측지학

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  1. This includes tectonophysics, structural geology, geochronology, sedimentology, geothermometry, geodesy, numerical modeling, mineralogy, petrology, geochemistry and geophysics.[1]
  2. Geodetic data are becoming increasingly available from dense, continuously recording Global Positioning System (GPS) networks.[1]
  3. Geodesy is the science of accurately measuring the Earth's size, shape, orientation, mass distribution and how these vary with time.[2]
  4. Measuring Earth's gravity field, is also an element of geodesy.[2]
  5. The applications of SfM are wide-ranging, from many sub-fields of geoscience (geomorphology, tectonics, structural geology, geodesy, mining) to archaeology, architecture, and agriculture.[2]
  6. Three types of meters can supplement the data collected using the geodetic techniques detailed above: borehole strainmeters, tiltmeters, and creepmeters.[2]
  7. Specifically, high-precision geodesy means measuring the position of a point on the surface of the earth with millimeter accuracy.[3]
  8. In precision geodesy, VLBI is used to make measurements from pairs of radio telescopes of an extragalactic object such as a quasar that—from Earth—appears at a fixed point in space.[3]
  9. Geodetic VLBI also allows scientists to measure the movement of the Earth’s tectonic plates extremely accurately.[3]
  10. A major goal of GGOS is to ensure that observations from the four fundamental space geodetic techniques—VGOS (VLBI), GPS, SLR, and DORIS—are rigorously combined to realize an accurate and stable TRF.[3]
  11. Many organizations use geodesy to map the U.S. shoreline, determine land boundaries, and improve transportation and navigation safety.[4]
  12. These Decadal Survey missions are highly complementary and are essential to fully exploiting existing geodetic observation systems.[5]
  13. The operational applications and scientific research made possible by an accurate and easily-accessible global geodetic infrastructure are limited only by the imagination of the user community.[5]
  14. Geodesy, scientific discipline concerned with the precise figure of the Earth and its determination and significance.[6]
  15. It is now possible to use satellites in conjunction with the land-based system to refine knowledge of the Earth’s shape and dimensions; this endeavour is sometimes termed satellite geodesy.[6]
  16. geodesy Geodetic control mark set into the ground.[6]
  17. Our Division within the School of Earth Sciences emphasizes the multidisciplinarity that geodesy today enjoys and nurtures, especially in the Earth Sciences.[7]
  18. The field also incorporates studies of how these properties change over time and equivalent measurements for other planets (known as planetary geodesy).[8]
  19. The word geodesy comes from the Ancient Greek word γεωδαισία geodaisia (literally, "division of Earth").[8]
  20. Such geodetic operations are also applied to other astronomical bodies in the solar system.[8]
  21. For this reason, the study of Earth's gravitational field is called physical geodesy.[8]
  22. This series of reference books describes sciences of different elds in and around geodesy with independent chapters.[9]
  23. The material is suitable to provide a general overview of geodetic sciences for high-level geodetic researchers, educators as well as engineers and students.[9]
  24. Geodesy is an old science, going back to the days when land was taken into agricultural use and needed to be mapped.[10]
  25. Geodesy is the science of precisely measuring and mapping the Earth’s surface and locations of objects on it, the figure of the Earth and her gravity field, and changes in all these over time.[10]
  26. Geodesy has a long tradition of assessing the requirements from various parts of the society and of projecting these into future developments of the geodetic techniques and observing systems.[11]
  27. Today, geodesy is the science of determining the geometry, gravity field, and rotation of the Earth and their evolution in time.[11]
  28. This understanding of modern geodesy has led to the definition of the three pillars of geodesy, namely (1) Geokinematics, (2) Earth Rotation and (3) the Gravity Field.[11]
  29. Traditionally, geodesy has been a service science, providing an important utility to other sciences and many applications.[11]
  30. Geodesy is the science of determining the size and shape of the Earth (including its temporal variation) using measurements primarily (today) of distance, time, and gravity.[12]
  31. Many geodetic principles and techniques also have found application in studies of the Moon, other planets, and their satellites.[12]
  32. Matlab, C++, Java, and FORTRAN are some of the most commonly used computer programming languages in geodetic science.[12]
  33. Geodesy is concerned with the measurement of the Earth's figure and the mapping of parameters related to it.[13]
  34. The three main quantities of geodesy science are: geoid height, gravity anomaly and vertical deflections.[13]
  35. Geodesy and Geodynamics, launched in October, 2010, is a bimonthly publication.[14]
  36. Geodesy and Geodynamics is committed to the publication of high-quality scientific papers in English in the fields of Geodesy and Geodynamics from authors around the world.[14]
  37. Seafloor geodetic techniques allow for measurements of crustal deformation over the ∼70% of Earth's surface that is inaccessible to the standard tools of tectonic geodesy.[15]
  38. Recent technological advances promise further improvements in precision as well as the development of smaller, more autonomous, and less costly seafloor geodetic systems.[15]
  39. Balidakis received the award for his outstanding scientific contribution to the combination of geodetic space techniques.[16]
  40. He also quantifies the atmospheric propagation delays of signals used by the geodetic space techniques VLBI, SLR, GNSS and DORIS.[16]
  41. With his work Balidakis supports the efforts of space geodesy to achieve an accuracy level of 1 mm on a global scale.[16]
  42. Geodesy has grown rapidly and there are crucial geodetic applications in different scientific fields now.[17]
  43. We need to summarize the current status of the field and articulate new and emerging research opportunities in geodesy and interdisciplinary applications.[17]
  44. High-resolution topography data and precise geodetic measurements now can be obtained.[17]
  45. Least-Squares Estimation (LSE) is commonly used in geodesy data processing.[17]
  46. These fundamental geodetic quantities are intimately related to mass transport in the fluid envelope of the solid Earth and its interior, as well as to the dynamics of the Earth System.[18]
  47. Detailed modeling of the dense geodetic data for the Japan earthquake suggests a fluid-triggered slab pull helping to initiate a massive event.[19]
  48. This analysis opens up a significant new way to understand the structure of the upper mantle using geodesy.[19]
  49. Geodetic observations can be used to determine the structure of volcanoes below the surface and help with hazard preparedness and response.[19]
  50. The expansion of Earth imaging satellites has expanded capabilities for geodetic observations and satellite imagery to describe earthquakes and their impacts.[19]
  51. Geodesy is the science of determining the size and shape of the earth and the precise location of points on its surface.[20]
  52. Our Division within the School of Earth Sciences is a new structure that emphasizes the multidisciplinarity that geodesy today enjoys and nurtures, especially in the Earth Sciences.[21]
  53. The breakthrough and innovation of some mathematical analysis problems in the special field of geodesy are realized, which will further enrich and perfect the theoretical system of geodesy.[22]
  54. In Section 2, we discuss the forward and inverse expansions of the meridian arc often used in geometric geodesy.[22]
  55. In Section 3, the nonsingular expressions of singular integration in physical geodesy are derived.[22]
  56. In Section 4, we discuss series expansions of direct transformations between three anomalies in satellite geodesy.[22]
  57. Geodesy and Geoinformatics, as the science of recording, administering, analysing and presenting geospatial data and processes, deals with the structures of our living spaces and economic areas.[23]

