
noise
impacting
deglitcher
operated
data
an onboard
sample
particles
The
detector
used
striping RMS of
detectors corrections
did
were not applied to these detectors. No corrections wereavailable for 20% of the survey scansdue to constraints in the empirical procedure. C.2. bands.
Zodiacal
Foregrottnd
Removal
Zodiacal dust emission is a prominent source of diffuse emission in all IRAS survey The apparent dust temperature of about 250 K makes the zodiacal emission most
prominent
in the
ecliptic
plane.
amount with
12 and
The
25 tl.nl bands.
zodiacal
contribution
of interplanetary the
Earth's
The
dust
position
the
the
discontinuities
different
times.
the
concentration
the
sky
model
and
These
artificial
useful
subtracted
it possible
spatial
from
model
a consistent
models
The
model
properties
of the
sylnmetry
plane
of wavelength. integration
dust. with The
of dust
data
zodiacal zodiacal difficulty
They
predicted
due
such
emission
that
Users wishing to know the total may do so by using the ZOHF Zodiacal
pole
emission
at 12 and
25/ml.
subtraction The
of a
at
associated faint
with
features
A zodiacal
on
emission
emission
on the radiative
use
the
and
at large
solar
of IRAS
cloud
for direction
where angles.
and the
density,
the
allowed
radiative
tilt of the
dust
(lust
as a function
time
was
obtained
model
dust
cloud.
by The
to a selected set of II1AS scans. Because that (lid not include the zodiacal dust
data.
95% of the total
zodiacal
at such
of the and
through
zodiacal
model
elongations
data
distribution
emissivity
properties
large-scale
of a physical
sky brightness in a particular Version 3.1 (§I.F).
removed
residual
brightness
zodiacal
to estimate
as dust and
line-of-sight
in the
based
the dust
plane
zodiacal
IRAS
difficult.
foreground
paucity
to describe features
remain
gradients
for scans
bands,
bands
the
used
to the
were determined by fitting the model assumed a physical dust distribution dust
varies
of sky were observed obscured
G. The
parameters the model the
on the
which
sky
plane,
emission was
ecliptic
along
the
natural
HCONs
to reduce
dust
zodiacal
emission
several
emission
include to the
depends
an amount
the
emission.
parameters
respect
brightness
patches
ecliptic
in Appendix
have
fourteen
the
foreground
of the
would used
ISSA
adjacent
as well as the
of the
in detail
prediction
empirical
where
remaining
of the
It is described
Consequently,
toward
of the zodiacal
distribution
emission.
the the
cloud.
toward
by IRAS, changes with time as the Earth moves of the variable zodiacal emission was to introduce
gradients, emission
surface
line-of-sight,
images
co-addition
to co-add
A physical and
SkyFlux
of zodiacal
made
was
make
in the
is concentrated
particular
dust
particular location on the sky, as observed along its orbit around the Sun. The effect step
distribution
to the observed
along
within
dust
emission
seen
region
brightness at the
as observed
at the north
north
ecliptic
by
ecliptic
pole
at 12
and 25 #m shows variations of 0.5 MJy sr -1 and 1.0 MJy sr -1 , respectively. This appears in the ISSA images as a "bow-tie" at the pole. At intermediate latitudes this variation in residual lower
foreground amplitude
to 1.0 MJy
sr -1
appears than and
the
as low-frequency polar
2.0 MJy
bow-tie sr -1
(greater
(0.2
at 12 and
III
MJy
than sr -1 at
25 l,m
11
5 ° period) 12 #m).
for fields
near
striping The the
of somewhat
residuals ecliptic
increase plane.
C.3
Destriping Due
to
imperfections
stripes remained to in-scan RMS three,
and
RMS
1.5 and noise
detector-to-detector
be
to derive
destripe
offset
computed
from
The
two algorithms
not
three
only
assisted
additional
the position-ordered, cross-scan RMS noise The ratio
noise,
Each
detector No gain
The found
of the
Overview
following
is a brief
assumption
when
pointed
zodiacal
that
each
detector
at the
same
spot
of many
A typical
hundreds
during tile mission. each detector scan. adjusted was
There issues
until were
related
the
zodiacal
size
of the were
database size of the
of the
the
of the
global
scan
in the
incoming
hysteresis
removal.
database size ranged database
needed focal between affected
and
destriper.
The
but
This
also
allows were
cor-
brought
mosaicking derived
from
cross-scan
the
striping
A detailed
1988).
should the
a single wavelength
scan
can be
a BasketWeave
algorithm
was
see the
same
mission
same
that
(§IV.E.1).
description using
This
original
such
1.0 for all bands
accomplished
in implementing datastream One
a global
crossings.
After
470 megabytes fitting
an
the
during
the
involved
to support plane
with
after
based intensity
removal
observation taken
on
of the
crosses at other
the times
difference history for Each scan was then
and
the
fit. The
process
minimized.
of difficulties
1.2 million
local
crossing
The local destriper reduced by an additional 10%.
during
path
between
a number and
level.
wavelength
of the
to anomalies emission
applied.
possible to generate an intensity data were fit with a polynomial. were
from
were the
the
to remove
corrected
parameters
destriper.
Gr£ves
same
detectors
to have
was
striping
is nearly
was
sky anytime
difference
differences
the
regions
and
was
methods
information
and
destripe
of ISSA
detector
of other
It was therefore The difference
by a portion
repeated
of the
in the
destriper
reduced
(Emerson
two
scan
background
local
in flat
destriping
(BWDS)
emission.
paths
overview
D. Global
algorithm
noise
of ISSA
corrections
detector data. global destriping
methods
Destriper
in Appendix
DeStriping
two RMS
the ratio of cross-scan #m is between two and
detector-to-detector
The
detector-to-detector
time-ordered, zodiacal-emission-removed detector within a scan. The global
to a common
adjustments.
to in-scan
Global
the
used
of each
to as the global
globally-corrected as measured after
combination
of cross-scan C.3.a
there
a goal
RMS
parameters.
(HCONs)
offset
destriping, 12 and 25
Since
Each
in decreasing
models,
in-scan
implemented.
are referred
sky coverages
without
the
were
derived
zodiacal
100 #m.
to the
destriper utilized the entire IRAS survey to derive destripe parameters for each
rections the
2.0 at 60 and
parameters. the
and
data. Without of the sky at
equivalent
variations
scans
global dataset
calibration
in the IRAS detector noise in a flat region
between
cross-scan
in the
major
III - 12
this approach, as
the
consideration
basketweaver. careful
for 25 #m
checking
as well
selection
Over
was the
(Appendix
to 730 megabytes
strategies.
including
completeness the
of
enormous
entire
mission,
D) the
final
at 12 #m.
The
Intensity differencefits wereperformed for eachscanat eachwavelengthusing at most tenth order orthogonal polynomials. The fit technique and order varied to someextent with wavelength. Intensity differenceplots provided good visibility as to the quality of the fit. However, due to the volume of data, comprehensivemanual checkingusing plots alone was not feasible. A computer program analyzedthe fits for eachdetector within eachscan, producing a set of parameters. These parameters servedto indicate possiblefitting problems. Histograms were generatedfor eachparameter and the fits which produced extreme outliers wereinvestigated. Identified problems were either fixed or removed (Appendix D). C.3.b. The rithm.
Local
local Each
De_triper
destriper detector
algorithm of the
was
same
the
field.
local
destriper
region.
The
by the
global
Input
the global utilized
local
A co-added
Then
the
were
taken
The
image
trajectory
of the
between
the
see the
from
utilized
all focal
in further
same
a subset plane
reducing
was position-ordered, process
was
assumption
as the
intensity
global when
made
detector
local
of all scan
segments
values
of focal
crossings the
plane
crossings,
within
cross-scan
the
RMS
the
dcstripe
parameters
within
a defined
co-added
image
was
detector
along
the
of the
determined. scan
and
Differences
co-added
process
iterations
of the
iteration
the lower frequency image to prevent
influencing
An error
image
to 1.5' for the final.
helped in reducing from the co-added thereby
co-added
the
in the
detector
local
image
scan
destriper
was
were
Starting
made with
quality
software Due scans, destriper
checking was fixed
the
to the fields from
process,
differences software
(§III.D).
for processing
residual covering the
fields
the
Some
1/31
Reject
III.D.l(b). Table
Amount
consisted
a somewhat
the inspections quality check. of data
20 ° sky is shown Set
faint
consistency
Johnson, performed this post-production
during
of energetic particles. As mentioned The tail of comet Iras-Araki-Alcock
appeared
maintain
The
found
of Data
III.D.l(a)
Removed
Wavelength
in Anomaly
% Data
Processing
Removed
(I/3] > 20 °)
% Data
Removed
(1 1 > 50°)
(1 I < 50°)
12
0.18
0.51
25
0.30
0.31
60
0.14
0.24
100
0.07
0.26
Table Amount
of Data
III.D.l(b)
Removed ISSA
in Anomaly
Reject
Set
of the
(]/_[ < 20 °)
% Data
Wavelength
Processing
Removed
(#m)
D.4
Types An
are
described
tion
process
except
those
0.34
25
0.30
6O
O.27
100
0.47
of Anomalie_
attempt
Anomalies
12
fell
was into below.
described that
made
two
to
main
Most
characterize groups,
of these
in §III.D.3.
caused
the
data
the
anomalies
anomalies
anomalies
were
All processing
improper
handling III - 22
found
and
processing
removed
problems of saturated
by
through
were data.
corrected
visual
inspection.
anomalies, the
which
visual
inspec-
in the
software
D.4.a
Data
Anomalie._
Focal
Plane
and
All or a subset time
then
fairly
fell
sharp.
Partial
of the
back
Focal
detectors
in the
to approximately
This
was
likely
Plane
focal
their
due
Anomalies plane
original
to either
Detector
to a higher
intensity.
a particle
the telescope or by a shower of secondary energetic Figure III.D.1 shows the distribution of focal plane --
jumped
Both
or paint
the
flake
particles from anomalies.
the
intensity
rise
problems.
Processing
--
The
distribution
of detector
Local
These
191>
structure.
streaks
and
Generally streaks
ministreaks
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is found
Anomalie_
Destriper
anomalies
were
shown
to appear
only
were caused by an error in the local destriper in the time-ordered detector data. A number prior
of
III.D.2.
D.4.b
images
were
field
Streaks/Ministreaks
to calibration
in Figure
fall
near
observing
One or a few detectors showed nonconfirming spikes or raised intensity. mini-streaks were due to orbital debris in the field of view, whereas detector due
and
in the
for a
because
they
were
not
bright
enough
to processing the 1/31 < 50 ° sky. 50 ° sky is found in Figure III.D.3. Saturated
An
error
was
Detector found
after
to stand
intensity
nonsaturated
intensity
in the Galactic a list of fields occurrences
values.
algorithm
for
in making
the
Figure
III.D.4
plane where 60 and along with the number
throughout
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destriper
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This
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the
Data
in the
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Distribution
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error affected the SkyFlux inmges as well as the eliminated the wrong detector when saturation of saturated
the
software that did not account for data gaps of local destriper anomalies were left in these
mission
saturated
intensity
saturation. There may be several detectors that on an average ten detectors saturate about < 0.005% of the survey data.
images shows
Each
saturated per second,
III
This
entire set of ISSA images. The algorithm occurred. This resulted in the inclusion while that
erroneously the
problem
100 pm detectors saturate. Table of occurrences in each field. The is 6,289.
values.
