• 한국멀티미디어학회논문지
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• 제6권1호
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• pp.28-39
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• 2003

본 논문은 고해상도에 대한 멀티 스펙트럴 영상들에 대한 압축기술에 대한 연구입니다. 원래는 원격센싱 컨텍스트에 대한 개발로 이를 식품과 의료영상에 적용하였습니다마는 이러한 가능성을 여러 컨텍스트에서 처리하는 것을 목표로 두었으며 즉, 원격센싱, 식품모니터링 그리고 의료영상의 새로운 분야로 탐구 및 적용하였다. 압축은 한 화소와 관계한 이웃 간의 화소들 간의 간단한 추정에 기반하여 나타날 수 있도록 하였다. 멀티 스펙트럴 영상들은 화소들이 같은 밴드 안에서 가까이 이웃하여 있는 어떤 상접한 정도의 관계를 해석하였으며 하나의 발견된 상관관계는 어떠한 한 밴드 내에서의 계수에 기반 한다. 그 계수와의 관계는 다른 밴드에서 계산되어진 것과 유사하다. 두 번째의 관찰에서는 개발되어진 알고리즘이 화소당 비트수를 멀티 스펙트럴 위성원격영상에서 16비트에서 4비트로 감소할 수 있었다. 따라서 다른 방법론들과 속도 및 압축률에 대해서 비교 분석하였다. 보통 그래픽 포맷인 GIF, JPEG 그리고 PCX를 사용하였으며 참조와 같이 LZW Huffman과 RLE의 알고리즘을 행하였다. 소개되어진 방법들은 압축을 줄이는 것이 선상, 프로그램 안에서 혹은 관례적인 압축 알고리즘에서 속도와 압축률에서 유사한 결과를 가져왔다.

• 대한원격탐사학회:학술대회논문집
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• 대한원격탐사학회 2003년도 Proceedings of ACRS 2003 ISRS
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• pp.825-827
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• 2003

Multi-Spectral Camera(MSC) is a payload on the KOMPSAT-2 satellite to perform the earth remote sensing. The instrument images the earth using a push-broom motion with a swath width of 15 km and a ground sample distance (GSD) of 1 m over the entire field of view (FOV) at altitude 685 Km. 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 MSC instrument has one(1) channel for panchromatic imaging and four(4) channel for multi-spectral imaging covering the spectral range from 450nm to 900nm using TDI CCD Focal Plane Array (FPA). In this paper, the architecture and function of MSC hardware including electrical interface and the operation concept which have been established based on the mission requirements are described. And the design and the preparation of MSC system operation are analyzed and discussed.

• 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.

• 대한원격탐사학회지
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• 제15권4호
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• pp.297-305
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• 1999

Ocean Scanning Multispectral Imager (OSMI) is a payload on the KOMPSAT satellite to perform global 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 800km 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 including instrument aliveness/functional test, such as launch environment, on-orbit environment (Thermal/Vacuum) and EMI/EMC test were performed at KARl. 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 on December 21,1999 and is scheduled to start collecting ocean color data in the early 2000 upon completion of on-orbit instrument checkout.

• 대한원격탐사학회:학술대회논문집
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• 대한원격탐사학회 2005년도 Proceedings of ISRS 2005
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• pp.509-511
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• 2005

KOMPSAT -2 equipped with an optical telescope(MSC) will be launched in this year. It can take images of the earth with push-broom scanning at altitude 685Km. Its resolution is 1m in panchromatic channel with a swath width of 15 km After the MSC is tested and the performance is measured at instrument level, it is installed on satellite. The image passes through the electro-optical system, compression and storage unit and fmally downlink sub-systems. This integration procedure necessitates the functional test of all subsystems participating in the image chain. The objective of functional test at satellite level(Quick Look test) is to check the functionality of image chain by real target image. Collimated moving image is input to the EOS in order to simulate the operational environments as if KOMPSAT -2 is being operated in orbit. The image chain from EOS to data downlink subsystem will be verified through Quick Look test. This paper explains the Quick Look test of KOMPSAT -2 and compares the taken images with collimated input ones.

• 대한원격탐사학회:학술대회논문집
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• 대한원격탐사학회 2003년도 Proceedings of ACRS 2003 ISRS
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• pp.1200-1202
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• 2003

Satellite and aerial images are very useful means to monitor ecological and environmental situation. Nowadays more and more officials at Ministry of Environment in Korea need to access and use these image data through networks like internet or intranet. However it is very hard to manage and service these image data through internet or intranet, because of its size problem. In this paper very large image data service system for Ministry of Environment is constructed on web environment using image compression and web based image processing technology. Through this system, not only can officials in Ministry of Environment access and use all the image data but also can achieve several image processing effects on web environment. Moreover officials can retrieve attribute information from vector GIS data that are also integrated with the system.

