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Link to MLS Home Page
The Microwave Limb Sounder (MLS) is one of 10 instruments aboard the
Upper Atmosphere Research Satellite (UARS). Its measurement objectives include
chlorine monoxide, nitric acid, ozone, sulfur dioxide, water vapor, and
atmospheric temperature in the stratosphere and mesosphere. Data collection
began 19 September 1991 and has continued, with a few interruptions, to the
present. MLS data have been processed to levels 1, 2, 3AL and 3AT. Currently,
MLS level 3A version 4 data products are available from the
Goddard Space Flight Center (GSFC)
Distributed Active Archive Center (DAAC).
-
- UARS MLS LEVEL 3AL DAILY LATITUDE ORDERED DATA
- UARS MLS LEVEL 3AT DAILY TIME ORDERED DATA
-
- The MLS level 3A data are a subset of the UARS data Set. The
MLS data are archived as two data products at the DAAC:
- Level 3AL
- MLS level 3AL data are daily latitude- and time-ordered data
interpolated to intervals of 4 degrees latitude at the intersection of the
tangent track of the instrument's line of sight (LOS). Each record consists of
a single array of data of one parameter for a specific time. Level 3AL data
records are written to UARS defined standard latitudes, which range from -88 to
+88 degrees in 4 degree intervals.
- Level 3AT
- MLS level 3AT data are daily time-ordered data, arranged at time
intervals of 65.536 seconds, or about 495 km intervals along the LOS tangent
track. The reference time at which level 3AT data are arranged is common
across all UARS level 3AT files.
-
- MLS measures naturally-occurring microwave thermal emission from the
limb of Earth's atmosphere to remotely sense vertical profiles of
selected atmospheric gases, temperature and pressure. The first MLS
experiment in space is on NASA's Upper Atmosphere Research Satellite
(UARS) with its major objective to improve understanding of
stratospheric ozone, especially ozone depletion due to chlorine chemistry.
-
- The primary MLS data products are vertical stratospheric profiles of
ozone (O3) at 183 and 205 GHz, chlorine monoxide (ClO),
water vapor (H2O), and temperature. Additional data
products which have been obtained from the UARS MLS include
sulfur dioxide (SO2), nitric acid (HNO3),
upper tropospheric water vapor, temperature variances associated with
atmospheric gravity wave activity, and geopotential height.
-
- The MLS Level 3AL and 3AT data files are written in the
Standard Data Format Units (SFDU) format. Each file consists of three
records called SFDU, LABEL, and DATA. SFDU and LABEL records contain
descriptive information about the instrument and the data, such as
start/stop time of the data, number of records in the file, etc. The
DATA record contains the profile data and their standard deviations.
Time, latitude longitude, local solar time, and solar
zenith angles are provided with each DATA record. Each data file is
accompanied by a short ASCII metadata file, which provides descriptive
information such as the start and stop time of the data, file record
lengths, and the UARS quality flag.
After the original level 3A file formats were agreed to, it was
realized that additional parameters were needed to describe the MLS
data. Level 3LP and 3TP parameter files were created to include values
for the MLS diagnostic quantities and retrieval quality indicators.
These are needed to supply reliable interpretation of the data in the
corresponding data files.
Each level 3AL file for a given day is accompanied by a level
3LP file. Similarly, each level 3AT file for a given day is
accompanied by a level 3TP file. The 3LP and 3TP files also consist
of the three record types SFDU, LABEL and DATA, and are also
accompanied by their own ASCII metadata files.
-
- All UARS level 3AL and 3AT files use the same formats to allow for
intercomparisons of atmospheric profiles between the different instruments.
Other UARS instruments which measure chemical species include the
Cryogenic Limb Array Etalon Spectrometer (CLAES), the
Halogen Occultation Experiment (HALOE), and the
Improved Stratospheric and Mesospheric Sounder (ISAMS).
