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Satellite Precipitation Measurement : Volume 1 (2020)

Levizzani, Vincenzo. [editor.] ; Kidd, Christopher. [editor.] ; Kirschbaum, Dalia B. [editor.] ; [et al.]

Cham :Springer International Publishing :

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Keywords: Atmospheric science. ; Water. ; Hydrology. ; Climatology. ; Measurement. ; Measuring instruments. ; Atmospheric Science. ; Water. ; Climate Sciences. ; Measurement Science and Instrumentation.

Description / Table of Contents: SECTION 1 Status of Observations and Satellite Programs: Chapter 1. The Global Precipitation Measurement (GPM) mission -- Chapter 2. Status of the CloudSat mission -- Chapter 3. The Megha-Tropiques mission after seven years in space -- Chapter 4. Microwave sensors, imagers and sounders -- Chapter 5. Microwave and sub-mm wave sensors: A European perspective -- Chapter 6. Plans for future missions -- SECTION 2 Retrieval Techniques, Algorithms and Sensors: Chapter 7. Introduction to passive microwave retrieval methods -- Chapter 8. The Goddard Profiling (GPROF) precipitation retrieval algorithm -- Chapter 9. Precipitation estimation from the Microwave Integrated Retrieval System (MiRS) -- Chapter 10. Introduction to radar rain retrieval methods -- Chapter 11. Dual-frequency Precipitation Radar (DPR) on the Global Precipitation Measurements (GPM) mission’s Core Observatory -- Chapter 12. DPR dual-frequency precipitation classification -- Chapter 13. Triple-frequency radar retrievals -- Chapter 14. Precipitation retrievals from satellite combined radar and radiometer observations -- Chapter 15. Scattering of hydrometeors -- Chapter 16. Radar snowfall measurement -- Chapter 17. A 1DVar-based snowfall rate algorithm for passive microwave radiometers -- Chapter 18. X-band synthetic aperture radar methods -- SECTION 3 Merged Precipitation Products: Chapter 19. Integrated Multi-satellitE Retrievals for the Global Precipitation Measurement (GPM) mission (IMERG) -- Chapter 20. Global Satellite Mapping of Precipitation (GSMaP) products in the GPM era -- Chapter 21. Improving PERSIANN-CCS using passive microwave rainfall estimation -- Chapter 22. TAMSAT -- Chapter 23. Algorithm and data improvements for version 2.1 of the Climate Hazards Center’s Infrared Precipitation with Stations Data Set -- Chapter 24. Merging the infrared fleet and the microwave constellation for tropical hydrometeorology (TAPEER) and global climate monitoring (GIRAFE) applications -- SECTION 4 Validation: Chapter 25. The IPWG satellite precipitation validation effort -- Chapter 26. The GPM Ground Validation Program -- Chapter 27. The GPM DPR Validation Program -- Chapter 28. Error and uncertainty characterization -- Chapter 29. Multiscale evaluation of satellite precipitation products: Effective resolution of IMERG -- Chapter 30. Remote sensing of orographic precipitation -- Chapter 31. Integrated multi-satellite evaluation for the Global Precipitation Measurement: Impact of precipitation types on spaceborne precipitation estimation -- Chapter 32. Hydrologic validation and flood analysis -- Chapter 33. Global-scale evaluation of 22 precipitation datasets using gauge observations and hydrological modeling -- Chapter 34. OceanRAIN – The global ocean surface-reference dataset for characterization, validation and evaluation of the water cycle -- SECTION 5 Observed Characteristics of Precipitation: Chapter 35. GPCP and the global characteristics of precipitation -- Chapter 36. Global snowfall detection and measurement -- Chapter 37. Snowfall detection by spaceborne radars -- Chapter 38. On the duration and lifecyle of precipitation systems in the tropics -- Chapter 39. Observational characteristics of warm-type heavy rainfall -- Chapter 40. Satellite precipitation measurement and extreme rainfall -- Chapter 41. Rainfall trends in East Africa from an ensemble of IR-based satellite products -- Chapter 42. Heavy precipitation systems in the Mediterranean area: The role of GPM -- Chapter 43. Dryland precipitation climatology from satellite observations -- Chapter 44. Haifall detection -- Chapter 45. Improving high-latitude and cold region precipitation analysis -- Chapter 46. Latent heating retrievals from satellite observations -- SECTION 6 Applications: Chapter 47. Operational applications of Global Precipitation Measurement observations -- Chapter 48. Assimilation of precipitation observations from space into numerical weather prediction (NWP) -- Chapter 49. Precipitation ensemble data assimilation in NWP models -- Chapter 50. PERSIANN-CDR for hydrology and hydro-climatic applications -- Chapter 51. Soil moisture and precipitation: The SM2RAIN algorithm for rainfall retrieval from satellite soil moisture -- Chapter 52. Drought risk management using satellite-based rainfall estimates -- Chapter 53. Two decades of urban hydroclimatological studies have yielded discovery and societal benefits -- Chapter 54. Validation of climate models -- Chapter 55. Extreme precipitation in the Himalayan landslide hotspot -- Chapter 56. The value of satellite rainfall estimates in agriculture and food security -- Chapter 57. Using satellite estimates of precipitation for fire danger rating -- Chapter 58. Variability of satellite sea surface salinity under rainfall.

