Abstract
Water vapour is a variable component of the atmosphere both in space and time. It is one of the most important components because of its effects in many fi elds: Meteorology, Climatology, Remote Sensing, Energy-Budget, Hydrology, etc. This work compares radiometric (sun photometer) readings, Global Positioning System (GPS) data and a meteorological model forecasted data. The aim is to understand if GPS measurements may help Numerical Weather Prediction (NWP) models. It is well known that GPS measurements are affected by the so-called tropospheric delay. Part of it, the so-called wet delay is related mainly to the amount of water vapour along the path of the GPS signal through the troposphere. Precise knowledge of the abundance of water vapour, in space and time, is important for NWP model because water vapour is the predecessor of precipitation. Despite the high variability of water vapour compared to other meteorological fi elds, like pressure and wind, water vapour observations are scarce, so that additional measurements of water vapour are expected to benefi t meteorology. A new sun photometer, which is part of the AERONET (AErosol and RObotic NETwork) program, has been installed at the ENEA (Ente per le Nuove tecnologie, l'Energia e l'Ambiente) base of Lampedusa Island. The sun photometer is quite close (less then 4 km) to an ASI (Agenzia Spaziale Italiana) GPS permanent receiver. A long record (summer period of the year 2000) of sun photometric measurements is available for the station at Lampedusa. We found that the GPS and sun photometric data are better correlated (std. dev. about 10 mm for the wet delay) than are the GPS measurements with the NWP model predictions. This is an indication that GPS delay data may contain information useful for weather prediction.
Highlights
Water vapour is a highly variable component of the atmosphere and plays a crucial role in many atmospheric phenomena (see all EmanuelRenato Santangelo, Sergio Pugnaghi, Stefano Corradini, Luca Lombroso and Sergio TeggiThe Integrated Water Vapour (IWV), called, the Precipitable Water (PW), is the mass per area of water vapour contained in an atmospheric vertical column
The Global Positioning System (GPS) zenith wet delay is obtained subtracting the High Resolution Limited Area Model (HIRLAM) zenith hydrostatic delay, computed from eq (2.1), using the HIRLAM surface pressure estimated at the antenna altitude
The pressure forecast by HIRLAM for Matera agrees very well with local pressure measurements; this is important because the GPS Zenith Wet Delay (ZWD) was obtained subtracting from the GPS Zenith Total Delay (ZTD) the HIRLAM Zenith Hydrostatic (or dry) Delay (ZHD), for which the predicted pressure at the antenna altitude was used
Summary
Water vapour is a highly variable component of the atmosphere and plays a crucial role in many atmospheric phenomena The Integrated Water Vapour (IWV), called, the Precipitable Water (PW), is the mass per area of water vapour contained in an atmospheric vertical column. This paper compares three different integrated water vapour estimates. This work derives from the research activities performed by different teams in the framework of the EUfunded MAGIC (Meteorological Applications of GPS Integrated Column Water Vapour Measurements in the Western Mediterranean) project. The three types of data we compare are from GPS measurements, sun photometric readings, and from forecast data produced running the meteorological model HIRLAM. To distinguish the HIRLAM and the sun photometer water vapour estimates: IWV and PW respectively have been used in the following. No meteorological measurements are available at the GPS site (Capitaneria di Porto)
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