• 한국측량학회:학술대회논문집
• /
• 한국측량학회 2010년 춘계학술발표회 논문집
• /
• pp.165-168
• /
• 2010

This paper describes the results of complete Bouguer anomalies computed from the Free-air anomalies that derived from Sandwell and DNSC08 mairne gravity models. Complete bouguer corrections consist of three parts: the bouguer correction (Bullard A), the curvature correction (Bullard B) and the terrain correction (Bullard C). These all corrections have been computed over the East Sea on a $1'{\times}1'$ elevation data (topography and bathymetry) derived from ETOPO1 global relief model. In addition, a constant topographic (sea-water) density of $2,670kg/m^3$ ($1,030kg/m^3$) has been used for all correction terms. The distribution of complete bouguer anomalies computed from DNSC08 are -34.390 ~ 267.925 mGal, and those from Sandwell are -32.446 ~ 266.967 mGal in East Sea. The mean and RMSE value of the difference between DNSC08 and Sandwell is $0.036{\pm}2.373$ mGal. The highest value of complete bouguer anomaly are found around the region of $42{\sim}43^{\circ}N$ and $137{\sim}139^{\circ}E$ (has the lowest bathymetry) in both models. Theses values show that the gravity distribution of both models, DNSC08 and Sandwell, are very similar. They indicate that satellite-based marine gravity model can be effectively used to analyze the geophysical, geological and geodetic characteristics in East Sea.

• 한국지구과학회지
• /
• 제32권1호
• /
• pp.12-20
• /
• 2011

변성암복합체, 옥천층군, 조선누층군 및 화성암류에서 지하 지질분포 및 밀도 불연속면을 파악하기 위해 충주호 주변에 있는 256개 지점에서 중력측정을 실시하였다. 부게 중력이상은 옥천층군에서 높은 값을 가지며 조선누층군으로 갈수록 상대적으로 낮은 값의 분포를 보였다. 지하 밀도 불연속면의 평균심도는 약 2.0 km이며, 전반적으로 문주리층과 황강리층이 서창리층보다 중력기반 심도가 상대적으로 얇으며, 옥천계 동측에 위치한 조선누층군이 옥천층군보다 비교적 두꺼운 기반 심도로 분포된 것으로 파악되었다.

• 자원환경지질
• /
• 제28권1호
• /
• pp.79-88
• /
• 1995

The gravity measurment has been carried out at 48 gravity stations with intervals of 1.0~1.5 km along the survey line between Samcheog, Gosari and Taebaek to study subsurface geology and geologic structure in the northeastern part of the Ockchon zone. The Bouguer gravity anomaly values were obtained from the measured gravity values through the gravity corrections. The subsurface geology and geologic structure were interpreted quantitatively by means of the Fourier series method and Talwani method for 2.5 dimensional body. In the study area, the depth of Conrad discontinuity is about 10 km at Samcheog, northeastern end of the survey line, and it is increased rapidly to about 12.5 km at Miro, 15 km at Gosari and 15.5 km at Dongjeom, southwestern end of the survey line, respectively. The depth of the basement of the Ockchon zone exposed at Samcheog is increased smoothly to about 2 km at 5 km from Samcheog along the survey line, and is exposed again in the area between Singiry and Gosari. Beyond Gosari its depth is increased to about 1.7 km, and displaced 2.3 km downward by Osipcheon fault near Dogyeri and 0.5 km by Baeksan thrust near Cheolam, respectively. Many V-shaped low Bouguer gravity anomalies resulted from the fracture zone associated with faults imply the existence of Osipcheon fault and several inferred faults. The low Bouguer gravity anomaly zone between Tongdong and Dongjeom is caused by Jurassic gneissose granite. A local high Bouguer gravity anomaly at 35 km along the survey line from Samcheog is interpreted by the effect of iron deposit of high density existed at subsurface. The thickness of Great Limestone Group varies from 0.5 km to 1.4 km, that of Pyeongan Supergroup from 0.4 km to 0.9 km, and that of Yangdeog Group is about 0.3 km. The thickness of Jurassic gneissose granite varies from 1.5 to 3.0 km.

