Observing APOD with the AuScope VLBI Array

Hellerschmied, Andreas; McCallum, Lucia; McCallum, Jamie; Sun, Jing; Boehm, J.; Cao, Jianfeng

doi:10.3390/s18051587

Cited by 21 publications

(22 citation statements)

References 35 publications

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“…The only difference between the processing of quasar and lunar data in this case is the utilization of the passband option of Fourfit, allowing to restrict the cross-power spectra to windows of one MHz for each of the four DOR tones, without including the carrier frequency. A quite similar approach, related to DOR tones and Fourfit, has been successfully applied to observations of Earth-orbiting satellites with geodetic VLBI (Hellerschmied et al 2018). In Step III, quasar-only delays in S band and X band were analyzed with νSolve (Bolotin et al 2014) to resolve ambiguities and derive ionosphere delays.…”

Section: Data Processingmentioning

confidence: 99%

“…When considering quasar observations, the geodetic VLBI analysis follows a well-established modeling approach (Petit and Luzum 2010). This, however, is not applicable to artificial radio sources on the Moon and the conventional VLBI delay model needs to be replaced with a model considered for targets at a finite distance (Duev et al 2012) and applied both to correlation and data analysis (Klopotek et al 2017a;Hellerschmied et al 2018).…”

Section: Vlbi Delay Modeling and Parameter Estimationmentioning

confidence: 99%

“…Step IVb by a constrained estimation (with σ = ± 3 TEC units) of the VTEC biases (one per station per 24 h) along with the lander's position components. In the same step, one additional clock offset per station was estimated as a constant parameter in order to handle ambiguities, potential absolute timing issues (Hellerschmied et al 2018) as well as to correct for an unknown constant offset caused by instrumental delays at X band. The latter is usually absorbed by the clock model in the geodetic parameter estimation in the case of dual-frequency quasar data (Sekido et al 2003;Hobiger et al 2006).…”

Section: Vlbi Delay Modeling and Parameter Estimationmentioning

confidence: 99%

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Position determination of the Chang’e 3 lander with geodetic VLBI

Kłopotek

Hobiger

Haas

et al. 2019

Earth Planets Space

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We present results from the analysis of observations of the Chang'e 3 lander using geodetic Very Long Baseline Interferometry. The applied processing strategy as well as the limiting factors to our approach is discussed. We highlight the current precision of such observations and the accuracy of the estimated lunar-based parameters, i.e., the lunar lander's Moon-fixed coordinates. Our result for the position of the lander is 44.12193 • N , − 19.51159 • E and − 2637.3 m, with horizontal position uncertainties on the lunar surface of 8.9 m and 4.5 m in latitude and longitude, respectively. This result is in good agreement with the position derived from images taken by the Narrow Angle Camera of the Lunar Reconnaissance Orbiter. Finally, we discuss potential improvements to our approach, which could be used to apply the presented concept to high-precision lunar positioning and studies of the Moon.

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Section: Data Processingmentioning

confidence: 99%

Section: Vlbi Delay Modeling and Parameter Estimationmentioning

confidence: 99%

Section: Vlbi Delay Modeling and Parameter Estimationmentioning

confidence: 99%

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Position determination of the Chang’e 3 lander with geodetic VLBI

Kłopotek

Hobiger

Haas

et al. 2019

Earth Planets Space

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“…Therefore, the relevance of Etalon-1/-2 data is thus marginal. The contribution of other geodetic satellites, such as Starlette, Stella, and Ajisai (Sośnica et al 2014;Sośnica 2014;Bloßfeld et al 2018), active low Earth-orbiting satellites (Arnold et al 2018;Guo et al 2018;Hellerschmied et al 2018;Strugarek et al 2019), as well as the constellation of Global Navigation Satellite Systems (GNSS) (Thaller et al 2011;Zajdel et al 2017;Sośnica et al 2018Sośnica et al , 2019 is still being investigated by many researchers. SLR integrates the three major pillars of the Global Geodetic Observing System (GGOS) (Plag and Pearlman 2009), i.e., the Earth gravity field, Earth rotation, and Earth geometry in one common adjustment (Bloßfeld et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Impact of network constraining on the terrestrial reference frame realization based on SLR observations to LAGEOS

