• 대한공간정보학회지
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• 제23권4호
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• pp.67-74
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• 2015

GNSS/Leveling기술은 GNSS기술과 Leveling기술을 이용하여 기하학적 방법으로 지오이드고를 얻을 수 있게 해주며, GNSS/Geoid기술은 GNSS기술을 통해 얻은 타원체고에서 Geoid기술을 통해 얻은 지오이드고를 제하여 정표고를 얻는 기술을 말한다. 본 연구에서는 GNSS/Geoid기술을 이용한 표고결정 정확도를 검증하기 위하여 GNSS 타원체고 측정의 정확도를 검증하고자 하였다. 연구를 위하여 경남 지역에 테스트 베드(test bed)를 선정하고 GNSS 정적측위관측을 실시하였으며, 여러 가지 해석 조건에 따라 데이터를 처리함으로써 관측조건에 따른 GNSS 타원체고 측정의 정확도를 규명하였다. 연구결과 GNSS 정적측위방법에 의한 타원체고 결정에 있어서 3cm의 목표정확도를 확보하기 위해서는 측량지역 주변부의 네 점의 기지점을 고정하여 두 시간 이상 관측하여야 하며 기선거리는 20km로 제한하여야 한다는 것을 알 수 있었다.

• 한국측량학회지
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• 제36권1호
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• pp.1-8
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• 2018

To compensate for the shortcomings of spirit leveling, research on the determination of GNSS (Global Navigation Satellite System)-derived orthometric height has been actively carried out. However, most analyses were primarily performed inland. In this study, the influences of the arrangement of control points, observation duration, and geoid model on the accuracy of the GNSS-derived orthometric height have been analyzed to suggest the proper method to apply the determination of GNSS-derived orthometric height to the leveling loop disconnected area. As a result, it was found that two known points located near the unknown points need to be fixed in the leveling loop disconnected area. Further, 3 cm level of accuracy can be achieved if the GNSS survey is performed over two days, for four hours per day. In terms of the geoid model, the latest national geoid model should be applied rather than the EGM08 (Earth Gravitational Model 2008) to minimize regional bias and increase accuracy. Future research is necessary to apply the determination of the GNSS-derived orthometric height technique as a method to connect with the islands because the vertical reference system used inland and that used for the islands in Korea are still different.

• 한국측량학회지
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• 제40권4호
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• pp.305-313
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• 2022

The evolution of the GNSS (Global Navigation Satellite System) technology has enhanced positioning performance in terms of positioning accuracy and time efficiency. The technology makes it possible to determine orthometric heights at a few centimeter accuracies by transforming accurate ellipsoid heights if an accurate geoid model has been employed. This study aims to generate a correction surface using GNSS/leveling co-points and a local geoid model, Thailand Geoid Model 2017 (TGM2017), through the Kriging interpolation method in a small local area. Combining the surface and TGM2017 significantly improves height transformation with the 1-cm RMSE (Root Mean Square Error) fit of 10 GNSS/leveling reference points and a mean offset of +0.1 cm. The evaluation of the correction surface at 5 GNSS/leveling checkpoints shows the RMSE of 1.0 cm, which is 82.6 percent of accuracy improvements. The GNSS leveling method can possibly be used to replace a conventional leveling technique at a few centimeter uncertainties in the case of small areas with clear-sky and high satellite visibility environments.

• 한국측량학회지
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• 제38권2호
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• pp.153-163
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• 2020

After launching the GOCE (Gravity Field and Steady-State Ocean Circulation Explorer) which obtains high-frequency gravity signal using a gravity gradiometer, many research institutes are concentrating on the development of GGM (Global Geopotential Model) based on GOCE data and evaluating its precision. The precision of some GGMs was also evaluated in Korea. However, some studies dealt with GGMs constructed based on initial GOCE data or others applied a part of GNSS (Global Navigation Satellite System) / Leveling data on UCPs (Unified Control Points) for the precision evaluation. Now, GGMs which have a higher degree than EGM2008 (Earth Gravitational Model 2008) are available and UCPs were fully established at the end of 2019. Thus, EIGEN-6C4 (European Improved Gravity Field of the Earth by New techniques - 6C4), GECO (GOCE and EGM2008 Combined model), XGM2016 (Experimental Gravity Field Model 2016), SGG-UGM-1, XGM2019e_2159 were collected with EGM2008, and their precisions were assessed based on the GNSS/Leveling data on UCPs. Among GGMs, it was found that XGM2019e_2159 showed the minimum difference compared to a total of 5,313 points of GNSS/Leveling data. It is about a 1.5cm and 0.6cm level of improvement compare to EGM2008 and EIGEN-6C4. Especially, the local biases in the northern part of Gyeonggi-do, Jeju island shown in the EGM2008 was removed, so that both mean and standard deviation of the difference of XGM2019e_2159 to the GNSS/Leveling are homogeneous regardless of region (mountainous or plain area). NGA (National Geospatial-Intelligence Agency) is currently in progress in developing EGM2020 and XGM2019e_2159 is the experimentally published model of EGM2020. Therefore, it is expected that the improved GGM will be available shortly so that it is necessary to verify the precision of new GGMs consistently.