-
- Name:
- Joe W. Waters
- Address:
- Jet Propulsion Laboratory
- Mail Code 183-701
- 4800 Oak Grove Drive
- Pasadena, CA 91109-8099
- Telephone Numbers:
- Phone: (818) 354-3025
- FAX: (818) 393-5065
- Electronic Mail Address:
- joe@mlsrac.jpl.nasa.gov
-
- Microwave Limb Sounder
-
- Name:
- MLS Data Manager
- Address:
- Jet Propulsion Laboratory
- Mail Code 183-701
- 4800 Oak Grove Drive
- Pasadena, CA 91109-8099
- Telephone Numbers:
- Phone: (818) 354-1995
- FAX: (818) 393-5065
- Electronic Mail Address:
- mlsdaac@jplrac.jpl.nasa.gov
The MLS instrument's major objective is to improve understanding
of stratospheric ozone, especially ozone depletion due to chlorine
chemistry. The MLS experiments measure naturally-occurring microwave
thermal emission from the limb of Earth's atmosphere to remotely sense
vertical profiles of selected atmospheric gases, temperature and pressure.
-
-
- The UARS MLS instrument is a limb sounder. It views perpendicular
to the orbital velocity vector from the never illuminated side of
the of the UARS satellite. The satellite's altitude of 585 km permits
the elevation scanning MLS to view the atmosphere at tangent points
about 22 tp 24 degrees below the orbital track. When the satellite
faces forward in the direction it is moving with the MLS viewing the
non-illuminated side, a latitude coverage of 34oN to
80oS is provided. When facing backward, the coverage is from
80oN to 34oS.
The UARS MLS instrument has three assemblies: sensor,
spectrometer and power supply. Thermal control of the sensor is
radiational by louvers, with in-orbit
temperature stability of approximately 0.01oC or better,
allowing "total power" measurements which do not
require fast switching to a reference. The overall instrument mass
is 280 kg, power consumption is 163 W
fully-on, and data rate is 1250 bits/second.
-
- Satellite data are collected from a near-circular Earth orbit of
about 585 km altitude and 57 degree inclination.
-
- Upper Atmosphere Research Satellite (UARS).
-
- UARS was launched September 12, 1991 with the mission of investigating
the chemical and dynamical processes of the Earth's upper atmosphere. See the
UARS
Project document for more information.
Data are telemetered from UARS through the Tracking and Data Relay
Satellite System (TDRSS) to the Data Capture Facility (DCF) at NASA GSFC. From
there the data are given an initial quality check, and are then forwarded to
the UARS Central Data Handling
Facility (CDHF). The instrument PI teams are
connected to the CDHF through remote analysis computers (RACs), where they have
developed software to convert the raw data to higher level processed data. The
CDHF uses the production software to convert the level 0 (raw) data to level 1,
2, 3A and 3B data. The Goddard DAAC acquires the UARS data from the CDHF.
-
- None at this time.
-
-
-
- Spatial coverage alternates each UARS yaw cycle,
approximately 36 days, between latitude -34 to 80 (northward looking)
and latitude -72 to 45 (southward looking).
MLS views the limb of the Earth perpendicular to the UARS
orbital velocity vector, and typically scans in discrete steps from
about 5 km to 90 km every MLS major frame of 65.536 seconds.
-
- Data coverage for MLS looking northward on 5/22/1992.
-
- Level 3AL: 4 degrees latitude.
- Level 3AT: about 3 degrees latitude near the equator.
- Vertical resolution
is about 5 km for species profiles, and horizontal (along-track) resolution
is 10 to 30 km.
Projection:
- Not Applicable.
-
- All MLS level 3A data have been referenced to the UARS standard
pressure grid. The index of the data array defines the pressure level (in
millibars) given by:
P(i) = 1000 x 10**(-i/6) mb, where i=0,1,2,...
-
-
- Temporal coverage is from 19 September 1991 to the present.
The 183 GHz radiometer failed in April 1993. The last good full
day of data was April 15, 1993 (UARS Day 582), for ozone from the
183-GHz band and for H2O. Therefore, only fields for O3_183 and
H2O
prior to April 16 1993 should be used for scientific studies.
Occasional interference effects (induced by the switching mirror
stepper motor at low spacecraft battery voltage) can perturb the
radiances and retrieved parameter values. This problem occurred
largely between September 1992 and June 1993, typically just before
sunrise (at the satellite location) for a few minutes. Some diagnostics
are sensitive to this effect (quality fields in the Level 3 parameter
files show a degradation for ClO and O3_205), but this is not
reflected in the error bars (quality values) given in the Level 3A
files.