Zajdel

Sośnica

Drożdżewski

et al. 2019

J Geod

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The Satellite Laser Ranging (SLR) network struggles with some major limitations including an inhomogeneous global station distribution and uneven performance of SLR sites. The International Laser Ranging Service (ILRS) prepares the time-variable list of the most well-performing stations denoted as 'core sites' and recommends using them for the terrestrial reference frame (TRF) datum realization in SLR processing. Here, we check how different approaches of the TRF datum realization using minimum constraint conditions (MCs) and the selection of datum-defining stations affect the estimated SLR station coordinates, the terrestrial scale, Earth rotation parameters (ERPs), and geocenter coordinates (GCC). The analyses are based on the processing of the SLR observations to LAGEOS-1/-2 collected between 2010 and 2018. We show that it is essential to reject outlying stations from the reference frame realization to maintain a high quality of SLR-based products. We test station selection criteria based on the Helmert transformation of the network w.r.t. the a priori SLRF2014 coordinates to reject misbehaving stations from the list of datum-defining stations. The 25 mm threshold is optimal to eliminate the epoch-wise temporal deviations and to provide a proper number of datum-defining stations. According to the station selection algorithm, we found that some of the stations that are not included in the list of ILRS core sites could be taken into account as potential core stations in the TRF datum realization. When using a robust station selection for the datum definition, we can improve the station coordinate repeatability by 8%, 4%, and 6%, for the North, East and Up components, respectively. The global distribution of datum-defining stations is also crucial for the estimation of ERPs and GCC. When excluding just two core stations from the SLR network, the amplitude of the annual signal in the GCC estimates is changed by up to 2.2 mm, and the noise of the estimated pole coordinates is substantially increased.

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“…According to Rothacher (2000), the challenging subject involving multiple geodetic techniques' integration should be solved at the following three different levels: parameter estimation, observation model and station network. At the station network level, the IERS fundamental sites (colocated sites) can give the only effective solutions for the multi-technique integration (Ray 2000;Munghemezulu et al 2014;Glaser et al 2015;Hellerschmied et al 2018). The inter-technique link is the terrestrial ties obtained from ground geodetic measurements of reference points for different space geodetic instruments (Ray 2000).…”

Section: Introductionmentioning

confidence: 99%

Estimation of SLR station coordinates by means of SLR measurements to kinematic orbit of LEO satellites

Guo

Wang

Shen

et al. 2018

Earth Planets Space

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Generally, the dynamical model is used to estimate coordinates of satellite laser ranging (SLR) stations. In this paper, we put forward a kinematic method to estimate the coordinates of SLR stations by using global navigation satellite system (GNSS) technique onboard a low Earth orbiting (LEO) satellite. We applied it to the processing of SLR and GNSS observations of the GRACE-A satellite from January to December 2012. We found that the LEO satellite as a spacebased connection between SLR and GNSS techniques allowed the precise estimation of SLR site positions with the agreement level of 2-3 cm with respective to SLRF2014. The SLR network can be attached to the IGS network at the centimeter level. The results show that the proposed method is feasible for determining the coordinates of SLR stations as an idea for the satellite-based integration of different space geodetic techniques.

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Observing APOD with the AuScope VLBI Array

Cited by 21 publications

References 35 publications

Position determination of the Chang’e 3 lander with geodetic VLBI

Position determination of the Chang’e 3 lander with geodetic VLBI

Impact of network constraining on the terrestrial reference frame realization based on SLR observations to LAGEOS

Estimation of SLR station coordinates by means of SLR measurements to kinematic orbit of LEO satellites

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