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Journal articles on the topic 'Department of Geodesy and Geophysics'

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Published: 2 March 2023
Last updated: 3 March 2023

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1

Brzeziński, Aleksander, Mieczysław Jóźwik, Marek Kaczorowski, Maciej Kalarus, Damian Kasza, Wiesław Kosek, Jolanta Nastula, et al. "Geodynamic Research at the Department of Planetary Geodesy, SRC PAS." Reports on Geodesy and Geoinformatics 100, no. 1 (June 1, 2016): 131–47. http://dx.doi.org/10.1515/rgg-2016-0011.

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Abstract The Department of Planetary Geodesy of the Space Research Centre PAS has been conducting research on a broad spectrum of problems within a field of global dynamics of the Earth. In this report we describe the investigations on selected subjects concerning polar motion (modeling and geophysical interpretation of the Chandler wobble, hydrological excitation of seasonal signals, search for optimal prediction methods), tectonic activity in the region of the Książ Geodynamic Laboratory of the SRC, and finally the new joint Polish-Italian project GalAc analyzing feasibility and usefulness of equipping second-generation Galileo satellites with accelerometers.
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2

Mustafin, M. G., A. Yu Romanchikov, N. S. Pavlov, and N. S. Kopylova. "Essay on the Century Jubilee of the Department of Engineering Geodesy, St. Petersburg Mining University." Geodesy and Cartography 991, no. 1 (February 20, 2023): 51–64. http://dx.doi.org/10.22389/0016-7126-2023-991-1-51-64.

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The authors mark the main historical events of the St. Petersburg Mining University’s Department of Engineering Geodesy hundred-year work. A great experience in Surveying theory and practice started in the times of Peter the Great was accumulated. The beginning of Russian Surveying skills forming dates at 1701 with foundation of “Navigation and Mathematic Sciences school” in Moscow. Beside engineers and gunners, surveyors were trained there. In 1715 navigation classes moved to St. Petersburg; on their base the Nautical academy was founded. In the first technical higher educational institution of Russia, St. Petersburg Miming University (at that time Mining School), the basic subjects were land- and underground Surveys. In the USSR industrializing of the country was started, so the part of Geodesy in it was among the main ones. Well-trained technical personnel were required. The Department occurred to be one of the first in the country. The history of its creating, establishment and development is given in brief. The main attention is paid to the Chairmen of the department, their achievements, scientific interests, tasks they were facing and solutions. The results of the research work which made a significant contribution in Geodetic science are also shown.
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3

Nikonov, A. V., E. I. Dolgov, and S. V. Sergeev. "Sergej Jakovlevich Belykh, Siberian surveyor, Tutor, Military Topographer (120th birthday anniversary)." Geodesy and Cartography 979, no. 1 (February 20, 2022): 54–64. http://dx.doi.org/10.22389/0016-7126-2022-979-1-54-64.

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The paper is about Sergey Yakovlevich Belykh (1901–1963), a practitioner, teacher and military topographer who made a significant contribution to the development of higher geodesic education in Siberia. Information on the activities of the Higher Geodetic Department in Siberian Field District, where S. Y. Belykh worked after graduation from the Geodetic Faculty of Omsk Agricultural Academy in 1922 is presented. It is told about the arrangement of the Siberian Astronomic-and-Geodetic Institute in Omsk. Novosibirsk Institute of Engineers of Geodesy, Aerial Photography and Cartography (NIIGAiK), was subsequently formed there. The difficulties that the young geodesic university faced in 1940–1950 were highlighted. S. Y. Belykh’s military service in the Red Army Military Topographic Service (MTS) troops including work in the Scientific Research Institute of the MTS is described. There is information on colleagues of S. Y. Belykh and fragments of his daughter’s recollections.
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4

Mason, Melvyn, and Robert S. White. "Cambridge radio sonobuoys and the seismic structure of oceanic crust." Notes and Records: the Royal Society Journal of the History of Science 74, no. 1 (April 3, 2019): 55–72. http://dx.doi.org/10.1098/rsnr.2018.0061.

