KR101513591B1 - System for providing real time ocean spatial data using web 3d - Google Patents

Abstract

The present invention relates to a real-time ocean spatial data providing system using web 3D and, more particularly, to a real-time ocean spatial data providing system using web 3D, capable of being used in navigation safety, maritime disaster prevention fields and the like and quickly displaying maritime data even though a display area is wide when an LOD is expressed according to a reduced scale and is outputted on a screen. According to the present invention, the maritime data is quickly displayed by selecting a division region by selecting a layer step-by-step according to the change of the reduced scale when the maritime data is checked. The real-time ocean spatial data providing system using web 3D according to the present invention includes a 3D ocean space DB, a real-time data connection module, and a maritime data providing server.

Description

TECHNICAL FIELD The present invention relates to a system for providing real-time marine spatial information using web 3D,

The present invention relates to a real-time ocean spatial information providing system using Web 3D, and more particularly, to a system for providing real-time ocean spatial information using web 3D, which can be used in areas such as navigation safety and marine disaster prevention, And more particularly, to a real-time ocean spatial information providing system using web 3D capable of quickly displaying ocean information.

The present invention relates to a real-time ocean spatial information providing system using web 3D.

Currently, Korea does not even produce topographical maps with accurate location information for a large number of uninhabited islands located in the territorial waters, and provides accurate information on unmanned island areas even on marine- It is a reality that can not be.

In addition, the marine spatial information providing system simply stays at a level where ocean current information is simply displayed for each ocean position.

In other words, if the existing marine information tidal current providing system is to expand information on a specific location, it is necessary to re-examine necessary information on the relevant part separately, There is a problem that data must be continuously used.

In addition, information on the sea floor topography has been obtained by using paper charts, electronic charts, and various electronic observing equipment when fishing in the ocean, structure of marine structures, military operations and port operations.

However, if the actual collected data is inferior in quality compared to other data, or can not be complemented with each other, long-term measurement data or research efforts may be in vain.

Currently, many countries are making various efforts to recognize the problems and to prepare countermeasures to utilize the data more efficiently through national promises and international promises.

Therefore, it is urgent to develop web 3D engine that can visualize marine spatial information more accurately and precisely and provide web service on the Internet in real time.

The background art of the present invention is disclosed in Korean Patent Registration No. 10-1344728 and the like, but a solution to the above-mentioned problem is not presented.

The object of the present invention which has been devised to solve the above-mentioned problems is to develop a web 3D engine capable of rendering a large-capacity marine data having geographical information as two-dimensional, three-dimensional and four- , 3-D comprehensive marine information system that integrates information related to the marine is linked with various real-time ocean observation data such as tide forecast data, tide data, algae prediction data, weather satellite data, weather data, In addition to this, it is possible to generate sub-current information map together with the basic current information map and output it according to the inputted selection information, so that it can be utilized in the fields of navigation safety and marine disaster prevention, Real-time marine ball using web 3D that can display marine information quickly even if display area is large in output to screen To provide an inter-information providing system.

The present invention also provides a real-time marine spatial information providing system using web 3D that can quickly display marine information by selecting a layer in a stepwise manner according to a scale change when checking marine information.

It is also intended to provide a real-time marine spatial information providing system using Web 3D, which can track a moving route of a virtual floating object by tracking the marine information with time, or estimate a future moving route of a virtual floating object by predicting the marine information .

Another object of the present invention is to provide a method and apparatus for managing various unmanned and uninhabited islands in the Korean marine territory from the viewpoint of marine territory management based on three-dimensional spatial information and using the high resolution satellite image or high- And to provide a real-time ocean spatial information providing system using Web 3D, which enables accurate information on the status of the islands through the Internet and enables decision support for the utilization of the book based on the information.

It is another object of the present invention to provide a marine image obtained by synthesizing detailed information on a marine space on a three-dimensional marine spatial data on a web to provide a user terminal with information on a marine space And to provide a real-time marine spatial information providing system using web 3D that can be easily provided.

It is another object of the present invention to provide a method and apparatus for providing a marine image obtained by synthesizing detailed information on a marine space on a three-dimensional marine spatial data such as a sunset, a mist, a cloud, a sand on the sea floor, a tidal flat on the sea floor, Providing a real-time marine spatial information system using Web 3D that can provide a user with a living marine environment by projecting natural effect images of marine space such as intertidal zone, waves, and sea surface to the ocean image It is for this reason.

