Your search keyword '"Thomas Artz"' showing total 9 results

1. Optimized scheduling of VLBI UT1 intensive sessions for twin telescopes employing impact factor analysis

Author

Judith Leek, Thomas Artz, and Axel Nothnagel

Subjects

Physics, Impact factor, Astrophysics::High Energy Astrophysical Phenomena, Astrophysics::Instrumentation and Methods for Astrophysics, Satellite system, Astrophysics::Cosmology and Extragalactic Astrophysics, Scheduling (computing), Radio telescope, Geophysics, Geochemistry and Petrology, Very-long-baseline interferometry, Pairwise comparison, Computers in Earth Sciences, Remote sensing, Earth's rotation

Abstract

Daily Very Long Baseline Interferometry (VLBI) intensive measurements make an important contribution to the regular monitoring of Earth rotation variations. Since these variations are quite rapid, their knowledge is important for navigation with global navigation satellite system and for investigations in Earth sciences. Unfortunately, the precision of VLBI intensive observations is 2–3 times worse than the precision of regular 24h-VLBI measurements with networks of 5–10 radio telescopes. The major advancement of research in this paper is the improvement of VLBI intensive results by (a) using twin telescopes instead of single telescopes and (b) applying an entirely new scheduling concept for the individual observations. Preparatory investigations of standardintensive sessions suggest that the impact factors of the observations are well suited for the identification of the most influential observations which are needed for the determination of certain parameters within the entire design of a VLBI session. Based on this experience, the scheduling method is designed for optimizing the observations’ geometry for a given network of radio telescopes and a predefined set of parameters to be estimated. The configuration of at least two twin telescopes, or one twin and two single telescopes, offers the possibility of building pairwise sub-nets that observe two different sources simultaneously. In addition to an optimized observing plan, a special parametrization for twin telescopes leads to an improved determination of Earth rotation variations, as it is shown by simulated observations. In general, an improvement of about 50 % in the formal errors can be realized using twin radio telescopes. This result is only due to geometric improvements as higher slew rates of the twin telescopes are not taken into account.

Published

2015

2. Using an atmospheric turbulence model for the stochastic model of geodetic VLBI data analysis

Author

Axel Nothnagel, Thomas Artz, Sebastian Halsig, and A. Iddink

Subjects

010504 meteorology & atmospheric sciences, Stochastic modelling, Turbulence, Turbulence modeling, Geodetic datum, Geology, 010502 geochemistry & geophysics, Geodesy, 01 natural sciences, Standard deviation, Physics::Geophysics, Space and Planetary Science, Very-long-baseline interferometry, Environmental science, Satellite, 0105 earth and related environmental sciences, Radio wave, Remote sensing

Abstract

Space-geodetic techniques at radio wavelength, such as global navigation satellite systems and very long baseline interferometry (VLBI), suffer from refractivity of the Earth’s atmosphere. These highly dynamic processes, particularly refractivity variations in the neutral atmosphere, contribute considerably to the error budget of these space-geodetic techniques. Here, microscale fluctuations in refractivity lead to elevation-dependent uncertainties and induce physical correlations between the observations. However, up to now such correlations are not considered routinely in the stochastic model of space-geodetic observations, which leads to very optimistic standard deviations of the derived target parameters, such as Earth orientation parameters and station positions. In this study, the standard stochastic model of VLBI observations, which only includes, almost exclusively, the uncertainties from the VLBI correlation process, is now augmented by a variance–covariance matrix derived from an atmospheric turbulence model. Thus, atmospheric refractivity fluctuations in space and time can be quantified. One of the main objectives is to realize a suitable stochastic model of VLBI observations in an operational way. In order to validate the new approach, the turbulence model is applied to several VLBI observation campaigns consisting of different network geometries leading the path for the next-generation VLBI campaigns. It is shown that the stochastic model of VLBI observations can be improved by using high-frequency atmospheric variations and, thus, refining the stochastic model leads to far more realistic standard deviations of the target parameters. The baseline length repeatabilities as a general measure of accuracy of baseline length determinations improve for the turbulence-based solution. Further, this method is well suited for routine VLBI data analysis with limited computational costs.