After 2.3 years in orbit (in late December 1993), the antenna-
scanning mechanism began to exhibit signs of wear. March 1994 through
May 1994, and July 1994 were periods of testing and significantly
reduced data gathering; these months have from one third of the days
with bad data to almost all bad days (days with no profiles retrieved).
August and September of 1994 contain mostly good data, but the months
of October 1994 through January 1995 again have very few days of useful
atmospheric profile data. Reverse scanning and other modifications to
the operations (including short periods of "mechanism rest" every orbit)
have been implemented since February 1, 1995. Very little limb data
gathering (typically only a few days per month) occurred from February
through July 1995, which was a period during which instrument power
sharing began for UARS (in May 1995) because of poor solar array
performance. Since June 1995, MLS has been in a mode of operation
characterized by off periods for power savings and on periods during
which typically 2 days of full (reverse) scans are obtained followed
by one day of limb tracking at altitudes near 18 km. The limb tracking
days do not lead to standard cataloged profile data files, although
there is some information on the atmosphere from those days. The
August 1995 through September 1996 time period generally contains
about one half to one third catalogued good days for atmospheric
profiles, and this mode of operation is expected to continue. We
note that MLS has been operating without "scan slips" since January
1995.
Calendars
describing the various instrument modes (especially useful
for time periods since March 1994, but also prior to this) can be made
available for interested users by contacting JPL. However, access of the
diagnostic
parameters mentioned above should generally allow users to appropriately screen for bad quality data and is ultimately needed for optimum
use of the MLS Level 3 data.
-
- The temporal resolution of MLS level 3A data granules is daily.
-
-
- UARS MLS measures microwave thermal emission from selected atmospheric
molecules, and provides information on tangent pressure and temperature.
The measured parameters are
listed in the table below with the original subtype name, DAAC
parameter name, units, and valid range:
| Subtype | DAAC Parameter Name | Units | Range |
| CLO | CHLORINE MONOXIDE | vmr | |
| H2O | WATER VAPOR | vmr | |
| HNO3 | NITRIC ACID | vmr | |
| O3_183 | OZONE AT 183 GHz | vmr | |
| O3_205 | OZONE AT 205 GHz | vmr | |
| SO2 | SULFUR DIOXIDE | vmr | |
| TEMP | ATMOSPHERIC TEMPERATURE | K | 0 to 300 |
NOTE:volume mixing ratio(vmr) = 10e-6 ppmv.
-
- MLS Level 3A granules are defined such that there is one granule
for each process level (3AL and 3AT), and parameter/subtype
per day. Thus, for MLS there are 6 granules per day. Each granule
is a multi-file granule consisting of four files:
- The binary data file (files ending with PROD, or *PROD extension)
which contains the vertical profile data, and quality (variances),
along with time, latitude, longitude, local solar time, and solar
zenith angle.
- An ASCII metadata file (files ending with META, or *META extension)
associated with the data file containing items such as the
begin date, end date, PI assigned quality flag and record length size
of the data file.
- A binary parameter file (also *PROD extension) designated 3LP for
3AL granules, and 3TP for 3AT granules. The subtype for these files
is PARAM. The MLS parameter files contain identifiers for satellite and
instrument, latitude and longitude, time and assorted record information.
These files were added to accommodate
the additional MLS values after the 3AL and 3AT file formats had
already been finalized.
- An ASCII metadata file associated with the parameter file (also
*META extension). The information is identical to the metadata file
associated with the data file, except that the record length applies
to the parameter file.
The naming convention for UARS files distributed by the Goddard DAAC is as follows:
CLAES_Llll_Sssss_Ddddd.Vvvvv_Ccc_xxxx,
where
- lll
- is the UARS processing level (3AL, 3AT, 3LP, or 3TP),
- ssss
- is the subtype or parameter),
- dddd
- is the UARS acquisition day (0001 = 12 September 1991),
- vvvv
- is the data version number,
- cc
- is the data version cycle number, and
- xxxx
- is the file extension
(PROD for the binary files, or META for the ASCII metadata files)
For a full description of the
naming convention see the "meta_desc.doc" file.