Abstract: This book offers a complete overview of the measurement of precipitation from space, which has made considerable advancements during the last two decades. This is mainly due to the Tropical Rainfall Measuring Mission (TRMM), the Global Precipitation Measurement (GPM) mission, CloudSat and a carefully maintained constellation of satellites hosting passive microwave sensors. The book revisits a previous book, Measuring Precipitation from Space, edited by V. Levizzani, P. Bauer and F. J. Turk, published with Springer in 2007. The current content has been completely renewed to incorporate the advancements of science and technology in the field since then. This book provides unique contributions from field experts and from the International Precipitation Working Group (IPWG). The book will be of interest to meteorologists, hydrologists, climatologists, water management authorities, students at various levels and many other parties interested in making use of satellite precipitation data sets. Chapter “TAMSAT” is available open access under a Creative Commons Attribution 4.0 International License via link.springer.com.

Type of Medium: Online Resource

Pages: LXXI, 450 p. 108 illus. in color. , online resource.

Edition: 1st ed. 2020.

ISBN: 9783030245689

Series Statement: Advances in Global Change Research, 67

URL: https://doi.org/10.1007/978-3-030-24568-9

DOI: 10.1007/978-3-030-24568-9

DDC: 551.5

Language: English

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Satellite Precipitation Measurement : Volume 2 (2020)

Levizzani, Vincenzo. [editor.] ; Kidd, Christopher. [editor.] ; Kirschbaum, Dalia B. [editor.] ; [et al.]

Cham :Springer International Publishing :

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Keywords: Atmospheric science. ; Climatology. ; Measurement. ; Measuring instruments. ; Water. ; Hydrology. ; Atmospheric Science. ; Climate Sciences. ; Measurement Science and Instrumentation. ; Water.

Description / Table of Contents: SECTION 4 Validation: Chapter 25. The IPWG satellite precipitation validation effort -- Chapter 26. The GPM Ground Validation Program -- Chapter 27. The GPM DPR Validation Program -- Chapter 28. Error and uncertainty characterization -- Chapter 29. Multiscale evaluation of satellite precipitation products: Effective resolution of IMERG -- Chapter 30. Remote sensing of orographic precipitation -- Chapter 31. Integrated multi-satellite evaluation for the Global Precipitation Measurement: Impact of precipitation types on spaceborne precipitation estimation -- Chapter 32. Hydrologic validation and flood analysis -- Chapter 33. Global-scale evaluation of 22 precipitation datasets using gauge observations and hydrological modeling -- Chapter 34. OceanRAIN – The global ocean surface-reference dataset for characterization, validation and evaluation of the water cycle -- SECTION 5 Observed Characteristics of Precipitation: Chapter 35. GPCP and the global characteristics of precipitation -- Chapter 36. Global snowfall detection and measurement -- Chapter 37. Snowfall detection by spaceborne radars -- Chapter 38. On the duration and lifecyle of precipitation systems in the tropics -- Chapter 39. Observational characteristics of warm-type heavy rainfall -- Chapter 40. Satellite precipitation measurement and extreme rainfall -- Chapter 41. Rainfall trends in East Africa from an ensemble of IR-based satellite products -- Chapter 42. Heavy precipitation systems in the Mediterranean area: The role of GPM -- Chapter 43. Dryland precipitation climatology from satellite observations -- Chapter 44. Haifall detection -- Chapter 45. Improving high-latitude and cold region precipitation analysis -- Chapter 46. Latent heating retrievals from satellite observations -- SECTION 6 Applications: Chapter 47. Operational applications of Global Precipitation Measurement observations -- Chapter 48. Assimilation of precipitation observations from space into numerical weather prediction (NWP) -- Chapter 49. Precipitation ensemble data assimilation in NWP models -- Chapter 50. PERSIANN-CDR for hydrology and hydro-climatic applications -- Chapter 51. Soil moisture and precipitation: The SM2RAIN algorithm for rainfall retrieval from satellite soil moisture -- Chapter 52. Drought risk management using satellite-based rainfall estimates -- Chapter 53. Two decades of urban hydroclimatological studies have yielded discovery and societal benefits -- Chapter 54. Validation of climate models -- Chapter 55. Extreme precipitation in the Himalayan landslide hotspot -- Chapter 56. The value of satellite rainfall estimates in agriculture and food security -- Chapter 57. Using satellite estimates of precipitation for fire danger rating -- Chapter 58. Variability of satellite sea surface salinity under rainfall.

