• 대한원격탐사학회지
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• 제38권1호
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• pp.103-110
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• 2022

Since satellite images generally include clouds in the atmosphere, it is essential to detect or mask clouds before satellite image processing. Clouds were detected using physical characteristics of clouds in previous research. Cloud detection methods using deep learning techniques such as CNN or the modified U-Net in image segmentation field have been studied recently. Since image segmentation is the process of assigning a label to every pixel in an image, precise pixel-based dataset is required for cloud detection. Obtaining accurate training datasets is more important than a network configuration in image segmentation for cloud detection. Existing deep learning techniques used different training datasets. And test datasets were extracted from intra-dataset which were acquired by same sensor and procedure as training dataset. Different datasets make it difficult to determine which network shows a better overall performance. To verify the effectiveness of the cloud detection network such as Cloud-Net, two types of networks were trained using the cloud dataset from KOMPSAT-3 images provided by the AIHUB site and the L8-Cloud dataset from Landsat8 images which was publicly opened by a Cloud-Net author. Test data from intra-dataset of KOMPSAT-3 cloud dataset were used for validating the network. The simulation results show that the network trained with KOMPSAT-3 cloud dataset shows good performance on the network trained with L8-Cloud dataset. Because Landsat8 and KOMPSAT-3 satellite images have different GSDs, making it difficult to achieve good results from cross-sensor validation. The network could be superior for intra-dataset, but it could be inferior for cross-sensor data. It is necessary to study techniques that show good results in cross-senor validation dataset in the future.

• 대한원격탐사학회:학술대회논문집
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• 대한원격탐사학회 2005년도 Proceedings of ISRS 2005
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• pp.357-360
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• 2005

Soil loss is widely recognized as a threat to farm livelihoods and ecosystem integrity worldwide. Soil loss prediction models can help address long-range land management planning under natural and agricultural conditions. Even though it is hard to find a model that considers all forms of erosion, some models were developed specifically to aid conservation planners in identifying areas where introducing soil conservation measures will have the most impact on reducing soil loss. Revised Universal Soil Loss Equation (RUSLE) computes the average annual erosion expected on hillslopes by multiplying several factors together: rainfall erosivity (R), soil erodibility (K), slope length and steepness (LS), cover management (C), and support practice (P). The value of these factors is determined from field and laboratory experiments. This study calculated soil erosion using GIS-based RUSLE model in Imha basin and examined soil erosion source area using SPOT 5 high-resolution satellite image and land cover map. As a result of analysis, dry field showed high-density soil erosion area and we could easily investigate source area using satellite image. Also we could examine the suitability of soil erosion area applying field survey method in common areas (dry field & orchard area) that are difficult to confirm soil erosion source area using satellite image.

• 대한원격탐사학회:학술대회논문집
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• 대한원격탐사학회 2006년도 Proceedings of ISRS 2006 PORSEC Volume II
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• pp.684-687
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• 2006

Airborne imagery must be precisely orthorectified to be used as geographical information data. GPS/INS (Global Positioning System/Inertial Navigation System) and LIDAR (LIght Detection And Ranging) data were employed to automatically orthorectify airborne images. In this study, 154 frame airborne images and LIDAR vector data were acquired. LIDAR vector data were converted to raster image for employing as reference data. To derive images with constant brightness, flat field correction was applied to the whole images. The airborne images were geometrically corrected by calculating internal orientation and external orientation using GPS/INS data and then orthorectified using LIDAR digital elevation model image. The precision of orthorectified images was validated using 50 ground control points collected in arbitrary selected five images and LIDAR intensity image. In validation results, RMSE (Root Mean Square Error) was 0.365 smaller then two times of pixel spatial resolution at the surface. It is possible that the derived mosaicked airborne image by this automatic orthorectification method is employed as geographical information data.

• 대한공간정보학회지
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• 제7권2호
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• pp.101-110
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• 1999

강과 호수와 같은 넓은 지역을 대상으로 수질조사를 실시할 경우, 주기적이고 동시적인 관찰과 분석이 요구되고 있으며 인공위성 영상을 이용한 원격탐사 기법은 이러한 측면에서 매우 유용한 것으로 평가되고 있다. 그러나 인공위성 영상으로부터 수질인자를 추출하고자 할 때, 대기 산란의 영향이 포함된 위성영상의 화소 값은 분석의 정확도를 감소시키는 주된 원인이 된다. 본 연구에서는 원격탐사 기법을 이용하여 수질 인자를 분석하고자 할 때, 대기의 산란에 의한 영향을 제거하기 위한 대기 보정방법을 선택하고자 하였다. 또한 대기 보정방법 중 클로로필-a 부유물질, 투명도에 대한 상관성이 가장 높은 밴드의 조합을 선정하였다. 이러한 대기 보정방법과 밴드 조합을 사용하여 1984년, 1989년, 1993년, 1995년에 각각 관측된 인공위성 영상으로부터 수질 인자간의 시계열 변화를 분석하고자 하였다.

• 한국측량학회지
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• 제22권4호
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• pp.359-365
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• 2004

많은 응용분야에서 단일 자료가 가진 한계를 극복하기 위해 다중 자료를 이용하여 통합 활용하는 기법이 요구되고 있다. 특히, 서로 다른 공간해상도와 분광해상도를 가진 영상들을 이용하여 영상의 공간해상도를 향상시키는 영상융합과 두 자료간의 상호 관계를 설정하는 영상등록에 대한 많은 연구가 진행되고 있다. 본 연구에서는 IKONOS 전정색 영상과 다중분광 위성영상에 대해 Brovey, IHS, PCA, HPF, CN, MWD 융합기법을 적용하여 원 영상의 분광정보를 가장 적게 왜곡하는 융합기법 에 대해 고찰하였다. 또한, SPOT-5 위성영상과 RADARSAT SAR 위성영상 간에 패치를 이용한 영상정합 기법을 적용하여 해석하였다. 본 연구를 통해 영상 융합에서 시각적 분석 및 통계적 분석 결과 HPF, MWD 융합기법이 가장 좋은 성과를 나타냈었으며, SPOT-5 위성영상과 RADARSAT SAR 위성영상으로부터 지형정보를 세밀하게 표현할 수 있는 패치를 추출함으로써 효과적인 영상등록이 가능하였다.