-
- The data are in a native UARS format (SFDU). The files were originally
created on a VAX/VMS system at the UARS CDHF, and now exist as UNIX
stream files at the Goddard DAAC. WINDII data file structures are
presented in the Standard Formatted Data Units (SFDU) documents listed
in the References section.
-
-
-
- All the algorithms used to process the data are defined in
detail in various software design documents, however, these are not needed
to understand the MLS data. The algorithms are set up to operate on
measurements in sequence. One atmospheric measurement is composed of a
background image and 4 (90 degree phase steps), 8 (45 degree phase steps)
or 2*4 (90 degree phase steps for each group of 4 images) phase images.
A 2*4 phase image measurement is called a "repeated measurement". Frequent
calibration measurements are also processed and used with the corresponding
atmospheric measurements. A frequent calibration measurement comprises a dark
current image and 4 phase images of one of the on board calibration lamps.
-
-
- The data processing is divided into three main jobs. The first
job reads the raw telemetry files or level 0 data and interprets the data
packet headers. The measurements are separated according to the atmospheric
line observed and saved in intermediate files. Next the instrument calibration
data is used to subtract dark current and to convert the count rate per bin
to a line of sight intensity given in rayleighs. Once the known instrument
corrections are made effects due to the UARS spacecraft are determined. The
orbit attitude data are used to compute the location of the tangent point for
each line of sight for each measurement bin. The frequent phase measurements are also processed in the first job step. The level 1 data, cataloged at
the end of job step 1, contain the calibrated data and the geo-referencing
data. These data are input to job step 2.
MLS views the limb of the airglow and so the intensity measured
in each bin is the line of sight integral of the volume emission rate
modified by the Michelson interferogram. In the second job step the level 1
bin intensities for each of the 4 or 8 phase steps are used to compute what
are termed "apparent quantities". These contain the atmospheric information.
The apparent phase is the intensity weighted line integral giving the
atmospheric wind. The apparent visibility is the intensity weighted line
integral giving the atmospheric temperature. The apparent intensity is the
line integral of the volume emission rate. Each measurement is composed of
vertical columns of bins. A column gives a vertical scan through the airglow
layer. A typical image has 6 columns, each about 25 km wide. In order to
reduce the effects of gravity waves on the final wind and temperature these
6 columns are averaged together to form a single vertical profile for each
field of view. The apparent intensity is inverted using constrained Twomey
inversion to give the volume emission rate profile (see "Introduction to
the Mathematics of Inversion in Remote Sensing and Indirect Measurements" by
S. Twomey, Development in Geomathematics series, Elsevier, New York, 1977).
This is then used to deconvolve the apparent phase and visibility. Finally
the wind and temperature profiles are computed from the inverted phase and
visibility for each field of view. The last step in the level 2 processing
is to combine the line of sight winds from each FOV to form the desired vector
winds. This is done by selecting data from the forward FOV which overlaps
data from the backward FOV. The zonal and meridional components of the wind
are computed only if the two FOVs see the same volume and the volume emission
rates and temperatures (both scalar quantities) agree within specified limits.
The level 2 data are saved for each measurement with no interpolation.
The final job step reads the level 2 data and interpolates from the
natural measurement locations to the standard UARS grid. Only the wind and
the temperature are gridded and saved in the level 3 data product. A
parameter file at level 3 gives the source of the data used to derive the
wind and temperature.
-
- Reprocessing of the data occur about once a year.
-
-
- None.
-
- Meridional and zonal wind components are calculated, as well
as temperature.
-
- The data quality is given by the standard deviation of the quantity.
Each data element in each file is stored along with a standard deviation which
has been calculated by the analysis software. The nominal error is 10 m/s
for the wind and 25 K for temperature.
-
-
-
- Data are checked by the MLS science team and assigned quality
values. These values appear as the DATA_QUALITY_UARS and DATA_QUALITY_PI
fields in the ASCII metadata files. The format for DATA_QUALITY_UARS is a
3 character field of the form "p.q" where:
VALUE MEANING
for p 0 Machine inspected
1 Qualitative evaluation
2 Intensive analysis
for q 1 less than 50% good data
2 50% - 75% good data
3 76% - 98% good data
4 better than 98% good data
-
- Variances are included with each data value.
-
- None.