It is still another object of the present invention to provide a method and system for providing a user with a specific space (for example, a tidal flat, a beach or the like) in a three-dimensional ocean space data of the ocean space A composite image obtained by projecting the photographed moving image is generated and detailed information of the specific area (e.g., tidal flats, beaches, etc.) is provided to the user along with the composite image, thereby increasing the field understanding rate of the user, This is to provide a real-time ocean spatial information providing system using Web 3D that can more intuitively grasp the change of the environment or the movement of objects.

According to an aspect of the present invention, there is provided a real-time ocean spatial information providing system for providing ocean spatial information to a user terminal, the system including a land area, a seabed area, a waiting area, A three-dimensional ocean spatial database storing three-dimensional ocean spatial data including a sea area; A real-time data linking module for re-processing marine spatial data selected by the user terminal among the tidal forecast data, tidal data, algae prediction data, weather satellite data, weather data, and typhoon data; And extracting three-dimensional marine spatial data for a marine space corresponding to the marine spatial data re-processed from the real-time data association module in the three-dimensional marine spatial database, A marine information providing server for generating a marine image to be overlapped and providing the marine image to the user terminal in real time; Wherein the marine spatial database includes an observation information DB for receiving and storing marine information including the direction of the ocean current and the flow velocity information from the constructed marine information collecting device, The method includes the steps of: dividing a whole area of a marine area where information is collected into basic unit grids, generating an ocean current electronic map according to a predetermined basic scale size, extracting the basic unit grid from the direction and flow velocity information of the ocean current included in the observation information DB, A basic current information map generation unit for generating current basic information maps by extracting the current vector information for each of the basic almanac information maps and assigning them to the basic unit grid of the ocean current algae map; The entire region of the basic current information map is divided into a plurality of predetermined division regions each of which is formed of a group of a plurality of adjacent basic unit grid regions and an enlarged map of the plurality of divided regions is provided, A sub current information map generation unit for calculating sub current vector information according to the preprogrammed current vector information of the basic unit grid constituting the zone and generating a sub current information map allocated to each of the sub zones; Dividing regions into a plurality of predetermined sub-division regions, providing sub-expansion maps for the plurality of sub-division regions, and providing sub-division regions for each sub-division region, A second sub-current information map generation unit for generating a second sub-current information map allocated to each sub-sub-region by calculating second sub-current vector information according to preprogrammed sub-current vector information of the sub-region constituting the sub-region; The method includes receiving ocean float information from a marine image information collecting apparatus constructed to capture a water surface image of a marine area where marine information is collected, tracing a moving path of the marine floating object from the ocean current vector information inversely, A suspension movement path tracking management unit for determining a movement path and an occurrence point; A main current information map generating unit connected to the basic current information map generating unit, the sub current information map generating unit and the second sub current information map generating unit, for outputting the basic current information map on the screen according to the selection information inputted through the user terminal, Extracts a portion of the selected submarine information map from the selected subarea and outputs it to the screen or extracts a portion of the selected subarea from the second subarea information map and outputs the extracted portion to the user terminal, An output management unit for providing the user terminal with a movement path and a generation point information of the marine suspended matter determined by the management unit; Wherein the sub-current vector information includes at least one of an average vector value of the current vector information of the basic unit grid constituting the subdivision area or a vector having the largest magnitude of the current vector information of the basic unit grid constituting the subdivision area Value or any vector value selected arbitrarily from the current vector information of the basic unit grid constituting the subdivision area, and the sub-current information map is programmed to have a basic unit Information about the first specific fundamental unit grid, which is a basic unit grid in which the direction of the current of the basic unit grid is different from the direction of the current wave vector information for the corresponding partition and the predetermined tolerance range, Of the basic unit lattices included in each of the divided areas, Information on a second specific fundamental unit lattice, which is a basic unit lattice in which a difference is generated between a current velocity of the sub-current vector information for the inverse and a predetermined tolerance range, is displayed, and the first specific fundamental unit lattice or the second specific When the basic unit grid is selected on the screen, basic current vector information for the first specific fundamental unit grid or the second specific fundamental unit grid is displayed on the screen, and for each of the divided areas, And furthermore, the base unit lattice to which the size of the sub-current vector information and the current vector information over a predetermined error magnitude range are allocated and the current vector information allocated to the base unit lattice are further included .