Published

2016

3. Methodology for the combination of sub-daily Earth rotation from GPS and VLBI observations

Author

Peter Steigenberger, L. Bernhard, Thomas Artz, Axel Nothnagel, and S. Tesmer

Subjects

business.industry, Nutation, Geodesy, law.invention, Geophysics, DUT1, Tidal Model, Geochemistry and Petrology, law, Universal Time, Polar motion, Very-long-baseline interferometry, Global Positioning System, Environmental science, Computers in Earth Sciences, business, Earth's rotation, Remote sensing

Abstract

A combination procedure of Earth orientation parameters from Global Positioning System (GPS) and Very Long Baseline Interferometry (VLBI) observations was developed on the basis of homogeneous normal equation systems. The emphasis and purpose of the combination was the determination of sub-daily polar motion (PM) and universal time (UT1) for a long time-span of 13 years. Time series with an hourly resolution and a model for tidal variations of PM and UT1-TAI (dUT1) were estimated. In both cases, 14-day nutation corrections were estimated simultaneously with the ERPs. Due to the combination procedure, it was warranted that the strengths of both techniques were preserved. At the same time, only a minimum of de-correlating or stabilizing constraints were necessary. Hereby, a PM time series was determined, whose precision is mainly dominated by GPS observations. However, this setup benefits from the fact that VLBI delivered nutation and dUT1 estimates at the same time. An even bigger enhancement can be seen for the dUT1 estimation, where the high-frequency variations are provided by GPS, while the long term trend is defined by VLBI. The estimated combined tidal PM and dUT1 model was predominantly determined from the GPS observations. Overall, the combined tidal model for the first time completely comprises the geometrical benefits of VLBI and GPS observations. In terms of root mean squared (RMS) differences, the tidal amplitudes agree with other empirical single-technique tidal models below 4 μas in PM and 0.25 μs in dUT1. The noise floor of the tidal ERP model was investigated in three ways resulting in about 1 μas for diurnal PM and 0.07 μs for diurnal dUT1 while the semi-diurnal components have a slightly better accuracy.

Published

2011

4. GGOS-D: homogeneous reprocessing and rigorous combination of space geodetic observations

Author

Wolfgang Bosch, N Panafidina, R Kelm, Peter Steigenberger, Thomas Artz, Axel Nothnagel, Volker Tesmer, Rolf König, Barbara Meisel, Detlef Angermann, Bernd Richter, Sergei Rudenko, Daniela Thaller, Horst Müller, W Schwegmann, Markus Rothacher, S. Tesmer, Hermann Drewes, Manuela Seitz, Michael Gerstl, and D. König

Subjects

business.industry, Geodetic datum, 550 - Earth sciences, International Earth Rotation and Reference Systems Service, Geodesy, Fundamental station, Geophysics, Geochemistry and Petrology, Polar motion, Very-long-baseline interferometry, Global Positioning System, Computers in Earth Sciences, business, Terrestrial reference frame, Geology, Zenith, Remote sensing

Abstract

In preparation of activities planned for the realization of the Global Geodetic Observing System (GGOS), a group of German scientists has carried out a study under the acronym GGOS-D which closely resembles the ideas behind the GGOS initiative. The objective of the GGOS-D project was the investigation of the methodological and information-technological realization of a global geodetic-geophysical observing system and especially the integration and combination of the space geodetic observations. In the course of this project, highly consistent time series of GPS, VLBI, and SLR results were generated based on common state-of-the-art standards for modeling and parameterization. These series were then combined to consistently and accurately compute a Terrestrial Reference Frame (TRF). This TRF was subsequently used as the basis to produce time series of station coordinates, Earth orientation, and troposphere parameters. In this publication, we present results of processing algorithms and strategies for the integration of the space-geodetic observations which had been developed in the project GGOS-D serving as a prototype or a small and limited version of the data handling and processing part of a global geodetic observing system. From a comparison of the GGOS-D terrestrial reference frame results and the ITRF2005, the accuracy of the datum parameters is about 5–7 mm for the positions and 1.0–1.5 mm/year for the rates. The residuals of the station positions are about 3 mm and between 0.5 and 1.0 mm/year for the station velocities. Applying the GGOS-D TRF, the offset of the polar motion time series from GPS and VLBI is reduced to 50 μas (equivalent to 1.5 mm at the Earth’s surface). With respect to troposphere parameter time series, the offset of the estimates of total zenith delays from co-located VLBI and GPS observations for most stations in this study is smaller than 1.5 mm. The combined polar motion components show a significantly better WRMS agreement with the IERS 05C04 series (96.0/96.0 μas) than VLBI (109.0/100.7 μas) or GPS (98.0/99.5 μas) alone. The time series of the estimated parameters have not yet been combined and exploited to the extent that would be possible. However, the results presented here demonstrate that the experiences made by the GGOS-D project are very valuable for similar developments on an international level as part of the GGOS development.