- 23
occurrence
reflects
eliminating occurred
some mainly
III.D.2 provides total number of a single
detector
within a second of data. Assuming the total number of occurrences is
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Table ISSA
and Field
ISSA #
Reject
Fields
Affected
Occurrences
Field
by #
Saturated
Data
Occurrences
17
14
153
387
18
12
170
338
32
194
171
103
33
289
182
22
34
24
* 183
22
35
30
189
278
36
76
* 190
278
37
57
206
436
52
113
2O7
196
58
17
226
136
59
369
227
14
6O
119
248
12
77
32
* 249
12
78
27
262
8
86
37
263
163
87
448
104 * 105
*
III.D.2
284
10
8
297
77
8
298
115
117
374
331
2
118
1603
360
6
119
30
361
4
137
8
390
9
* 138
8
391
59
152
27
407
6
Overlapping
area
with
adjacent
III - 27
field
not
included
in total.
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III
28
IV.
A.
Analysis
RESULTS
Overview
Analysis the
ANALYSIS
of the IRAS
quality
of the
sky, released
ISSA
in 1991.
Sky Survey
images. The
Atlas
The
analysis
was designed
analysis
is mainly
concentrated
to verify confined
on the position
accuracy,
sistency, spatial resolution and noise of the Atlas. The results to the entire ISSA data set, which covers the I_l > 20° sky. covering
the
Reject
l/_l < 20 ° sky is of reduced
Set.
plane
The
and
the
reduction
zodiacal
bands.
of ISSA
is 4.5'
are photometrically uncertainty was
used
is due
to the
surface brightness to-detector offsets in the the
ISSA
noise
B.
accuracy
Point 30 °,
Point
source data
spatial shifts
to have
small
source
at
12 and
ecliptic
for these
images,
§IV.F.
sources
show
Catalog
within
that
to within
the
data
10%.
This
tim convolution (Appendix
filter B).
that
Relative
The effects of detectorso that the noise level
is approximately
photometric
brightness
23 sources at 60 and a large
25 #m
that
expected
from
consistency
between
are listed
were
5 and
selected
55 Jy
and
to be correlation
were studied enough emission at
high
using
to measure or nearby Galactic
coefficients
point easily point
latitude, of 0.99
or
at 12 pm and 24 sources at 25 gm are listed in Table IV.B.1. 100 #m were selected from the IRAS galaxy list (Soifer et al.,
radial
velocity
Jy. The velocity criterion is designed be extended at the resolution of the at 100 pm
ISSA
at the
to 2' samples
sky
product,
emission
scales is possible. have been reduced
latitude
are applicable set of images
to within the limitations of than 0.1 pixel. The spatial
point
Source
con-
detectors.
and
sources
with
greater. The Point sources 1987)
accurate to better
IRAS
high-ecliptic
IRAS
images are accurately
selected from the IRAS Point Source Catalog to be bright ISSA data and to be free of interference from extended
sources. Ibl >
in the
is presented
of a point
over large emission
a separate
zodiacal
analysis
IRAS
analyze
photometric
reported here The remaining
considered
of ISSA
and
Accuracy
Positional sources in the
the
resolution
photometry and zodiacal
images
Positional
with
fldl
and
to residual
Measurement
positioning
the
in individual
the ISSA positioned
to 5'.
consistent
to resample
is due
A separate
The analysis results sllow that the IRAS data. ISSA data are resolution
quality
in quality
the accuracy
to the high-ecliptic-latitude
in Table
(>
4000
km
s -1)
with
brightness
between
5 and
55
to select small angular diameter galaxies unlikely to ISSA maps. The 14 sources at 60 #m and 15 sources
IV.B.1.
IV
1
o
=
_
_
_
_
_
_
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IV
- 2
The
position
selected
sources
Source
in the
Catalog.
ISSA
map.
The
over
Figures
IV.B.I(a)
the ISSA
obtained are than
analysis
ISSA ISSA
Photocenters
positions and
accuracy
and
less than
the
region
(9")
published
taken
and
a source
point mean
the
expected
PSC
of a single
and
ISSA
source
is less
point
spread
Statistics
25 #m
60 #m
100 #m
23
24 0.001
0.040
0.031
a(A R.A.)(') Mean A Dec.
(')
0.156 0.070
0.267 0.034
0.179 -0.078
0.224 -0.131
0.126
0.225
0.156
0.236
Dec.)(')
selected
point
sources
function
of 1.5' period
of interpolated there is some the
(see
widths which
apodized
with
§IV.B)
were
used
to study
the
a cosine
to a full width
of 12 zero
ISSA
point sources spacing using crossings.
point spread functions are shown in Figures IV.C.I(a) noncircularity evident. The short axes of the PSFs, when scan
the point spread functions indicate that the resolution
in both of the
algorithm
15
at half maximum (FWHM) of these had been interpolated to 0.15' sample
predominant
axis of the
14
Function
(PSF). The full from ISSA data
binning
position
the statistics
the
0.004
function measured
long
pixel
background. PSC
summarizes
between
uncertainty
the
(')
Spread
with
IV.B.2
Point in the
of the
of a local
A R.A.
a(A
line up
IRAS source
average
between
of the
IV.B.2
Difference
# of Sources Mean
plots that
Table
position
12 #m
The
in the of the
subtraction
differences
position
(18").
Position
Point
after
sources.
Table
C.
locations
photocenter
of difference
position
apparent
a flux-weighted
histograms
The
the
source
to be the
by producing
display
for the selected
of comparing
the
was
surrounding
histograms.
0.1 pixel
0.2 pixel
with
obtained
IV.B.I(b)
position
from
maps position
were
a circular
consisted
image. used
This
spatial
to produce
direction.
Table
IV.C.1
lists
the
the long and short dimensions. ISSA is 4' to 5', depending on resolution the
ISSA
is consistent images.
IV - 3
with
measured
were a sinc
Contour (d). Note discernible, FWHMs
of
These measurements the orientation of the
expectations
based
on the
' 4.0-- MEAN
I
'
I
'
= .070
n
POP = .126
II
SIGMA - SIGMA
MEAN
I
'
'
4.0
I
'
I
'
i"1
= .034
I
]l ii
SIGMA
= .026 ]1
"SIGMA
3.0
3.O
N
POP = .225 MEAN
t1
= .046 II
= 24
2.0
_2.0
1.0
l°r P lIIt
0.0
4.0 -
-1.0
0.0
12 Bm DELTA
RA (ARCMIN)
'
I
I
MEAN
'
O0
1.0
4.0
= - .078
'
--
0.0
RA (ARCMIN)
' I MEAN=
i
' -.131
SIGMA
POP = .236
MEAN
SIGMA
MEAN
= .042
1.0
25 I.tm DELTA
POP = .156
'
I
'
= .061
N=15
3.0
b-, Z
Z © 2.0
2.0
LAL -1.0
0.0
60 Bm DELTA
Figure
I
,
SIGMA
3.0
0.0
I
SIGMA N=I4
1.0
-1.0
IV.B.I(a)
1.0
-1.0
RA (ARCMIN)
Histograms
0.0
100 Bm DELTA
of Position
IV
Differences
4
in RA Between
1.0
RA (ARCMIN)
PSC
and
ISSA
4.0-
_
-
MEAN
= .004
I] SIGMA
POP=
"7 .156
4.0
j
rl SIGMA MEAN = .032[ N=23
3.0
SIGMA
[
SIGMA MEAN = .054
POP = .267
]
N=24
3.0
0.0
L
I
I
j
- 1.0
0.0
12 I-tm DELTA '
4.0
1
MEAN
DEC
'
I
I
0.0-
(ARCMIN) !
POP = .179 MEAN
I
,
]
i
= .041
,
0.0
25 pm DELTA 4.0
SIGMA
I
- 1.0
= .040
SIGMA
-
1.0
N=14
3.0
EAN L
I
I
1.0
DEC
' I ' I MEAN = .031 SIGMA POP = .224 SIGMA MEAN = .058 N=15
(ARCMIN) '
I
'
_
I
I
3.0
m
Z
b-. Z
© 2.0
_2.0
1.0
I -1.0
0.0
60 pm DELTA
Figure
IV.B.I(b)
0.0
1.0
DEC (ARCMIN)
Histograms
1
1
- 1.0
0.0
100 pm DELTA
of Position
Differences
IV - 5
in DEC
I
1.0
DEC
Between
(ARCMIN)
PSC
and
ISSA
Table Point IRAS
12 #m
25 #m
Spread Name
100 #m
Function
Dimensions
field
flux
FWHM
(JY)
(arcmin) 3.7 × 4.8 3.7 x 4.9
10521+7208
414
35.6
15448+3828
355
37.0
17133+3651
357
48.2
05174-3345
102
27.3
3.6 × 5.3 3.6 x4.7
03040-8013
3
26.2
3.6 x4.7
20427-8243
9
12.6
3.6 x 4.6
3
20.8
4.5 x 4.9 3.6 x 5.3
01452-8026
60 #m
IV.C.1
17329+5359
383
21.4
04330-6307
28
12.1
02238-5947
26
12.1
08354+2555
316
24.3
00163-1039
162
6.9
3.7 x4.2 2.7 × 3.9
04315-0840
169
33.5
3.5 x 4.6
23488+2018
270
17.0
3.2 × 5.2
13183+3423
322
24.4
10565+2448
319
14.3
4.5 x 4.8 4.6 x 5.2
23488+2018
270
21.0
09320+6134
397
20.1
IV - 6
3.5 x 3.9 3.8 x 4.6
5.2 x6.1 4.8 x 5.2
IRAS '
15448+3828
I
2O
Z ×
C)
_3
I
,
,
!
I
i
,
5
10 ISSA
J
15 PIXEL
Figure IV.C.I(a) Contour Plot of Point Spread from 0.0 to 13.6, Interval 0.8 IV - 7
I 20
NUMBER
Function
for a 12/zm
Source,
Contoured
I
IRAS 20427-8243 '
'
I
'
'
I
,
I
_
,
i
I
[
1
15-m
z .d
10-
< r/3
5-m
0 0
5
10 ISSA PIXEL
Figure IV.C.I(b) from 4.0 to 11.6,
Contour Plot Interval 0.4
of Point
Spread
IV - 8
15
NUMBER
Function
for a 25 #m
Source,
Contoured
IRAS 04315-0840
15
Z
10
'
'
'
'
,
,
i
i
I
'
'
'
'
I
J
,
,
J
I
'
'
I
, .--u
'
'
I
'
I
,
m
m
m
cause was gain version of the
and
rejected.