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Further, a detailed information database in which marine environment detailed information of a specific marine space is stored; And a natural effect database storing natural effect image data of a land area, a seabed area, a waiting area, and a seawater area; Wherein the ocean information providing server receives a marine spatial information transmission signal to receive information on a specific marine space from the user terminal, and transmits the marine spatial information transmission signal to the three-dimensional marine spatial database Extracts data of the marine environment corresponding to the marine space from the detailed information database, generates a marine image for superimposing the detailed information of the marine environment on the three-dimensional marine spatial data, And the natural effect image data is at least one of sea level image data, wave image data, seabed texture image data, cloud image data, fog image data, and sunrise sunset image data.

In addition, when the oceanographic information providing server receives the sea level image or the wave image request signal from the user terminal while the ocean image is being output to the user terminal, the sea level image data or the wave image data is stored in the sea water area of the ocean image. A first ocean image is generated and provided to a user terminal or a sea floor image request signal is received from a user terminal while the ocean image is being output to a user terminal, A second ocean image is generated and provided to the user terminal or a cloud image, a mist image, or a sunrise sunset image request signal is received from the user terminal while the ocean image is being output to the user terminal, The cloud image data or the mist image data or the cloud image data After projecting the sunset image data to generate a third image marine it characterized in that it provides to the user terminal.

The marine information providing server collectively converts satellite screens, aerial photographs, multi-beam, single beam, magnetic exploration data, geological exploration data, numerical map, and numerical chart into UTM coordinate systems, converts them into 3-dimensional global coordinates, The satellite image, the aerial photograph, the DEM data and the vector data are analyzed and converted into tiles / pyramids through respective makers, and then the terrain area, the seabed area, the atmospheric area and the sea area are included Dimensional ocean spatial data.

In addition, the real-time ocean spatial information providing system using the web 3D may further include at least one camera for photographing the specific space in a specific space of the ocean space, When receiving the situation information request signal to receive the scene situation information, judges the time when the situation information request signal is inputted, receives the shot image from one or more cameras that have photographed the specific space from the time of the input, Projecting the provided photographed image onto the three-dimensional marine spatial data to generate a scene situation image, and providing the generated scene image to the user terminal.

As described above, according to the present invention, it is possible to use in the fields of navigation safety and prevention of marine disaster, and to display the LOD according to the scale and display it on the screen. The present invention can provide a real-time ocean spatial information providing system using the real-

Further, according to the present invention, there is provided a real-time marine spatial information providing system using Web 3D which can quickly display marine information by selecting layers in a stepwise manner according to a scale change when checking marine information .

In addition, according to the present invention, a real-time ocean spatial information providing system using Web 3D capable of tracking a moving route of a virtual floating object by tracking ocean information over time, estimating a moving route of a virtual floating object by predicting ocean information, .

According to the present invention, it is possible to manage various unmanned and uninhabited islands in the Korean waters in terms of marine territory management based on three-dimensional spatial information, and to utilize high resolution satellite images or high- ) Can be accurately provided through the Internet, and a real-time ocean spatial information providing system using Web 3D can be provided, which enables decision support for the utilization of the book based on the present status information.

In addition, according to the present invention, by providing the user terminal with a marine image obtained by synthesizing detailed information on the marine space on the web on the three-dimensional marine spatial data, the user can easily provide information about the marine space, The present invention can provide a real-time ocean spatial information providing system using web 3D.

In addition, according to the present invention, when providing a marine image obtained by synthesizing detailed information on a marine space on a three-dimensional marine spatial data, it is possible to provide a marine image that includes a sunset, a mist, a cloud, a sand on the sea floor, a tidal flat on the sea floor, And sea water surface by projecting the natural effect image of the marine space on the marine image to provide a real-time marine spatial information providing system using the web 3D that can provide a user with a living marine environment appearance.