• 대한원격탐사학회지
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• 제18권1호
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• pp.53-59
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• 2002

The MSC is a payload on the KOMPSAT-2 satellite to perform the earth remote sensing. The instrument images the earth using a push-broom motion with a swath width of 15 km and a GSD(Ground Sample Distance) of 1 m over the entire FOV(Field Of View) at altitude 685 km. The instrument is designed to haute 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 MSC instrument has one channel for panchromatic imaging and four channel for multi-spectral imaging covering the spectral range from 450nm to 900nm using TDI(Time Belayed Integration) CCD(Charge Coupled Device) FPA(Focal Plane Assembly). The MSC hardware consists of three subsystem, EOS(Electro Optic camera Subsystem), PMU(Payload Management Unit) and PDTS(Payload Data Transmission Subsystem) and each subsystems are currently under development and will be integrated and verified through functional and space environment tests. Final verified MSC will be delivered to spacecraft bus for AIT(Assembly, Integration and Test) and then COMSAT-2 satellite will be launched after verification process through IST(Integrated Satellite Test). In this paper, the introduction of MSC, the configuration of MSC electronics including electrical interlace and design of CEU(Camera Electronic Unit) in EOS are described. MSC Operation parameters induced from the operation concept are discussed and analyzed to find the influence of system for on-orbit operation in future.

• 대한원격탐사학회지
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• 제18권6호
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• pp.359-367
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• 2002

본 논문에서는 효율적인 영상 부호화를 위해 분할계수의 상관관계를 이용한 새로운 웨이블릿 패킷 영상 부호화기 알고리즘을 제안한다. 제안된 웨이블릿 패킷 영상 부호화기 알고리즘은 주파수 부대역간의 상관관계를 이용하여 계수분할 순서(CPSO, Coefficient Partitioning Scanning Order)를 정의한 후, 이를 이용하여 새로운 부모-자식 노드 관계를 도출하고, 도출된 부모-자식 노드 관계를 이용하여 계수들을 제로트리 방식으로 부호화함으로써 영상 복원시 오차를 감소시켰다. 그 결과 기존의 알고리즘들과 비교하여 비트율과 제곱 오차에 대해서 성능개선이 이루어 졌고, 응용분야에 따라 비트율 조정을 쉽게 제어할 수 있는 능력을 입증하였다. 특히 항공사진이나 위성사진 중 도시 중심부나 농경지 등과 같이 중고주파 대역성분이 많이 포함된 영상의 경우, 기존 알고리즘에 비해 처리 방법이 간단하면서도 정확한 결과를 보여준다. 또한 자료 영상들에 대한 실험 결과를 통해서, 제안한 알고리즘이 작은 파일크기에서도 고해상도를 요구하는 실시간 시스템이나 온라인 영상처리, 영상합성 분야에 적용될 수 있는 가능성이 있음을 증명하고자 하였다.

• 한국위성정보통신학회논문지
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• 제10권1호
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• pp.1-5
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• 2015

멀티미디어 기술의 급속한 발전과 사용자의 대형 화면에 대한 선호도가 높아지는 가운데 새로운 영상 압축 기술인 HEVC(High Efficiency Video Coding) 고화질 영상 압축 표준을 탄생시켰으며, 그 결과 기존의 HD급 영상보다 4배 이상, 16배까지 선명한 초고화질 UHD(Ultra High Definition) 영상 서비스가 새롭게 주목받고 있다. 또한 JPEG 2000 압축도 기존 처리되던 픽셀 이미지를 넘어 초고화질 해상도 이미지(4K : $3,840{\times}2,160$ 또는 8K : $7680{\times}4320$)를 처리 지원을 하고 있다. 따라서 초고화질 이미지의 획득 및 저장을 위해서는 고속의 처리 기술이 필요하다. 이에 본 논문은 초고화질 해상도 이미지의 고속 처리를 위한 병렬처리 기술에 대한 연구를 위하여, JPEG 2000의 처리 과정을 살펴보고 전처리 단계인 색공간 변환 알고리즘 적용을 위하여 GPU환경에서 병렬 컴퓨팅을 통해 처리속도를 향상시키는 방법을 제안한다. 병렬화한 알고리즘의 구현은 OpenCL(Open Computing Language)을 이용하였다. 실험 결과 사용자 정의 쓰레드 기반 고속 처리와 비교하여 초고화질 해상도 이미지(UHD 4K : $3,840{\times}2,160$)를 기준으로 최대 5배의 성능 향상의 결과를 보여주었다.

• 한국측량학회:학술대회논문집
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• 한국측량학회 2004년도 춘계학술발표회논문집
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• pp.215-220
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• 2004

Satellite and aerial images are very useful means to monitor ecological and environmental situation. Nowadays more and more officials at Ministry of Environment in Korea need to access and use these image data through networks like internet or intranet. However it is very hard to manage and service these image data through internet or intranet, because of its size problem. In this paper very large image data service system for Ministry of Environment is constructed on web environment using image compression and web based image processing technology. Through this system, not only can officials in Ministry of Environment access and use all the image data but also can achieve several image processing effects on web environment. Moreover officials can retrieve attribute information from vector GIS data that are also integrated with the system.