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The Cambridge University Department of Geodesy and Geophysics pioneered the development of radio sonobuoys which could be used from a single ship to study the structure of the submarine crust. By contrast, contemporaneous marine seismic research, mainly in the USA, used more expensive techniques requiring the use of two ships. For nearly three decades from the early 1950s several generations of Cambridge sonobuoys were used as the primary tool to study the structure of the oceanic crust and the adjacent continental margins by seismic refraction methods, until superseded by ocean-bottom seismographs. An early result was to confirm the ubiquity across the world of relatively thin (compared with continental crust), probably volcanic, oceanic crust. This in turn underpinned the subsequent recognition of seafloor spreading and plate tectonics.
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5

Sjöberg, L. E. "Arne Bjerhammar- a personal summary of his academic deeds." Journal of Geodetic Science 11, no. 1 (January 1, 2021): 1–6. http://dx.doi.org/10.1515/jogs-2020-0117.

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Abstract Arne Bjerhammar is well known worldwide mainly for his research in physical geodesy but also for introducing a new matrix algebra with generalized inverses applied in geodetic adjustment. Less known are his developments in geodetic engineering and contributions to satellite and relativistic geodesy as well as studies on the relation between the Fennoscandia land uplift and the regional gravity low. Most likely part of his research has contributed to worldwide political relaxation during the cold war, which deed was honored by a certificate of achievement awarded by the Department of Research of the US army as well as the North Star Order by the King of Sweden. Arne Bjerhammar’s pioneer scientific production, in particular on a world geodetic system, towards what would become GPS, as well as relativistic geodesy, is still of great interest among the worldwide geodetic community, while the memories and spirit along his outstanding academic deeds have more or less fainted away from his home university (KTH) only a decade after he passed away.
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6

Imrišek, Martin, Mária Derková, and Juraj Janák. "Estimation of GNSS tropospheric products and their meteorological exploitation in Slovakia." Contributions to Geophysics and Geodesy 50, no. 1 (May 24, 2020): 83–111. http://dx.doi.org/10.31577/congeo.2020.50.1.5.

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This paper discusses the in near–real time processing of Global Navigation Satellite System observations at the Department of Theoretical Geodesy at the Slovak University of Technology in Bratislava. Hourly observations from Central Europe are processed with 30 minutes delay to provide tropospheric products. The time series and maps of tropospheric products over Slovakia are published online. Zenith total delay is the most important tropospheric parameter. Its comparison with zenith total delays from IGS and E–GVAP solutions and the validation of estimated zenith total delay error over year 2018 have been made. Zenith total delays are used to improve initial conditions of numerical weather prediction model by the means of the three–dimensional variational analysis at Slovak Hydrometeorological Institute. The impact of assimilation of different observation types into numerical weather prediction model is discussed. The case study was performed to illustrate the impact of zenith total delay assimilation on the precipitation forecast.
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7

Everett, J., and A. Smith. "Genesis of a Geophysical Icon: The Bullard, Everett and Smith Reconstruction of the Circum-Atlantic Continents." Earth Sciences History 27, no. 1 (January 1, 2008): 1–11. http://dx.doi.org/10.17704/eshi.27.1.w0v227931k184h64.

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The first computer fit of the continents had its origins in a controversy over Warren Carey's visual fit between South America and Africa. Sir Harold Jeffreys denied that there was a fit, but Sir Edward Bullard considered the fit to be impressive. Bullard suggested quantifying the fit to Jim Everett, a graduate student at the time. Everett did so, developing his own method from his mathematical background, and computed the fit for the South Atlantic. Alan Smith, then a research assistant, used his geological knowledge and worked with Everett to fit together all the circum-Atlantic continents. Thus Bullard had the idea of quantifying the fit, and Everett and Smith implemented it. Then Smith extended the method to fits beyond the Atlantic. The outcome owed much to Bullard's leadership, and to the lively and open discussions that prevailed during coffee and tea at Madingley Rise, which housed the Department of Geodesy and Geophysics of the University of Cambridge at that time.
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8

Searle, Roger C. "Sir Anthony Seymour Laughton. 29 April 1927—27 September 2019." Biographical Memoirs of Fellows of the Royal Society 69 (July 22, 2020): 291–311. http://dx.doi.org/10.1098/rsbm.2020.0021.

