Abstract:
본 발명은 대용량 공간영상 고속처리 시스템 및 그 방법에 관한 것으로서, 가상 파이프라인을 이용하여 다양한 프로세서를 결합하여 구동하고, 그 프로세서의 결과를 상기 파이프라인을 통하여 고속으로 처리하는 공간영상 프로세스 서버와; 대용량의 다양한 공간영상의 데이터를 포맷 및 구성 특징의 변경없이 저장하고, 데이터를 계층적 최적 분할 및 다중 해상도 기법을 이용하여 관리하는 공간영상 데이터 서버와; 사용자의 공간영상 데이터 요구가 입력될 때, 데이터 서버와 프로세서 서버와의 상호동작을 통하여 요구된 데이터의 결과물 및 명령을 교환하여 사용자에게 제시하는 하나 이상의 클라이언트; 및 프로세스 서버 및 데이터 서버와 클라이언트 사이에 연결되어, 데이터를 전송하여 분산 처리하는 네트워크로 구성되며, 이에 따라서, 공간영상 데이터의 접근 독립성을 확보하고, 데이터 접근 효율성을 극대화하고, 네트워크 환경에서 서버와 클라이언트간의 네트워크 효율을 향상시키며, 대용량 공간영상의 고속처리를 수행할 수 있다.
Abstract:
PURPOSE: A non-linear color gamut compression apparatus and a method using multi-convergent points are respectively provided to make a color of an image displayed on a display apparatus equal to an original image by using a non-linear, multi-convergent type. CONSTITUTION: The non-linear color gamut compression apparatus using multi-convergent point includes a color transforming part(210), a color gamut compression part(220), and a color information reverse transforming part(230). The color transforming part(210) transforms red, green and blue input variables into luminance and chrominance variables. The color gamut compression part(220) non-linearly compresses color information inputted from the color transforming part(210) and performs the luminance-chrominance gamut compression based on a multi-convergent point. And, the color information reverse transforming part(230) converts the compressed luminance and chrominance variables by the color gamut compression part(220) into magenta, yellow and black color coordinates.
Abstract:
PURPOSE: A color converting process chip-set for concurring color between computer peripheral devices is provided to obtain a color similar to a real object by adding a color converting chip-set. CONSTITUTION: A data input unit(201) receives R, G, B values, Y, Cb, Cr values, information as to a kind of video input and output device, a manufacturing company, a model name and provides the received R, G, B values, Y, Cb, Cr values, and information to an operating unit(202). A microprocessor(202) obtains the video signal inputted from the data input unit(201) and information to the input and output device, and requests specific information needed to a color conversion of a corresponding video input and output device and pa RAMeters as to a memory unit(203). The memory unit(203) searches pa RAMeter values corresponding to the video input and output device and provides the searched pa RAMeter values to the operating unit(202).
Abstract:
본 발명은 공간컨텐츠 서비스 제공 장치 및 그 방법에 관한 것으로, 기 설정된 필터 설정값에 따라 영상 및 영상의 공간에 대해 필터링하여 영상에 포함된 공간객체(GeoObject)들을 추출하고, 공간객체들의 정보를 영상에 삽입하는 공간컨텐츠 삽입부, 기 등록된 공간컨텐츠 모델을 로드하여 공간컨텐츠 모델의 구조에 대응하는 공간객체들의 정보를 공간컨텐츠 모델에 포함시켜 영상에 대응하는 공간컨텐츠를 생성하는 공간컨텐츠 생성부, 공간컨텐츠의 공간위치정보와 다른 공간컨텐츠들의 공간위치정보를 비교하여, 공간컨텐츠와 다른 공간컨텐츠들 사이의 공간위상관계를 정의하는 위상관계 생성부, 및 공간컨텐츠와 공간위상관계가 있는 다른 공간컨텐츠들을 공간컨텐츠에 결합 또는 링크시키는 공간컨텐츠 합성부를 포함한다.
