N: 50 S: -50 E: 180 W: -180
Description
TMPA (3B42_Daily) dataset have been discontinued as of Dec. 31, 2019, and users are strongly encouraged to shift to the successor IMERG dataset (doi: 10.5067/GPM/IMERGDF/DAY/06).
This daily accumulated precipitation product is generated from the research-quality 3-hourly TRMM Multi-Satellite Precipitation Analysis TMPA (3B42). It is produced at the NASA GES DISC, as a value added product. Simple summation of valid retrievals in a grid cell is applied for the data day. The result is given in (mm). The beginning and ending time for every daily granule are listed in the file global attributes, and are taken correspondingly from the first and the last 3-hourly granules participating in the aggregation. Thus the time period covered by one daily granule amounts to 24 hours, which can be inspected in the file global attributes.
Counts of valid retrievals for the day are provided for every variable, making it possible to compute conditional and unconditional mean precipitation for grid cells where less than 8 retrievals for the day are available.
Efforts have been made to make the format of this derived product as similar as possible to the new Global Precipitation Measurement CF-compliant file format.
The information provided here on the TRMM mission, and on the original 3-hr 3B42 product, remain relevant for this derived product. Note, however, this product is in netCDF-4 format.
The following describes the derivation in more details.
The daily accumulation is derived by summing valid retrievals in a grid cell for the data day. Since the 3-hourly source data are in mm/hr, a factor of 3 is applied to the sum. Thus, for every grid cell we have
Pdaily = 3 SUM{Pi 1[Pi valid]}, i=[1,Nf]
Pdaily_cnt = SUM{1[Pi valid]}
where:
Pdaily - Daily accumulation (mm)
Pi - 3-hourly input, in (mm/hr)
Nf - Number of 3-hourly files per day, Nf=8
1[.] - Indicator function; 1 when Pi is valid, 0 otherwise
Pdaily_cnt - Number of valid retrievals in a grid cell per day.
Grid cells for which Pdaily_cnt=0, are set to fill value in the Daily files.
Note that Pi=0 is a valid value.
On occasion, the 3-hourly source data have fill values for Pi in a very few grid cells. The total accumulation for such grid cells is still issued, inspite of the likelihood that thus resulting accumulation has a larger uncertainty in representing the "true" daily total. These events are easily detectable using "counts" variables that contain Pdaily_cnt, whereby users can screen out any grid cells for which
Pdaily_cnt less than Nf.
There are various ways the accumulated daily error could be estimated from the source 3-hourly error. In this release, the daily error provided in the data files is calculated as follows. First, squared 3-hourly errors are summed, and then square root of the sum is taken. Similarly to the precipitation, a factor of 3 is finally applied:
Perr_daily = 3 { SUM[ (Perr_i 1[Perr_i valid])^2 ] }^0.5 , i=[1,Nf]
Ncnt_err = SUM( 1[Perr_i valid] )
where:
Perr_daily - Magnitude of the daily accumulated error power, (mm)
Ncnt_err - The counts for the error variable
Thus computed Perr_daily represents the worst case scenario that assumes the error in the 3-hourly source data, which is given in mm/hr, accumulates first within the 3-hour period of the source data, and then continues to accumulate during the day. These values, however, can easily be converted to root mean square error estimate of the rainfall rate:
rms_err = { (Perr_daily/3) ^2 / Ncnt_err }^0.5 (mm/hr)
This estimate assumes that the error given in the 3-hourly files is representative of the error of the rainfall rate (mm/hr) within the 3-hour window of the files, and it is random throughout the day. Note, this should be interpreted as the error of the rainfall rate (mm/hr) for the day, not the daily accumulation.
Product Summary
Citation
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Documents
Publications Citing This Dataset
| Title | Year Sort ascending | Author | Topic |
|---|---|---|---|
| Moist Entropy and Water Isotopologues in a Zonal Overturning Circulation Framework of the MaddenJulian Oscillation | Hurley, John V., Verlinden, Kathryn L., Blossey, Peter N., Kuang, Zhiming, Noone, David | Total Surface Precipitation Rate | |
| The northeast winter monsoon over the Indian subcontinent and Southeast Asia: evolution, interannual variability, and model simulations | Sengupta, Agniv, Nigam, Sumant | Total Surface Precipitation Rate | |
| Performance evaluation of three satellites-based precipitation data sets over Iran | Miri, Morteza, Masoudi, Reyhaneh, Raziei, Tayeb | Total Surface Precipitation Rate, Precipitation, Precipitation Amount, Precipitation Rate, Snow, Rain | |
| Hydrologic Response to Land Use Change in a Large Basin in Eastern Amazon | Dos Santos, Vanessa, Laurent, Francois, Abe, Camila, Messner, Francois | Deforestation, Land Use/Land Cover Classification, Leaf Characteristics, Leaf Area Index (LAI), Soil Bulk Density, Soil Chemistry, Soil Temperature, Forest Composition/Vegetation Structure, Vegetation Species, Soil Classification, Soil Color, Potassium, Nutrients, Calcium, Magnesium, Nitrogen, Phosphorus, Total Surface Precipitation Rate | |