The intensity difference increases the gain errors directly. This option
at the Galactic was investigated
plane could only be handled by fitting (see Appendix E) but, since applying
a gain
correction
the point
calibration,
fitting
investigation
are due Both
gain
errors was
coupled within
would
made
at I00
The
100 #m
the
magnitudes
much
greater.
in the
that
an error have
intensity
DC response
to be addressed
to fit this
region
differences
of each
to get
accurately
and
fits near
the
good
allowed
for
near
detector
at 60 pm.
polynomials plane.
it was not
The good
inverse fits
used.
the
The
gain
Galactic
plane
residual
hysteresis.
Galactic
plane.
intensity
weighting
everywhere
No
except
for
#m fit procedure of the
They
were
low intensity
improvement.
source
the increased in the
with the higher order 1 ° to 2 ° of the Galactic Fits
that
compromise
showed
to two effects:
attempt
D.4.d
would
was
similar
intensity
so large
regions.
to the
differences
that
even
60 pm
near
fits up
Letting [P represent the path (W) is defined as follows:
worked
intensity
and
Galactic
to tenth
Inverse-intensity-squared
Inverse-intensity-cubed
procedure
the
order
better
I x the
crossing
and
the
at
caused
weighting
even
with plane
fitting
resulted was
were
problems
in considerable
adopted
intensity,
exception
100 #m
the
for
100 pro.
weighting
factor
I max = MAX(IIPI, IlXl) I ba_ = 2.5 x 10 -7 Wm-2sr W
The
100
thresholds and
residual
pm
and
= 1/(Irnax/Ibar)
fit
was
(_ settings
hysteresis
done the
made
-1
3
in three same
about
W
W=10
iterations
as at 60 gm. the
10._ with All the
60 lira fit are even D-
14
the
order-of-fit
comments more
table,
regarding
applicable
rejection gain
to the
errors
100 pro.
As with the 60 #m fits, the 100 #m fits should be consideredquestionablewithin 1° to 2° of the Galactic plane. D.5
Monitoring Algorithm
global
performance
RMS
in Table
values
D.4 for each
of reduction
carefully
rather
time required to obtain do another iteration.
time. than the
monitored as a function
The
is reduced
Tile
RMS
RMS
a measured difference
value
after
value. statistics
Table RMS Wavelength 12
of Intensity
(pro)
6O
100
Note:
Items
Intensity visibility feasible was
written
prot)lems.
plots,
a. scan-by-scan to the that
The
computed following
the
last
each
iteration
iteration
This
is because
was
not
as
RMS
process. are but
at each
the
amount
wavelength
the
considerable
significantly
less than
required
a Function
Difference (MJy 0.616
sr -1)
% Reduction 33.4 45.8
3
0.306
50.3
4
[0.2961 1.178
[51.9]
0 1
0.717
39.1
2
0.541
54.1
3
0.476
59.6
4
0.435
63.0
5
[65.7]
0
[0.404] 0.672
1
0.437
35.0
2
0.295
56.1
3
[0.2421 1.785
[64.0]
0 1
1.117
37.4
2
0.900
49.6
3
[0.8111
[54.61
some number
from
of which
extrapolation
have
Comprehensive
proved
D
that most
15
of previous
already
been
checking
of detector/scan
a set of parameters parameters
to
of Iteration
0.334
results
is
computer
0.410
are
The
tabulated
2
basis.
prohit)itive
with
fitting number
1
brackets
difference
on due
within
the
of iteration
D.4
Differences
Iteration 0
25
throughout
differences
wavelength.
is less each
an extrapolated
was
of intensity
shown,
using
combinations. served
useflfl:
as indicators
values.
provided
plots
alone
Instead,
good was
not.
a program
of possible
fitting
1) variance of fit for detector-scan 2) absolute value of fit at eachextreme point 3) absolute value of fit slope midway betweeneachextreme point pair aswell as at each end point 4) absolute value of 2"d derivative of fit at eachextreme point 5) number of points rejected in detector-scan. Histograms weregeneratedfor eachparameter and detector-scanwith extremeparameter valueswritten into the Problem ScanSummary File (PSSF). Detector-scansidentified as anomalousfrom other sources(see Appendix C) were written into the PSSF as well. Tile file was then usedto establish namelists for making large numbers of intensity differenceplots. The plots were manually inspected and the scansactually causing difficulties were identified. For the identified scans,problem type, severity and affected time interval were determined and loaded back into the PSSF. During the fitting processa file of rejected intensity differenceswasgenerated. Using this file, all-sky mapslike the onein Figure D.6 wereplotted to showthe global position of rejects. It wasfound that rejects wereconcentratedin high-intensity regions. The Galactic plane is prominent in all four bands; exceptionally bright areassuch as found in Orion, Cygnus and Ophiuchus also show up. The rejects scattered over the sky are associated with bright point sources.The long strings of rejects are due to problem scanswhich }lad to be corrected or eliminated. Problems identified from the intensity differenceplots weredivided into different types basedon characteristic signatures. The types can be grouped into three categories,which map as follows into two of the three broad anomaly classespreviously discussed(§D.3): 1) problemsintroduced into the data stream prior to BWDS processingthat could distort the BWDS fits (Class IA) 2) problems introduced into the data stream prior to BWDS processingwhich would not distort the BWDS fits (Class IB) 3) time intervals identified when the global BWDS fits shouldnot be usedfor downstream processing(ClassIII). ClassII anomalieswereeliminated prior to fitting. Residualeffectsfrom incompletely removed Class II anomalies were apparently small; none were identified on the intensity difference plots checked. It is possible that some of the scattering attributed to other causesmay have resulted from incompletely removedClassIIs. ClassIA anomalieswhich could be identified beforehandwerealsoeliminated prior to fitting. Pre-fit identification of theseanomaliescamefrom the original imagesaswell as the latest calibration and pointing reconstruction processing. Figure D.7 illustrates a serious ClassIA anomaly. This particular anomaly affectsall detectorsin all bands and is believed to be the result of a paint flake passingin front of the focal plane. If not removed, it would not only distort the fit (solid line in figure) for the observationin which it occurs but could also adverselyaffect the crossingscanfits. This
D - 16
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type of anomaly, once but for all downstream Figure moved
identified, processors
D.8
illustrates
hysteresis
as the
anomaly
sometimes side of the
point
point
source,
signature
the
ing and
descending
because
they
the
time
periods
gone
into
dency
too
Class
for the a plate
ference
between
a spatial
help the
intensities
Time
point
Another type of Class III anomaly can occur when there is a large internal there
are
no
crossing
points
of this where
slope
source. negative
the
affect
Had
intensity
An
automated for this type
Second,
those
gap period to provide
type, the
fits
whose
the
fit within
Those
gap
times
with
at the
to maintain
marked
to prevent
points
would
an individual
possible
to the
would
have
there
is a ten-
when
heavily
stressed
an
extreme
the
of intensity sr -1
point
intensity
dif-
difference
were
flagged
for
the
gap,
it is possible not
only
detector-scans detector-scan
for large on the
size
with the powas identified.
an extreme
point
within
the
fit was evaluated at each end of the gap interpolation across the gap. Differences
extreme
points
and
magnitudes
the
greater
linearly
than
interpolated
1.0 MJy
sr -1
only. The one exception to this was in the dual-hemisphere the near-linear assumption does not apply.
relative
photometry
had to remain low. The intent was that or to remove real structure smaller than extreme
bright
figure,
and
0.2 MJy
fits contained
difference-from-linear
were flagged for local destriper overlap region at 25 tin1 where In order
polynomial
Next, the polynomial needed for a linear
between the actual fit values values were computed.
been
be
is illustrated in Figure D.9. This type of problem gap in crossing times within a detector-scan. Since
to constrain
detector-scans
database
techniques,
having
magnitude
exceeded
on
It should
differences
identified
approach was developed to help identify of problem. First, the longest gap in each
were marked. the end points
fit.
it not
ends
of
by the
surrounding
by the
were
type
mix of ascend-
BWDS
the
immediately
the
re-
components
on the
from
excursions to occur within that region. Whether it happens depends of the gap, but also on how stressed the fit is outside the gap.
tential
This
dual-hemisphere
the
database
by incompletely
depends
D.5(a).
BWDS
may also be affected
removed
off near
or finish)
intervals
end
plots
illustrated
to flair
(start
and
scans
and
from As
problems
two saved. or the
order
appreciably
point
positive
in areas
in Figure
anomalies.
potential
not
in the
point
to appreciably
of higher
III
bright
crossing
were
was shown
of an end sr -1
with
the
difference
fits occasionally
locate
MJy
spike
only
It is caused
a very
frequency
that
fit differed
as Class
width
exceeded 14.0 local fit only.
anomalies
anomaly
polynomial
To
within
intensity
These
not
anomaly.
crosses
on the
however,
the
PSSF
IB
Since
a combination
where
the
elsewhere.
III
fit with
scan
crossing.
high
for non-use
Class
up as a double
source
by the user, suspect.
A typical improve
affected
scans.
have
remembered sources are
a typical
shows
either
was flagged as well.
be separated polynomial
across
a plate,
the
it should not be possible 12.5 ° . Order-of-fit criteria
by more
than
fit from
a field width.
having
D -18
rapid
There
fluctuations
frequency
of the
fits
to introduce were selected
artifacts so that
is, of course,
nothing
over
a portion
of
50
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2_
4_
6_
SECONDS Figure
D.7
Intensity
differences
along
a detector-scan
track
illustrating
a
class
IA
class
IB
anomaly. 50
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'
I
'
I
'
I
'1
'
I
'
I
"7, r._
:_
25-
g
Z
-50 -
Z -7: 0
, I, I, I, I, I, I, l,l 200 400 600 800 1000 1200 1400 1600
,I
I ,I L'I,
1800 2000
I
2200
2400
illustrating
a
SECONDS Figure anomaly.
D.8
Intensity
differences
along
a detector-scan
D
19
track
50
I
'
1
,
1
'
I
I
I
'
I
J
I
'
I
I
I
'
I
,
I
I
I
_
I
'
I
,
I
'
I
J
I
Z
Z Z
,
200
400
600
800
1000
1200
1400
1
1600
1800
SECONDS Figure D.9 III anomaly. the
scan.
way
The
real
as to introduce
those
fits with
greater the
than
identified In areas
to the
the
scans
artifacts
or remove
real
structure.
In order
point
pairs
point
been
many
close
out
and
global
extreme
pairs,
every
effort some
tion
fitting and
points, every
errors
sky
position.
which plate
slipped
occur
were
global BWDS such effects.
through
By far near
checked
contribution
the
the
which most
ecliptic
manually
were
likely poles.
(§III.D).
to the
image
systematically
place
to happen
against
where
these
there out
and
a
question, differences
legs between D.10.