소스

  1. 1.0 1.1 Geodesy - an overview
  2. 2.0 2.1 2.2 2.3 What is Geodesy?
  3. 3.0 3.1 3.2 3.3 MIT Haystack Observatory
  4. What is geodesy?
  5. 5.0 5.1 Precise Geodetic Infrastructure: National Requirements for a Shared Resource
  6. 6.0 6.1 6.2 Geodesy | science
  7. School of Earth Sciences
  8. 8.0 8.1 8.2 8.3 Wikipedia
  9. 9.0 9.1 Sciences of Geodesy - I - Advances and Future Directions
  10. 10.0 10.1 Geodesy: The science underneath
  11. 11.0 11.1 11.2 11.3 International Association of Geodesy
  12. 12.0 12.1 12.2 Geodetic Science Program and Course Offerings Guidelines
  13. 13.0 13.1 Earth Online
  14. 14.0 14.1 Geodesy and Geodynamics
  15. 15.0 15.1 Seafloor Geodesy
  16. 16.0 16.1 16.2 Kyriakos Balidakis receives the Geodesy Science Award
  17. 17.0 17.1 17.2 17.3 Special Issue : Recent Advances in Geodesy & Its Applications
  18. Geodesy and Geomatics Engineering
  19. 19.0 19.1 19.2 19.3 Geodetic Science Snapshots - All Topics
  20. Earthquake Glossary
  21. Welcome to Geodesy
  22. 22.0 22.1 22.2 22.3 Mathematical Analysis of Some Typical Problems in Geodesy by Means of Computer Algebra
  23. HafenCity Universität Hamburg (HCU): Geodesy and Geoinformatics

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