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Anthony (Tony) Laughton was an oceanographer who promoted the science of oceanograpy in Britain. Focusing on the shape of the seafloor, his work included underwater photography, ocean drilling, long-range side-scan sonar and scientific charting of the ocean floor. Following undergraduate studies at King's College, Cambridge, he joined Maurice Hill (FRS 1962) at the Cambridge Department of Geodesy and Geophysics, beginning a career in marine geophysics. Following his PhD, he spent a year at Lamont Geological Observatory, USA, where he met many leading US workers, and became interested in deep-seafloor photography and bathymetric mapping. Returning to the UK, he joined the National Institute of Oceanography (Institute of Oceanographic Sciences from 1973) at Wormley, Surrey, and became director in 1978. He developed the first UK seafloor camera, was an enthusiastic supporter and user of the revolutionary Precision Echo Sounder and later of the GLORIA long-range side-scan sonar. He played a significant part in the International Indian Ocean Expedition, subsequently developing a new understanding of the Gulf of Aden. A consummate committee man, he had a vital role in reviving the General Bathymetric Chart of the Oceans and promoted UK involvement in the international Deep-Sea Drilling Project. He was an accomplished amateur musician (playing French horn), small-boat sailor and handyman.
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9

Popadyev, V. V., I. Yu Mosolkova, and S. S. Rakhmonov. "On the presentation of the heights theory in the Russian literature." Geodesy and Cartography 976, no. 10 (November 20, 2021): 52–63. http://dx.doi.org/10.22389/0016-7126-2021-976-10-52-63.

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Our review of the Russian literature on geodesy caused a desire to consider the texts related to determining the heights of points on the earth’s surface. This topic, seeming simple, is very complex and is a mandatory part of most textbooks for students of geodetic specialties in universities and colleges. The presentation of the heights theory in the course of topography affects not only the specialized departments of construction, polytechnic universities and specialized colleges, but higher geodetic educational institutions as well. The authors review and evaluate the sections on the theory of heights in the domestic educational geodetic literature. Typical inaccuracies in the presentation of elevation systems are analyzed, criticism of the most common clichés among surveyors is given, recommendations are made on the minimum of presentation of the elevation system for non-specialists, and some useful illustrations are provided to make understanding the essence of the phenomenon easier. The article was written basing on the experience of lecturing height systems by employees of the departments of surveying and higher geodesy. We hope to arouse the interest to this topic.
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10

Ogden, R. W. "Peter Chadwick. 23 March 1931—12 August 2018." Biographical Memoirs of Fellows of the Royal Society 69 (June 3, 2020): 109–31. http://dx.doi.org/10.1098/rsbm.2020.0012.

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Peter Chadwick studied mathematics as an undergraduate at the University of Manchester, graduating with first-class honours in 1952, from where he moved to Cambridge and completed a PhD on the thermal history of the Earth in the Department of Geodesy and Geophysics under the supervision of Dr Robert Stoneley. His research then developed to focus primarily on the propagation of waves, and he made a major contribution to the mathematical theory of elastic wave propagation and became a world-leading authority in this area. He also made fundamental advances in the modelling of the thermo-elastic properties of rubberlike materials. At the University of East Anglia, where he was a professor for 26 years, he was the driving force behind the development of a research group in theoretical mechanics in the School of Mathematics and Physics, leading by example and supporting and encouraging fellow faculty members, especially the younger staff, academic visitors and students. He gave considerable service to the University of East Anglia in a number of capacities, including a period as Dean of the School, and to the scientific community, through substantial journal editorial activities and as a member of several national and international committees.
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11

Raskolets, Viktor V., and Alexander N. Sorokin. "Activities of the Geographical Department of the Research Institute of Siberia and its contribution to the development of geodesy, geophysics and hydrology in the Siberian region (July 1919 - June 1920)." Vestnik Tomskogo gosudarstvennogo universiteta, no. 425 (December 1, 2017): 147–54. http://dx.doi.org/10.17223/15617793/425/19.

