Sea Level Monitoring Using a GNSS-Based Tide Gauge
Global climate change is believed to result in the melting of large masses of ice in Polar Regions, bringing freshwater into the ocean, and changing the sea level. The traditional way to measure the sea level, by tide gauges, results in measurements relative to the Earth’s crust. However, in order t...
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| Online Access: | https://research.chalmers.se/en/publication/102006 |
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ftchalmersuniv:oai:research.chalmers.se:102006 2024-11-03T14:55:24+00:00 Sea Level Monitoring Using a GNSS-Based Tide Gauge Löfgren, Johan Haas, Rüdiger Johansson, Jan 2009 text https://research.chalmers.se/en/publication/102006 unknown https://research.chalmers.se/en/publication/102006 Other Engineering and Technologies not elsewhere specified Other Earth and Related Environmental Sciences Earth and Related Environmental Sciences Geophysics Oceanography Hydrology Water Resources GNSS sea level monitoring tide gauge reflection signals 2009 ftchalmersuniv 2024-10-22T15:54:49Z Global climate change is believed to result in the melting of large masses of ice in Polar Regions, bringing freshwater into the ocean, and changing the sea level. The traditional way to measure the sea level, by tide gauges, results in measurements relative to the Earth’s crust. However, in order to fully understand the sea level changes, absolute measurements (change in sea level in relation to the Earth’s center of gravity) are necessary, in particular in regions affected by post-glacial uplift, e.g., Fennoscandia. Satellite techniques, e.g., GNSS can be used to determine the motion of the Earth’s crust in relation to the center of gravity. By measuring reflected GNSS-signals from the sea surface, information of the sea level change can be obtained. Therefore a GNSS-based tide gauge is proposed.The proposed GNSS-based tide gauge installation consists of two antennas, one zenith looking right hand circular polarized (RHCP) and one nadir looking left hand circular polarized (LHCP), mounted back-to-back on a beam over the ocean. The RHCP antenna receives the GNSS-signals directly, whereas the LHCP antenna receives the signals reflected from the sea surface. Because of the additional path delay of the reflected signal, the LHCP antenna will appear to be a virtual GNSS-antenna located below the sea surface. When the sea level changes, the path delay of the reflected signal changes, thus the LHCP antenna will appear to be in a new position. The vertical position change corresponds to twice the sea level change, and therefore monitors sea level changes.Multiple satellites with different elevation and azimuth angles are observed each epoch and will give rise to reflected signals with different incidence angles from different directions. This means that the estimated sea level change can not be considered to originate from one specific point on the surface, but rather represents the change of an average surface formed by the reflection points.An experimental setup was installed in December 2008 over the ocean at ... Other/Unknown Material Fennoscandia Chalmers University of Technology: Chalmers research |
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Open Polar |
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Chalmers University of Technology: Chalmers research |
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ftchalmersuniv |
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unknown |
| topic |
Other Engineering and Technologies not elsewhere specified Other Earth and Related Environmental Sciences Earth and Related Environmental Sciences Geophysics Oceanography Hydrology Water Resources GNSS sea level monitoring tide gauge reflection signals |
| spellingShingle |
Other Engineering and Technologies not elsewhere specified Other Earth and Related Environmental Sciences Earth and Related Environmental Sciences Geophysics Oceanography Hydrology Water Resources GNSS sea level monitoring tide gauge reflection signals Löfgren, Johan Haas, Rüdiger Johansson, Jan Sea Level Monitoring Using a GNSS-Based Tide Gauge |
| topic_facet |
Other Engineering and Technologies not elsewhere specified Other Earth and Related Environmental Sciences Earth and Related Environmental Sciences Geophysics Oceanography Hydrology Water Resources GNSS sea level monitoring tide gauge reflection signals |
| description |
Global climate change is believed to result in the melting of large masses of ice in Polar Regions, bringing freshwater into the ocean, and changing the sea level. The traditional way to measure the sea level, by tide gauges, results in measurements relative to the Earth’s crust. However, in order to fully understand the sea level changes, absolute measurements (change in sea level in relation to the Earth’s center of gravity) are necessary, in particular in regions affected by post-glacial uplift, e.g., Fennoscandia. Satellite techniques, e.g., GNSS can be used to determine the motion of the Earth’s crust in relation to the center of gravity. By measuring reflected GNSS-signals from the sea surface, information of the sea level change can be obtained. Therefore a GNSS-based tide gauge is proposed.The proposed GNSS-based tide gauge installation consists of two antennas, one zenith looking right hand circular polarized (RHCP) and one nadir looking left hand circular polarized (LHCP), mounted back-to-back on a beam over the ocean. The RHCP antenna receives the GNSS-signals directly, whereas the LHCP antenna receives the signals reflected from the sea surface. Because of the additional path delay of the reflected signal, the LHCP antenna will appear to be a virtual GNSS-antenna located below the sea surface. When the sea level changes, the path delay of the reflected signal changes, thus the LHCP antenna will appear to be in a new position. The vertical position change corresponds to twice the sea level change, and therefore monitors sea level changes.Multiple satellites with different elevation and azimuth angles are observed each epoch and will give rise to reflected signals with different incidence angles from different directions. This means that the estimated sea level change can not be considered to originate from one specific point on the surface, but rather represents the change of an average surface formed by the reflection points.An experimental setup was installed in December 2008 over the ocean at ... |
| author |
Löfgren, Johan Haas, Rüdiger Johansson, Jan |
| author_facet |
Löfgren, Johan Haas, Rüdiger Johansson, Jan |
| author_sort |
Löfgren, Johan |
| title |
Sea Level Monitoring Using a GNSS-Based Tide Gauge |
| title_short |
Sea Level Monitoring Using a GNSS-Based Tide Gauge |
| title_full |
Sea Level Monitoring Using a GNSS-Based Tide Gauge |
| title_fullStr |
Sea Level Monitoring Using a GNSS-Based Tide Gauge |
| title_full_unstemmed |
Sea Level Monitoring Using a GNSS-Based Tide Gauge |
| title_sort |
sea level monitoring using a gnss-based tide gauge |
| publishDate |
2009 |
| url |
https://research.chalmers.se/en/publication/102006 |
| genre |
Fennoscandia |
| genre_facet |
Fennoscandia |
| op_relation |
https://research.chalmers.se/en/publication/102006 |
| _version_ |
1814715237741363200 |