Data Access:
TRMM Microwave Imager (TMI) Level 2A Hydrometeor Profile Product
2A12:
http://disc.sci.gsfc.nasa.gov/data/datapool/TRMM_DP/01_Data_Products/01_Orbital/05_Tmi_Prof_2A_12/
| The latent heating products of TRMM 2A12 and 3A12 over ocean surfaces should
be regarded as experimental. Please confer first with the algorithm developers (by
contacting the GES DISC) when using the latent heating product
over ocean. Over-land latent heating estimates from TRMM products 2A12 and 3A12 should not be
used, as they have not been evaluated quantitatively or qualitatively. |
Contents:
[Skip Contents]
- Summary
- TRMM Satellite Operating Altitude
Change
- Sponsor and
Acknowledgement
- Future Updates
- Data Flow Description
- Data Set Description
-
- Tools for Visualizing Data
-
- Sample Software
-
- Data Access
- Points of Contact
- References
This document provides basic information on 2A12, TRMM Microwave Imager
(TMI) Level 2 Hydrometeor Profile Product. The TMI profiling algorithm
(2A12) generates vertical profiles of hydrometeors from TMI brightness
temperatures by blending the radiometric data with dynamical cloud
models. For each pixel, the algorithm assigns a surface type
(land/ocean/coast) and a freezing height; and computes surface rain,
convective surface rain, and profiles of hydrometeors (cloud liquid,
cloud ice, water vapor, etc.) at 14 vertical levels.
The average operating altitude for TRMM was changed from 350 to 403 km
during the period of August 7-24, 2001. This orbit boost maneuver
extended the mission life significantly. All post-boost data products had
been released by the TRMM Science Project, as of early December 2001. All
TRMM data products (post- and pre-boost) are available via the TRMM data
search-and-order system at http://disc.sci.gsfc.nasa.gov/data/datapool/TRMM_DP/.
The time period before August 7, 2001 is referred to as
pre-boost, and the time period after August 24, 2001 is
referred to as post-boost.
The characteristics of the three rain instruments for pre- and post-boost
are shown in following table:
| Characteristics of TRMM Instruments |
| |
Swath Width (km) |
Ground Resolution (km) |
| Pre-boost |
Post-boost |
Pre-boost |
Post-boost |
| VIRS |
720 |
833 |
2.2 |
2.4 |
| TMI |
760 |
878 |
4.4* |
5.1* |
| PR |
215 |
247 |
4.3 |
5.0 |
| * Ground resolutions of TMI
are those at 85.5 GHz (highest resolution). |
The pre- and post-boost characteristics of TRMM data are different; their
details are listed in the Data Characteristics table for each orbital
product. Some caveats associated with post-boost TRMM Precipitation Radar
(PR) products have been released by the PR algorithm scientists and are
available at
ftp://disc2.nascom.nasa.gov/data/TRMM/Documentation/TRMM_Boost_PR_Caveats.html.
For TRMM version 5 products, the post-boost filenames all have a "5A"
in the product version part of the name, compared with a "5" in pre-boost
filenames. For version 6, the filenames have no differences for pre-boost
and post-boost.
The distribution of this data set is funded by NASA's Earth Science Enterprise
(ESE). The data are not copyrighted; however, we request
that when you publish data or results using these data, please
acknowledge as follows:
The data used in this study were acquired as part of the Tropical
Rainfall Measuring Mission (TRMM). The algorithms were developed by the
TRMM Science Team. The data were processed by the TRMM Science Data and
Information System (TSDIS) and the TRMM Office; they are archived and
distributed by the Goddard Distributed Active Archive Center. TRMM is
an international project jointly sponsored by the Japan National Space
Development Agency (NASDA) and the U.S. National Aeronautics and Space
Administration (NASA) Office of Earth Sciences.
Please send a copy of your publication to Help Desk, Goddard
DAAC, Code 610.2, NASA GSFC, Greenbelt, MD 20771 or email the
reference of your publication to help-disc@listserv.gsfc.nasa.gov.