Published

2011

5. VLBI terrestrial reference frame contributions to ITRF2008

Author

Axel Nothnagel, Thomas Artz, and S. Böckmann

Subjects

International Terrestrial Reference System, Offset (computer science), International Earth Rotation and Reference Systems Service, Astrometry, Geodesy, Geophysics, DUT1, Geochemistry and Petrology, Polar motion, Very-long-baseline interferometry, Computers in Earth Sciences, Terrestrial reference frame, Mathematics, Remote sensing

Abstract

In late 2008, the Product Center for the International Terrestrial Reference Frame (ITRF) of the International Earth Rotation and Reference Systems Service (IERS) issued a call for contributions to the next realization of the International Terrestrial Reference System, ITRF2008. The official contribution of the International VLBI Service for Geodesy and Astrometry (IVS) to ITRF2008 consists of session-wise datum-free normal equations of altogether 4,539 daily Very Long Baseline Interferometry (VLBI) sessions from 1979.7 to 2009.0 including data of 115 different VLBI sites. It is the result of a combination of individual series of session-wise datum-free normal equations provided by seven analysis centers (ACs) of the IVS. All series are completely reprocessed following homogeneous analysis options according to the IERS Conventions 2003 and IVS Analysis Conventions. Altogether, nine IVS ACs analyzed the full history of VLBI observations with four different software packages. Unfortunately, the contributions of two ACs, Institute of Applied Astronomy (IAA) and Geoscience Australia (AUS), had to be excluded from the combination process. This was mostly done because the IAA series exhibits a clear scale offset while the solution computed from normal equations contained in the AUS SINEX files yielded unreliable results. Based on the experience gathered since the combination efforts for ITRF2005, some discrepancies between the individual series were discovered and overcome. Thus, the consistency of the individual VLBI solutions has improved considerably. The agreement in terms of WRMS of the Terrestrial Reference Frame (TRF) horizontal components is 1 mm, of the height component 2 mm. Comparisons between ITRF2005 and the combined TRF solution for ITRF2008 yielded systematic height differences of up to 5 mm with a zonal signature. These differences can be related to a pole tide correction referenced to a zero mean pole used by four of five IVS ACs in the ITRF2005 contribution instead of a linear mean pole path as recommended in the IERS Conventions. Furthermore, these systematics are the reason for an offset in the scale of 0.4 ppb between the IVS’ contribution to ITRF2008 and ITRF2005. The Earth orientation parameters of seven series used as input for the IVS combined series are consistent to a huge amount with about 50 μas WRMS in polar motion and 3 μs in dUT1.

Published

2009

6. Scheduling Scenarios for VLBI Observations of Satellites

Author

Axel Nothnagel, Judith Leek, Laura La Porta, and Thomas Artz

Subjects

Geography, Very-long-baseline interferometry, Global network, Geostationary orbit, Satellite, Covariance, Physics::Atmospheric and Oceanic Physics, Scheduling (procedure), Remote sensing, Scheduling (computing)

Abstract

In this paper, a methodology for automatic scheduling of Very Long Baseline Interferometry (VLBI) observations of satellites is presented and first scheduling approaches are investigated. For this investigation the orbit of a geostationary satellite has been chosen, but, the methodology has also been successfully applied to an orbit of a Global Navigation Satellite Systems satellite. A scheduling procedure based on covariance optimization is developed and observations are simulated. In contrast to other simulation studies for a dedicated VLBI satellite mission, we are performing a scheduling process where observations of quasars and satellites are considered being equally important. Thus, the satellites are consistently included into a VLBI experiment. To validate the individual schedules, simplistic daily constant orbit shifts are estimated and analyzed. In this way, the necessary time between two subsequent satellite observations and the geometry of the observing network are investigated. Taking into account all circumstances, large global networks are the best option for estimating orbit shifts. Such a configuration leads to a large number of observations and a good observing geometry for the orbit. For a geostationary satellite, it is sufficient to carry out only one observation per hour or even longer. However, the presented results are only valid for the estimation of orbit shifts. Various improvements of these initial investigations are imaginable, e.g., considering orbit parameters within the scheduling process or estimating realistic orbit parameters.