In addition, according to the present invention, when a user inputs a request to view a specific area (for example, a tidal flat, a beach, etc.) in real time in a marine space, And provides detailed information of the specific area (e.g., tidal flats, beaches, etc.) to the user in addition to the composite image, thereby increasing the field understanding rate of the user, It is possible to provide a real-time ocean spatial information providing system using Web 3D that can more intuitively grasp changes and movement of objects.

1 is a block diagram illustrating an internal configuration of a real-time marine spatial information providing system using web 3D according to a preferred embodiment of the present invention.
2 is a block diagram of a marine space DB including an observation information DB.
FIG. 3 and FIG. 4 are block diagrams of a system for providing a marine information numerical tidal current according to a preferred embodiment of the present invention.
5 is an exemplary diagram of a basic current information map including basic unit grids to which current vector information is respectively allocated.
FIG. 6 is an exemplary view of a sub-current information map including sub-regions to which sub-current vector information is allocated.
FIG. 7 is an exemplary view of a second sub-current information map including sub-divisions in which second sub-current vector information is allocated.
8 is an example of an actual screen on which a basic current information map, a sub current information map, and a second sub current information map are outputted.
FIGS. 9 to 13 are explanatory diagrams illustrating operations of a marine information providing server according to a preferred embodiment of the present invention.
FIG. 14 is a flowchart illustrating a method for providing real-time marine spatial information using a web 3D according to a preferred embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, the present invention will be described with reference to the drawings for explaining a real-time ocean spatial information providing system using web 3D according to embodiments of the present invention.

FIG. 1 is a block diagram illustrating an internal configuration of a real-time ocean spatial information providing system using Web 3D according to a preferred embodiment of the present invention, and FIG. 2 is a configuration diagram of a marine space DB including an observation information DB.

3 and 4 are block diagrams of a system for providing a maritime information tidal current map according to a preferred embodiment of the present invention. FIG. 5 shows an example of a basic current information map including basic unit grid FIG. 6 is an exemplary view of a sub-current information map in which sub-current vector information is allocated, and FIG. 7 is a diagram illustrating a sub-current information map including a sub- Fig. 2 is an example of an ocean current information map; Fig.

8 is an example of an actual screen on which a basic current information map, a sub current information map, and a second sub current information map are outputted.

FIGS. 9 to 13 are explanatory diagrams illustrating operations of a marine information providing server according to a preferred embodiment of the present invention.

The real-time ocean spatial information providing system using web 3D according to the preferred embodiment of the present invention includes a marine information providing server 100, a marine spatial database 110, a detailed information database 120, a natural effect database 130, An association module 140, a user terminal 200, and one or more cameras 300.

The three-dimensional ocean space database 110 stores three-dimensional ocean space data including a land area, a seabed area, an atmospheric area, and a seawater area of the global ocean space.

At this time, the three-dimensional ocean spatial database 110 includes an observation information DB 111 for receiving and storing ocean information including the direction of the ocean current and the flow velocity information from the constructed ocean information collecting apparatus.

The real-time data linking module 140 re-processes the marine spatial data selected by the user terminal 200 among the tide forecast data, tidal data, algae prediction data, weather satellite data, weather data, and typhoon data, (100).

At this time, it is most preferable to re-process the two-dimensional, three-dimensional and four-dimensional marine spatial data.

The marine information providing server 100 extracts three-dimensional marine spatial data of the marine space corresponding to the re-processed marine spatial data from the real-time data linking module 140 in the three-dimensional marine spatial database 110, A marine image is generated so that the re-processed marine spatial data is superimposed on the three-dimensional marine spatial data, and the marine image is provided to the user terminal 200 in real time.

Therefore, it is possible to realize dynamic height of sea level by real-time tide forecast data by superimposing real-time marine spatial data with three-dimensional ocean spatial data, realizing the function of superimposing numerical algae vectors by real- Satellite data superimposition function, realization of sunlight natural effect by cloud image, typhoon movement path and location display, and real time diary superimposition function.

At this time, the real-time weather satellite data are obtained through Multi-Functional Transport Satellite (MTSAT) and radar images.