It is expected that some of the TRMM algorithms will be refined or
improved as new measurements are gathered and analyzed by the TRMM
Science Team. The data products are expected to be periodically
reprocessed by TSDIS in order to provide the scientific and other user
communities with the most current and best available rainfall products.
The exact reprocessing schedule will be set by a team designated by the
TRMM Project Scientist. This document will be updated in coordination
with the TRMM reprocessing schedule and whenever appropriate as
determined by the Goddard DAAC Hydrology Data Support Team.
TMI Level 1A ==> 1B11 Calibrated TMI brightness temperatures ==>
2A12 TMI Rainfall Structure
The data flow of all products are shown in Satellite Algorithm Flow Diagram.
Data Characteristics
| TRMM 2A12
(TMI) Data Characteristics |
| |
Pre-boost (before 08-07-2001) |
Post-boost (after 08-24-2001) |
| Temporal Coverage |
Start Date: 12-08-1997
Stop Date: 08-07-2001 |
Start Date: 08-24-2001
Stop Date: - |
| Geographic Coverage |
Latitude: 38°S - 38°N
Longitude:180°W - 180°E |
Latitude: 38°S - 38°N
Longitude:180°W - 180°E |
| Vertical Coverage |
Surface - 18 km |
Surface - 18 km |
| Temporal Resolution |
About 91.5 minutes per orbit
About 16 orbits per day
More information about revisit
frequency |
About 92.5 minutes per orbit
About 16 orbits per day
More information about revisit
frequency |
| Horizontal Resolution |
4.4 km at 85.5 GHz |
5.1 km at 85.5 GHz |
| Vertical Resolution |
0.5 km from surface to 4 km
1.0 km from 4 to 6 km
2.0 km from 6 to 10 km
4.0 km from 10 to 18 km
|
0.5 km from surface to 4 km
1.0 km from 4 to 6 km
2.0 km from 6 to 10 km
4.0 km from 10 to 18 km
|
| Scan Characteristics |
Swath Width: 760 km
Pixels/Scan: 208
Scans/Second (SS): 36.100/60
Seconds/Orbit (SO): 5490
Average Scans/Orbit: nscan = SS*SO+100 = 2991
|
Swath Width: 878 km
Pixels/Scan: 208
Scans/Second (SS): 36.100/60
Seconds/Orbit (SO): 5550
Average Scans/Orbit: nscan = SS*SO+100 = 3023
|
| Average File Size |
Compressed: ~8.5 MB
Original: ~102 MB |
Compressed: ~8.5 MB
Original: ~103 MB |
| File Type |
HDF |
HDF |
Data Format Structure
The following table summarizes the contents and structure of the TMI
rain profile (2A12) product. Further information can be found in Volume 4
of the "File Specifications for TSDIS Products - Level 2 and Level 3" .