• 한국측량학회지
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• 제32권5호
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• pp.527-537
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• 2014

2013년 국토지리정보원에서는 합성 지오이드 모델 KNGeoid13(Korean National Geoid Model 2013)을 개발하여 제공함으로서 우리나라에서도 GNSS 측위 기술을 이용하여 높이측량을 적용하기 위한 기반이 마련되었다. 본 연구에서는 GNSS 정지측량 및 KNGeoid13을 이용하여 지역적인 수직기준과 부합하는 GNSS 기반 표고를 결정하기 위해 기지점의 타원체고 성과를 직접수준측량 성과와 모델 지오이드고를 더하여 계산된 보정타원체고로 사용하는 방법을 적용하고, 그 영향을 분석하였다. 보정타원체고를 이용하지 않은 경우에는 약 3cm 수준의 편의가 나타나는 반면 보정타원체고를 이용하면, 오차의 평균이 0.5cm 이하로 지역적인 편의가 제거되었다. GNSS 기반 표고의 정밀도를 관측시간에 따라 분석한 결과, 1일 4시간씩 2일간 관측할 경우에는 전체 데이터의 95%가 4cm 미만의 오차를 가진 것으로 나타났으며, 1일 4시간 및 2시간 관측을 수행하는 경우에는 5cm 이하의 오차를 보였다. 30분 관측하여 모호수가 고정될 경우, 전체 데이터의 95%가 10cm 이하의 정확도를 갖는 표고를 결정할 수 있는 것으로 나타났다. 본 연구에서 도출된 결과는 향후 공공측량에 GNSS 높이측량 도입을 위한 기반 자료로 활용될 수 있을 것으로 사료된다.

• 한국지리정보학회지
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• 제24권2호
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• pp.78-90
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• 2021

정밀지오이드를 구축하기 위하여 육상, 해상, 항공, 위성 중력측정 방법으로 다양화되고 측정 기술이 발전되어 고해상도 고정밀도의 중력자료 확보가 가능해졌다. 정밀지오이드의 구축은 별도의 수준측량 없이 GNSS 측량을 통해 표고를 빠르고 편리하게 결정할 수 있으며 우리나라는 2014년부터 국토지리정보원에서 GNSS를 기반으로 한 높이측량 정확도를 향상시키기 위해 합성지오이드 모델을 개발하고 있다. 본 연구에서는 공공측량의 GNSS높이측량을 검증하기 위하여 기존의 고시된 공공기준점을 선점하여 GNSS높이측량 결과와 비교 분석하였다. 실험은 연구보고서 등에서 정밀도가 낮은 지역으로 제시되거나 정밀도가 낮을 것으로 예상되는 연안, 접경, 산악지형의 공공기준점에 대하여 GNSS높이측량을 수행하고 정밀도를 분석하였다. GNSS높이측량 검증을 위해 공공기준점 GNSS높이측량 기지점으로 사용될 주변 통합기준점의 GNSS 타원체고를 점검하였다. 점검된 통합기준점을 기준으로 공공기준점의 GNSS 타원체고를 산출하고 KNGeoid18 모델을 이용하여 표고를 계산하여 직접수준측량 표고결과와 비교하였다. 분석 결과 연안, 접경, 산악 지역 공공기준점의 GNSS 높이측량 결과가 3·4급 공공수준측량 정확도에 만족하는 것으로 나타났다. 이를 통하여 사용자가 요구하는 높이 정확도에 따라 기존의 직접수준측량보다 GNSS 높이측량이 효율적으로 이용될 수 있으며, KNGeoid18도 자율주행자동차, 무인항공기 등 다양한 분야에서 활용될 수 있을 것으로 판단된다.