BWDS
contribution
effects. fit problems
coupled
wrong
for this
subtracted
scan
fits will have
problem fits greater danger
To guard
this
to identify
parameters
problem
In areas was
the global
in such
intensity
of the
made
of indicator
However,
combine
fits in Figure
for adverse was
the screen. We can be confident that the individual BWDS monitoring were not severe in nature. The small
positions
inspected
a class
to address
having
100 #m
point
manually
illustrating
involved
width
for the
checking
scans.
a plate
The
described,
of automated
of indicated
than
are plotted
identified
previously
closer
identified.
pairs
subtracted
method
inspection
track
individual
sr -1 were
has
a detector-scan
the
extreme with
along
is whether
1.0 MJy
was
through
differences
question
extreme
image
As ual
Intensity
with
slipped
slipping is that
through a number
in the
same
is at the dangers,
are many
man-
through
direc-
scan
end
images
scan
manually
the of
ends,
inspected
of the for
References Emerson, IRAS bauer,
D. T.
Catalogs
and and
H. J. Habing,
R. Gr£ve Atlases:
1988,
Explanatory
P. E. Clegg,
and
Astron.
Astrophys.,
Supplement T. J. Chester D - 20
190, 1988, ed.
(Washington,
353. C. A. Beichman, D.C.:GPO).
G. Neuge-
0
°,-_
°,._
_O 0
C_ c_
0
0
0
"3
_n
0
\
D
- 21
APPENDIX Gain
As tensity
discussed
in Appendix
difference
histories.
from
a given
cross
the
detector
path
These
with
of the
the
first
intensity
D, the These
intensity,
suggesting
computed
from
intensity
difference
for
60 and
total
100 #m
emission The
detector, for that
since
near
average
the
gain
data
errors
for each
and
are too large
at these
associated
relative
These
adjustments
were
Detector
01
Gain
Err
Pop.
Sig (%)
The
(%)
02
+11
+01
8.0
analysis
5.1
was
as the mini-survey in Table E.2.
+06
-05
5.5
6.2
repeated
(IRAS
#m
04
03
Gain
08
Gain
Err
Pop.
Sig (%)
These not
(%)
+10
values
a function
3.8
09
10
-02
-09
3.2
3.3
do not of photon
fluctuate exposure
with and
by
percentage
of
broken
that
and
down
the
should
by
intensities be reduced
data.
+02
6.2
of the
1988
57
-01
7.1
14
5.0
Galactic
5.5
IRAS
§III.C.11).
15
32
+13
+08
5.9
58
59
60
61
-01
-20
-05
00
6.1
5.0
7.1
6.9
survey Results
1
are
33
data
known
are tabulated
not
35
38
-03
-23 5.2
4.0
3.4
4.2
3.9
suggests
that
they
to hysteresis.
+09
37
-05
which due
34
+03
3.0
longitude,
therefore E
done
Errors
-06
2.9
was
was
E.2
13
9.2
band
56
a subset
Gain
+02
error
Only intensities considered viable
at 100 #m,
IRAS
+15
5.2
Supplement
+09
This
of
importance to the were converted to
is a small
sign suggests
07
+04
7.8
12
gain
detectors. This was
in the
06
Table
Detector
magnitude
Errors
+11
#m
which
E.1
for 60 /am using
60
band
that the intensities for that detector and should be increased by the given
to the
05
Explanatory
gave more differences
sigmas
detectors
uot applied Table
of in-
intensities
wavelengths.
sign suggests in the band
100
percentage
dust
E. 1. A positive
to other
the
at 100 #m.
zodiacal
population
in Table
by the indicated percentage. A negative are too small relative to other detectors percentage.
average
detector
to the
same
between
from the crossing readily available.
due
plane
as shown
The
use
the
mission.
which, at 100 #m, plane. The intensity
emission
Galactic
the
of the
a correlation
errors.
the intensities removed were
the
were computed detector
gain
makes
by comparing
detectors
during
revealed
differences the Galactic
gain errors using zodiacal foreground
time
(BWDS)
generated
of all other
histories
and
DeStriper
were
at any
differences
percentage with the
BasketWeave
intensities
difference
using the intensity-weighted detector differences near
Errors
histories
detector
E
The
are
values
presentedabove are expected to approximate DC gain errors. To a lesserextent, they may also reflect errors in determination of the detector solid angles. Residual hysteresiseffects werealso noted in all bands. These wererelatively shortlived with time constants roughly of the order of 10 to 20 seconds. References IRAS bauer,
Catalogs
and
H. J. Habing,
Atlases:
Explanatory
P. E. Clegg,
and
Supplement T. J. Chester
E-2
1988, ed. (Washington,
C. A. Beichman, D.C.:GPO).
G. Neuge-
APPENDIX Gain
and
F
Offset
Corrections
F. Boulanger A file containing History
File
presented
(ZOHF)
below
Version versus
3.0
the that
scan
by deriving light
discarding
This
correction
computed
procedure
at high
IR and
that larger the
to the
zodiacal
light
prevented Correction
(30 ° of scan previous and
factors length)
scans
which
have
factors
the root
are
mean
the
average
gain
the
corrections
Table plotted
dispersion F.2
gives
against
is no systematic
too
and
presented
of the
gain
a histogram SOP effect
and
change of the
in the
of low
longer and
F.2.
and
are
close
to one
gain
overall
corrections. with
F-1
which
and
F.l(a) respect
3_
The
the are
by using
only
between
the
in this
at
least
60
the
data.
of the and
These
to elongation
points in the scans
file gives gain
average
and value
At all wavelengths
respectively.
of the gain
The on the
gives
corrections.
data
for short
emission.
zero,
factors the sky,
described
Statistics F.1
region
contribution
were obtained
for each - (c).
elongation.
accuracy.
emission
30 °.
with
which
Galactic
sufficient
Table
offset
calibration
is about
in Figures
the
Galactic
than
These
1988). No correction I correlation across
corrections
gain
the
corrections
for
next.
for which
exists emission
for low Galactic
offset
F.1
with
scans
points
was satisfied
and
times,
corrections,
Galactic
the
three
and
correlation
25 #m
of the
corrections
elongation
for
scans
in Tables
corrections
not
The
emission
in regions
dispersion
offset do
and
80_0 of tile
condition a good
and Pbrault in the IR-H
criteria
no gain
few points
square
This
for each
by all scans
of observations)
of the
between
to match
to the
over data
It was
linear
scan
measured
magnitude
profile
profiles.
iterated
iteration
dataset
light
obtained
of the was
fit is made
at 12 and
only
selection
is
emission
IRAS
was
were
process
day
1988).
Galactic
time
envelope
light
entire
average
and
fitting
where
(Boulanger variations
measured the
for about
that square
were
Therefore,
corrections
and
of the
satisfy
paragraph.
correction offset
subtraction
Zodiacal derived
A zodiacal
corrections
a half
Pbrault
at 60 pm was removed using H I data were derived at 100 #m due to the which
nearest
one
emission.
and
zodiacal
of the
zodiacal
to the
(Ibl _> 25°),
(Boulanger
of the for the
5er from
correction
zodiacal
latitude
IRAS were
1988.
the lower
roughly
if the
axis)
elongation
This
than
compared
the
corrections
P6rault
offset
average
Plan,
only
of the
Galactic
compared
forced
residuals
is valid
on DC
scan.
to match
is negligible
and
and
for that
Observing
H I emission
is negligible
Gain
the
profiles
Earth-Sun
interpolation
scan
a few percent
points
the
with
(Survey
average
dependence
a linear
emission
typically
by linear
accompanies
of how
compute
about
light
offsets,
corrections.
in Boulanger
profiles.
the
DC
on the to
angle
scan
and
A description
used
zodiacal
profile
SOP
Galactic
was
average
force
same
3.0.
described
all points
corrections
gains
statistics
(azimuth
the
consecutive
the
ZOHF
for each
two
zodiacal
with
method
computed
assumed
Version
along
inclination
following was
corrections,
The three
offset figures and
This
shows
root
mean
wavelengths. corrections
show SOP.
that
are there
References Boulanger, F. and M. P6rault 1988, Ap.
J., 330,
Table Statistics
A
Number
( MJy
12
3616
2133
25
3617
60
3384
(3)
Gains
Residuals
sr -1)
( MJy
(5)
(6)
(7)
(8)
0
-0.105
0.482
1.004
0.030
0.114
2132
0
-0.125
0.835
1.001
0.032
0.172
2295
70
0.036
0.403
0.994
0.036
0.162
number
of scans
with
(2)
number
of scans
without
(3)
number
of scans
with
(4)
average
offset
(5)
standard
(6)
average
(7)
standard
(8)
average
a good
fit (correlation
a fit; most a poor
of these
fit (correlation
coefficient are
short
coefficient
larger
than
0.96)
scans smaller
than
0.96)
correction
deviation
of offset
corrections
correction
deviation amplitude
sr -1)
(4)
(1)
gain
Factors
Offsets
(#m) (2)
F.1
of Correction
of Scans
(1)
64.
of gain
corrections
of residuals
(RMS
dispersion)
F-2
after
subtraction
of the
fit
Table Histogram
F.2 of Gains
Number
Range 12 #m 1.045 Total
F-3
12 _m I .5:
I
t
I
7,o_
•
I
I
u
1.5--
1.5
-,,[: ..._... _'..: ,-
,=o
,
,..,_..- _,..--,,.:_ flilJli!c_" ,.:..-
O=E . o•
-15
..
:.." -
o:
.
"
•
_
J
•°
",_:: :-o -.': ol,.
:':::'
"
..
•
.._{o It•"
..
.
" •:" _
"
•,
• .:..-
"
.o.-"
°-
m
•
-2.5
-2.5 -3.5
] 65
55
I 75
I 85
I
I
I 105
I g5
ELONGATION
I 115
-3.5 -50
125
J 50
t 150
I
I
I
-
. •
I
I
-
Z
.
I
1.04
.96
'"
"° ";'.
:': .#
1.12
-;_
.
I 65
_" :
I 85
ELONGATION
F.l(a)
Gain
I
I
!
•
t.
". -_.
_.;_" -"_;:
o•
::_ • .
I 75
i 650
..
.:
._.-_.,
•
1.00
.,,_:-.
.96
.-
and
"_r'._.
:
.
,.• --
_;,
, _-_:_. :.
._._"
,
-.
{'."
•
.92 -
,92
55
l•-.
.o4
•o
.88
I
• ;".._
_...:.'= :,:.:, .: ..
-_'_'_9'-" _
1.16
-"
::,r:o _" ".
,:,. _-." -: _-,,._
1.00
I
¢., -.
1.08
• (,_:
_4
-
i 550
"." o
•_ .=, .'.; "
_ 450
1.20
1.12 1.08
I 350 SOP
•
1.16
I 250
(DEGREES)
1.20 --
t 95
t 105
I 115
1'25
.88 -50
I 50
I 150
offset
I 250
1 350
J 450
SOP
(DEGREES)
corrections
versus
F-4
\
:"
.
-
.-.:..,.