| Data Format
Structure for 2A12, TMI Profiling |
| Name |
Type |
Record
Size
(byte) |
Dim Size
(# of Records) |
Scaled
by |
Range |
Unit |
Description |
| ECS Core Metadata |
Char Attribute |
10,000 |
- |
- |
- |
- |
ECS Core Metadata. |
| PS Metadata |
Char Attribute |
10,000 |
- |
- |
- |
- |
Product Specific Metadata. |
| Swath Structure |
Char Attribute |
5,000 |
- |
- |
- |
- |
Specifications for the swath geometry. |
| Scan Time |
Vdata Table |
9 |
nscan |
- |
- |
- |
Time associated with each scan. |
| Geolocation |
Float SDS |
4 |
2*npixel*nscan |
- |
- |
degree |
Earth location of the center of the IFOV at the altitude of the
earth ellipsoid. The first dimension is latitude and longitude, in
that order. The next dimensions are numbers of pixels and scans. |
| Scan Status |
Vdata Table |
21 |
nscan |
- |
- |
- |
Status of each scan. |
| Navigation |
Vdata Table |
88 |
nscan |
- |
- |
- |
Spacecraft geocentric information. |
| Data Flag |
Integer SDS |
1 |
npixel*nscan |
- |
- |
- |
Indicates the quality of data. |
| Rain Flag |
Integer SDS |
1 |
npixel*nscan |
- |
- |
- |
Indicates if rain is possible
>=0 : rain is possible;
<0 : non-raining. |
| Surface Flag |
Integer SDS |
1 |
npixel*nscan |
- |
0 ~ 3 |
- |
Indicates the type of surface
0-ocean; 1-land; 2-coast; 3-other. |
| Surface Rain |
Float SDS |
4 |
npixel*nscan |
- |
0.0 ~ 3000.0 |
mm/h |
Instantaneous rain rate at the surface for each pixel. |
| Convective Surface Rain |
Float SDS |
4 |
npixel*nscan |
- |
0.0. ~ 3000.0 |
mm/h |
Instantaneous convective rain rate at the surface for each
pixel. |
| Confidence |
Float SDS |
4 |
npixel*nscan |
- |
0.0 ~ 300.0 |
K |
Associated with the surface rain, and measured as an rms
deviation in temperatures. |
| Cloud Liquid Water |
Integer SDS |
2 |
nlayer*npixel*nscan |
1000 |
0.00 ~ 10.00 |
g m-3 |
Cloud liquid water content for each pixel at 14
layers. |
| Precipitation Water |
Integer SDS |
2 |
nlayer*npixel*nscan |
1000 |
0.00 ~ 10.00 |
g m-3 |
Precipitation water content for each pixel at 14
layers. |
| Cloud Ice Water |
Integer SDS |
2 |
nlayer*npixel*nscan |
1000 |
0.00 ~ 10.00 |
g m-3 |
Cloud ice water content for each pixel at 14
layers. |
| Precipitation Ice |
Integer SDS |
2 |
nlayer*npixel*nscan |
1000 |
0.00 ~ 10.00 |
g m-3 |
Precipitation content for each pixel at 14
layers. |
| Latent Heating |
Integer SDS |
2 |
nlevel*npixel*nscan |
10 |
-256 ~ 256 |
°C/hour |
Latent heating release for each pixel at 14
levels. |
| Note: |
nlevel: the number of latent heating levels (14)
nlayer: the number of profiling layers (14)
|
The Goddard DAAC provides the following tools to help users visualize
data in the Hierarchical Data Format (HDF).
TSDIS Orbit Viewer
The TSDIS Orbit Viewer is a menu-driven graphical interface for
dynamically generating images from TRMM HDF files. The viewer can
display, at the full instrument resolution, TRMM satellite, Ground
Validation, browse, and Coincidence Subsetted Intermediate (CSI)
products, as well as other derived products.
The software runs on Microsoft Windows and UNIX.
The source code and installation instructions for the Orbit Viewer are
available from the Goddard DAAC's TRMM ftp site (ftp://disc2.nascom.nasa.gov/software/trmm_software/Orbit_Viewer).
Please note: TSDIS can provide technical support for
the Orbit Viewer only to certain members of the TRMM Science Team. Other
users should contact the DAAC's Hydrology Data Support
Team (hydrology-disc@listserv.gsfc.nasa.gov).
EOSView
EOSView is a standalone X-based data visualization tool that displays
HDF files. It can be used to view data ordered from the Goddard DAAC. In
addition, it provides a secondary mechanism for previewing browse files
before ordering data. (The primary mechanism is the preview feature of
the TRMM Data
Search and Order System.) EOSView serves as a file verification tool.
The contents of HDF files are displayed and individual objects can be
selected for display. Displayable objects include raster images, data
sets in tables, pseudocolor images of data sets, attributes, and
annotations. Simple animations can be performed for a file with multiple
raster images.
A unique interface has been provided for handling HDF-EOS data
structures. The Swath/Point/Grid interface uses only HDF-EOS library
calls. EOSView users will not see the underlying HDF structures but will
be prompted for what parts of the HDF-EOS object they wish to view. The
EOSView requires at least 4 megabytes of memory and a larger than 24-bit
graphics board.
