Abstract
Abstract. Surface pressure (Ps) and weighted mean temperature (Tm) are two necessary variables for the accurate retrieval of precipitable water vapor (PWV) from Global Navigation Satellite System (GNSS) zenith total delay (ZTD) estimates. The lack of Ps or Tm information is a concern for those GNSS sites that are not collocated with meteorological sensors. This paper investigates an alternative method of inferring accurate Ps and Tm at the GNSS station using nearby synoptic observations. Ps and Tm obtained at the nearby synoptic sites are interpolated onto the location of the GNSS station by performing both vertical and horizontal adjustments, in which the parameters involved in Ps and Tm calculation are estimated from ERA-Interim reanalysis profiles. In addition, we present a method of constructing high-quality PWV maps through vertical reduction and horizontal interpolation of the retrieved GNSS PWVs. To evaluate the performances of the Ps and Tm retrieval, and the PWV map construction, GNSS data collected from 58 stations of the Hunan GNSS network and synoptic observations from 20 nearby sites in 2015 were processed to extract the PWV so as to subsequently generate the PWV maps. The retrieved Ps and Tm and constructed PWV maps were assessed by the results derived from radiosonde and the ERA-Interim reanalysis. The results show that (1) accuracies of Ps and Tm derived by synoptic interpolation are within the range of 1.7–3.0 hPa and 2.5–3.0 K, respectively, which are much better than the GPT2w model; (2) the constructed PWV maps have good agreements with radiosonde and ERA-Interim reanalysis data with the overall accuracy being better than 3 mm; and (3) PWV maps can well reveal the moisture advection, transportation and convergence during heavy rainfall.
Highlights
Water vapor is an important meteorological parameter, which plays a crucial role in the formation of various weather phenomena such as cloud, rain and snow (Ahrens and Samson, 2011)
We investigate the construction of precipitable water vapor (PWV) maps from Global Navigation Satellite System (GNSS) observations over the Hunan Province by performing the following five tasks: (1) Tm–Ts relationship and vertical reduction models for Ps and Tm are developed for each synoptic station; (2) Ps and Tm data interpolated by nearby meteorological observations are compared with those derived from radiosonde and GPT2w models; (3) a PWV vertical reduction model is developed for each GNSS station; (4) a PWV interpolation is performed over the whole Hunan region and evaluated by radiosonde and European Centre for Medium-Range Weather Forecasts (ECMWF) ERA-Interim reanalysis; and (5) the water vapor variation during a heavy rain event that occurred over a wide range of Hunan is examined based on PWV maps
This paper investigates an alternative method for accurate determination of PWV for nearreal-time applications using GNSS data and nearby synoptic observations
Summary
Water vapor is an important meteorological parameter, which plays a crucial role in the formation of various weather phenomena such as cloud, rain and snow (Ahrens and Samson, 2011). The monitoring of atmospheric water vapor variation is of significant value for short-term severe weather forecasting (Brenot et al, 2013; Labbouz et al, 2013; Van Baelen et al, 2011; Zhang et al, 2015). Among the various atmosphere sensing techniques, the Global Navigation Satellite System (GNSS) is regarded as a uniquely powerful means to estimate the water vapor with advantages of all-weather capability, high accuracy and low operating expenses (Bevis et al, 1992; Guerova et al, 2016; Yao et al, 2017).
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