•_ _ •,,_. ,_ ....
-1.5
Figure
•
.--" : -
:._- ,.,-___
"
O_
._; .:, _'_ -'-'_C._J,.I,'_. "%
.:"-
•
•
•
-
• ".._'Jl
'- • f •
.6 .2
=z-J-. '-C,-
_
._!
r._
_-
-f_;
-,2 .o
._1_
:o.
..oo
.
-.6 %.
(a _ Ii
O_
-1.0
,-'3
:
-1.8
L
-2.2 -2.5
L
-3.0 -3.4
I 75
I 65
55
I 95
I 85
ELONGATION
I
1 281
I
I 105
I 115
u
-1.8 -
E
-2.2 --
E
-2.5 L
Z
-3.0
" .o*_,_
I.
o,
-
-3.4 -50
125
°
I 50
I 150
(DEGREES)
I
I
1.28 -
I
I
1.24 1.20
1.20 -
1.16
1.16 "--
1.08
o
o °,_
,,"
°., "_ _,:.;. "_• el'.--:= t_-
•
1.04 1.00
,
•
1.08 i-
. .... °"
Zl.04
._-_:..-..,.:'__.-.
---
.96
•
.92
;,,,
.o
f
I
°
-_'.-
°-°°
55
I 65
I 75
,,,.
I 85
ELONGATION
F.1
(c)
Gain
and
I 550
650
I
i
I
I
_
,
_.:
'
;'
.
-
_-_°''' •_ _,..1
o
.;.. --
..
o
_'
. .._-:::._. ;.-:_
°,,, :. °
I 95
I 105
.80 .75 115
125
: .--
.88 .84
o
.84 .80 25
r
" .°.
.92., .
_ 450
:,.
_,.
.88
I 350
"-'-
1.12 -
1.12 ,t"
I 250
SOP
1.24
Figure
*
-1.4"
L
-1.4
Z 5
"
LL >,-1.0
-50
_ 50
• "...... ..
i 150
corrections
.:_ ..,
i 250
! 350
versus
F-6
elongation
and
SOP,
. - • _-
I 450
SOP
(DEGREES)
offset
.
60/am
l 550
.
650
APPENDIX Zodiacal
Dust
Cloud
G
Modeling
Using
IRAS
Data
J. Good G.1
Overview A physical
model
for the
interplanetary
dust
cloud
was
model consists an inclination
of spatial distributions for the dust volumetric and line of nodes for the cloud, and a simple
emissivity
a function
as
as r -ls distance
of wavelength.
The
coordinates
and
z is the
distance
from
density drop-off differs from the r -13 power measurements of scattered sunlight, but the dust
decreases
The
IRAS
consequently comparison and
IRAS
emissivity
was
x exp[-4.97(lzl/r) 126] and the temperature as R -°a6, where from the Sun in spherical coordinates, 7" is the radial distance
cylindrical
the
volumetric
fit to the
emissivity and parameterization
Price
data
heliocentric
are
plane
law for the discrepancy
This
found
to vary
R is the radial from the Sun in
of symmetry
of the
dust.
This
dust density deduced from Helios can be explained if the albedo of
distance.
limited
to
solar
elongation
angles
between
60 ° and
120 ° and
are not sensitive to material closer to the Sun than about 0.9 AU. However, of the predicted model flux and Zodiacal Infrared Project (ZIP) data (Murdock 1985)
agreement
with
the
data.
temperature, of the dust
which
in shape
looked
(Figure
to within G.1),
22 ° of the
though
there
Sun
at
10 and
is a calibration
20 #m
scale
shows
excellent
discrepancy.
It also
implies that the r -1'8 power law is good to 0.4 AU. The inclination of the zodiacal dust cloud is 1.7 ° and its line of ascending nodes is at 69 ° ecliptic longitude, substantially different from the 3.4 ° and 87 ° deduced from the Helios measurements. However, since the Helios
measurements
were
to material
outside
sensitive symmetry
plane
The
model
calibration. that
the
with
between
presented
here
and
is based
offsets
on the
of IRAS
require
the
variability
of the
and
the
IRAS
differences
infrared
IRAS data
small
Supplement, 19 July 1993). Consequently, zodiacal dust cloud need reinterpretation. curately
1 AU these
data
is primarily
to variation
of the cloud
distance.
comparisons
gains
0.3 and
0.9 AU, we attribute
heliocentric
Preliminary IRAS
made
data
with
change
the
and
after
COBE-DIItBE
data
(§IV.D.3
the physical However, the
background
as understood and
DIRBE
the
Explanatory
parameters deternfined for purpose here is to represent the
current
model
final
suggests
does
that
the acquite
well. G.2
Data Tile
acal
IttAS
dust
cloud.
data
provide
First,
us with
the sheer
an unprecedented
volume
of data
makes
opportunity it possible
to investigate to fit for a large
of dust cloud parameters unambiguously. Furthermore, the extremely allows differentiation and exclusion of Galactic IR structure. Finally, age
(7
140 pm
in four
bands)
allows
concurrent
information. G-1
extraction
the
zodi-
number
high signal-to-noise the spectral cover-
of temperature
and
emissivity
-8
10
10 .9
"C
0-10
_
-11
10
-
m
m
I
-12
10
0
I
I
I
30
I
I
60
I
I
I
90
I
I
I
I
120
I
I
150
I
I
180
Solar Elongation Figure
G.1
ZIP
data
(Murdock
and
Price
1985)
showing
zodiacal
brightness
ecliptic plane as a function of solar elongation. The dashed curve represents flux (scaled by a factor of 1.5) from the zodiacal dust cloud model.
G-2
the
in the predicted
The
IRAS
orbital
satellite
plane
through
roughly
the year
during
normal
pointed
pole
half
orbit
from
the
Sun
by varying
from
the
Sun
(the
The
solar
elongation
The
azinmth
-90
° when
scan. the
(i.e.,
Since
back
The
sky
tant fluxes
and
by as much
the
part
appendix
satellite out
north
with
ecliptic
of the
orbit
from
but
the
angle)
has
the
side
pole
any
given
rate
or away
come.
+10 °.
defined
to be
of the
Earth
of the opposite
in the
of the
be
s -1).
within
direction
Many
will
angle
(3.84'
in the
of 0 ° looks
plots)
ecliptic
toward
is arbitrarily
the
path
sky at a constant
increases
on
Earth on
either
the
precessed scan
during
was usually
an inclination
(particularly
from
azimuthal
normal
occurred
a line
tilted
with
orbit
nominal
on the
a constant
and
The the
however,
was
pole
G.2),
which
traced
a cone
inclination
(see Figure
direction
and
oriented
G.2). Thus
In practice,
as -I-30 ° from
to as the
in the
given
Earth's
coordinate
in this
solar
system. observed
modeling often
through
(Figure
G.3)
play
be
four
wide
(IRAS
to use the
distance
will
the
angle)
in this
was
for the
other)
elongation
of motion
100 #m
heliocentric
Earth
Sun.
swept
passes
elongation/inclination
the the
It then
descending
references
to the
(referred
satellite
the
25, 60, and
pole
from
from
(Figure
to the Sun.
amounts.
varied
direction
plane
angle
one
solar
away
of 99 ° inclination
vector
orientation
90 ° away
angle
the
Earth's
orbital
from
orbit
Sun-Earth
constant
directly
in a plane
in a near-polar
to the
to maintain
an orbit
to ecliptic
was placed
exact
bandpass
an important
given
bandpass
Explanatory role
in in-band
filters,
shape,
in the
Wm-2sr
nominally
Supplement
-1
since
temperature
observed and
infrared
only
centered
1988, §II.C).
variations flux.
converted
at
12,
It is imporwith
Consequently,
to MJy
sr -1
when
appropriate. Almost to pole.
6000
Of these,
elongations shown
and
were
made
200 scans
were
which
in Figure The
scans
uniformly
major
portion
of the
The
become
at 100 #m.
dominant
noise
is too small
to be a major local
minima
devised
G.3
mission,
which the
about
were
time
1700 of which
representative
period
of the
went
of the
mission.
from
range
pole
of solar
A typical
scan
is
flux seen
in the
that
It is important on these fitting
of "lower
this problem
no zodiacal flux.
at 12, 25, and
variations
to note
plots; since
envelope" on the
that
the typical it implied rather
will be discussed
emission
60 _m is due to the
zodiacal
are left are due to Galactic these SNR that
than
the
the
in the section
sky that
was not
fluctuations
is about
are
1,000).
model
data
should
as a whole.
on fitting.
contaminated
emission
sources,
which
not
This
noise proved
be fit to the The
method
At 100
/zm there
by a large
amount
of Model
Density An
most
chosen covered
local
to show
problem
Description
G.3.a
small
in a kind
to handle
was almost of Galactic
the
G.4.
we wish to model. (the
during
adequate
important
variation
of dust
Poynting-Robertson
representation factor
for
in modeling
density effect)
with
the
of the
heliocentric
would
produce
spatial observed distance a radial G-3
distribution infrared (where distribution
of the flux. the
zodiacal
A simple dust
spirals
proportional
dust model in due to r-1
is the for the to the (Briggs
ECLIPTIC POLE ((_=270) INCREASING
TO SUN
SCAN
\ \
Figure
G.2
The
scanning
geometry
of the
IRAS
nate system is defined by the solar elongation angle the inclination angle ¢, which changes at a constant
G-4
satellite O, which rate.
is illustrated. remains
The fixed
scan
coordi-
for a scan,
and
I
I
I
I
I
I
I
I
I
I
i
1
I
I
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I
i
O --LO
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o q',1
D
o_
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uo!ss!msue_±
G
eA!_,eleEl
.5
1. In this study the radial part of the r -_ where a is a free parameter (r is the radial in cylindrical The data,
Leinert
of density
Wikan
1980)
study the z-dependence free parameters. In practice, our
used
not
that
that
density
same
p0, ol, fl, and
G.3.b
Temperature Gray
distance)
when
(with
heated
as R -°'s.
However,
ideal
Consequently,
case.
a free
parameter.
with
variation The
heliocentric
The
diameters
by the
complete
the
can
]
constant
distance
at 1 AU (T0)
of the
to deal
local
6 are
To and
G.3.c
Emissivity The
of the
emission
IRAS
band
free
parameters
behavior passes
However,
it became
clear
necessary
to attenuate
the
of solid
making
from
fitting
(where
emissivity
that
this is a level
the
60 and
of complication
out to some
that
unwarranted
that
6 is
a constant
(2)
infrared
a long
wavelength
6
data
then and
the
is complex
and
the
breadth
composition.
emissivity emissivity
drop-off
was
produced
(Roser and Staude 1978) 10 to 25 #m region but fall
drops the
Sun).
about
(a flat
Consequently,
(A0) and by the
from
statements
predictions
wavelengths.