Download Instructions for the
Software:
-
These tools can be downloaded via anonymous ftp using a command
line ftp client, available on all Unix machines.
The source code, installation instructions, and documentation for
EOSView and Orbit Viewer are available from the Goddard DAAC's
TRMM ftp site
(ftp://disc2.nascom.nasa.gov/software/trmm_software).
The following files should be downloaded for EOSView:
- EOSView (executable)
- eosview.csc (help)
- eosview.uid (user interface description file)
- eosview.dat (IDL commands file)
- How to start EOSView:
-
Start EOSView by typing 'EOSView' at the command prompt. The
current working directory must contain the four EOSView files.
TRMM HDF Data File Read Software
The Goddard DAAC Hydrology Team has developed the TRMM HDF Data File
Read Software, first released in February 1999. The software reads TRMM
HDF data files and writes out to flat binary files. The software has been
tested with most of the TRMM standard products, as well as with some
derived subset products. Both C and Fortran versions are available from
ftp://disc2.nascom.nasa.gov/software/trmm_software/Read_HDF/.
TSDIS Toolkit
TSDIS developed the TSDIS Science Algorithm Toolkit to assist the TRMM
Science Team's algorithm developers. The toolkit provides a library of
commonly used routines, constants, and macros. It also allows seamless
integration of TRMM algorithms into the TSDIS environment.
The toolkit provides routines for reading and writing data to and from
the HDF files; routines are provided for Levels 1-3 products and for both
satellite and GV. Each of the routines in the toolkit are callable in
either C or Fortran. The toolkit also includes routines for reading
land/sea data and topographical data.
The Goddard DAAC maintains archives of all TRMM data products and many
other Hydrology data sets. The archived data can be ordered via FTP network transfer.
| Data Volume Limits By Media |
| CDR |
FTP-Pull |
| Min. |
Max. |
Min. |
Max. |
Min. |
Max. |
Min. |
Max. |
| 0 GB |
3.17 GB |
0 GB |
2 GB |
1 GB |
50 GB |
1 GB |
50 GB |
TRMM 2A12 can be accessed and ordered from the Goddard DISC's
TRMM Data Search and Order System at
http://disc.sci.gsfc.nasa.gov/data/datapool/TRMM_DP/01_Data_Products/01_Orbital/05_Tmi_Prof_2A_12/
.
- For information about or assistance in using any Goddard DAAC data,
contact the DAAC Help Desk at:
-
GES Distributed Active Archive Center (DAAC)
Code 610.2
NASA Goddard Space Flight Center
Greenbelt, Maryland 20771
Email: help-disc@listserv.gsfc.nasa.gov.
301-614-5224 (voice)
301-614-5268 (fax)
Tropical Rainfall Measuring Mission Science Data and Information System
(TSDIS) Interface Control Specification Between the TSDIS and the TSDIS
Science User (TSU)
Volume 3: File Specifications for TRMM Products - Level 1.
Volume 4: File Specifications for TRMM Products - Level 2 and Level 3.
Papers associated with the over-ocean latent heating algorithm:
Olson, W. S., C. D. Kummerow, S. Yang, G. W. Petty, W.-K. Tao, T. L. Bell, S.
A. Braun, Y. Wang, S. E. Lang, D. E. Johnson and C. Chiu. 2006: Precipitation and latent heating distributions from satellite passive microwave radiometry.
Part I: Improved method and uncertainties. J. Appl. Meteor. and Climatol., 45, 702-720.
Yang, S., W. S. Olson, J.-J. Wang, T. L. Bell, E. A. Smith and C. D. Kummerow.
2006: Precipitation and latent heating distributions from satellite passive microwave radiometry.
Part II: Evaluation of estimates using independent data.