At this time, the marine information providing server 100 divides the whole area of the marine area where the marine information is collected into the basic unit grid 121, generates an ocean current electronic map according to a predetermined basic scale size, Extracts the current vector 122 information for each of the basic unit grids from the current direction and flow velocity information included in the information DB 111 and generates a basic current information map allocated to each of the basic unit grids of the ocean current electronic map A basic current information map generating unit 120 for generating a basic current information map including a plurality of basic unit information grids and a plurality of segmentation zones 131, And provides an enlarged map of the area. From the current vector information of the basic unit grid constituting each divided area for each divided area, A sub current information map generation unit 130 for calculating the sub current image information 132 and generating a sub current information map allocated to each of the sub regions, A scrolling movement route tracking unit for receiving marine floating information from the constructed marine image information collecting device and determining a moving route and an origin of the marine floating item by tracing the moving route of the marine floating item from the current vector information, 160), and a base current information map generating unit and a sub current information map generating unit, and outputs the basic current information map to the screen according to the selection information input through the user terminal, And outputs the extracted portion to the screen, and the suspended body movement path tracking management unit And an output management unit 150 for providing the user terminal with the movement path and the generation point information of the determined marine suspended matter.

First, the basic current information map generation unit 120, the sub current information map generation unit 130, the output management unit 150, and the suspended matter movement path tracking management unit 160 included in the marine information providing server 100 Will be described in detail.

The basic current information map generating unit 120 divides the entire area of the marine area where the marine information is collected into basic unit grids, generates an ocean current electronic map according to a predetermined basic scale size, 111), and generates a basic current information map allocated to each of the basic unit grid of the ocean current electronic map by extracting the current vector information for each of the basic unit grids.

That is, the basic current information map generation unit 120 divides the entire area of the marine area where the marine information is collected into basic unit grids, which are the minimum unit areas in which the marine information can be differentially provided, Generate a marine algae map based on scale size.

At this time, the current flow information map for each of the basic unit grids of the ocean current electronic map is extracted by extracting current flow vector information for each of the basic unit grids from the current direction and flow velocity information included in the observation information DB 111 .

That is, the basic current information map includes, for each region partitioned by the basic unit grid 121, current flow information, that is, current vector information 122 indicating the direction and intensity of the current flow in the form of a vector.

The sub-current information map generating unit 130 divides the entire area of the basic current information map into a predetermined plurality of sub-regions 131 and provides an enlarged map of the plurality of sub-regions.

At this time, the sub-current information map generating unit 130 generates the sub current vector information 132 according to the algorithm programmed from the current vector information of the basic unit grid 121 constituting each sub- And generates a sub current information map 135 allocated to each of the sub regions 131.

In this case, the sub-current vector information may be an average vector value of the current unit vector information constituting the divided region, or a vector value having the largest size among the current vector information of the basic unit grid constituting the divided region, Or any vector value arbitrarily selected from the current vector information of the basic unit grid constituting the segmented region.

In this case, the sub-current vector information may include at least one of current vector information of a grid which is read first among the current vector information of the basic unit grid constituting the subdivision region, To be the current unit vector information of the basic unit grid corresponding to the current unit vector.

The output management unit 150 is connected to the basic current information map generating unit and the sub current information map generating unit and outputs the basic current information map to the screen or selects one of the sub current information map Extracts a portion of one or more divided regions, and outputs the extracted portion.

That is, when the current information about the scale and the position required by the user is input, a portion of the selected one of the basic current information map or the sub current information map corresponding to the current scale and position is extracted and output to the screen, Can effectively provide marine information about the ocean.

The sub-current information map includes, for each of the sub-regions, a sub-current information map of the sub-current vector information in which the direction of the sub-current vector information and the current vector information over a predetermined error direction range are allocated Grid and the current vector information allocated to the corresponding base unit grid.

Further, in the sub-current information map, the size of the sub-current vector information and the current vector information over a predetermined error size range are allocated among the current unit vector information constituting the sub- And the current vector information allocated to the corresponding base unit grid may be further included.

That is, the sub-current information map is composed of a basic unit grid having basic sub-current vector information that is displayed in the sub-region and basic current vector information of a predetermined error direction range or more among the basic current vector information of basic unit grids originally included in the sub- And / or a basic unit grid having basic current vector information of a predetermined error magnitude or more.

In this case, the basic current vector information and the sub-current vector information include information on the current direction and velocity (velocity) of the basic unit grid, and information on the current direction and velocity (velocity) allocated to the divided region.