• 한국지구물리탐사학회:학술대회논문집
• /
• 한국지구물리탐사학회 2003년도 Proceedings of the international symposium on the fusion technology
• /
• pp.379-382
• /
• 2003

In gravity data correction process, mass effect of the upper part of base level is removed with Bouguer density. Usually, Bouguer density is estimated as a mean density in the field area. But, this may causes a serious problem when ore body is in the area. To overcome this problem, we tried to apply a new method mixing up mass corrections and inversion (3DGTI). 3-D Gravity Terrain Inversion (3DGTI) includes information of topography and distribution of Bouguer density. For this method does not remove the mass effect above base level, it is no longer useless to use Bouguer density. Numerical model tests have shown that the 3DGIT successfully retrieves the anomalous subsurface density distribution of both surface and deeper layers. Model tests shows that this method shows better results than those of conventional one, especially when main target is ore body. The inversion result well delineates the three-dimensional shape of the intruded granite body and basement.

• 대한원격탐사학회:학술대회논문집
• /
• 대한원격탐사학회 2005년도 Proceedings of ISRS 2005
• /
• pp.589-592
• /
• 2005

Gravity characteristics and Moho undulations are investigated in the Korean peninsula by using satellite gravity data. According to the development of satellite geodesy, gravity potential models which have high accuracy and resolution were released. Using the EIGEN-CGOIC model based on low orbit satellite data such as CHAMP and GRACE, geoid and gravity anomaly were calculated by spherical harmonic analysis. The study area is located at $123^{\circ}\sim132^{\circ}E, 33^{\circ}\sim43^{\circ}$N including Korea. Free-air anomalies, which show the effect of terrain, have the values between $-37\sim724 mgal. After Bouguer correction, the range of simple Bouguer anomalies is $-221\sim246$ mgal. Complete Bouguer anomalies after terrain correction increase from continent to marine. This phenomenon is related rise of Moho discontinuity. The cut-frequency for extraction of Moho undulation was determined by power spectrum analysis, and then 3D inversion modeling was implemented. The mean, maximum, minimum, and standard deviation of Moho depth undulation are -26, -36, -8, and 4.9 krn, respectively.

• 자원환경지질
• /
• 제32권6호
• /
• pp.645-651
• /
• 1999

The gravity and magnetic measurements have been obtained from 34 stations with 50m intervals along the survey line positioned between Jangtanri and sindapri for studying subsurface geology and structures of the volcanic rocks in Yeoncheon area. The Bouguer gravity and magnetic anomaly values were evaluated from the reduction of the field observation, and then interpreted by Nettleton's method and maximum-pepth rules, are approximately 160m based on magnetic data and 135m based on gravity data. High Bouguer gravity anomaly zone between 0m in Jangtanri and 900m along the survery line, is caused by thick and high density, older dasalt which is positioned beneath jijangbong tuff breccia, and this result corresponds to the interpretation result based on magnetic anomly. Lower gravity and magnetic anomaly zones ariund 900m are caused by between 1300m and 1550m are caused by high density of Quarternary basalt exposed in the surface, and lower gravity and magnetic anomalies at 200m and 1250m are caused by faults.

• 지구물리와물리탐사
• /
• 제9권2호
• /
• pp.171-175
• /
• 2006

중력 보정은 관측 중력을 어떤 기준면에서의 값으로 환산해 주는 것이며, 부게 이상은 기준면에 위치한다고 많은 문헌에 소개되어 있다. 물리탐사에서 부게 이상은 측점에서의 측정 중력과 측점에서의 표준 중력의 차이로 정의되며, 중력 보정은 타원체상에서 정의된 표준 중력을 측점에서의 표준 중력으로 바꾸는 일련의 과정이다. 따라서 보정을 거친 부게 이상은 기준면에 위치하는 것이 아니고 여전히 측점에 위치한다. 일반적으로 쓰이고 있는 중력 보정식들은 과거 계산의 간편함을 위한 근사식들인데, 이들의 완전한 식을 소개하여 보다 정밀한 보정을 위하여 완전한 식을 사용하는 것이 바람직할 것이다. 또한, 중력 보정의 원래의 의미대로 지오이드가 아닌 지구 타원체를 기준면으로 할 것을 제안하며, 이들이 표준 중력 보정 과정으로 확립되기를 기대한다.