-
- Data files are checked to ensure that they are properly
transferred and translated from their original VAX/VMS format at the
UARS CDHF to the DAAC's UNIX format. No additional data checks are
performed by the DAAC.
-
- The data files exist as UNIX stream files at the DAAC. Binary data are
IEEE formatted. The binary data files should be read on 32 bit
machines running UNIX operating systems. This is especially important for
fields which are IEEE floating point values, such as the profile data and
quality values. If you are going to use a non 32-bit and/or non-UNIX machine,
then you will need to write your own conversion routines to read the data files.
File record length information is only listed in the ASCII metadata files
(*META extension) which accompany the data and parameter files.
-
- None at this time.
-
- The data may be used to provide global synoptic maps of wind and
temperature in the upper mesosphere and lower thermosphere.
-
- None.
-
- MLS has produced an enormous amount of data on the upper atmosphere.
Scientists around the world are using the data in a number of applications,
for example:
- to characterize large scale atmospheric wave phenomena
- to measure seasonal and long term variations in the atmospheric composition
- to measure polar mesospheric cloud phenomena and
- to model the global upper atmosphere weather
-
- The MLS instrument continues to acquire data. Future reprocessing
of the data are anticipated.
-
- Simple read/dump programs are available for reading the CLAES level 3A
data files. The read programs are available in both Fortran and C languages.
These programs simply print the file contents to the screen.
The *META and *PROD files (see the Data Granularity section)
must be kept in the same directory, because the programs require the *META file
as the input parameter in order to read the *PROD file. The *META file is
necessary because it contains file record length information, which is not in
the *PROD files.
If you are using the Fortran READ programs you may need to change the OPEN
statement. Some machines read 4 byte words, while other machines read 1 byte.
If the program isn't working correctly, you should try changing RECL=RECSIZ/4
to RECL=RECSIZ.
Contact science@eosdata.gsfc.nasa.gov for problems with the read/dump
software.
-
- To compile the programs, just type:
f77 FILE_NAME.F -o FILE_NAME (Fortran programs)
or cc file_name.c -o file_name (C programs)
Below are examples showing how to run the programs:
$ READUMP_L3AT_DATA (Fortran program)
PLEASE ENTER META DATA FILE NAME BELOW:
CLAES_L3AT_SH2O_D0001.V0003_C01_META
or $ readump_l3at_data CLAES_L3AT_SH2O_D0001.V0003_C01_META (C program)
-
- Name:
- Help Desk
- Addresses:
- NASA Goddard Space Flight Center
- Code 610.2
- Greenbelt, MD 20771
- Telephone Numbers:
- Phone: 1-301-614-5224
- FAX: 1-301-614-5268
- Electronic Mail Address:
- daacuso@daac.gsfc.nasa.gov
-
- The UARS MLS data are archived at the GSFC DAAC, and can be identified
by the attributes listed below.
Data Set = UARS
Data Product = MLS L3AL DAILY LAT ORDERED
MLS L3AT DAILY TIME ORDERED
-
- The MLS level 3A data files can be obtained from the Goddard DAAC
by several mechanisms. These include the following:
- The
DAAC Web-Based Archive Interface provides a means for searching
and ordering data. To search the data holdings and place an order, go to
the DAAC Home Page located at "/index.shtml", and click on
the "Search and Order" icon. Next, pick the "Data Set" link, and from
there choose "UARS".
- Anonymous FTP.
The most recent month of MLS data (about 2 months from current) can be
down loaded from the DAAC anonymous FTP server located at
daac.gsfc.nasa.gov, in directory http://disc.sci.gsfc.nasa.gov/data/uars/mls. This area can also be
accessed through the World Wide Web at ftp://daac.gsfc.nasa.gov/data/uars/mls.
For convenience, the data files are arranged in directories by instrument,
level, and subtype (e.g. http://disc.sci.gsfc.nasa.gov/data/uars/mls/3al/clo).
- Earth Observing System
Data Gateway (EDG). You can place orders for the UARS data through
the Earth Observing System (EOS) Data Gateway. From here you can also
order data products from other data centers. The web address for the EDG
is "http://wist.echo.nasa.gov/~wist/api/imswelcome/".
- DAAC Help Desk.