• 대한공간정보학회지
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• 제16권3호
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• pp.15-20
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• 2008

IKONOS-2, QuickBird, KOMPSAT-2와 같은 고해상도 위성영상은 높은 공간해상도의 흑백영상과 멀티스펙트럴 영상을 동시에 제공하고 있다. 영상융합은 서로 다른 공간, 분광해상도를 가지는 영상을 이용하여 두 개의 장점을 모두 가지는 영상으로 재구성하는 것을 의미하며 위성영상을 영상의 시각화, 개체 추출 등에 더욱 효과적으로 사용할 수 있도록 한다는 점에서 중요한 연구분야이다. 이를 위해 많은 영상융합 알고리즘이 제안되었지만, 대부분 의 알고리즘들은 융합 후에 원 멀티스펙트럴 영상의 분광정보를 효과적으로 보존하지 못하는 문제점을 가지고 있다. 이러한 문제점을 해결하기 위하여 본 논문에서는 수정된 영상 유도 기법을 통하여 융합영상의 분광왜곡량을 줄이는 알고리즘을 제안하였다. 원 멀티스펙트럴 영상과 해상도를 낮춘 융합영상과의 비교 분석을 통하여 융합영상의 분광 정보 왜곡량을 보정하도록 유도기법을 조정하였다. QuickBird 영상에 적용한 결과, 다양한 융합영상들이 본 알고리즘을 적용할 경우에 분광왜곡량이 줄어드는 것을 확인할 수 있었다.

• 대한원격탐사학회:학술대회논문집
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• 대한원격탐사학회 2007년도 Proceedings of ISRS 2007
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• pp.620-624
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• 2007

Recently, Gonzalez-Audicana et al. proposed the substitute wavelet intensity (SWI) method which provided a solution based on the intensity-hue-saturation (IHS) method for the fusing of panchromatic (PAN) and multispectral (MS) images. Although the spectral quality of the fused MS images is enhanced, this method is not efficient enough to quickly merge massive volumes of data from satellite. To overcome this problem, we introduce a new SWI method based on a fast IHS transform to implement efficiently as an alternative procedure. In addition, we show that the method is well applicable for fusing IKONOS PAN with MS images.

• 대한원격탐사학회:학술대회논문집
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• 대한원격탐사학회 1999년도 Proceedings of International Symposium on Remote Sensing
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• pp.375-380
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• 1999

Ocean Scanning Multispectral Imager (OSMI) is a payload on the KOMPSAT satellite to perform worldwide ocean color monitoring for the study of biological oceanography. The instrument images the ocean surface using a wisk-broom motion with a swath width of 800 km and a ground sample distance (GSD) of<1km over the entire field of view (FOV). The instrument is designed to have an on-orbit operation duty cycle of 20% over the mission lifetime of 3 years with the functions of programmable gain/offset and on-board image data compression/storage. The instrument also performs sun and dark calibration for on-board instrument calibration. The OSMI instrument is a multi-spectral imager covering the spectral range from 400nm to 900nm using CCD Focal Plane Array (FPA). The ocean colors are monitored using 6 spectral channels that can be selected via ground commands. KOMPSAT satellite with OSMI was integrated and the satellite level environment tests and instrument aliveness/functional test as well, such as launch environment, on-orbit environment (Thermal/vacuum) and EMl/EMC test were performed at KARI. Test results met the requirements and the OSMI data were collected and analyzed during each test phase. The instrument is launched on the KOMPSAT satellite in the late 1999 and the image is scheduled to start collecting ocean color data in the early 2000 upon completion of on-orbit instrument checkout.

• 한국측량학회:학술대회논문집
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• 한국측량학회 2003년도 추계학술발표회 논문집
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• pp.397-402
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• 2003

This study is aimed to improve the quality of image fusion results through shadow effects correction. For this, shadow effects correction algorithm is proposed and visual comparisons have been made to estimate the quality of image fusion results. The following four steps have been performed to improve the image fusion qualify First, the shadow regions of satellite image are precisely located. Subsequently, segmentation of context regions is manually implemented for accurate correction. Next step, to calculate correction factor we compared the context region with the same non-shadow context region. Finally, image fusion is implemented using collected images. The result presented here helps to accurately extract and interpret geo-spatial information from satellite imagery.

• 대한원격탐사학회:학술대회논문집
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• 대한원격탐사학회 2008년도 International Symposium on Remote Sensing
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• pp.240-242
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• 2008

In the present article, we analyze airborne Pi-SAR (Polarimetric-Interferometric SAR) X-band images of ocean waves around the Miyake Island at approximately 180 km south from Tokyo, Japan. Two images of a same scene were produced at approximately 40 min. interval from two directions at right angles. One image shows dominant range travelling waves, but the other image shows a different wave pattern. This difference can be caused by the different image modulations of RCS and velocity bunching. We have estimated the dominant wavelength from the image of range waves, and from the wave phase velocity computed from the dispersion relation (though no wave height data were available), the image intensity is computed by using the velocity bunching model. The comparison of the result with the second image at right angle strongly suggests the evidence of velocity bunching.