Tropical Rainfall Measuring Mission
Artist conception of the TRMM satellite | |
Mission type | Environmental research |
---|---|
Operator | JAXA / NASA |
COSPAR ID | 1997-074A |
SATCAT № | 25063 |
Spacecraft properties | |
Launch mass | 3524 kg[1] |
Dry mass | 2634 kg[1] |
Power | 1100 W[1] |
Start of mission | |
Launch date | 27 November 1997 |
Rocket | H-II[1] |
Launch site | Tanegashima Space Center |
End of mission | |
Deactivated | 9 April 2015 |
Orbital parameters | |
Reference system | Geocentric |
Regime | LEO |
Eccentricity | 0.0001344 |
Perigee | 174 kilometers (108 mi) |
Apogee | 176 kilometers (109 mi) |
Inclination | 34.9372° |
Period | 92.5 minutes |
RAAN | 203.9770 degrees |
Argument of perigee | 140.8634 degrees |
Mean anomaly | 219.2792 degrees |
Mean motion | 16.36482121[2] |
Epoch | 15 June 2015 at 18:20:01 UTC |
The Tropical Rainfall Measuring Mission (TRMM) was a joint space mission between NASA and the Japan Aerospace Exploration Agency (JAXA) designed to monitor and study tropical rainfall. The term refers to both the mission itself and the satellite that the mission used to collect data. TRMM was part of NASA's Mission to Planet Earth, a long-term, coordinated research effort to study the Earth as a global system. The satellite was launched on November 27, 1997 from the Tanegashima Space Center in Tanegashima, Japan.
As of July 2014, fuel to maintain orbital altitude was insufficient and NASA ceased station-keeping maneuvers for TRMM, allowing the spacecraft's orbit to slowly decay. Re-entry was originally expected sometime between May 2016 and November 2017.[3] The probe was turned off on April 9, 2015 after its orbital decay accelerated.[4] Re-entry occurred on June 16, 2015 at 06:54 UTC.[5]
Background
Tropical precipitation is a difficult parameter to measure, due to large spatial and temporal variations. However, understanding tropical precipitation is important for weather and climate prediction, as this precipitation contains three-fourths of the energy that drives atmospheric wind circulation.[6] Prior to TRMM, the distribution of rainfall worldwide was known to only a 50% degree of uncertainty.[7]
The concept for TRMM was first proposed in 1984. The science objectives, as first proposed, were:[6]
- To advance understanding of the global energy and water cycles by providing distributions of rainfall and latent heating over the global Tropics.
- To understand the mechanisms through which changes in tropical rainfall influence global circulation and to improve ability to model these processes in order to predict global circulations and rainfall variability at monthly and longer timescales.
- To provide rain and latent heating distributions to improve the initialization of models ranging from 24-hour forecasts to short-range climate variations.
- To help to understand, to diagnose, and to predict the onset and development of the El Niño, Southern Oscillation, and the propagation of the 30- to 60-day oscillations in the Tropics.
- To help to understand the effect that rainfall has on the ocean thermohaline circulations and the structure of the upper ocean.
- To allow cross calibration between TRMM and other sensors with life expectancies beyond that of TRMM itself.
- To evaluate the diurnal variability of tropical rainfall globally.
- To evaluate a space-based system for rainfall measurements.
Japan joined the initial study for the TRMM mission in 1986.[6] Development of the satellite became a joint project between the space agencies of the U.S. and Japan, with Japan providing the Precipitation Radar (PR) and H-II launch vehicle, and the U.S. providing the satellite bus and remaining instruments.[8] The project received formal support from the U.S. congress in 1991, followed by spacecraft construction from 1993 through 1997. TRMM launched from Tanegashima Space Center on 27 November 1997.[6]
Instruments aboard the TRMM
Precipitation Radar (PR)
The Precipitation Radar was the first space-borne instrument designed to provide three-dimensional maps of storm structure. The measurements yielded information on the intensity and distribution of the rain, on the rain type, on the storm depth and on the height at which the snow melts into rain. The estimates of the heat released into the atmosphere at different heights based on these measurements can be used to improve models of the global atmospheric circulation. The PR operated at 13.8 GHz and measured the 3-d rainfall distribution over land and ocean surfaces. It defined a layer depth of perception and hence measured rainfall that actually reached the latent heat of atmosphere. It had a 4.3 km resolution at radii with 220 km swath.
