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Različni vidiki izračuna vpliva troposfere na opazovanja GNSS : magistrsko delo
ID Kogelnik, Leon (Author), ID Pavlovčič Prešeren, Polona (Mentor) More about this mentor... This link opens in a new window

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Abstract
Tema magistrske naloge združuje področji geodezije in meteorologije, ki na različne načine omogočata določiti vpliv troposfere na opazovanja GNSS. Troposfera povzroči ukrivljanje signala in zato podaljšanje poti razširjanja signala glede na razširjanje v vakuumu. Zakasnitev prispetja signala zaradi vpliva troposfere lahko izračunamo direktno iz meteroloških podatkov, ki jih dobimo iz radiosondaže. Obstaja tudi posredni način določitve vpliva iz obdelave opazovanj GNSS. Oba pristopa obravnavanja modeliranja posledic vpliva imata prednosti in slabosti. Glavni cilj naloge je bil primerjati rezultate obeh in jih optimalno združeno uporabiti v nadaljnjih ocenah vpliva. V ta namen smo za leto 2017 pridobili celoletne podatke vertikalne sondaže kot tudi modeliranje podaljšanja poti razširjanja signala zaradi delovanja troposfere v omrežju stalnih postaj GNSS, SIGNAL. Pokazali smo, da razlike med različno pridobljenimi rezultati obravnavanja vpliva troposfere na opazovanja GNSS za satelite v zenitu v le redkih primerih presegajo 5 centimetrov. Radiosondažne podatke smo uporabili za izračun letnih sprememb suhe in mokre komponente vplvia troposferske refrakcije ter za izbrana enotedenska obdobja v različnih letnih časih analizirali vrednosti posameznih komponent vpliva. Z rezultati obdelave opazovanj GNSS v omrežju SIGNAL smo prikazali dnevne spremembe delovanja troposfere na opazovanja GNSS, vendar tokrat le za združeno obravnavanje suhe in mokre komponente. Nazadnje smo pokazali, da velika višinska razlika med krajiščema baznega vektorja vodi do situacije, da vpliva s faznimi razlikami in ob uporabi modelov ne moremo v celoti odstraniti. Zato je v teh primerih, enako kot pri tehniki absolutne določitve položaja s faznimi opazovanji PPP, vpliv troposfere bolje ocenjevati kot neznanko v obdelavi opazovanj.

Language:Slovenian
Keywords:zakasnitev signala iz zenita, suha in mokra komponenta, radiosondaža, obdelava faznih opazovanj GNSS
Work type:Master's thesis/paper
Typology:2.09 - Master's Thesis
Organization:FGG - Faculty of Civil and Geodetic Engineering
Publisher:[L. Kogelnik]
Year:2018
PID:20.500.12556/RUL-103307 This link opens in a new window
UDC:528.2:551.510.52(043.3)
COBISS.SI-ID:8574817 This link opens in a new window
Publication date in RUL:16.09.2018
Views:1539
Downloads:436
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Secondary language

Language:English
Title:Different aspects of zenith tropospheric delay modelling in GNSS : master thesis
Abstract:
The master thesis combines the fields of geodesy in meteorology, which both in various specific ways enable the determination of the zenith tropospheric delay of the signals. The troposphere refracts the signal and therefore prolongs the range between a receiver and a satellite according to the propagation in vacuum. The delay of the incoming signal, due to the influence of the troposphere, can be calculated directly from the meteorological data obtained from the radiosonde measurements. There is also an indirect way of estimating the impact, i.e. from GNSS carrier-phase processing. Each of the approach has distinctive pros and cons, so the main objective of the research was to compare the results as well as to combine them for the further impact assessments. For this, the 2017 year-round data of the zenith tropospheric delay was acquired from the Slovene continuously operating reference station network, SIGNAL. Zenith tropospheric delays from radiosonde were improved to be comparable with GNSS processing results, so in only some rare cases differences exceeded 5 centimetres. From the radiosonde data, changes in dry and wet components of the tropospheric zenith delays of the selected one-week periods in different seasons were analysed. Secondly, from the GNSS processing results in the SIGNAL network, daily changes in the zenith tropospheric delay, i.e. combined for dry and wet component, were acquired for the very same intervals. Eventually, tropospheric impacts for the specific baseline endpoints were modelled to show that in the situations with significant altitude differences the tropospheric impacts cannot be easily eliminated by the use of tropospheric models. The conclusion is, that in such situations, as well as in the absolute technique of precise point positioning, the influence of the troposphere should be assessed as an additional unknown in the carrier-phase processing.

Keywords:zenith tropospheric delay, hydrostatic and wet component, radiosonde, GNSS carrier-phase processing

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