G
this
properties.
distance
definitive
model
cutoff
varies
as R -_ where
It is assumed
dust
that
will disturb
to vary
Models of dust grain properties are reasonably constant in the
r] = 1 - 3) for longer
is constant
radial
in the any
100 #m
temperature
K
R is the
particles
precludes
too much flux in these bands). indicate that typical materials off as t-,1
(and
heliocentric
is
r = To(Ro/R) where
coordinates.
with
or wavelength
is also free.
temperature
(I)
albedo
temperature
with
complete
is then
(r, z) are cylindrical
with
is sufficient
and
cm-'
of properties
the
3' are
cross-section
however,
cross-section
rise to an equilibrium
we allow
In this
= 1AU, z = 0).
absorption
and
models and
absorption
be used,
R0 = 1 AU, and
fit Helios
] where/_
volumetric
form
To
appropriate.
exp[-3(tzl/r)_
× exp[-#(lzl/r)
study
clear.
Collision
be more
po = p(Ro
>2>wavelength
temperature
description
is less
Sun will give
in this
distance
but
value
7 are free parameters,
particles
form
volumetric
p(r,z) = po(Ro/r) where
2] might
functional
of the
ecliptic
of exp[-2.1(Izl/r)].
exp[-/_r
a reference
description
of the
to be of the
the
the
of p(r, z) with
plane
a z-dependence
is assumed
We will assume
complete
of the
indicate
we model
description The
out
et al., (1978a)
and
p(r, z).
is assumed to vary as distance from the Sun
coordinates).
variation
(Trulsen
density distribution component of the
et al. 1981) vary as r -k
this study as A-_.
has used
In practice,
two parameters,
an
even
A0 and
r/,
cannot be fit simultaneously (they are to() strongly correlated). _Vetherefore arbitrarily choseto let r! = 1 (Mie theory for spherical particles). This approximation will be shown to have no effect on any of the parametersother than A0. The complete description of our model for the emissivity is
eo e0(_/A0)-'
e= where
Ao is a parameter.
volumetric G.3.d
absorption
Cloud The
have the
zodiacal
dust
cloud
in different the
is assumed
relative
angle
to tile
i and
will be in error
to detect
and
will be subsumed
by no,
the
is allowed
to
cross-section.
an inclination
symmetry
e0 is an unknown
(3)
Orientation
inclination
nodes
In practice,
< Ao __ > A0
parts
presence
the if the
of the
ecliptic.
This
line
of ascending
cloud
is warped
solar
of such
to be azimuthally
system
introduces nodes
and
in the
two
ft.
thus
(Misconi
discrepancies
symmetric The
has
but
more
different
1980).
free
of azinmthal
inclinationslines
We should,
residuals
parameters:
assumption
of
however,
be able
to the fit as a flmction
of solar
elongation. G.3.e
Constant
Background
It became only
apparent
is unclear;
it could
component COBE
each
that
the
on the
sky.
A detailed
comparison
with
may
resolve
this
for the
a total
of fourteen
temperature,
However,
the
free
parameters
parameters
emissivity,
as inentioned
and
previously,
simultaneously
to 13. Although
Fitting
ZIP
origin
emission of this
an isotropic
(Murdock
could
extra
flux
background
and
Price
1985)
or
this
scan.
z-dependence temperature
simple
Such
of the and
to generate
a fit gives density
is insensitive
To determine fllll time
the
cloud
model
therefore,
of parameters
the
may
for the and
to derive total
seem
(samples)x4 to make
(four
orientation,
it is impossible
and,
number
in our
four
values
number
density, for the for both
of parameters
excessive,
the
number
of
(bands)]. It will be shown a unique solution possible.
Procedure
It is relatively
the
represent
the
zodiacal
The
Parameter_
emissivity
of one
of the
band.
uncertainty.
degrees of freedom is large [_ 200 (scans)x360 that these parameters are sufficiently uncorrelated G.4
shape
in each or it might
are thus
is reduced
fitting introduced offset,
background). of the
the were
a calibration
Model There
offset
be
data
G.3.f
two
during
be fit if a baseline
range
the
cloud
of tile
a model
a moderately but
does
to the orientation mission
that
good
is capable
estimate
not
do well on
cloud
inclination
parameters
(equivalently, G
radial
and requires
the 7
the
of fitting
of the
range
one
paraIneters
wavelength defining
dependence
the
of density
or
line of nodes. several of Earth
scans
spread
orbital
out
over
longitudes).
In addition,
to
requires
use of the
the
determine
temperature
and
Preliminary
fitting
1986)
gave
than
the
values
those
with
dependence
elongation
emissivity of our
for
and
radial
of solar
the
a subset
effort
the
addition
to its by some
a smooth
Galactic
celestial
zodiacal
Finally,
we must
and
data
of the
parameters
fit but
fit (further
dust
We
are
cloud),
used
amount
and
(Good,
with
temperature
to constrain
fit all four much
the
at once.
and
higher the
fully
bands
Hauser
emphasizing
fitting can
to both
simultaneous
Gautier
uncertainties
need
flux
integral
along
any
conclusion
that
to the
for the
¢ are
as described function,
above R_o(1)
wavelengths at time
the
elongation
full
[with is the
._o = (12,
t.
Positions
25,
60 or 100 #m)
in (rc, Zc)-space
orbital position of the Earth at time orientation of the dust cloud.
are
be sensitive
of the
the
to
cloud
above.
The
using
method
a
of least
]
not
e is the
calculated
p(r, z) and
ecliptic)].
B)_(T)
vector
eccentricity
with
in the
(e, 0, ¢) taking of the
T(R)
is the
combination
unit
from
(4)
dl
observation,
detector/filter
t (including
on
of the
by
of the
and
is out
position
amounts
200 scans
using
p(r_,z_)B_(T(R))de
of the
same
described
of all
parameters
coordinates,
response
of scans
[/0
inclination
(re, zc in cloud spectral
the
derivation
estimates
scan
to separate
different
accurate
full subset
is given
R,ko(,,_)
and
an
the
a single
will implicitly
model
line-of-sight
J_min
0 and
covering
through
simultaneously
to generate
[Am'_
FAo(O,_),t)-_
(i.e.,
cloud.
parameters, It is impossible
if two scans
given set of model parameters, and b) to adjust squares until the best fit is achieved. The
model light.
to the
fitting is a)
the
times
scans
be due
to the
fitting
but
at different
only
forced
in the
all
of Galactic
in one scan,
observed
which
requires
procedure
to constrain
are
therefore
parameters
inability unknown
component
sphere
variability,
where
angles.
properties
model
a poorer
of density
set).
In
time
with
credible
contaminated the
full range
to estimate
present
parameter
accurately
Planck nominal
direction into
Earth's
are
(0, ¢)
account
orbit)
the
and
the
To generate the model scans, the flux several lines of sight and over the bandpass.
from the Thirteen
model cloud was integrated along reference points were used for each
scan,
-90 ° and
+90 ° but
spread
ecliptic
out
plane
between
where
points
was
interpolated,
of the
real
data
integration Each slightly. ferences
the
points.
is typically parameter The between
updates to the eters converged.
inclination variation using The
variations the estimated
was a cubic
most
of the model
The
under
between
resultant
tension,
this
concentrated
toward
flux for the
to give model
interpolated
reference
fluxes
function
and
the
for each a full flux
0.05%.
model
nominal
extreme.
spline
difference
less than in the
angles
(the
model model
thirteen with
and
the
parameters.
respect real This
G-8
described to these data
were
procedure
above)
was
then
perturbations then was
and
combined
iterated
perturbed
until
the
dif-
to generate the
param-
As mentioned but
Galactic
the
model
weight
previously,
structure. (when
to
exclude
incorporated
into
the
scheme.
the
longer
G.4.a
The cients
the the
results
galaxy
become and
points
the
zodiacal
envelope" Galactic
zodiacal
background
are strong
positive
accurate) (lust
since
should
bands.
approach
be given
Such
an uncertainty
our model
between
the
to the 200 scans
parameters
are
are shown
shown
point
be biased,
in Table
in Table
elongations and times) are shown in Figures G.4, of parameters, even the highest of the correlations on
p and
T) is quite
in our
from low
can
be
is part
of
especially
at
model
small.
We therefore
is justified
and,
G.2.
the
coeffi-
Representative
scans
G.5 and G.6. Considering (0.91, between the power
conclude
moreover,
G.1 and
that
that
the
inclusion
they
are
all
of all
required
properly.
Model of Parameter
Density
Parameter Values
Temperature
Emissivity
G.1
Values
and
Uncertainties
of Parameters
Po = 1.439 -1- 0.004 c_ = 1.803 + 0.014
Units cnl-
x 10 -2°
unitless unitless
7 = 1.265 -t- 0.003
unitless Kelvin
To = 266.20 + 0.18 6 = 0.359 + 0.004 _o = 37.75
unitless
+ 0.09
[/, In
(fixed)
r/=l Orientation
1
+ 0.024
/3 = 4.973
0 = 68.61
+ 0.03
degrees
i = 1.73 4- 0.01 Offsets
noise
a very
a weighting
for each
the fit would
are not excursions
emission.
Table
Class
the that
reasonably
process
"lower
by the
of fitting
parameters data
has
above
those
Results
law exponents fit the
fluctuations
least-squares this
of correlation
free
model
Without
(for several the number the
the
wavelengths,
Model
the
Consequently,
degrees
12 #m = 35.53
4- 0.15
x 10 -s
Win-
25 #m
= 49.97
4- 0.14
x 10 -s
Win
60 #m
= 2.19 4- 0.03
100 #m = 5.24 4- 0.07
G
9
x 10 -s x 10 -s
2 sr-
1
sr-
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W111-
2 s r-
1
Will-
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1
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Inclina'don (degrees)
Figure (solid
G.4 line).
as bumps is Galactic
A typical This
scan
at the ecliptic emission.
IRAS
Inclinal_on(degrees)
pole-to-pole
was at a solar plane
scan
elongation
(inclination
with
the
zodiacal
of 90 °. The
zodiacal
180 °) and
G
10
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dust dust
cloud bands
remaining
model
fit
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105
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i 180%
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Inclination (degrees)
InclinaSon(degrees)
Figure G.5 of 112 °. The
1 ,_ 0
dust cloud model and less intense
farther
from
the
Sun,
G
11
height.
prediction than those which
for a scan in Figure
is both
cooler
at solar elongation G.4 since this scan and
has
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z
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Inclination(degrees)
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model
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G.5
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is observing
G
12
for a scan for
these
material
data. closer
at solar These to the
elongation profiles Sun.
are
Table Correlation
Coefficients
G.2
Between
Model
Parameters
Parameters Offsets 25 -.11
(pro)
60 0.00
100 0.00
p0 0.30
0.06
0.01
-0.52
0.03
-0.06 -0.02
a 0.24
/4 0.24
7 0.18
-0.28
0.27
0.19
0.56
0.32
-0.08
0.04
0.03
0.08
0.09
-0.31
-0.04
-0.02
0.01
0.01
0.02
0.02
-0.05
-0.01
0.25
0.0
-0.86
-0.55
0.31
0.20
-0.77
-0.91
0.12
0.89
-0.08
-0.08
0.1
-0.47
-0.19
-0.06
-0.11
0.12
-0.56
-0.10
0.18
-0.09
0.73
To -0.44
6 -0.26
A0 0.00
_ -0.05
0.34
-0.11
-0.17
0.78
-0.09
i -0.01
12#m
0.04
25tim
-0.01
60pro
0.00
0.14
-0.19
0.06
-0.16
100#m P0
7
To
0.11
-0.05
-0.09
-0.0
-0.05
Ao
-0.09
Ttle
complete
volumetric p = 1.43
and
the
temperature
emissivity
x 10-2°(Ro/r)l8°
implications
here,
but
terms
of these
some
are
background The various
materials
(eg., about
olivine,
approximation long the
wavelength IRAS
filters
126]
by
(5)
CFI1-1
properties (Roser
30 pm
and have
but
the cloud
emissivity
material Models
1978)
crude, relatively finer
flat
drop but flat
are extremely
results
emissivity
that
several
very
uneven)
analysis
of the
of our between
is needed.