Abstract:
PURPOSE: A system and a method for visualizing an analysis result of geographic reference data in three-dimension are provided to visualize an analysis result of geographic information reference data through a visualized unit. CONSTITUTION: A three-dimensional spatial information generating unit(210) generates three-dimensional space information through geographic information. A data obtaining unit(220) obtains geographic information reference data including location information. A visualization communicating unit(260) receives an analysis result of the geographic information. A visualization unit(200) visualizes the analysis result.
Abstract:
PURPOSE: Three dimensional space model mapping and visualizing apparatus and method for time-series information are provided to accurately visualizing the time-series information to a 3D target position on a 3D space model. CONSTITUTION: A three dimensional space model mapping and visualizing apparatus comprises the following: a 3D facility model generator(30) for mapping time series information, generating a 3D facility model using a space information providing unit(10); a time series information 3D facility mapping unit(50) mapping the time series information to the 3D facility model based on an inputted expression method; and a time series information 3D facility mapping integrated visualizing unit(60) syntagmatically visualizing the mapping result.
Abstract:
PURPOSE: An augmented reality device and a virtual image mixing method are provided to mix a virtual image with a realistic image captured by a camera on an exact location, thereby providing a more lively and realistic stereoscopic image. CONSTITUTION: An image input module(210) receives a realistic image through a camera(100). A camera sensor module(220) receives location information and initial attitude information of the camera from a camera sensor(110). An image analysis module(230) adds rotation information received from the camera sensor to the initial attitude information, generates current attitude information of the camera, and calculates a mixing location of a virtual image through the location information and the current attitude information. An image mixing module(250) mixes the virtual image with the realistic image based on the mixing location.
Abstract:
A system and a method for processing spatial data streams by using a spatial sliding window are provided to process an expensive spatial continuous inquiry quickly through the spatial sliding window for efficiently processing the spatial data streams obtained in real time, thereby minimizing the total response time of a real time monitoring system. A plan sub system(110) makes an inquiry plan by parsing a continuous spatial inquiry requested by a user. An execution sub system(120) reconfigures a spatial sliding window and index for an interest area of the continuous inquiry, and executes a continuous inquiry for real time spatial data streams by referring to the index according to the inquiry plan made in the plan sub system.
Abstract:
An apparatus and a method for determining the installation position of an image acquisition camera using 3D space information are provided to maximize the utility of the image acquisition camera by determining an optimized installation position of the camera through the analysis of 3D space information and analyzing the effect of the determined installation position. An apparatus for determining the installation position of an image acquisition camera includes a 3D space information processing unit(100) for processing geographic information to generate 3D space information(700), a 3D space information storage unit(200) for storing the 3D space information, and a 3D space information service unit(300) for transmitting 3D space information of a geographic region of interest from the 3D space information storage unit. The apparatus further includes a 3D space information analysis unit(400) for setting the geographic region of interest and a simulated position of the camera and performing 3D space information analysis to determine the optimized installation position of the camera, and a 3D space information visualization unit(500) for visualizing the result of the 3D space information analysis unit.
Abstract:
PURPOSE: A system and a method for fast processing a large capacity spatial image are provided to enhance a network efficiency and manage system resources efficiently by reducing the unnecessary data transmission between a server and a client on a network environment as transmitting only a processing result of a processor. CONSTITUTION: Spatial image processing servers(230,240) are operated by combining various processor through a virtual pipeline, and process the result of the processor through the pipeline fast. Spatial image database servers(210,220) store various large capacity spatial images without changing a format and a configuration characteristic, and manage the data by using a hierarchical optimal division and multi-resolution method. Clients(250) present the result to a user by exchanging the result and an instruction for the requested data through the cooperation between the data server and the processing server when the user requests the spatial image data. A network(260) connecting the processing servers, the data servers, and the clients performs a distributed process by transmitting the data.