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GPS meteorology and the phenomenology of precipitable waterFoster, James H., January 2002 (has links)
Thesis (Ph. D.)--University of Hawaii at Manoa, 2002. / Includes bibliographical references (leaves 62-66).
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Relationship Between Surface Dewpoint and Precipitable Water During the North American MonsoonJanuary 2017 (has links)
abstract: The North American Monsoon (NAM) is a late summer increase in precipitation fundamentally caused by a wind shift that is evident in the southwestern United States and northwest Mexico from approximately June-August. Increased precipitation during these months bring an increased regional threat from heavy rains, blowing dust, and damaging storms. (Adams and Comrie 1997). Researchers in Phoenix, AZ theorized that using surface dewpoint measurements was an objective way to officially mark the start of the NAM in Phoenix, AZ (and Tucson, AZ). Specifically, they used three consecutive days at or above a certain dewpoint temperature (Franjevic 2017). The justification for this method was developed by Reitan (1957) who established that 25.4mm (1.00”) of integrated precipitable water (IPW) was a sufficient threshold to create storm activity in the NAM region. He also determined (Reitan 1963) that a strong correlation existed between (IPW) and surface dewpoint (Td), whereas, Td could be used as a proxy to determine IPW.
I hypothesize that the correlation coefficients between IPW and Td will be greatest when using seasonal mean averages of IPW and Td, and they will decrease with shortened mean timescales (from seasonal to three-days). Second, I hypothesize that there is a unique relationship between IPW/Td that may signal monsoon onset. To conduct this study, I used the North American Regional Reanalysis (NARR) dataset (1979-2015). For ten locations in the Southwest, I conducted a series of statistical analyses between IPW, Td, and accumulated precipitation. I determined that there is a correlation between the two as set forth by Reitan (1963) as well as (Benwell 1965; Smith 1966; Ojo 1970). However, from the results I concluded this relationship is highly variable, spatially and temporally. Additionally, when comparing the three-hour, three-day, and the weekly mean measurements, I can conclude that, for my study, timescale averaging did enhance the IPW/Td relationship from three-hour to weekly as expected. The temporal and spatial evolution of the IPW/Td correlation as presented in this thesis may provide a framework for future research that reevaluates the NAM’s domain and the associated methods for determining its onset. / Dissertation/Thesis / Masters Thesis Geography 2017
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Seasonal Cycles of Precipitation and Precipitable Water and Their Use in Monsoon Onset and RetreatLu, Er January 2005 (has links)
Precipitation (P) and precipitable water (W) are important components of the hydrological cycles in the earth system, and their seasonal cycles are closely related to monsoon circulations over monsoon regions. Through theoretical analyses and extensive analysis of data from in-situ measurements, satellite remote sensing, and regional reanalysis, significant progress has been made (via four peer-reviewed publications) in four areas related to P, W, and monsoon onset and retreat. First, based on the normalized W index, a novel unified method is proposed to determine global monsoon onset and retreat dates. The results are consistent with those obtained from different local criteria. Second, theoretical and data analyses demonstrate that, because of the large annual range of temperature, W can increase from winter to summer anywhere except in the tropics, including both monsoon and nonmonsoon regions. Third, while the seasonal variation of P is, in general, caused by complex processes (e.g., atmospheric circulations), thermodynamic derivations and data analysis demonstrate that the variation of P from winter to summer can be easily understood from the comparative strength between the change of water vapor and the change of temperature. In monsoon regions, the change of water vapor from winter to summer is much greater than the change of temperature, so P has an in-phase relation with W. While in some of the nonmonsoon regions, where winter is the rainy season, the change of temperature is much greater than the change of water vapor, leading to an out-of-phase relation between P and W, and, relative to summer, the coldness of the winter air is much more significant than its dryness. Finally, the satisfactory performance of the globally unified monsoon index can be understood by comparing the seasonal cycles of P and W. The significant positive correlations between P and W at seasonal and synoptic scales imply that W has the ability to indicate both the means and the interannual variations of the monsoon onset and retreat. Since large increase of W from winter to summer can occur in both monsoon and nonmonsoon regions, the global monsoon regions cannot be obtained from the seasonal change of W.