Both
of these
approximation
uncertain,
likely
and
10 and
although
tile
a decreasing
of the dust.
for the
properties
to beyond
30/tin.
their
behavior
candidates
emission
3) out
fit require
composition
G - 13
will not be discussed
absorption/emission
off as A-'_ (n = 1 -
the
(6)
effect.
of the
show
(though
terms
it is a crude
a calibration
of the dust high.
parameters
background
because
quite fairly
and
orientation
and
emissivity
Staude
then
is very
precludes
K.
well be merely
is probably
obsidian)
10 and
exp[-4.97z/r
is given
°'36 and
the
it may
emissivity
emissivity
of the
ambiguous,
because
overall
profiles
discussion
quite
description
by T = 266(Ro/R)
The
distribution
The
dust
between
100 pro. emissivity large
for
width
Our at of
References Briggs, R.E. 1962, Astron. DIRBE Center
Explanatory (NSSDC).
Good,
J.C.,
IRAS
Hauser,
H.J.
and
T.N.
in Space
Atlases:
Habing,
P.E.
and
Leinert,
C., M. Hanner,
H. Link
Leinert,
C., M. Hanner,
I. Richter,
Leinert,
C.,
Misconi,
N.Y.
Particles
in the
Mukai, Murdock, Roser, Trulsen,
T.,
and
1980, Solar R.H.
T.L.
and
S., and
H.J.
J., and
"The
Giese S.D. Staude
A. Wikan
and
B. Planck
eds. 1984,
Price
1980,
I. Halliday Astron.
1985,
1978,
Plane
Astron. Astron.
1988,
of the and
Aatron. Astron. Zodiacal
B.A.
Y., 90, 375.
A_trophys., Astrophys.,
G - 14
C.A.
87,
381.
91,
155.
of the
Data
Zodiacal COSPAR
Beichman,
G. Neuge-
D.C.:GPO). 63,
183.
Astrophya., A_trophya., Astrophys., Cloud
Mclntosh,
131,355.
Science
of the XXVIth
ed.
Astron.
1981,
Space
Observations
A_trophys.,
1980,
Astrophys.,
Aatron.
IRAS
(Washington,
1978b,
E. Pitz
by National
Proceedings
Astron.
E. Pitz
Symmetry
System,
1986,"
Chester
1978a,
and
and
1986,
Supplement T.J.
E. Pitz
E. Pitz,
distributed
Research
and
C., M. Hanner,
1993,
Gautier
Explanatory Clegg,
Leinert,
I. Richter,
710. 19 July
and
in "Advances
Catalogs
bauer,
Supplement
M.G.
Background, Meeting.
J., 67,
Near
84,
119.
82,
328.
103,
177.
1 AU",
(Reidel:Dordrecht),
in Solid 49.
APPENDIX Zodiacal
H.1
The
IRAS
ZodiacM
problem
2.0,
which
that
are
outlined
found
in Version
All references 3.1. The proved
to Version
major and
rerun
change,
History
Version
improvements
and
History Version
File 3.0
(ZOHF)
Introduction
It replaced
was
H
below.
3.0.
with
the
were
improved
processing
to be an exhaustive
essential
information
of the
in the
calibration.
effects
Other
improvements, Results
and
The
changes
of the
to enable
baseline
Version
ZOHF
tests
a researcher
to use
below.
was
IRAS
included
presented.
3.0 or its the
a
to Version
a format change, This
analysis.
ZOHF
im-
survey
a sampling
are
Version
of
fixed
is given
entire
improvements,
ZOHF
3.1,
calibration
The
to the
in 1988.
a number
are applicable
incorporated.
position
by IPAC
its effect
in §H.8
of tile verification
description
is presented
than
were
in 1990,
problem
other
released
3.0 incorporates
release
appendix
calibration.
changes.
intended
3.0 was Version
A subsequent
for hysteresis
calibration
Version in 1986.
A statement
improvements
additional
(ZOtIF)
released
3.0 in this
corrections
several
File was
Version
is not Only 3.0
product. The
ZOHF
are, however,
Product The
data
seconds pixel 2.0. focal
Version
all detectors,
of time. sizes
Due
remains problem
the
differences
a systematic is discussed
final
at the
calibration
few-percent
of the level
IRAS
between
difference between ascending and in the section on anomalies below.
data.
observations. descending
There In scans.
Description
ZOHF
from
3.0 incorporated
still calibration
particular, there This systematic H.2
Version
This
are given to elimination
3.0 was created except
the
resulted
in Table
in the same
1/4
sized
manner
detectors,
in an approximately H.1.
of the
The
smallest
beam
sizes
detectors,
as the previous were
square
Table Pixel
Wavelength (_m)
Sizes
have
not
are not
Pixel
H.1 for
ZOHF
Size (arcminutes)
In-Scan
Cross-Scan
12
30.8
28.4
25
30.8
30.3
60
30.8
28.5
100
30.8
30.5
H
1
beam
they
plane.
boxcar
changed the
versions.
averaged 0.5 ° wide. from
those
full width
IRAS
over
eight
The
exact
in Version of the
IRAS
H.3
Format The
record
2.0 to give H.2.
format
UTCS
of the
ZOHF
in centiseconds
Version
instead
3.0 has
of seconds.
Table Format (Replaces
name
description
format
format
of Version
is given
Version
Explanatory
Supplement
1988)
units
type
NSOP
SOP
Number
I3
NOBS
OBS
Number
I3
7
NUTCS
Time
UTCS
1
in Table
3.0
1
centisec
I10
Inclination
degrees
F6.2
Solar
degrees
F6.2
degrees
F6.2
17
INCL 1
23
ELONG
29
BETA
Ecliptic
35
LAMBDA
Ecliptic
degrees
F6.2
41
I_
12 #m
Brightness
Density
Jy/sr
E10.4
51
I_,_
25 tim
Brightness
Density
Jy/sr
E10.4
61
1,3
60 #m
Brightness
Density
Jy/sr
El0.4
71
I_,4
100 #m
Jy/sr
E10.4
to page
X-62
1
of tile
IRAS
Elongation Latitude Longitude
Brightness
Explanatory
Density
Supplement
1988
for definitions.
Processing Several
in Version different Version
improvements 2.0 was
in data
corrected.
calibrated
using
Version
In total,
Version
3.0.
processing
The
from that of Version 2.0 was included for
be properly
prior
new
the
4
Refer H.4
in IRAS
byte
The
from
H.2
of ZOHF
old version
changed
set
were made
of observations
average
position
3.0 and
in Version
an error
3.0 is slightly excluded from that could not
the
excluded
new
stimulator
3.0 contains
extraction
0.07%
fewer
glitches
method
were
observations
were
removed
than by
Version
a deglitch
from 2.0.
processor
data used in tile ZOHF Version 2.0 were destriped with an algorithm the gain and offset of each individual detector in a band to match those of all detectors
should have and did not An
contained
Version
2.0. A small set of survey scans erroneously the first time in Version 3.0. Observations
Radiation spikes and other electronic to resampling the data (§III.A.3).
The adjusted
for ZOHF
in that
band.
This
destriper
little effect since the destriper left the affect the striping caused by calibration
error in-scan
was
found
in Version
by 115" for half
2.0
and
of the mission H-2
was
used
for Version
average value of the variations between
corrected data.
not
in Version
Improvements
ZOHF scans.
3.0 that in the
which of the
3.0.
unchanged
advanced
satellite
This
the
pointing
reconstruction made to support the IRAS the
ZOHF
to the
Version
resolution
The
impact
ZOHF
interval
adjacent
adjacent in-scan to Version 2.0.
The
of the
sampling
between
H.5
3.0.
ZOHF
pixels.
pixels,
of these
Source
Survey
improvements
1992
were
is generally
incorporated
not
large
in
relative
(§III.A.3).
in the
in-scan
Paint
Version
Because
the
3.0 is eight
ZOHF
the file size of Version
seconds
Version
and
there
2.0 was made
3.0 is reduced
by a factor
with
is no overlap overlapping
of two as compared
Calibration Several
detailed H.6
important
in §III.A.2
Analysis Several
characterize H.6.a
Gain
minima
analyses
it with
respect
and
the
approximately for Version a linear sources
in the
IRAS
calibration
software.
the
Version
These
are
done
at IPAC
to Version
intensities, The
covered
given
expected
mission
offsets
of these
in Table
H.3.
from
calibration
extremes
to the during
and
3.0 observation
the of gain
ZOHF
3.0 data
and
detector
Gain
and
Offset
Compared Wavelength Coefficient
Band
GAIN
OFFSET -1)
The
and
was linearly
fit to its counterpart
fits
as
changes
offset
nonlinearities
as well
mission are
mean that
caused
encountered
the
maxima
and
gain
and
were
implemented
by
attempting
when
especially
offset
bright
(#m)
H.3
of each
Version
to each
Version
Mission
Error
Mean
Mean
3.0 2.0
Observation Observation
of (1 c,)
Mission
Mission
Maximum
Minimum
12
0.896
0.013
1.083
0.685
25
0.919
0.022
1.420
0.713
60
1.075
0.042
1.344
0.706
100
1.031
0.082
1.999
0.505
12
-0.028
0.072
.441
-0.680
25 60
-0.158 -0.008
0.065 0.021
0.452 0.120
-1.092 -0.142
100
0.014
0.018
0.227
-0.118
g
--
3
is
to fit
a scan.
Table
(106 Wm-2sr
to verify
2.0.
Version
gain
are
value
The
each
average
mission the
3.0.
were
Offset
transformation are
made
Supplement.
general
2.0. for
of this
were
Results
To compare in Version
changes
H.6.b
Position The
cumulative
effect
of the
position
correction
and the
improved
can be shown by differencing the position given in the ZOHF Observation Parameter File for each ZOHF record in Versions Parameter
File
is an internal
scan
to an accuracy
Note
that
Version Version would
Version 2.0.