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12

Pobedinskiy, G. G., V. E. Zhukovskiy, and V. M. Boginsky. "Actual problems of Russian toponyms transcribing in foreign languages." Geodesy and Cartography 981, no. 3 (April 20, 2022): 56–63. http://dx.doi.org/10.22389/0016-7126-2022-981-3-56-63.

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After analyzing a number of international and national regulatory documents in the field of names of geographical and other objects, as well as the practice of applying the requirements of these documents, the authors concluded that the main method of geographical objects’ names transmitting, as well as those of streets, squares, stops, road and city signs, and of other inner-city objects in foreign languages (letters of the Latin alphabet) is currently adopted transliteration. On the one hand it can simplify spelling them with Latin letters, but, on the other hand inscriptions unreadable in any language are created, since their pronunciation is unknown. In connection with participation in international economic and other activities, holding mass events with foreign representatives, the problem of writing and adequate reading the names of geographical and other objects in other languages (letters of the Latin alphabet) has aggravated. The authors see the solution of the mentioned task in creating a specialized multilingual database through including transcribed names in it, i. e. converted according to pronunciation into English, then into the official languages of the United Nations and German. This will require enormous work, which should involve translators, philologists, cartographers and local historians; in addition, it will be necessary to revive the work of the department of geographical names in the head scientific organization in the industry of geodesy, cartography and names of geographical objects.
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13

Creer, Kenneth, and Edward Irving. "Testing Continental Drift: Constructing the First Palaeomagnetic Path of Polar Wander (1954)." Earth Sciences History 31, no. 1 (January 1, 2012): 111–45. http://dx.doi.org/10.17704/eshi.31.1.t4101011075g8125.

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We describe the discovery that the natural remanent magnetisation (NRM) of certain rock formations in Britain that are Eocene or older have directions that differed significantly from the Earth's present field and from one another. In 1954 the first author, a third year research student in the Department or Geodesy and Geophysics (DG&G) at Cambridge University, observed that the poles corresponding to these old geomagnetic field directions fell consecutively on a path beginning in the Proterozoic in Arizona, swooped across the Pacific Ocean to the coast of eastern Asia and from there northwards to the present north geographic pole by the middle Tertiary. This was the first path of apparent polar wander (APW) based on the NRM of rocks. This path ought to have been reproducible in all continents had they not moved. Thus was born the first successful physical test of Wegener's Theory of continental drift. The work had its origins several years earlier with the construction in the later 1940s of a very sensitive magnetometer by P. M. S. Blackett at Jodrell Bank, a field station of the University of Manchester. In the summer and autumn of 1951, the second author, a recent geology graduate from Cambridge University, showed that Blackett's instrument, which had been made for an entirely different purpose, was well suited to measuring the NRM of rocks (palaeomagnetism). In the following years Blackett-type magnetometers became the means by which the British path of APW was observed. Although Creer's path was based only on nine poles we show that subsequent work fully justifies its use as a starting point for the successful global test of Wegener's theory that was carried out in the following years. Since then, palaeomagnetic poles and the APW paths derived from them have become the basis for constructing the general frame of reference for palaeogeographic maps, for mapping the past distribution of continents, oceans and orogenic belts, the location of ancient climatic zones and many other applications.
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14

Gryshchuk, P. "20TH ANNIVERSARY OF THE STUDENT CHAPTER OF EXPLORATION GEOPHYSICISTS AT KYIV UNIVERSITY!" Visnyk of Taras Shevchenko National University of Kyiv. Geology, no. 2(97) (2022): 97–105. http://dx.doi.org/10.17721/1728-2713.97.13.