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Bestimmung und Analyse des atmosphärischen Wasserdampfgehaltes aus globalen GPS-Beobachtungen einer Dekade mit besonderem Blick auf die Antarktis / Estimation and analysis of atmospheric water vapour content derived from one decade of global GPS observations with special regard to AntarcticaVey, Sibylle 24 January 2008 (has links) (PDF)
Der Wasserdampfgehalt der Atmosphäre gehört zu den Hauptkontrolleuren des Treibhauseffektes und spielt eine Schlüsselrolle im globalen Energiekreislauf, wobei den Polargebieten als globale Wärmesenken eine besondere Bedeutung zukommt. Im Rahmen dieser Arbeit wurde aus Messungen des Global Positioning System (GPS) der integrierte Wasserdampfgehalt innerhalb der letzten Dekade bestimmt und analysiert. Die Untersuchungen stützen sich auf die Reprozessierung eines aus 195 Stationen bestehenden globalen GPS-Netzes. Die aus den geschätzten GPS-Troposphärenparameter bestimmten Wasserdampf- zeitreihen wurden hinsichtlich Genauigkeit und Homogenität untersucht. Nach Korrektion der Inhomogenit äten ist es möglich, mit GPS mehrjährige Schwankungen im potenziellen Niederschlagswasser mit einer Genauigkeit besser als 0,3 mm Höhe der Wassersäule zu erfassen. Als Ergebnis der Untersuchungen zeigen sich in Europa und großen Teilen Nordamerikas Anomalien des Wasserdampfgehaltes im Bereich eines Millimeters, welche sich vor allem auf thermodynamische Effekte zurückführen lassen. In den Tropen und im Südosten der USA können die Wasserdampfanomalien 3 bis 5 mm betragen. Sie sind durch dynamische Prozesse bedingt, die mit der Südlichen Oszillation im Zusammenhang stehen. Eine Anwendung der aus GPS-Beobachtungen bestimmten Wasserdampfzeitreihen ist die Validierung des Wasserdampfes im globalen Wettervorhersagemodell des National Center for Environmental Predicton (NCEP). Über Europa und großen Teilen Nordamerikas reproduziert NCEP die Schwankungen des Wasserdampfgehaltes sehr gut und stellt damit eine gute Datengrundlage für ?ächendeckende Untersuchungen langfristiger Veränderungen im Wasserdampfgehalt dar. In der Antarktis und den Tropen wird jedoch das saisonale und mehrjährige Signal des Wasserdampfes von NCEP um 25% bis 40% unterschätzt. Als zweite Anwendung der GPS-Wasserdampfzeitreihen erfolgt die Validierung satellitenbasierter Radiometermessungen über der Antarktis. Sie zeigt eine gute Übereinstimmung der Wasserdampfwerte aus GPSund Radiometermessungen. Die im Rahmen dieser Arbeit aus GPS-Beobachtungen bestimmten Wasserdampfzeitreihen bilden eine sehr gute Datengrundlage für weitergehende Untersuchungen der Wetter- und Klimaforschung. / The atmospheric water vapour is one of the main variables controlling the greenhouse effect and it plays a crucial role in the global energy cycle. In this context the polar regions which act as global heat sinks are especially important. This study uses observations from the Global Positioning System (GPS) to investigate changes of the integrated atmospheric water vapour. It is based on a reprocessing of a global GPS network consisting of 195 stations. A strong emphasis was placed on the investigation of the accuracy and the homogeneity of the GPS derived water vapour time series. After correcting the inhomogeneities interannual ?uctuations in the precipitable water can be determined from GPS data with an accuracy of 0.3 mm in water column height. As a result, the interannual variations in the water vapour content are in the order of one millimetre over Europe and over large areas of North America. They are mainly related to thermodynamic effects. In the tropics and in the south east of the USA water vapour anomalies can reach 3 to 5 mm caused by dynamic processes connected to the Southern Oscillation. As one application of the estimated GPS water vapour time series a validation of water vapour from the global numerical weather prediction model of the National Center for Environmental Prediction (NCEP) was carried out. Over Europe and large parts of North America the seasonal signal and the interannual variations of the water vapour are very well reproduced by NCEP. Hence, in these regions NCEP presents a good database for area-wide investigations of long-term changes in the water vapour content. However, in Antarctica and in the Tropics the seasonal and also the interannual signals of the NCEP water vapour are strongly underestimated by 25% to 40%. A second application of the estimated GPS water vapour time series is the validation of satellite-based radiometer measurements over Antarctica. A good agreement was found between the water vapour derived from GPS and radiometer data. The water vapour time series estimated in this study provide a good basis for further weather and climate related investigations.