• 한국측량학회지
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• 제36권5호
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• pp.403-412
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• 2018

Recently, GNSS (Global Navigation Satellite System)-derived orthometric height determination has been studied to improve the time and cost-effectiveness of traditional leveling surveying. However, the accuracy of this new survey method was evaluated when unknown points are located lower than control points. In this study, the accuracy of GNSS-derived orthometric height was examined using TPs (Triangulation Points) to verify the stability of surveying in mountainous areas. The GNSS survey data were obtained from Mungyeong, Unbong/Hadong, Uljin, and Jangseong. Three unknown points were surrounded by more than three UCPs (Unified Control Points) or BMs (Benchmarks) following the guideline for applying GNSS-derived orthometric height determination. A newly developed national geoid model, KNGeoid17 (Korean National Geoid 2017), has been applied for determining the orthometric height. In comparison with the official orthometric heights of the TPs, the heights of the unknown points in Mungyeong and Unbong/Hadong differ by more than 20 cm. On the other hand, TPs in Uljin and Jangseong show 15-16 cm of local bias with respect to the official products. Since the precision of official orthometric heights of TPs is known to be about 10 cm, these errors exceed the limit of the precision. Therefore, the official products should be checked to offer more reliable results to surveyors. As an alternative method of verifying accuracy, three different GNSS post-processing software were applied, and the results from each software were compared. The results showed that the differences in the whole test areas did not exceed 5 cm. Therefore, it was concluded that the precision of the GNSS-derived orthometric height was less than 5 cm, even though the unknown points were higher than the control points.

• 한국측량학회지
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• 제36권1호
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• pp.9-15
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• 2018

Precise regional geoid heights on and around Mount Jiri were calculated and were compared to the KNGeoid14 (Korean National Geoid 2014) model. In this study, gravimetric geoid heights were calculated by using RCR (Remove-Compute-Restore) technique and then hybrid geoid heights were calculated by using the LSC (Least Square Collocation) method in the same area. In addition, gravity observation and GNSS(Global Navigation Satellite System) surveying performed in this study were utilized to determine gravimetric geoid heights and to compute hybrid geoid heights, respectively. The results of the study show that the post-fit error (mean and standard deviation) of hybrid geoid heights was evaluated as $0.057{\pm}0.020m$, while the mean and standard deviation of the differences were -0.078 and 0.085 m, respectively for KNGeoid14. Therefore, hybrid geoid heights in this study show more considerable progress than KNGeoid14.

• Structural Monitoring and Maintenance
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• 제8권4호
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• pp.309-328
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• 2021

The objective of this work was to develop a methodology for geodetic monitoring on onshore wind towers, to ascertain the existence of displacements from object points located in the tower and at the foundation's base. The geodesic auscultation was carried out in the Gravatá 01 and 02 wind towers of the Eólica Gravatá wind farm, located in the Brazilian municipality of Gravatá-PE, using a stable Measurement Reference System. To verify the existence of displacements, pins were implanted, with semi-spherical surfaces, at the bases of the towers being monitored, measured by means of high-precision geometric leveling and around the Gravatá 02 tower, concrete landmarks, iron rods and reflective sheets were implanted, observed using geodetic/topographic methods: GNSS survey, transverse with forced centering, three-dimensional irradiation, edge measurement method and trigonometric leveling of unilateral views. It was found that in the Gravatá 02 tower the average rays of the circular sections of the transverse welds (ST) were 1.8431 m ± 0.0005 m (ST01) and 1.6994 m ± 0.0268 m of ST22, where, 01 and 22 represent the serial number of the transverse welds along the tower. The average calculation of the deflection between the coordinates of the center of the circular section of the ST22 and the vertical reference alignment of the ST1 was 0°2'39.22" ± 2.83" in the Northwest direction and an average linear difference of 0.0878 m ± 0.0078 m. The top deflection angle was 0°8'44.88" and a linear difference of ± 0.2590 m, defined from a non-linear function adjusted by Least Squares Method (LSM).

• 한국측량학회지
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• 제36권4호
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• pp.245-254
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• 2018

본 논문에서는 GPS 높이측량의 정확도 제고 측면에서 대류권오차 보정방법이 기선해석을 통한 타원체고 추정 정확도와 정밀도에 미치는 영향을 실험적 방법에 의해 연구하였다. 이를 위해 국내 상시관측소 88점을 이용해 기선장과 표고차에 따라 247개 기선을 구성하고, GNSS 통합 데이터센터로부터 7일 분량의 관측 데이터를 취득한 후 2가지 기선해석 소프트웨어에 의해 Hopfield, 수정 Hopfield 그리고 Saastamoinen와 같은 경험식과 이중차분 및 정밀절대측위 대류권 오차 추정기법을 적용해 총 8,645개 실험기선을 처리하였다. 산정한 각 관측점 타원체고의 정확도와 정밀도를 오차 보정기법 따라 계산하고 기선장과 표고차와 같은 기선 구성 조건에 대해 분석하였다. 이를 통해 대류권오차 보정방식의 특징을 정확도와 정밀도 측면에서 고찰하고 GPS 높이측량의 기선해석에서 기선장과 표고차에 대해 적합한 대류권오차 모형화 기법선정을 위한 기초자료를 제공하고자 하였다.