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Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals

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Zeitschriftentitel: Ocean Science
Personen und Körperschaften: Astin, I., Feng, Y.
In: Ocean Science, 11, 2015, 5, S. 695-698
Format: E-Article
Sprache: Englisch
veröffentlicht:
Copernicus GmbH
Schlagwörter:
General Medicine
author_facet Astin, I.
Feng, Y.
Astin, I.
Feng, Y.
author Astin, I.
Feng, Y.
spellingShingle Astin, I.
Feng, Y.
Ocean Science
Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
General Medicine
author_sort astin, i.
spelling Astin, I. Feng, Y. 1812-0792 Copernicus GmbH General Medicine http://dx.doi.org/10.5194/os-11-695-2015 <jats:p>Abstract. This paper introduces a potential method for the remote sensing of sea surface salinity (SSS) using the measured propagation delay of low-frequency Loran-C signals transmitted over an all-seawater path between the Sylt station in Germany and an integrated Loran-C/GPS receiver located in Harwich, UK. The overall delay variations in Loran-C surface waves along the path may be explained by changes in sea surface properties (especially the temperature and salinity), as well as atmospheric properties that determine the refractive index of the atmosphere. After removing the atmospheric and sea surface temperature (SST) effects from the measured delay, the residual delay revealed a temporal variation similar to that of SSS data obtained by the European Space Agency's Soil Moisture and Ocean Salinity (SMOS) satellite. </jats:p> Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals Ocean Science
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title Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_unstemmed Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_full Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_fullStr Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_full_unstemmed Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_short Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_sort technical note: remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
topic General Medicine
url http://dx.doi.org/10.5194/os-11-695-2015
publishDate 2015
physical 695-698
description <jats:p>Abstract. This paper introduces a potential method for the remote sensing of sea surface salinity (SSS) using the measured propagation delay of low-frequency Loran-C signals transmitted over an all-seawater path between the Sylt station in Germany and an integrated Loran-C/GPS receiver located in Harwich, UK. The overall delay variations in Loran-C surface waves along the path may be explained by changes in sea surface properties (especially the temperature and salinity), as well as atmospheric properties that determine the refractive index of the atmosphere. After removing the atmospheric and sea surface temperature (SST) effects from the measured delay, the residual delay revealed a temporal variation similar to that of SSS data obtained by the European Space Agency's Soil Moisture and Ocean Salinity (SMOS) satellite. </jats:p>
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author Astin, I., Feng, Y.
author_facet Astin, I., Feng, Y., Astin, I., Feng, Y.
author_sort astin, i.
container_issue 5
container_start_page 695
container_title Ocean Science
container_volume 11
description <jats:p>Abstract. This paper introduces a potential method for the remote sensing of sea surface salinity (SSS) using the measured propagation delay of low-frequency Loran-C signals transmitted over an all-seawater path between the Sylt station in Germany and an integrated Loran-C/GPS receiver located in Harwich, UK. The overall delay variations in Loran-C surface waves along the path may be explained by changes in sea surface properties (especially the temperature and salinity), as well as atmospheric properties that determine the refractive index of the atmosphere. After removing the atmospheric and sea surface temperature (SST) effects from the measured delay, the residual delay revealed a temporal variation similar to that of SSS data obtained by the European Space Agency's Soil Moisture and Ocean Salinity (SMOS) satellite. </jats:p>
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spelling Astin, I. Feng, Y. 1812-0792 Copernicus GmbH General Medicine http://dx.doi.org/10.5194/os-11-695-2015 <jats:p>Abstract. This paper introduces a potential method for the remote sensing of sea surface salinity (SSS) using the measured propagation delay of low-frequency Loran-C signals transmitted over an all-seawater path between the Sylt station in Germany and an integrated Loran-C/GPS receiver located in Harwich, UK. The overall delay variations in Loran-C surface waves along the path may be explained by changes in sea surface properties (especially the temperature and salinity), as well as atmospheric properties that determine the refractive index of the atmosphere. After removing the atmospheric and sea surface temperature (SST) effects from the measured delay, the residual delay revealed a temporal variation similar to that of SSS data obtained by the European Space Agency's Soil Moisture and Ocean Salinity (SMOS) satellite. </jats:p> Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals Ocean Science
spellingShingle Astin, I., Feng, Y., Ocean Science, Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals, General Medicine
title Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_full Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_fullStr Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_full_unstemmed Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_short Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_sort technical note: remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
title_unstemmed Technical Note: Remote sensing of sea surface salinity using the propagation of low-frequency navigation signals
topic General Medicine
url http://dx.doi.org/10.5194/os-11-695-2015