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Detection of atmospheric water vapour using the Global Positioning System / A.Z.A. CombrinkCombrink, Adriaan Zacharias Albertus January 2003 (has links)
The Global Positioning System (GPS) has been used for more than a decade for the
accurate determination of position on the earth's surface, as well as navigation. The
system consists of approximately thirty satellites, managed by the US Department of
Defense, orbiting at an altitude of 20 200 kilometres, as well as thousands of stationary
ground-based and mobile receivers. It has become apparent from numerous studies that
the delay of GPS signals in the atmosphere can also be used to study the amosphere,
particularly to determine the precipitable water vapour (PWV) content of the troposphere
and the total electron content (TEC) of the ionosphere.
This dissertation gives an overview of the mechanisms that contribute to the delay of
radio signals between satellites and receivers. The dissertation then focuses on software
developed at the Hartebeesthoek Radio Astronomy Observatory's (HartRAO's) Space
Geodesy Programme to estimate tropospheric delays (from which PWV is calculated) in
near real-time. In addition an application of this technique, namely the improvement of
tropospheric delay models used to process satellite laser ranging (SLR) data, is
investigated. The dissertation concludes with a discussion of opportunities for future
work. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2004.
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Remote sensing of atmospheric water vapour above the Chilean AndesQuerel, Richard Robert, University of Lethbridge. Faculty of Arts and Science January 2010 (has links)
Water vapour is the principle source of opacity at infrared wavelengths in the Earth’s atmosphere.
In support of site testing for the European Extremely Large Telescope (E-ELT),
we have used La Silla and Paranal as calibration sites to verify satellite measurements of
precipitable water vapour (PWV). We reconstructed the PWV history over both sites by
analysing thousands of archived high-resolution echelle calibration spectra and compared
that to satellite estimates for the same period. Three PWV measurement campaigns were
conducted over both sites using several independent measurement techniques. Radiosondes
were launched to coincide with satellite measurements and provide a PWV reference
standard allowing intercomparison between the various instruments and methods. This
multi-faceted approach has resulted in a unique data set. Integral to this analysis is the
internal consistency provided by using a common atmospheric model. / xvii, 206 leaves : ill. (some col.) ; 28 cm
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Detection of atmospheric water vapour using the Global Positioning System / A.Z.A. CombrinkCombrink, Adriaan Zacharias Albertus January 2003 (has links)
The Global Positioning System (GPS) has been used for more than a decade for the
accurate determination of position on the earth's surface, as well as navigation. The
system consists of approximately thirty satellites, managed by the US Department of
Defense, orbiting at an altitude of 20 200 kilometres, as well as thousands of stationary
ground-based and mobile receivers. It has become apparent from numerous studies that
the delay of GPS signals in the atmosphere can also be used to study the amosphere,
particularly to determine the precipitable water vapour (PWV) content of the troposphere
and the total electron content (TEC) of the ionosphere.
This dissertation gives an overview of the mechanisms that contribute to the delay of
radio signals between satellites and receivers. The dissertation then focuses on software
developed at the Hartebeesthoek Radio Astronomy Observatory's (HartRAO's) Space
Geodesy Programme to estimate tropospheric delays (from which PWV is calculated) in
near real-time. In addition an application of this technique, namely the improvement of
tropospheric delay models used to process satellite laser ranging (SLR) data, is
investigated. The dissertation concludes with a discussion of opportunities for future
work. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2004.