Published

2015

7. Subdiurnal variations in the Earth's rotation from continuous Very Long Baseline Interferometry campaigns

Author

Peter Steigenberger, S. Böckmann, Axel Nothnagel, and Thomas Artz

Subjects

Atmospheric Science, Series (stratigraphy), Ecology, Paleontology, Soil Science, Forestry, Astrometry, Aquatic Science, Oceanography, Geodesy, Session (web analytics), Geophysics, Amplitude, Space and Planetary Science, Geochemistry and Petrology, Very-long-baseline interferometry, Polar motion, Earth and Planetary Sciences (miscellaneous), Rotation (mathematics), Geology, Earth-Surface Processes, Water Science and Technology, Earth's rotation, Remote sensing

Abstract

[1] Subdiurnal periodic effects in the Earth's rotation as seen by Very Long Baseline Interferometry (VLBI) are investigated on the basis of continuous VLBI observing campaigns (CONT) observed by the International VLBI Service for Geodesy and Astrometry (IVS). In 2008, the latest campaign (CONT08) was observed adding another valuable data set of 15 consecutive days to the series of CONT sessions. Among other things, CONT08 as well as CONT02 and CONT05 had been scheduled with the aim of observing short-period variations of the Earth orientation parameters. In this publication, we describe an analysis, which is based on hourly estimates of polar motion and UT1-TAI and a subsequent spectral analysis. The generation of the time series is performed with a modified analysis approach. We add the normal equations of each individual 24 hour session to one big equation system for the whole campaign where observations of adjacent sessions contribute to parameters at session borders simultaneously. Over the years, the experience in operating and analyzing the CONT sessions has improved and the procedures have been adapted for improvement of the results. However, at the same time, the observing network has suffered considerable changes. Thus, a comparative overview over the three CONT campaigns is given in this paper. The intermittent detection of periodicities as reported by Haas and Wunsch (2006) applies in this analysis for CONT02 as well. For CONT05 and CONT08 minute signals at periods of around 6 hours are contained in the amplitude spectra. The origin of these signals is still questionable.

Published

2010

8. International VLBI Service for Geodesy and Astrometry: Earth orientation parameter combination methodology and quality of the combined products

Author

Axel Nothnagel, S. Böckmann, Volker Tesmer, and Thomas Artz

Subjects

Atmospheric Science, Satellite geodesy, Computer science, media_common.quotation_subject, Soil Science, Aquatic Science, Oceanography, Geochemistry and Petrology, Very-long-baseline interferometry, Earth and Planetary Sciences (miscellaneous), Earth-Surface Processes, Water Science and Technology, Remote sensing, media_common, Ecology, business.industry, Paleontology, Forestry, Astrometry, Geodesy, Geophysics, Space and Planetary Science, GNSS applications, Service (economics), Polar motion, Global Positioning System, Satellite, business

Abstract

[1] The analysis coordinator of the International VLBI Service for Geodesy and Astrometry (IVS) regularly disseminates the official IVS products of Earth orientation parameters (EOPs). For 2 years now, these parameters have been produced by combining datum-free normal equations of up to six IVS analysis centers. In this paper we document the combination methodology, discuss critical issues, and report on the quality of the products. The agreement of the very long baseline interferometry results with the International Global Navigation Satellite Systems (GNSS) Service GPS EOPs is of the order of 18 μs for length of day and 100 μas (microarc seconds) and 300 μas/d for the polar motion components and their rates, respectively.

Published

2010

9. GGOS-D Consistent, High-Accuracy Technique-Specific Solutions

Author

Daniela Thaller, S. Böckmann, Horst Müller, R Kelm, Rolf König, Sergei Rudenko, Barbara Meisel, Axel Nothnagel, Thomas Artz, Volker Tesmer, and Peter Steigenberger

Subjects

Interferometry, Geography, Positioning system, business.industry, Homogeneous, Very-long-baseline interferometry, Satellite laser ranging, Global Positioning System, Geodetic datum, 550 - Earth sciences, Geodesy, business, Remote sensing

Abstract

Consistent and homogeneous long-time series of the space geodetic techniquesGlobal Positioning System (GPS), Satellite Laser Ranging (SLR), andVery Long Baseline Interferometry (VLBI) provide the basis for thecombination efforts of GGOS-D. For a consistent combination, thedefinition of common standards for parameterization and modeling isessential. These standards and the technique-specific processingoptions of all individual GPS, SLR, and VLBI solutions as well asthe combined SLR and VLBI solutions are discussed.

Published

2010