• 자원환경지질
• /
• 제32권3호
• /
• pp.281-291
• /
• 1999

This study presents the gravity data with GPS survrying and the geophysical profiles at the Choogaryeong Rift Valley. And in determing geoid by GPS measurement, survey control points (SCP) whoch built by the Republic of Korean Army are used. Seventy nine SCP and the two triangulation stations are reviewd by GPS. Digital terain model is under for terrain analysis. The analyses of the gravity surveying with GPS are as follows. The low values of the negative Bouguer anomalies represent the high elevation terrain. The Bouguer anomalies show the decrrasing trend toward the eastern part of the study area. Characteristics of free-air anomalies are related with terrain elevation. The regional gravity anomalies decreas toward the eastern part of the study area. The trends of variations are associated with the thermotectonic and geologic structure beneath the Choogaryeong Rift Valley. The most parts of the study area represent negative residual gravity anomalies due to the low dencity of sedimentary cover in the Rift Valley. There are three valleys and four mountains in the direction of NE-SW or NNE-SSW which are structured by the geological features.

• 한국측량학회지
• /
• 제28권3호
• /
• pp.317-328
• /
• 2010

본 연구는 Sandwell 및 DNSC08 해상중력모델로부터 구한 프리에어 이상으로부터 동해 지역의 완전부우게 이상을 구한 결과를 설명한 것이다. 완전부우게 보정은 부우게 보정(Bullard A), 곡률보정(Bullard B)과 지형보정(Bullard C)의 세 부분으로 구성된다. 각 보정량의 계산을 위하여 전지구 기복모델인 ETOPO1을 통해 1분 간격의 표고데이터(지형 및 수심)를 취득하여 이용하였으며, 지형(해수)의 밀도로는 $2,670kg/m^3$($1,030kg/m^3$)의 수치를 일괄적으로 적용하였다. DNSC08 모델을 이용하여 계산된 완전부우게 이상은 동해 지역에 대하여 약 -34.390~267.925mGal의 분포를 나타내었으며, Sandwell 모델의 경우 -32.446~266.967mGal의 분포를 나타내었다. 또한, 두 모델 간 완전부우게 이상의 차이는 평균 $0.036{\pm}2.373mGal$로 계산되었으며, 가장 큰 완전부우게 이상값은 가장 낮은 수심분포를 보이는 위도 $42{\sim}43^{\circ}N$ 및 경도 $137{\sim}139^{\circ}E$ 사이의 지역에서 나타났다. 이러한 수치를 통해 DNSC08과 Sandwell 모델의 중력분포가 동해 지역에 대해 매우 유사한 것을 알 수 있었으며, 위성기반의 해상중력모델이 동해 지역의 지구물리학적, 지질학적, 측지학적 특성의 해석에 효율적으로 이용될 수 있다고 판단되었다.

• 자원환경지질
• /
• 제30권4호
• /
• pp.363-369
• /
• 1997

As a part of the study to know the deep geological structure of the Ogcheon Zone. gravity survey is performed along the survey line of which direction is roughly perpendicular to major faults of the Zone. Recent studies for petrology. geochemistry. and structural geology in south-western Ogcheon Zone are outlined. Raw gravity data are corrected to obtain Bouguer anomalies and the anomalies are interpreted to obtain subsurface structures along the survey line. The subterranean density discontinuities determined from the power spectrum method are appeared at depths of 15.4 km and 2.8 km. It is considered that the depth of 15.4 km indicates the boundary between upper and lower crust. Probably the depth of 2.8 km represents the boundary between upper volcanic formations and granites. Alternatively. the observed Bouguer anomalies are interpreted in terms of lateral density variation model. Finally. the subterranean geological structure to satisfy the Bouguer anomalies is presented through the iterative forward method in which results obtained from surface geological informations and from the inverse method are adopted as an initial model.