Type of Medium: Online Resource

Pages: XCIII, 725 p. 300 illus., 251 illus. in color. , online resource.

Edition: 1st ed. 2020.

ISBN: 9783030357986

Series Statement: Advances in Global Change Research, 69

URL: https://doi.org/10.1007/978-3-030-35798-6

DOI: 10.1007/978-3-030-35798-6

DDC: 551.5

Language: English

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Relationships between the Raindrop Size Distribution and Properties of the Environment and Clouds Inferred from TRMM (2013)

Elsaesser, Gregory ; Munchak, Stephen Joseph ; Kummerow, Christian

In: CASI

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Publication Date: 2019-07-12

Description: Variability in the raindrop sized distribution (DSD) has long been recognized as a source of uncertainty in relationships between radar reflectivity Z and rain rate R. In this study, we analyze DSD retrievals from two years of data gathered by the Tropical Rainfall Measuring Mission (TRMM) satellite and processed with a combined radar-radiometer retrieval algorithm over the global oceans equatorward of 35. Numerous variables describing properties of each reflectivity profile, large-scale organization, and the background environment are examined for relationships to the reflectivity-normalized median drop diameter, epsilonDSD. In general, we find that higher freezing levels and relative humidities are associated with smaller epsilonDSD. Within a given environment, the mesoscale organization of precipitation and the vertical profile of reflectivity are associated with DSD characteristics. In the tropics, the smallest epsilonDSD values are found in large but shallow convective systems, where warm rain formation processes are thought to be predominant, whereas larger sizes are found in the stratiform regions of organized deep convection. In the extratropics, the largest epsilonDSD values are found in the scattered convection that occurs when cold, dry continental air moves over the much warmer ocean after the passage of a cold front. The geographical distribution of the retrieved DSDs is consistent with many of the observed regional ZR relationships found in the literature as well as discrepancies between the TRMM radar-only and radiometer-only precipitation products. In particular, mid-latitude and tropical regions near land tend to have larger drops for a given reflectivity, whereas the smallest drops are found in the eastern Pacific Intertropical Convergence Zone.

Keywords: Communications and Radar; Earth Resources and Remote Sensing

Type: GSFC-E-DAA-TN9046

Format: application/pdf

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Closing the water cycle from observations across scales: where do we stand? (2022)

Dorigo, Wouter ; Dietrich, Stephan ; Aires, Filipe ; [et al.]

American Meteorological Society

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Publication Date: 2022-05-27

Description: Author Posting. © American Meteorological Society, 2021. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Bulletin of the American Meteorological Society 102(10), (2021): E1897–E1935, https://doi.org/10.1175/BAMS-D-19-0316.1.

Description: Life on Earth vitally depends on the availability of water. Human pressure on freshwater resources is increasing, as is human exposure to weather-related extremes (droughts, storms, floods) caused by climate change. Understanding these changes is pivotal for developing mitigation and adaptation strategies. The Global Climate Observing System (GCOS) defines a suite of essential climate variables (ECVs), many related to the water cycle, required to systematically monitor Earth’s climate system. Since long-term observations of these ECVs are derived from different observation techniques, platforms, instruments, and retrieval algorithms, they often lack the accuracy, completeness, and resolution, to consistently characterize water cycle variability at multiple spatial and temporal scales. Here, we review the capability of ground-based and remotely sensed observations of water cycle ECVs to consistently observe the hydrological cycle. We evaluate the relevant land, atmosphere, and ocean water storages and the fluxes between them, including anthropogenic water use. Particularly, we assess how well they close on multiple temporal and spatial scales. On this basis, we discuss gaps in observation systems and formulate guidelines for future water cycle observation strategies. We conclude that, while long-term water cycle monitoring has greatly advanced in the past, many observational gaps still need to be overcome to close the water budget and enable a comprehensive and consistent assessment across scales. Trends in water cycle components can only be observed with great uncertainty, mainly due to insufficient length and homogeneity. An advanced closure of the water cycle requires improved model–data synthesis capabilities, particularly at regional to local scales.

Description: WD acknowledges ESA’s QA4EO (ISMN) and CCI Soil Moisture projects. WD, CRV, AG, and KL acknowledge the G3P project, which has received funding from the European Union’s Horizon 2020 research and innovation programme under Grant Agreement 870353. MIH and MS acknowledge ESA’s CCI Water Vapour project. MS and RH acknowledges the support by the EUMETSAT member states through CM SAF. DGM acknowledges support from the European Research Council (ERC) under Grant Agreement 715254 (DRY–2–DRY). Part of this research was carried out at the Jet Propulsion Laboratory, California Institute of Technology, under a contract with the National Aeronautics and Space Administration (80NM0018D0004).

Description: 2022-04-01

Keywords: Hydrologic cycle ; Satellite observations ; Surface fluxes ; Surface observations ; Water masses/storage ; Water budget/balance

Repository Name: Woods Hole Open Access Server

Type: Article

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