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An Investigation of Ground-Based GNSS Atmospheric Remote Sensing Techniques for Weather and Climate Monitoring in NigeriaIsioye, Olalekan Adekunle January 2017 (has links)
Radio signals from Global Navigation Satellite Systems (GNSS) satellites suffer delay
as they propagate through the atmosphere (neutral and non-neutral) and this delay is
partially driven by the water vapour content in the atmosphere. The delay component
due to the non-neutral atmosphere (ionosphere) is removed through the use of dual
frequency GNSS receivers. The main tropospheric parameter is the zenith
tropospheric (or total) delay (ZTD), which is a widely accepted parameter with which
to express the total delay in the signal from all satellites due to the neutral atmosphere.
The ZTD is a measure of the integrated tropospheric condition over a GNSS receiver
station. Accordingly, the integrated water vapour or precipitable water vapour (PWV)
can be obtained from a portion of the ZTD, if the atmospheric pressure and
temperature at the station are known through a concept often referred to as GNSS
meteorology. A number of GNSS receivers have been deployed for mapping and
geodetic services in Nigeria under the African reference frame initiative, but
unfortunately most of these receivers do not have co-located meteorological sensors
for pressure and temperature measurements. The prospect of incorporating GNSS
meteorology into weather monitoring and climate analysis in Nigeria was investigated
and is reported in this thesis. During the first task of this research, the technical basis
for ground-based GNSS meteorology was reviewed and the potentials and challenges of the approach to meteorological activities in Africa (including Nigeria) were
identified. Thereafter an in-depth analysis of the spatial and temporal variability of
ZTD over Nigeria for the period of 2010-2014 was conducted; results revealed weak
spatial dependence among the stations. Tidal oscillations (of the diurnal and semidiurnal
components) were observed at the GNSS stations of which the diurnal ZTD
cycles exhibited significant seasonal dependence, affirming the prospective relevance
of ground-based GNSS data to atmospheric studies. Also in this research, the
accuracy and suitability of using reanalysis datasets (ERA-Interim and NCEP/NCAR)
and a GPT2 neutral model in retrieving PWV from GNSS observations over Nigeria
were investigated; results showed that PWV can be retrieved to within a precision of
about 1 mm, provided GNSS-derived ZTD is of high precision. A fundamental issue
for GNSS meteorology in the West African region was yet again addressed in this
research; this is the development of a weighted tropospheric mean temperature model
for use in current and future GNSS meteorology activities in the region. A multitechnique
comparison of PWV estimates showed good agreement between GNSS
estimates and other techniques (i.e. the atmospheric infrared sounder, and ERAInterim
reanalysis). This result is suggestive of the potential of assimilating GNSS
atmospheric products into reanalysis and climate models. Diurnal and seasonal
variability of GNSS PWV estimates exhibits strong correlation with weather events
that influence the region (i.e. solar activity and rainfall events); this further
demonstrated the immense contribution of the approach to efficient weather
forecasting and climate monitoring for Nigeria. / Thesis (PhD)--University of Pretoria, 2017. / Geography, Geoinformatics and Meteorology / PhD / Unrestricted
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A global GPS data reprocessing strategy: Implications for the reference frame, orbital solutions, and trends in zenith delay parameters and total column water vapor (1994 - 2011)Brown, Abel K. 19 December 2011 (has links)
No description available.