Data can also be obtained by contacting the GSFC DAAC Help Desk
listed above.
Data can be ordered electronically (FTP).
-
- The DAAC currently supports MLS level 3AL and 3AT data products.
The MLS level 3A data are available.
See the section above on Procedures for Obtaining Data
for specific information.
For more information on MLS, please refer to the
MLS Home Page.
-
- Reber, C. A., C. E. Trevathan, R. J. McNeal, and M. R. Luther, The
Upper Atmosphere Research Satellite (UARS) Mission, J. Geophys. Res. 98, D6,
10643-10647, 1993.
G.G. Shepherd, G. Thuillier, W.A. Gault, B.H. Solheim, C. Hersom,
J.M. Alunni, J.-F. Brun, S. Brune, P. Charlot, L.L. Cogger, D.-L. Desauliniers,
W.F.J. Evans, R.L. Gattinger, F. Girod, D. Harvie, R.H. Hum, D.J. W. Kendall,
E.J. Llewellyn, R.P. Lowe, J. Ohrt, F. Pasternak, O. Peillet, I. Powell,
Y.J. Rochon, W.E. Ward, R.H. Wiens, J. Wimperis, MLS - The Wind Imaging
Interferometer on the Upper Atmosphere Reseasrch Satellite. J. Geophys, Res.,
98: 10725-10750, 1993.
Gault, W.A., G.G. Shepherd, W.E. Ward, C.H. Hersom, Y.J. Rochon,
and B.H. Solheim, On-orbit performance of the MLS instrument on UARS.
Proceedings of the SPIE Conference on Optical Spectroscopic Techniques and
Instrumentation for Atmospheric and Space Res. Vol 2266, San Diego, 1994.
-
-
G.G. Shepherd, G. Thuillier, B.H. Solheim, S. Chandra, L.L. Cogger,
M.L. Duboin, W.F.J. Evans, R.L. Gattinger, W.A. Gault, M. Herse, A Hauchecorne,
C. Lathuilliere, E.J. Llewellyn, R.P. Lowe, H. Teitelbaum and F. Vial,
Longitudinal Structure in Atomic Oxygen Concentrations Observed with MLS
on UARS. Geophys. Res. Lett. 20: 1303-1306, 1993.
W.E. Ward, Y.J.Rochon, C. McLandress, D.Y. Wang, J.R. Criswick,
B.H. Solheim, G.G. Shepherd. Correlations between the mesospheric O(1S)
emission peak intensity and height and temperature at 98 km. using MLS Data.
Adv. Space Res. 14: 57-60, 1994.
W.F.J. Evans, L.R. Laframboise, and G.G. Shepherd, Mesospheric
temperatures from Rayleigh scattering measurements by the MLS instrument
on UARS. Adv. Space Res. 14:285-288 (No. 9) 1994.
McLandress, C., Y. Rochon, G.G. Shepherd, B.H. Solheim, G. Thuillier,
and F. Vial, The meridional wind component of the thermospheric tide observed
by MLS on UARS. Geophys. Res. Letts. 21: 2417-2420, (November) 1994.
G.G. Shepherd and C. McLandress Southern Hemisphere Dynamics Observed
by MLS: The WIND Imaging Interferometer on the UARS Mission. Adv. Space Res.
16: (5) 53-60, 1995.
Evans, W.F.J., L.R. Laframboise, K. R. Sine, R.H. Wiens,
and G.G. Shepherd, Observation of polar mesospheric clouds in scattered
sunlight by the MLS instrument on UARS. Geophys. Res. Letts. 22: 2793-2796,
1995.
Wiens, R.H., W.F.J. Evans, D.Y. Liang, M.S. Zalcik, and A.H. Manson,
MLS Observation of a PMC breakup event during ANLC-93. Geophys. Res. Letts.
22: 2797-2800, 1995.
G. Hernandez, R.H. Wiens, R.P. Lowe, G.G. Shepherd, G.J. Fraser,
R.W. Smith, L. LeBlanc, and M. Clark Optical determination of the vertical
wavelength of propagating upper atmosphere oscillations. Geophys. Res. Letts.,
22: 2389-2392, 1995.