J. Appl. Meteor. and Climatol., 45, 721-739.
Appendix
| TRMM 2A12 Scan Time |
| Name |
Format |
Description |
| Year |
2-byte integer |
4-digit year, e.g., 1998 |
| Month |
1-byte integer |
The month of the Year |
| Day of Month |
1-byte integer |
The day of the Month |
| Hour |
1-byte integer |
The hour (UTC) of the Day |
| Minute |
1-byte integer |
The minute of the Hour |
| Second |
1-byte integer |
The second of the Minute |
| Day of Year |
2-byte integer |
The day of the Year |
| TRMM 2A12 Data Flag Specific Values |
| Value |
Description |
| 0 |
Good data quality |
| -9 |
Channel brightness temperature outside valid range |
| -15 |
The neighboring 5 x 5 pixel array is incomplete due to edge or bad
data quality |
| -21 |
Surface type invalid |
| -23 |
Date time invalid |
| -25 |
Latitude or longitude invalid |
| 14
Vertical Profiling Layers |
| Layer Index |
Layer Height |
| 1 |
surface - 0.5 km |
| 2 |
0.5 - 1.0 km |
| 3 |
1.0 - 1.5 km |
| 4 |
1.5 - 2.0 km |
| 5 |
2.0 - 2.5 km |
| 6 |
2.5 - 3.0 km |
| 7 |
3.0 - 3.5 km |
| 8 |
3.5 - 4.0 km |
| 9 |
4.0 - 5.0 km |
| 10 |
5.0 - 6.0 km |
| 11 |
6.0 - 8.0 km |
| 12 |
8.0 -10.0 km |
| 13 |
10.0 -14.0 km |
| 14 |
14.0 - 18.0 km |
|
| 14
Vertical Heating Levels |
| Level Index |
Level Height |
| 1 |
0 km |
| 2 |
1 km |
| 3 |
2 km |
| 4 |
3 km |
| 5 |
4 km |
| 6 |
5 km |
| 7 |
6 km |
| 8 |
7 km |
| 9 |
8 km |
| 10 |
9 km |
| 11 |
10 km |
| 12 |
12 km |
| 13 |
14 km |
| 14 |
16 km |
|
|
TRMM Navigation
|
| Name |
Format |
Description |
Spacecraft Geocentric
Position [3] |
3 X 4-byte float |
The position (m) of the spacecraft in Geocentric Inertial
Coordinates at the Scan mid-Time (i.e., time at the middle pixel/IFOV
of the active scan period). The order of components is: x, y, and z.
Geocentric Inertial Coordinates are also commonly known as Earth
Centered Inertial coordinates. These coordinates will be True of Date
(rather than Epoch 2000 which are also commonly used), as interpolated
from the data in the Flight Dynamics Facility ephemeris files generated
for TRMM. |
Spacecraft Geocentric
Velocity [3] |
3 X 4-byte float |
The velocity (ms -1) of the spacecraft in Geocentric
Inertial Coordinates at the Scan mid-Time. The order of components is:
x, y, and z. |
Spacecraft Geodetic
Latitude |
4-byte float |
The geodetic latitude (decimal degrees) of the spacecraft at the
Scan mid-Time. |
Spacecraft Geodetic
Longitude |
4-byte float |
The geodetic longitude (decimal degrees) of the spacecraft at the
Scan mid-Time. Range is -180 to 179.999999. |
Spacecraft Geodetic
Altitude |
4-byte float |
The altitude (m) of the spacecraft above the Earth Ellipsoid at the
Scan mid-Time. |
Spacecraft
Attitude [3] |
3 X 4-byte float |
The satellite attitude Euler angles at the Scan mid-Time. The order
of the components in the file is roll, pitch, and yaw. However, the
angles are computed using a 3-2-1 Euler rotation sequence representing
the rotation order yaw, pitch, and roll for the rotation from Orbital
Coordinates to the spacecraft body coordinates. Orbital Coordinates
represent an orthogonal triad in Geocentric Inertial Coordinates where
the Z-axis is toward the geocentric nadir, the Y-axis is perpendicular
to the spacecraft velocity opposite the orbit normal direction, and the
X-axis is approximately in the velocity direction for a near circular
orbit.
