Measuring rainfall from above and below the sea surface
Measuring rainfall from above and below the sea surface
Satellites play a major role in the determination of the rainfall at sea. Researchers at Southampton Oceanography Centre (SOC) have been involved in two projects addressing this task. First they have been instrumental in developing techniques to retrieve rain rate information from the 10+ years of dual-frequency altimeter data. The TOPEX radar measures rainfall via the attenuation it causes, producing a climatology that is independent of those derived from passive microwave (PM) and infrared (IR) sensors. Because TOPEX is an active microwave sensor, it can have a much smaller footprint than PM sensors. Therefore it can be used to estimate the size of rain cells, showing that the ITCZ and mid-latitude storm tracks are characterized by larger rain systems than elsewhere. TOPEX’s simultaneous recording of wind and wave data reveal that, for mid-latitude systems, rain is most likely in association with developing seas.
All satellite-based datasets require validation, and SOC's work on the development and testing of acoustic rain gauges is the second aspect of this paper. By listening at a range of frequencies, an underwater hydrophone may distinguish the spectra of wind, rain, shipping etc., and estimate the wind speed or rain rate according to the magnitude of the signals. All our campaigns have shown a good acoustic response to changes in wind speed. However the quantitative inversion for recent trials has given values that are too high, possibly because of significant acoustic reflection from the sea bottom. The changes in spectral slope often agree with other observations of rain, although validation experiments in coastal regions are hampered by the extraneous sources present. Acoustic rain gauges would eventually see service not only for routine satellite validation, but also for real-time monitoring of locations of interest.
rainfall, precipitation, satellite altimetry, in situ, acoustic rain gauges, ENSO, inter-annual
Quartly, Graham D.
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Guymer, Trevor H.
41a19cb1-9428-4f0a-b153-2eda2632807e
Srokosz, Meric A.
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Birch, Keith G.
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Jones, Claire E.
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Quartly, Graham D.
3d1e4e87-f001-4d18-b95f-9bca4db6ff9d
Guymer, Trevor H.
41a19cb1-9428-4f0a-b153-2eda2632807e
Srokosz, Meric A.
1e0442ce-679f-43f2-8fe4-9a0f0174d483
Birch, Keith G.
07d58b23-a9f4-4e1f-b03a-6518defb9022
Jones, Claire E.
4d20c9b9-446e-488d-a69e-928e7511cecf
Quartly, Graham D., Guymer, Trevor H., Srokosz, Meric A., Birch, Keith G. and Jones, Claire E.
(2003)
Measuring rainfall from above and below the sea surface.
3rd Global Precipitation Meeting, ESTEC, Noordwijk, The Netherlands.
24 - 26 Jun 2003.
7 pp
.
(Submitted)
Record type:
Conference or Workshop Item
(Paper)
Abstract
Satellites play a major role in the determination of the rainfall at sea. Researchers at Southampton Oceanography Centre (SOC) have been involved in two projects addressing this task. First they have been instrumental in developing techniques to retrieve rain rate information from the 10+ years of dual-frequency altimeter data. The TOPEX radar measures rainfall via the attenuation it causes, producing a climatology that is independent of those derived from passive microwave (PM) and infrared (IR) sensors. Because TOPEX is an active microwave sensor, it can have a much smaller footprint than PM sensors. Therefore it can be used to estimate the size of rain cells, showing that the ITCZ and mid-latitude storm tracks are characterized by larger rain systems than elsewhere. TOPEX’s simultaneous recording of wind and wave data reveal that, for mid-latitude systems, rain is most likely in association with developing seas.
All satellite-based datasets require validation, and SOC's work on the development and testing of acoustic rain gauges is the second aspect of this paper. By listening at a range of frequencies, an underwater hydrophone may distinguish the spectra of wind, rain, shipping etc., and estimate the wind speed or rain rate according to the magnitude of the signals. All our campaigns have shown a good acoustic response to changes in wind speed. However the quantitative inversion for recent trials has given values that are too high, possibly because of significant acoustic reflection from the sea bottom. The changes in spectral slope often agree with other observations of rain, although validation experiments in coastal regions are hampered by the extraneous sources present. Acoustic rain gauges would eventually see service not only for routine satellite validation, but also for real-time monitoring of locations of interest.
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Submitted date: 24 June 2003
Venue - Dates:
3rd Global Precipitation Meeting, ESTEC, Noordwijk, The Netherlands, 2003-06-24 - 2003-06-26
Keywords:
rainfall, precipitation, satellite altimetry, in situ, acoustic rain gauges, ENSO, inter-annual
Identifiers
Local EPrints ID: 144
URI: http://eprints.soton.ac.uk/id/eprint/144
PURE UUID: 10c741fe-06b4-414b-8364-1e9a29773baa
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Date deposited: 02 Sep 2003
Last modified: 15 Mar 2024 04:37
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Contributors
Author:
Graham D. Quartly
Author:
Trevor H. Guymer
Author:
Meric A. Srokosz
Author:
Keith G. Birch
Author:
Claire E. Jones
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