| Landslide inventory for hazard assessment in a data-poor context: a regional-scale approach in a tropical African environment | Monsieurs, Elise, Jacobs, Liesbet, Michellier, Caroline, Basimike Tchangaboba, Joseph, Ganza, Gloire Bamulezi, Kervyn, Francois, Maki Mateso, Jean-Claude, Mugaruka Bibentyo, Toussaint, Kalikone Buzera, Christian, Nahimana, Louis, Ndayisenga, Aloys, Nkurunziza, Pascal, Thiery, Wim, Demoulin, Alain, Kervyn, Matthieu, Dewitte, Olivier | Population Density, Total Surface Precipitation Rate | |
| A new mechanism for the dependence of tropical convection on freetropospheric humidity | Virman, M., Bister, M., Sinclair, V. A., Jarvinen, H., Raisanen, J. | Total Surface Precipitation Rate | |
| Assessing suitability of satellite rainfall data for estimation of daily streamflows of a small tropical catchment In India | Nandi, Saswata, Reddy, M Janga | Total Surface Precipitation Rate | |
| Atmospheric water budget over the South Asian summer monsoon region | Unnikrishnan, C. K., Rajeevan, M. | Total Surface Precipitation Rate | |
| Evaluation of satellite-based precipitation products from IMERG V04A and V03D, CMORPH and TMPA with gauged rainfall in three climatologic zones in China | Wei, Guanghua, Lu, Haishen, T. Crow, Wade, Zhu, Yonghua, Wang, Jianqun, Su, Jianbin | Total Surface Precipitation Rate, Cloud Liquid Water/Ice, Precipitation Amount, Precipitation Rate | |
| Linking stochasticity of convection to large-scale vertical velocity to improve Indian summer monsoon simulation in the NCAR CAM5 | Wang, Yong, Zhang, Guang J., Jiang, Yiquan | Total Surface Precipitation Rate | |
| A study of Bangladesh's sub-surface water storages using satellite | Khaki, M., Forootan, E., Kuhn, M., Awange, J., Papa, F., Shum, C.K. | Total Surface Precipitation Rate | |
| Evaluation and hydrological application of satellite-based precipitation datasets in driving hydrological models over the Huifa river basin in Northeast China | Zhu, Honglei, Li, Ying, Huang, Yanwei, Li, Yingchen, Hou, Cuicui, Shi, Xiaoliang | Total Surface Precipitation Rate | |
| Impact of Change in Monsoonal Circulation Due to SST Warming on the North East Asian Monsoon: A Model Analysis Using Satellite Based Sub-Grid Hydrometeors | Bhattacharya, Anwesa, Park, Rae Seol, Kwon, Young Cheol | Total Surface Precipitation Rate, Condensation, Evaporation, Sublimation, Cloud Liquid Water/Ice, Cloud Precipitable Water, Liquid Water Equivalent, Precipitation Rate, Rain, Heat Flux | |
| Observations of Precipitable Water Vapor along the Maritime Continent Associated with El Nino-Southern Oscillation Activity | Suparta, Wayan | Total Surface Precipitation Rate | |
| On the ecohydrology of the Yucatan Peninsula: Evapotranspiration and carbon intake dynamics across an ecoclimatic gradient | UuhSonda, Jorge M., GutierrezJurado, Hugo A., FigueroaEspinoza, Bernardo, MendezBarroso, Luis A. | Total Surface Precipitation Rate | |
| Open and scalable analytics of large Earth observation datasets: From scenes to multidimensional arrays using SciDB and GDAL | Appel, Marius, Lahn, Florian, Buytaert, Wouter, Pebesma, Edzer | Total Surface Precipitation Rate | |
| Statistical modeling of extreme precipitation with TRMM data | Demirdjian, Levon, Zhou, Yaping, Huffman, George J. | Total Surface Precipitation Rate | |
| Performances of GPM satellite precipitation over the two major Mediterranean islands | Caracciolo, Domenico, Francipane, Antonio, Viola, Francesco, Noto, Leonardo Valerio, Deidda, Roberto | Total Surface Precipitation Rate | |
| Prediction of drought on pentad scale using remote sensing data and MJO index through random forest over East Asia | Park, Seonyoung, Seo, Eunkyo, Kang, Daehyun, Im, Jungho, Lee, Myong-In | Total Surface Precipitation Rate | |
| Rainfall from resolved rather than parameterized processes better represents the presentday and climate change response of moderate rates in the community ... | Kooperman, Gabriel J., Pritchard, Michael S., O'Brien, Travis A., Timmermans, Ben W. | Total Surface Precipitation Rate | |
| Rainfall thresholds for possible landslide occurrence in Ulu Kelang, Selangor, Malaysia using TRMM satellite precipitation estimates | Yaacob, Norsuzila, Tajudin, Noraisyah, Yusof, Azita laily, Ali, Darmawaty Mohd, Sarnin, Suzi Seroja | Total Surface Precipitation Rate | |
| Rainfall variability, wetland persistence, and watercarbon cycle coupling in the Upper Zambezi river basin in Southern Africa | Lowman, Lauren E. L., Wei, Tiffany M., Barros, Ana P. | Droplet Size, Precipitation Rate, Radar Reflectivity, Total Surface Precipitation Rate | |
| Rainfalllandslide potential mapping using remote sensing and GIS at Ulu Kelang, Selangor, Malaysia | Tajudin, Noraisyah, Yaacob, Norsuzila, Ali, Darmawaty Mohd, Adnan, Noraizam, Naim, Nani Fadzlina | Total Surface Precipitation Rate | |
| Assessment of the consistency among global precipitation products over the United Arab Emirates | Wehbe, Youssef, Ghebreyesus, Dawit, Temimi, Marouane, Milewski, Adam, Al Mandous, Abdulla | Total Surface Precipitation Rate | |
| Chloromethane and dichloromethane in the tropical Atlantic Ocean | Kolusu, Seshagiri Rao, Schlunzen, K. Heinke, Grawe, David, Seifert, Richard | Total Surface Precipitation Rate |