Note this is geocentric, not geodetic, referenced, so that pitch and
roll will have twice orbital frequency components due to the onboard
control system following the oblate geodetic Earth horizon. Note also
that the yaw value will show an orbital frequency component relative to
the Earth fixed ground track due to the Earth rotation relative to
inertial coordinates. |
Sensor Orientation
Matrix [3 X 3] |
3 X 3 X 4-byte float |
The rotation matrix from the instrument coordinate frame to
Geocentric Inertial Coordinates at the Scan mid-Time. |
Greenwich
Hour Angle |
4-byte float |
The rotation angle (degrees) from Geocentric Inertial Coordinates
to Earth Fixed Coordinates. |
| TRMM TMI Scan Status
|
| Name |
Format |
Values |
Description |
| Missing |
1-byte integer |
Value and meaning |
Indicates whether information is contained in the scan. |
| Validity |
1-byte integer |
Bit and meaning |
A summary of status modes. |
| QAC |
1-byte integer |
0: No decoding error occurred. |
The Quality and Accounting Capsule of the Science packet as it
appears in Level-0 data. |
Geolocation
Quality |
1-byte integer |
Bit and Meaning |
A summary of geolocation quality in the scan. |
| Data Quality[9] |
9 x 1-byte integer |
- |
A quality of Channel Data for given channel on given scan
line is the percentage of pixels whose value are within the
acceptable range listed in the metadata. |
Current Spacecraft
Orientation |
1-byte integer |
Value and Meaning |
Current spacecraft orientation. |
| Current ACS Mode |
1-byte integer |
Value and Meaning |
Current ACS mode. |
| Yaw Update Status |
1-byte integer |
0: Inaccurate
1: Indeterminate
2: Accurate |
Yaw update status. |
| TMI Instrument Status |
1-byte integer |
Bit and Meaning |
TMI instrument status. |
Fractional
Orbital Number |
4-byte float |
|
The orbit number and fractional part of the orbit at Scan Time.
The orbit fraction part is calculated as:
(Time-Orbit Start Time)/(Orbit End Time-Orbit Start Time) |
| Value
and Meaning of Missing
|
| Value |
Meaning |
| 0 |
Scan data elements contains information |
| 1 |
Scan was missing in the telemetry data |
| 2 |
Scan data contains no elements with rain |
|
Bit and Meaning of Validity
|
| Bit |
Meaning if bit=1 |
Note |
| 0 |
Spare (always 0) |
Validity is a summary of status modes. If all status
modes are
routine, all bits in Validity = 0. Routine means that scan data
has been measured in the normal operational situation as far as
the status modes are concerned. Validity does not assess data or
geolocation quality. Validity is broken into 8 bit flags. Each
bit=0 if the status is routine but the bit = 1 if the status is
not routine. Bit 0 is the most significant bit (i.e., if bit i=1
and other bits = 0, the unsigned integer value is 2**(8-i)-1 ). |
| 1 |
Non routine spacecraft orientation (2 or 3) |
| 2 |
Non routine ACS mode (other than 4) |
| 3 |
Non routine yaw update status (0 or 1) |
| 4 |
Non routine instrument status (other than 1) |
| 5 |
Non routine QAC (non-zero) |
| 6 |
Spare (always 0) |
| 7 |
Spare (always 0) |
| Bit and
Meaning of Geolocation Quality
|
| Bit |
Meaning if bit=1 |
| 0 |
Grossly bad geolocation results:
* Spacecraft position vector magnitude outside range 6720 to 6740 km.
* Z component of midpoint of scan outside range -4100 to 4100 km.
