Estimation of Earth Rotation Parameter UT1 from Lunar Laser Ranging Observations

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

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  • DLR-Institute for Satellite Geodesy and Inertial Sensing
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Details

Original languageEnglish
Title of host publicationGeodesy for a Sustainable Earth - Proceedings of the 2021 Scientific Assembly of the International Association of Geodesy
EditorsJeffrey T. Freymueller, Laura Sánchez
Pages259-265
Number of pages7
ISBN (electronic)978-3-031-29507-2
Publication statusPublished - 2023

Publication series

NameInternational Association of Geodesy Symposia
Volume154
ISSN (Print)0939-9585
ISSN (electronic)2197-9359

Abstract

Since 1969 Lunar Laser Ranging (LLR) data have been collected by different observatories and analysed by various analysis groups. LLR is providing the longest time series of any space geodetic technique for studying the Earth-Moon dynamics. In recent years, observations have been carried out with larger telescopes and at infra-red (IR) wavelength, resulting in a better distribution of precise LLR data over the lunar orbit and the observed retro-reflectors on the Moon. The increased number of high-accuracy observations allows for more accurate determination of Earth Orientation Parameters (EOPs) from LLR data compared to previous years. In this study we focus on ΔUT1 results from different constellations and compare our LLR solution to the IERS EOP C04 series.

Keywords

    Earth rotation parameters, Earth rotation phase, Lunar laser ranging

ASJC Scopus subject areas

Cite this

Estimation of Earth Rotation Parameter UT1 from Lunar Laser Ranging Observations. / Biskupek, Liliane; Singh, Vishwa Vijay; Müller, Jürgen.
Geodesy for a Sustainable Earth - Proceedings of the 2021 Scientific Assembly of the International Association of Geodesy. ed. / Jeffrey T. Freymueller; Laura Sánchez. 2023. p. 259-265 (International Association of Geodesy Symposia; Vol. 154).

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Biskupek, L, Singh, VV & Müller, J 2023, Estimation of Earth Rotation Parameter UT1 from Lunar Laser Ranging Observations. in JT Freymueller & L Sánchez (eds), Geodesy for a Sustainable Earth - Proceedings of the 2021 Scientific Assembly of the International Association of Geodesy. International Association of Geodesy Symposia, vol. 154, pp. 259-265. https://doi.org/10.1007/1345_2022_178
Biskupek, L., Singh, V. V., & Müller, J. (2023). Estimation of Earth Rotation Parameter UT1 from Lunar Laser Ranging Observations. In J. T. Freymueller, & L. Sánchez (Eds.), Geodesy for a Sustainable Earth - Proceedings of the 2021 Scientific Assembly of the International Association of Geodesy (pp. 259-265). (International Association of Geodesy Symposia; Vol. 154). https://doi.org/10.1007/1345_2022_178
Biskupek L, Singh VV, Müller J. Estimation of Earth Rotation Parameter UT1 from Lunar Laser Ranging Observations. In Freymueller JT, Sánchez L, editors, Geodesy for a Sustainable Earth - Proceedings of the 2021 Scientific Assembly of the International Association of Geodesy. 2023. p. 259-265. (International Association of Geodesy Symposia). Epub 2022 Nov 8. doi: 10.1007/1345_2022_178
Biskupek, Liliane ; Singh, Vishwa Vijay ; Müller, Jürgen. / Estimation of Earth Rotation Parameter UT1 from Lunar Laser Ranging Observations. Geodesy for a Sustainable Earth - Proceedings of the 2021 Scientific Assembly of the International Association of Geodesy. editor / Jeffrey T. Freymueller ; Laura Sánchez. 2023. pp. 259-265 (International Association of Geodesy Symposia).
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abstract = "Since 1969 Lunar Laser Ranging (LLR) data have been collected by different observatories and analysed by various analysis groups. LLR is providing the longest time series of any space geodetic technique for studying the Earth-Moon dynamics. In recent years, observations have been carried out with larger telescopes and at infra-red (IR) wavelength, resulting in a better distribution of precise LLR data over the lunar orbit and the observed retro-reflectors on the Moon. The increased number of high-accuracy observations allows for more accurate determination of Earth Orientation Parameters (EOPs) from LLR data compared to previous years. In this study we focus on ΔUT1 results from different constellations and compare our LLR solution to the IERS EOP C04 series.",
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AB - Since 1969 Lunar Laser Ranging (LLR) data have been collected by different observatories and analysed by various analysis groups. LLR is providing the longest time series of any space geodetic technique for studying the Earth-Moon dynamics. In recent years, observations have been carried out with larger telescopes and at infra-red (IR) wavelength, resulting in a better distribution of precise LLR data over the lunar orbit and the observed retro-reflectors on the Moon. The increased number of high-accuracy observations allows for more accurate determination of Earth Orientation Parameters (EOPs) from LLR data compared to previous years. In this study we focus on ΔUT1 results from different constellations and compare our LLR solution to the IERS EOP C04 series.

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