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Geological education is the basis for training specialists in the study of natural resources. The rational use of subsoil is the basis of the economic development of Ukraine, especially in the conditions of the energy transition. Educational institutions provide a wide range of disciplines for the geological training of students. Participation in international societies contributes to getting additional knowledge. The distribution of professional societies within institutions and enterprises is world practice in many countries. There are several geological associations that cooperate with Ukraine in the geologic sciences. The student section of the Society of Exploration Geophysicists (SEG) was established at Taras Shevchenko National University of Kyiv at the Department of Geophysics twenty years ago. The introduction to new features was interesting and useful for students and teachers. Thanks to SEG programs, students received new computer equipment, geophysical literature, educational courses, attendance of lectures, international participation in symposia, possibility of organizing field camps, getting of scholarships, etc. The field of activity of the SEG Kyiv student chapter covers reports on its work at international conferences and educational institutions, the invitation of specialists of the geological industry, participation in geological quizzes and competitions among foreign students, conducting geophysical studies, etc. Members of the SEG section organized international geoscience investigations in various regions of Ukraine. The geophysical surveys were conducted to study ancient buildings in Kamianets-Podilskyi, a gypsum Verteba cave and paleovolcanoes near Uzhgorod. 49 students from 11 countries participated in the field camps. Local studies of pipelines were carried out by geophysical methods near the building of the ESI "Institute of Geology" (Kyiv) and on Totoha Mount, located in Kyiv region. Students performed magnetics, electrical resistivity tomography (ERT), surface seismic exploration, ground-penetrating radar (GPR), geodesic measurements and surveys UAV. The student chapter activity was presented at its meetings, with more than 50 reports. For 20 years, more than 100 students were members of the SEG section, which has been the basis for the AAPG and EAGE faculty circles. The SEG Kyiv student chapter is recognized as the best one in 2018. The geophysical section SEG has made a significant contribution to the spread of geological knowledge and the presentation of Taras Shevchenko National University of Kyiv internationally.
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15

Amalvict, Martine, and Joaquim Boavida. "The geoid: From geodesy to geophysics and from geophysics to geodesy." Surveys in Geophysics 14, no. 4-5 (September 1993): 477–94. http://dx.doi.org/10.1007/bf00690573.

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16

Bills, Bruce G., and Stephen P. Synnott. "Planetary geodesy." Reviews of Geophysics 25, no. 5 (1987): 833. http://dx.doi.org/10.1029/rg025i005p00833.

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17

Henneberg, Heinz G. "Neotectonic geodesy." Tectonophysics 130, no. 1-4 (November 1986): 95–104. http://dx.doi.org/10.1016/0040-1951(86)90103-4.

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18

Brzeziński, Aleksander, Marcin Barlik, Ewa Andrasik, Waldemar Izdebski, Michał Kruczyk, Tomasz Liwosz, Tomasz Olszak, et al. "Geodetic and Geodynamic Studies at Department of Geodesy and Geodetic Astronomy Wut." Reports on Geodesy and Geoinformatics 100, no. 1 (June 1, 2016): 165–200. http://dx.doi.org/10.1515/rgg-2016-0013.

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Abstract The article presents current issues and research work conducted in the Department of Geodesy and Geodetic Astronomy at the Faculty of Geodesy and Cartography at Warsaw University of Technology. It contains the most important directions of research in the fields of physical geodesy, satellite measurement techniques, GNSS meteorology, geodynamic studies, electronic measurement techniques and terrain information systems.
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19

Li, Xiong, and Hans‐Jürgen Götze. "Ellipsoid, geoid, gravity, geodesy, and geophysics." GEOPHYSICS 66, no. 6 (November 2001): 1660–68. http://dx.doi.org/10.1190/1.1487109.