* Distance from S/C to midpoint of scan outside range 340 to 360
km. |
| 1 |
Unexpectedly large scan to scan jumps in geolocated positions in
along and cross track directions for first, middle, and last pixels in
each scan. Allowed duration from nominal jump in along track motion =
0.06 km (first pixel), 0.04 km (middle pixel), and 0.06 km (last
pixel). Allowed duration from nominal jump in cross track motion = 0.05
km (first pixel), 0.04 km (middle pixel), and 0.05 km (last pixel). Bit
set in normal mode only. |
| 2 |
Scan to scan jumps in yaw, pitch, and roll exceed maximum values.
Values are : yaw = 0.0001 radians; pitch = 0.0001 radians; roll =
0.0001 radians. Bit set in normal control mode only. |
| 3 |
In normal mode, yaw outside range (-0.003, 0.003) radians; pitch
outside range (-0.007, 0.007) radians; roll outside range (-0.007,
0.007). |
| 4 |
Satellite undergoing maneuvers during which geolocation will be
less accurate. |
| 5 |
Questionable ephemeris quality (including use of predicted
Ephemeris for quicklook) or questionable UTCF quality. |
| 6 |
Geolocation calculations failed (fill values inserted in the per
pixel geolocation products, but not in metadata). |
| 7 |
Missing attitude data. ACS data gap larger than 20 seconds. |
Value
and Meaning of
Current ACS Mode
|
| Value |
Meaning |
| 0 |
Standby |
| 1 |
Sun Acquire |
| 2 |
Earth Acquire |
| 3 |
Yaw Acquire |
| 4 |
Nominal |
| 5 |
Yaw Maneuver |
| 6 |
Delta-H (Thruster) |
| 7 |
Delta-V (Thruster) |
| 8 |
CERES Calibration |
Bit and
Meaning of
Instrument Status
|
| Bit |
Meaning |
| 0 |
Receiver Status (1=ON, 0=OFF) |
| 1 |
Spin-up Status (1=ON, 0=OFF) |
| 2 |
Spare Command 1 Status |
| 3 |
Spare Command 2 Status |
| 4 |
1 Hz Clock Select (1=A, 0=B) |
| 5 |
21 GHz Cold Count Flag |
| 6 |
Spare Command 4 Status |
| 7 |
Spare Command 5 Status |
TRMM Frequency Analysis Result*
(Number of visits for a 30-day period) |
| Radar Site |
Latitude (°) |
PR (~215 km) |
VIRS (~720 km) |
TMI (~760 km) |
| Kwajalein Atoll |
8.72 |
9 |
29 |
31 |
| Darwin, Australia |
-12.45 |
10 |
31 |
32 |
| Guam |
13.50 |
9 |
32 |
32 |
| Om Koi, Thailand |
17.80 |
9 |
31 |
33 |
| Kauai, HI |
22.17 |
13 |
36 |
38 |
| Sao Paolo, Brazil |
-23.58 |
12 |
41 |
42 |
| Taiwan |
23.92 |
11 |
40 |
42 |
| Key West, FL |
24.67 |
13 |
41 |
42 |
| Miami, FL |
25.75 |
13 |
45 |
45 |
| Brownsville, TX |
25.97 |
13 |
43 |
47 |
| Corpus Christi, TX |
27.85 |
15 |
49 |
51 |
| Tampa, FL |
28.03 |
13 |
51 |
52 |
| Melbourne, FL |
28.10 |
15 |
49 |
53 |
| San Antonio, TX |
29.53 |
16 |
57 |
59 |
| Jacksonville, FL |
30.33 |
19 |
63 |
65 |
| Texas A&M, TX |
30.58 |
18 |
67 |
68 |
| Jerusalem, Israel |
31.87 |
20 |
92 |
102 |
PR:
Precipitation Radar
VIRS: Visible/InfraRed Scanner
TMI: TRMM Microwave Imager
* This analysis result was derived based on TRMM
pre-boost orbital information.
The revisit frequency should be slightly higher after TRMM boost
(August 24, 2001).
If you have questions regarding this table, please send email to:
helpdesk@tsdis02.nascom.nasa.gov. |
|
Atmos Composition