TRMM Microwave Imager (TMI)
The TRMM Microwave Imager (TMI) was a passive microwave sensor designed to provide quantitative rainfall information over a wide swath under the TRMM satellite. By carefully measuring the minute amounts of microwave energy emitted by the Earth and its atmosphere, TMI was able to quantify the water vapor, the cloud water, and the rainfall intensity in the atmosphere. It was a relatively small instrument that consumed little power. This, combined with the wide swath and the quantitative information regarding rainfall made TMI the "workhorse" of the rain-measuring package on Tropical Rainfall Measuring Mission.
Visible and Infrared Scanner (VIRS)
The Visible and Infrared Scanner was one of the three instruments in the rain-measuring package and serves as a very indirect indicator of rainfall. VIRS, as its name implies, sensed radiation coming up from the Earth in five spectral regions, ranging from visible to infrared, or 0.63 to 12 micrometers. VIRS was included in the primary instrument package for two reasons. First was its ability to delineate rainfall. The second, and even more important reason, was to serve as a transfer standard to other measurements that are made routinely using POES and GOES satellites. The intensity of the radiation in the various spectral regions (or bands) can be used to determine the brightness (visible and near infrared) or temperature (infrared) of the source.
Clouds and the Earth's Radiant Energy Sensor (CERES)
CERES measured the energy at the top of the atmosphere, as well as estimates energy levels within the atmosphere and at the Earth's surface. The CERES instrument was based on the successful Earth Radiation Budget Experiment which used three satellites to provide global energy budget measurements from 1984 to 1993.[9] Using information from very high resolution cloud imaging instruments on the same spacecraft, CERES determines cloud properties, including cloud-amount, altitude, thickness, and the size of the cloud particles. These measurements are important to understanding the Earth's total climate system and improving climate prediction models. It only operated during January - August 1998, and March 2000, so the available data record is quite brief (although later CERES instruments were flown on other missions such as the Earth Observing System (EOS) AM and PM satellites.)
Lightning Imaging Sensor (LIS)
The Lightning Imaging Sensor was a small, highly sophisticated instrument that detects and locates lightning over the tropical region of the globe. The lightning detector was a compact combination of optical and electronic elements including a staring imager capable of locating and detecting lightning within individual storms. The imager's field of view allowed the sensor to observe a point on the Earth or a cloud for 80 seconds, a sufficient time to estimate the flashing rate, which told researchers whether a storm was growing or decaying.
See also
- Global Precipitation Measurement, successor spacecraft launched Feb 2014
References
- 1 2 3 4 "Satellite Overview."JAXA. Retrieved: 5 July 2015
- ↑ TRMM - Orbit. Heavens Above. Retrieved: 23 April 2016.
- ↑ “Rainfall Research Satellite Begins Decent from Orbit”. ‘’Spaceflight Now’’. Retrieved: 17 September 2014.
- ↑ https://twitter.com/NASA/status/608050374994477057/
- ↑ http://www.nasa.gov/feature/rainfall-spacecraft-re-enters-over-tropics
- 1 2 3 4 Kummerow, C; J. Simpson; O. Thiele; W. Barnes; A. T. C. Chang; E. Stocker; R. F. Adler; A. Hou; R. Kakar; F. Wentz; et al. (December 2000). "The Status of the Tropical Rainfall Measuring Mission (TRMM) after Two Years in Orbit". Journal of Applied Meteorology. 39: 1965–1982. Bibcode:2000JApMe..39.1965K. doi:10.1175/1520-0450(2001)040<1965:TSOTTR>2.0.CO;2.
- ↑ "Tropical Rainfall Measuring Mission University."NASA. Retrieved: 5 July 2015.
- ↑ "History of TRMM." JAXA. Retrieved: 5 July 2015.
- ↑ NASA, Clouds and the Earth's Radiant Energy System (CERES) (accessed Sept. 9, 2014)
External links
- TRMM home page
- Twitter and Facebook
- Tropical Rainfall Measuring Mission Profile by NASA's Solar System Exploration
- TRMM De-Orbit Alternatives