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Geophysics uses gravity to learn about the density variations of the Earth’s interior, whereas classical geodesy uses gravity to define the geoid. This difference in purpose has led to some confusion among geophysicists, and this tutorial attempts to clarify two points of the confusion. First, it is well known now that gravity anomalies after the “free‐air” correction are still located at their original positions. However, the “free‐air” reduction was thought historically to relocate gravity from its observation position to the geoid (mean sea level). Such an understanding is a geodetic fiction, invalid and unacceptable in geophysics. Second, in gravity corrections and gravity anomalies, the elevation has been used routinely. The main reason is that, before the emergence and widespread use of the Global Positioning System (GPS), height above the geoid was the only height measurement we could make accurately (i.e., by leveling). The GPS delivers a measurement of height above the ellipsoid. In principle, in the geophysical use of gravity, the ellipsoid height rather than the elevation should be used throughout because a combination of the latitude correction estimated by the International Gravity Formula and the height correction is designed to remove the gravity effects due to an ellipsoid of revolution. In practice, for minerals and petroleum exploration, use of the elevation rather than the ellipsoid height hardly introduces significant errors across the region of investigation because the geoid is very smooth. Furthermore, the gravity effects due to an ellipsoid actually can be calculated by a closed‐form expression. However, its approximation, by the International Gravity Formula and the height correction including the second‐order terms, is typically accurate enough worldwide.
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20

Anonymous. "Geodesy and geomatics added to department name." Eos, Transactions American Geophysical Union 75, no. 13 (1994): 149. http://dx.doi.org/10.1029/94eo00846.

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21

Jekeli, Christopher. "New instrumentation techniques in geodesy." Reviews of Geophysics 25, no. 5 (1987): 889. http://dx.doi.org/10.1029/rg025i005p00889.

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22

Hudnut, Kenneth W. "Earthquake geodesy and hazard monitoring." Reviews of Geophysics 33 (1995): 249. http://dx.doi.org/10.1029/95rg00406.

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23

Herring, T. A. ""Introduction to Geodesy: The History and Concept of Modern Geodesy" by James R. Smith." Seismological Research Letters 69, no. 1 (January 1, 1998): 52–53. http://dx.doi.org/10.1785/gssrl.69.1.52.

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24

Whitten, Charles A. "Geodesy and geodynamics." Tectonophysics 130, no. 1-4 (November 1986): 9–21. http://dx.doi.org/10.1016/0040-1951(86)90097-1.

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25

Goad, Clyde C. "Introduction to the Report on Geodesy." Reviews of Geophysics 25, no. 5 (1987): 823. http://dx.doi.org/10.1029/rg025i005p00823.

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26

Ziegel, Eric R. "Probability and Statistics in Geodesy and Geophysics." Technometrics 33, no. 2 (May 1991): 241. http://dx.doi.org/10.1080/00401706.1991.10484816.

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27

Koch, K. R. "Probability and statistics in geodesy and geophysics." Physics of the Earth and Planetary Interiors 53, no. 1-2 (December 1988): 184–85. http://dx.doi.org/10.1016/0031-9201(88)90147-1.

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28

Agterberg, F. P. "Probability and statistics in geodesy and geophysics." Marine Geology 89, no. 1-2 (September 1989): 171–72. http://dx.doi.org/10.1016/0025-3227(89)90035-2.

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29

Chilingar, George V. "Probability and statistics in geodesy and geophysics." Earth-Science Reviews 27, no. 3 (May 1990): 267. http://dx.doi.org/10.1016/0012-8252(90)90007-i.

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30

Závoti, J., J. Somogyi, J. Kalmár, and L. Battha. "Research in mathematical geodesy." Acta Geodaetica et Geophysica Hungarica 40, no. 3-4 (October 2005): 283–92. http://dx.doi.org/10.1556/ageod.40.2005.3-4.3.