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Bestimmung und Analyse des atmosphärischen Wasserdampfgehaltes aus globalen GPS-Beobachtungen einer Dekade mit besonderem Blick auf die AntarktisVey, Sibylle 26 October 2007 (has links)
Der Wasserdampfgehalt der Atmosphäre gehört zu den Hauptkontrolleuren des Treibhauseffektes und spielt eine Schlüsselrolle im globalen Energiekreislauf, wobei den Polargebieten als globale Wärmesenken eine besondere Bedeutung zukommt. Im Rahmen dieser Arbeit wurde aus Messungen des Global Positioning System (GPS) der integrierte Wasserdampfgehalt innerhalb der letzten Dekade bestimmt und analysiert. Die Untersuchungen stützen sich auf die Reprozessierung eines aus 195 Stationen bestehenden globalen GPS-Netzes. Die aus den geschätzten GPS-Troposphärenparameter bestimmten Wasserdampf- zeitreihen wurden hinsichtlich Genauigkeit und Homogenität untersucht. Nach Korrektion der Inhomogenit äten ist es möglich, mit GPS mehrjährige Schwankungen im potenziellen Niederschlagswasser mit einer Genauigkeit besser als 0,3 mm Höhe der Wassersäule zu erfassen. Als Ergebnis der Untersuchungen zeigen sich in Europa und großen Teilen Nordamerikas Anomalien des Wasserdampfgehaltes im Bereich eines Millimeters, welche sich vor allem auf thermodynamische Effekte zurückführen lassen. In den Tropen und im Südosten der USA können die Wasserdampfanomalien 3 bis 5 mm betragen. Sie sind durch dynamische Prozesse bedingt, die mit der Südlichen Oszillation im Zusammenhang stehen. Eine Anwendung der aus GPS-Beobachtungen bestimmten Wasserdampfzeitreihen ist die Validierung des Wasserdampfes im globalen Wettervorhersagemodell des National Center for Environmental Predicton (NCEP). Über Europa und großen Teilen Nordamerikas reproduziert NCEP die Schwankungen des Wasserdampfgehaltes sehr gut und stellt damit eine gute Datengrundlage für ?ächendeckende Untersuchungen langfristiger Veränderungen im Wasserdampfgehalt dar. In der Antarktis und den Tropen wird jedoch das saisonale und mehrjährige Signal des Wasserdampfes von NCEP um 25% bis 40% unterschätzt. Als zweite Anwendung der GPS-Wasserdampfzeitreihen erfolgt die Validierung satellitenbasierter Radiometermessungen über der Antarktis. Sie zeigt eine gute Übereinstimmung der Wasserdampfwerte aus GPSund Radiometermessungen. Die im Rahmen dieser Arbeit aus GPS-Beobachtungen bestimmten Wasserdampfzeitreihen bilden eine sehr gute Datengrundlage für weitergehende Untersuchungen der Wetter- und Klimaforschung. / The atmospheric water vapour is one of the main variables controlling the greenhouse effect and it plays a crucial role in the global energy cycle. In this context the polar regions which act as global heat sinks are especially important. This study uses observations from the Global Positioning System (GPS) to investigate changes of the integrated atmospheric water vapour. It is based on a reprocessing of a global GPS network consisting of 195 stations. A strong emphasis was placed on the investigation of the accuracy and the homogeneity of the GPS derived water vapour time series. After correcting the inhomogeneities interannual ?uctuations in the precipitable water can be determined from GPS data with an accuracy of 0.3 mm in water column height. As a result, the interannual variations in the water vapour content are in the order of one millimetre over Europe and over large areas of North America. They are mainly related to thermodynamic effects. In the tropics and in the south east of the USA water vapour anomalies can reach 3 to 5 mm caused by dynamic processes connected to the Southern Oscillation. As one application of the estimated GPS water vapour time series a validation of water vapour from the global numerical weather prediction model of the National Center for Environmental Prediction (NCEP) was carried out. Over Europe and large parts of North America the seasonal signal and the interannual variations of the water vapour are very well reproduced by NCEP. Hence, in these regions NCEP presents a good database for area-wide investigations of long-term changes in the water vapour content. However, in Antarctica and in the Tropics the seasonal and also the interannual signals of the NCEP water vapour are strongly underestimated by 25% to 40%. A second application of the estimated GPS water vapour time series is the validation of satellite-based radiometer measurements over Antarctica. A good agreement was found between the water vapour derived from GPS and radiometer data. The water vapour time series estimated in this study provide a good basis for further weather and climate related investigations.
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