3.0 positions
are
20".
Histograms
3.0 compares
It should the
file that
of about
much
also be noted
2.0 Observation reflect
IPAC
actually
to the
both
does
better
not
than Table
differences of the
It is likely
histogram
the
of Comparison Observation
Difference
(")
Version
of ZOHF Parameter
Positions File
Version
3.0 (%)
2 (%)
39.0
37.7
10-20
15.7
23.6
20-30
9.1
17.4
30-40
5.9
12.0
40-50
4.2
7.0
50-60 60-70
3.3 2.7
2.1 .1
70-80
2.5
**
80-90
2.2
0.
90-100
1.9
0.
100-200
11.9
0.
200-300
1.5
0.
300-400 400-500
** **
0. 0.
500-600
0.
0.
600-700
**
0.
700-800
**
O.
800-900
O.
O.
900-1000
**
O.
1000-2000
**
0.
**
0.
** represents
a percentage
H-4
< .05
the
for each
in Table File than
compared
Parameter that
shows.
0-10
>2000
were
H.4
Histograms with
given
Parameter ZOHF
scheme
predicted in the The Observation
information are
3.0 Observation
exist). the
the pointing
Observation
versions
File (a Version
pointing, slightly
of these
better that
Parameter
improved
summarizes
interpolation
to a position 2.0 and 3.0.
File, ZOHF
H.4. does to the which
Version
H.6.c
Calibration M.G.
Verification
Hauser,
L.J.
formed extensive Their results are If the the
calibration
during
daily
TFPR
t)rightness between
H.1.
scatter
were
some
the
survey
is seen
should
measure
of the
agree
with
stability
Flight
and
the
TFPR
the
these
3% at 12 and
TFPR
used
during
two
of the
model
25 ttm,
per-
of the
model
uncertainty and
have
consistency.
brightness
between
and
TFPR
Center
calibration
tile
discrepancy
of the
to be approximately
level
perfectly,
The
observations
Space
noise
working
observations.
gives
at Goddard
checking
observations
calibration
difference I00
J. Vrtilek
system
survey
baseline
The
and
analyses of the ZOHF summarized here.
IRAS
measured
Rickard
values
baseline.
is shown
of The
in Figure
4% at 60, and
8%
at
#m. We should
model
that
TFPR
be able
we used
model
that
part
This
check
variability
due
seriously.
descending H.7
model
accurate
Hauser
the
same
variable
part
et al.'s
check
of the
variable
of the symmetry the
the
and
free
the
and
et aI. also
scans,
see §H.7
of the
ZOHF
zodiacal
that
data
alone
enough
systematic
the
differences
part
both
drift.
of the
reproduced above.
ecliptic
poles.
Derivation
is unreliable
to affect
TFPR
discussed
cross
of baseline
of the
dust
consistency
scans
effects
survey
of the
internal
of survey the
are large found
plane
model's
ends from
from
not eliminated
survey
ZOHF
Hauser
to within
to eccentricity are
the
calibration.
by differencing
quite
drifts
from
inclination
TFPR
is done be
baseline
in the
to the
of the
It should
term
due
to re-derive
of the
because
calculated between
residual
eccentricity ascending
and
below.
Anomalies Several
which
users
progress
with
plane
than
are
the
Note
that,
in the
Version
decreasing ascending
IRAS
2.0 have
ecliptic scans
orbit,
found
latitude)
(scans
descending
are
that
the
descending
systematically
which
progress
scans
always
with
brighter
increasing
look behind
scans
(scans
at the
ecliptic
ecliptic
the
latitude.)
Earth
in its orbit
while ascending scans always look ahead. We have investigated this effect and found that a discrepancy on the order of 2% (2% at 12 and 60 ttm, 1.5% at 25 tim, and 4% at 100/_m) is seen the
at the
north
ecliptic
sets
of scans
are
two
zero.
The
error
This the
detector
after
DC
the
at the
same
could
pole
crossing was
a scale
few-percent
level.
the
to the
survey
scans
following
an
group
of scans,
which
to the
scan
SAA are
further
part
the
after
to vary
the
This
descending These
scans
have
SAA
and
H
5
are
AC
in the
only may
dominate
the fluxes
predominantly
At the
DC
and
first
be
response
of
implemented
for the not
pole
should
calibration.
model
response
assumption
elevated
scans. difference
DC gain
The
derived
the
scans
the
effect
(SAA).
was
with
and
of the
hysteresis
SAA
linearly
descending
sky
Anomaly
AC response.
from
and
of the
uncertainties
Atlantic
strategy,
crossing.
ascending
by a residual
South
hysteresis
assumed
factor
is within
be caused
for handling
response
by applying
Due
between
at the
difference
in calibration The
seen
pole looking
AC response. was
obtained
be correct
group
relative ascending.
at the
of survey
to the
next
In Figure
H.1, the abscissais the ratio of the measuredflux at the North Ecliptic Pole (NEP) and the flux calculatedfrom the calibration model and assignedto the NEP. This is plotted against the time from tile SAA crossingfor the 12, 25, 60, and 100 tim bands. If the calibration were the
perfect, time
for each
all measurements
axis.
Figure
grouping
In short,
H.2
attributed
to uncorrected
possibility
that
H.8
Zodiacal
some
3.1.
This
No samples
that
the
mean
a large
calibration of the File
flux
observations
ratio
and
fall
population
into
groups
standard
ascending-descending
At this
is a real
along
deviation
time,
feature
asymmetry
we cannot of the
however
can
eliminate
be the
sky.
3.1
for the
ZOHF
a small
Version
number
at 12 or 25 #m,
at 100 #m. Most of the samples affected at 100/_m were lowered
Tile
100 #m.
of the
drifts.
Version
affected
were affected
part
asymmetry
the averages problem
be unity.
at 12, 25, 60, and
History
In calculating included.
shows
of scans
we believe
would
3.0, some
of ZOHF
one sample
intensities
samples
and
at 60 #m and
were erroneously was fixed
in Version
382 (0.03%)
affected were in short low gain observations. 23%, on average, with a maximum decrease
samples
The samples of 45%.
References IRAS bauer, Moshir, 2, JPL
Catalogs
and
Atlases:
H. J. Habing,
Explanatory
P. E. Clegg,
M. et al., 1992, Explanatory D-10015
8/92
and
Supplement T. J. Chester
Supplement
(Pasadena:JPL).
tt-6
1988, ed.
C. A. Beichman,
(Washington,
to the
IRAS
Faint
G. Neuge-
D.C.:GPO). Source
Survey
Version
1.10 12 t.tm X 1.06 £:3 III
_
_
0 UJ n" 13..
_0,,
&' o_o
.
O
0
0 A
1.02
nO
A A
0
A
-......
x
A
A
_ 0.98
o
--
A A
t_
A
0A g
%
_
A
A
A A
LLI > rc
w 0.94 O0
0 0.90 0
I 1500
I 3000
I 4500
I 6000
I 7500 SECONDS
I 9000
I 10500
I 12000
1 13500
[ 15000
1.10 25 I.tm X
1.06 ILl I-0 W n-
1.02
R A
O 0 O O0 0
x
0.98
R ---
l.lJ > rr W ¢/1 rn
R
A
0
0
R
A O
A A
g
A
A
A
A
0.94
O 0.90
0
I 1500
I 3000
l
I
4500
6000
I 7500 SECONDS
I
I
I
I
9000
10500
12000
13500
Figure H.1 Flux ratio at North Ecliptic Pole vs. time 12, 25, 60, and 100 #m. (See text, Anomalies.)
H-7
(seconds)
1 15000
from SAA crossing
at
1.10
60 pm X -J
LL 1.06 a LM t-O a 1.02 LU rr 12. X 3
w
--
w
0.98-
w
)11
II
}i
Q uJ :> rr w 0.94 m 0
t
-
I
0.90 0
I
1500
3000
I
I
I
I
I
I
I
I
45O0
6000
7500
9000
10500
12000
13500
15000
SECONDS 1.10
1O0 p.m x -J
LL 1.06 D LU _t-O n 1.02LM
rr 13.. X :::3 " 0.98 LL a uJ > rr W rj) 0.94 133 O
w
I
0.90 0
1500
I 3000
I 4500
I
I
6000
I
7500
9000
SECONDS
Figure
H.2
H-
(cont'd)
10
I 10500
I 12000
I 13500
I 15000
TECHNICAL
1.
Report No.
4.
Title IRAS
Sky
Author(s)
9.
Per_rming
Survey
Accession
- Explanatory
Name
PROPULSION
Pasadena,
91109
Agency
California Name
AERONAUTICS
Washington, Supplementary
D.C.
No.
5.
Report May
6.
Performing
OrganizaHon
Code
8.
Performing
Organization
Report
Date 1994
Unit
No.
No.
LABORATORY of Technology
Spomoring
Reclplent's
10. Work
ondAddress
Catalog
TITLE PAGE
3.
No.
Supplement
California Institute 4800 Oak Grove Drive
NATIONAL
116.
Atlas
Organization JET
15.
Government
and Subtitle
7.
12.
2.
"94-11
REPORT STANDARD
Ill. 13.
Type of Report
Supplement Atlas
and Addre_ AND
Contract or Grant NAS7-918
SPACE
ADMINISTRATION
!14.
to
Sponsoring
No.
and Period Sky
Agency
Covered
Survey
Code
20546
Notes
Abstract
This Explanatory Supplement accomparfies the IRAS Sky Survey Atlas (ISSA) and the ISSA Reject Set. The first ISSA release in 1991 covers completely the high ecliptic latitude sky, I#l > 50°, with some coverage down to I_I _ 40°. The second ISSA release in 1992 covers ecliptic latitudes of 50 ° > I#1 > 20 °, with some coverage down to J#J 13". The remaining fields covering latitudes within 20 ° of the ecliptic plane are of reduced quality compared to the rest of the ISSA fields and therefore are released as a separate IPAC product, the ISSA Reject Set. The reduced quality.is due to contamination by zodiacal emission residuals. Special care should be taken when using the ISSA Reject images (§IV.F). In addition to information on the ISSA images, some information is provided in this Explanatory Supplement on the/P.AS Zod/aca/H/story File (ZOHF), Version 3.0, which was described in the December 1988 release memo (AppendixH). The data described in this Supplement are available at the National Space Science Data Center (NSSDC) at the Goddard Space Flight Center. The interested reader is referred to the NSSDC for access to the IRAS Sky Survey Atlas (ISSA).
1"7. Key Words Astronomy Astrophysics Astronomical Infrared Infrared Infrared 19.
(Selected
Images
Sky Survey Atlas
Security
Cl_slf.
Unclassified
_f
byAuthor(s)) i Infrared Images Atlas
18.
Distribution
Statement
Images
Sky Surveys IRAS i IRAS Images this repo_) 20. Security
Clmsif.
Unclassified
_fthis
page)
21.
No.
of
Pages
22.
Price
164 JPL
0184
R9183