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31

Bányai, L. "Results in physical geodesy." Acta Geodaetica et Geophysica Hungarica 40, no. 3-4 (October 2005): 307–15. http://dx.doi.org/10.1556/ageod.40.2005.3-4.5.

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32

Paláncz, B., and J. L. Awange. "Nonlinear homotopy in geodesy." Acta Geodaetica et Geophysica 52, no. 1 (March 30, 2016): 1–4. http://dx.doi.org/10.1007/s40328-016-0169-1.

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33

Müller, Jürgen, Michael Soffel, and Sergei A. Klioner. "Geodesy and relativity." Journal of Geodesy 82, no. 3 (June 6, 2007): 133–45. http://dx.doi.org/10.1007/s00190-007-0168-7.

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34

Brookes, Clive J. "Satellite geodesy." Journal of Atmospheric and Terrestrial Physics 57, no. 13 (November 1995): 1668–69. http://dx.doi.org/10.1016/0021-9169(95)90036-5.

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35

Kiani Shahvandi, Mostafa. "Applications of numerical integration in geodesy and geophysics." Acta Geophysica 69, no. 1 (January 19, 2021): 29–45. http://dx.doi.org/10.1007/s11600-020-00525-x.

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36

Monhor, Davaadorjin. "Dirichlet distribution with views on geodesy and geophysics." Acta Geodaetica et Geophysica 48, no. 2 (April 9, 2013): 235–45. http://dx.doi.org/10.1007/s40328-013-0016-6.

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37

Pobedinsky, G. G. "Liquidation of the geodetic and cartographic service of the country through the prism of time." Vestnik SSUGT (Siberian State University of Geosystems and Technologies) 27, no. 4 (2022): 16–30. http://dx.doi.org/10.33764/2411-1759-2022-27-4-16-30.

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The article considers the problems of legal, organizational, scientific and technical crisis in the field of geodesy and cartography. It discloses the proposals of the Russian Society of Geodesy, Cartography and Land Management in such areas of improving legislation and law enforcement in the field of geodetic and cartographic activities as the state coordinate system and local coordinate systems, scientific support in the field of geodesy and cartography, the federal executive authority in the field of geodesy and cartography, legal regulation in the field of geodesy and cartography. It gives a brief history of the reorganization of the national cartographic and Geodetic service from the Main Department of Cartog-raphy under the Council of Ministers of the Russian Soviet Federative Socialist Republic (RSFSR) in 1991 to the Public Legal Company "Roskadastr" in 2022. The articles analyses the consequences of the planned reorganization in 2022 by joining JSC "Roskartografiya" and the Federal State Budgetary Institution "Center for Geodesy, Cartography and Spatial Data Infrastructure" to the Public the legal company "Roskadastr".
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38

Stein, S. "Looking for Bears: Space Geodesy for Earthquake Studies." Seismological Research Letters 69, no. 5 (September 1, 1998): 377–79. http://dx.doi.org/10.1785/gssrl.69.5.377.

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Tscherning, C. C., and P. Vanicek. "Editorial. Journal of Geodesy." Bulletin Géodésique 69, no. 4 (December 1995): 191. http://dx.doi.org/10.1007/bf00806731.

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Zhan, Yan, and Patricia M. Gregg. "Data assimilation strategies for volcano geodesy." Journal of Volcanology and Geothermal Research 344 (September 2017): 13–25. http://dx.doi.org/10.1016/j.jvolgeores.2017.02.015.

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Arutyunov, V. V. "Analysis of the demand for the results of scientific activity in the main areas of Earth Sciences." Scientific and Technical Libraries, no. 2 (February 20, 2020): 91–104. http://dx.doi.org/10.33186/1027-3689-2020-2-91-104.