-
-
G.G. Shepherd, G. Thuillier, B.H. Solheim, S. Chandra, L.L. Cogger,
M.L. Duboin, W.F.J. Evans, R.L. Gattinger, W.A. Gault, M. Herse, A Hauchecorne,
C. Lathuilliere, E.J. Llewellyn, R.P. Lowe, H. Teitelbaum and F. Vial,
Longitudinal Structure in Atomic Oxygen Concentrations Observed with MLS
on UARS. Geophys. Res. Lett. 20: 1303-1306, 1993.
W.E. Ward, Y.J.Rochon, C. McLandress, D.Y. Wang, J.R. Criswick,
B.H. Solheim, G.G. Shepherd. Correlations between the mesospheric O(1S)
emission peak intensity and height and temperature at 98 km. using MLS Data.
Adv. Space Res. 14: 57-60, 1994.
W.F.J. Evans, L.R. Laframboise, and G.G. Shepherd, Mesospheric
temperatures from Rayleigh scattering measurements by the MLS instrument
on UARS. Adv. Space Res. 14:285-288 (No. 9) 1994.
McLandress, C., Y. Rochon, G.G. Shepherd, B.H. Solheim, G. Thuillier,
and F. Vial, The meridional wind component of the thermospheric tide observed
by MLS on UARS. Geophys. Res. Letts. 21: 2417-2420, (November) 1994.
G.G. Shepherd and C. McLandress Southern Hemisphere Dynamics Observed
by MLS: The WIND Imaging Interferometer on the UARS Mission. Adv. Space Res.
16: (5) 53-60, 1995.
Evans, W.F.J., L.R. Laframboise, K. R. Sine, R.H. Wiens,
and G.G. Shepherd, Observation of polar mesospheric clouds in scattered
sunlight by the MLS instrument on UARS. Geophys. Res. Letts. 22: 2793-2796,
1995.
Wiens, R.H., W.F.J. Evans, D.Y. Liang, M.S. Zalcik, and A.H. Manson,
MLS Observation of a PMC breakup event during ANLC-93. Geophys. Res. Letts.
22: 2797-2800, 1995.
G. Hernandez, R.H. Wiens, R.P. Lowe, G.G. Shepherd, G.J. Fraser,
R.W. Smith, L. LeBlanc, and M. Clark Optical determination of the vertical
wavelength of propagating upper atmosphere oscillations. Geophys. Res. Letts.,
22: 2389-2392, 1995.
- DATA PRODUCT
- A collection of parameters packaged with associated ancillary and
labeling data. Uniformly processed and formatted. Typically uniform temporal
and spatial resolution. MLS level 3A data products include MLS_L3AL_DAILY
and MLS_L3AT_DAILY. The MLS data product class is divided into data product
subclasses according to measured parameters.
- DATA SET
- A logically meaningful grouping or collection of similar or related
data. Data having mostly similar characteristics (source or class of source,
processing level and algorithms, etc.) MLS is a subset of the UARS data set.
- GRANULE
- A Granule is the smallest aggregation of data which is independently
managed.
- PARAMETER
- A measurable or derived variable represented by the data (e.g. air
temperature, snow depth, relative humidity). At the Goddard DAAC, parameters
are grouped into a Parameter General category, which is broken down into
Parameter Specific.
| CCD | Charged Coupled Device |
| CDHF | Central Data Handling Facility |
| DAAC | Distributed Active Archive Center |
| DCF | Data Capture Facility |
| EOS | Earth Observing System |
| FOV | Field of View |
| GSFC | Goddard Space Flight Center |
| IMS | Information Management System |
| K | Kelvin |
| km | kilometer |
| LOS | line of sight |
| m | meter |
| MLS | Microwave Limb Sounder |
| m/s | meters per second |
| NASA | National Aeronautics and Space Administration |
| PI | Principal Investigator |
| RAC | Remote Analysis Computer |
| SFDU | Standard Formatted Data Units |
| MLS | Wind Imaging Interferometer |
| TDRSS | Tracking and Data Relay Satellite System |
| UARS | Upper Atmosphere Research Satellite |
| vmr | Volume Measured Ratio |
| USO | User Services Office |
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UARS Project
Change History
- Version 2.0
- Version baselined on addition to the GES Controlled Documents List, February 19, 1998.
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Atmos Composition