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The paper analyzes the importance of geological knowledge for solving a wide range of practical problems. The purpose of this study is to evaluate the results of the research of scientists and specialists in 2012–2018 in Geology, Geophysics, Geography, Mining, Geodesy and cartography on the basis of RSCI databases (Russian science citation index). The analysis was carried out taking into account a number of scientometric indicators: the publication activity of researchers – the annual number of their publications, as well as the citation of these publications and the demand for the results of their work. Features of publication activity are revealed: high values of its indicators for Geology and Geophysics and minimum values – for Geodesy and cartography; thus the number of publications on Geography and Mining approximately coincide. For Geology, there is stability in the number of publications since 2015, while in other analyzed industries there is a decline in the number of publications since 2017. Citation rates for all years under review are continuously decreasing. At the same time, in the field of Geophysics, citation rates are 3–4 times higher than similar indicators for Geography, and 7–9 times – indicators for Mining. The most popular are the results of research in Geophysics, the least – in the field of Geodesy and cartography. At the same time, if the annual demand for the results of studies in Geophysics exceeds similar indicators for Geography by 15–20%, for Geodesy and cartography – about 1.5 times. Low demand for all areas of research in 2018. The reason is obviously the same as for the small citation indicators this year: the delayed "response" of the scientific community to the publications of the current year.
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Ivan, M. "Polyhedral approximations in physical geodesy." Journal of Geodesy 70, no. 11 (November 1996): 755–67. http://dx.doi.org/10.1007/bf00867154.

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Ivan, M. "Polyhedral approximations in physical geodesy." Journal of Geodesy 70, no. 11 (September 1, 1996): 755–67. http://dx.doi.org/10.1007/s001900050065.

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Zund, J. D., and W. Moore. "Hotine’s conjecture in differential geodesy." Bulletin Géodésique 61, no. 3 (September 1987): 209–22. http://dx.doi.org/10.1007/bf02521228.

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Bennett, Richard A. "Instantaneous slip rates from geology and geodesy." Geophysical Journal International 169, no. 1 (April 2007): 19–28. http://dx.doi.org/10.1111/j.1365-246x.2007.03331.x.

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Rummel, Reiner. "The interdisciplinary role of space geodesy—Revisited." Journal of Geodynamics 49, no. 3-4 (April 2010): 112–15. http://dx.doi.org/10.1016/j.jog.2009.10.006.

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Sturkell, Erik, Páll Einarsson, Freysteinn Sigmundsson, Halldór Geirsson, Halldór Ólafsson, Rikke Pedersen, Elske de Zeeuw-van Dalfsen, Alan T. Linde, Selwyn I. Sacks, and Ragnar Stefánsson. "Volcano geodesy and magma dynamics in Iceland." Journal of Volcanology and Geothermal Research 150, no. 1-3 (February 2006): 14–34. http://dx.doi.org/10.1016/j.jvolgeores.2005.07.010.

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Tango, G. G. "Inverse gravimetric problems in GeoProspecting and geodesy." Tectonophysics 186, no. 3-4 (February 1991): 387. http://dx.doi.org/10.1016/0040-1951(91)90371-x.

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Dvořáček, Filip. "Precision Tests of Geodetic Centring Equipment." Geoinformatics FCE CTU 15, no. 2 (December 8, 2016): 5–14. http://dx.doi.org/10.14311/gi.15.2.1.

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The paper introduces testing procedures of several different geodetic centring devices performed mostly at the laboratory of the Research Institute of Geodesy, Topography and Cartography. Functional construction characteristics of a spherically mounted retroreflector Leica RRR 1.5’’, rotatable carriers Sokkia AP41 and Leica GZR3 and 12 different geodetic tribraches were examined. Further, a centring displacement instrument developed at the Czech Technical University in Prague, Faculty of Civil Engineering, Department of Special Geodesy, is evaluated in both laboratory and field conditions. For all tests, laser tracker Leica AT401 with a 5 μm standard uncertainty of absolute distance measurement, was employed.
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Saltogianni, Vasso, and Stathis C. Stiros. "Topological inversion in geodesy-based, non-linear problems in geophysics." Computers & Geosciences 52 (March 2013): 379–88. http://dx.doi.org/10.1016/j.cageo.2012.11.010.

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