At this time, in the sub-current information map, the current direction of the basic unit grid among the basic unit grid included in each of the sub-regions is different from the current direction of the sub-current vector information for the corresponding sub- Information of the first specific fundamental unit grid, which is a basic unit grid in which the first unitary grid is generated, is displayed. Of the basic unit grid included in each of the divided regions, Information on a second specific fundamental unit lattice that is a basic unit lattice in which a difference is generated between a current velocity and a predetermined tolerance range is displayed and the first specific fundamental unit lattice or the second specific basic unit lattice is selected on the screen The basic current vector information for the first specific fundamental unit grid or the second specific fundamental unit grid is displayed on the screen Display.

That is, as shown in FIG. 4, the sub-current information map includes basic current unit vector information of basic unit grids, that is, current direction information of the current and current velocity The information of the basic current unit vector information including the information is further displayed on the sub-current vector information of the sub-region including each basic unit grid and information on the specific basic unit grid, which is a basic unit grid having a predetermined error size or more.

Specifically, among the basic unit grids included in the divided area, there exists a basic unit lattice in which the direction of the current of the basic unit grid is different from the direction of the current of the sub-current vector information for the corresponding divided area and the predetermined tolerance range or more (For example, a basic unit lattice indicated by triangles in FIG. 4) by classifying the basic unit lattice into a first specific basic unit lattice having specific current direction information.

In addition, among the basic unit lattices included in the divided area, there exists a basic unit lattice in which the current speed of the basic unit lattice differs from the current speed of the sub-current vector information for the corresponding divided area to a predetermined tolerance range or more , The corresponding basic unit grid is classified into a second specific basic unit grid having specific current velocity information (for example, a basic unit grid indicated by a circle (circle) in FIG. 4).

In this case, when the first specific fundamental unit grid or the second specific basic unit grid is selected on the screen, basic current vector information for the first specific fundamental unit grid or the second specific basic unit grid, To be displayed on the screen.

The real-time ocean spatial information providing system using the web 3D according to the present invention divides each divided sub-region constituting the sub-current information map into a plurality of predetermined sub-subdivisions, The second sub-current vector information is pre-programmed from the sub-current vector information of the sub-sub-divisions constituting the sub-sub-divisions for each sub-sub-region, and the second sub- And a second sub-current information map generation unit 140 for generating two sub-current information maps.

At this time, the output managing unit 150 is connected to the second sub-current information map generating unit and outputs the basic current information map to the screen according to the inputted selection information, Extracts a portion for a zone and outputs it to a screen or extracts a portion of a selected sub-segment of the second sub-current information map and outputs it to the screen.

In addition, the marine information providing server 100 receives the marine floating information from the marine image information collecting device constructed to capture a sleep image of the marine area where the marine information is collected, And a scavenging route tracking unit 160 for scrolling a route backward to determine a moving route and a point of occurrence of the floating scavenger.

At this time, the output management unit further outputs the movement path and the generation point information of the marine suspended object determined by the floating object movement path tracking management unit.

The detailed information database 112 stores detailed information of the marine environment (for example, time information, tide information, ocean current component information, wave information, weather information, sea bed quality distribution information, buoy information, survey data, (SS) information, etc.) are stored. Here, the sub-similar information means the distribution of the sub-similar concentration of the submarine sand deposit in the presence of waves.

The natural effect database 113 stores natural effect image data (for example, sea surface image data, wave image data, seabed texture image data, cloud image data, mist image data, sunrise Sunset image data, sea-level surface image data, etc.) are stored.

When the marine information providing server 100 receives a marine spatial information transmission signal to receive information on a specific marine space from the user terminal 200, the marine information providing server 100 searches the three-dimensional marine spatial database 110 for the marine space Dimensional ocean spatial data, extracts detailed information of the marine environment for the marine space from the detailed information database 112, and superimposes the marine spatial detail information of the marine space on the three-dimensional marine spatial data Generates a marine image, and provides the marine image to the user terminal 200. FIG. 9 shows a state of a user terminal when a user connected to a web site operated by a marine information providing server requests a marine image of a specific marine space (e.g., Jeju Island in FIG. 9).

At this time, the oceanographic information providing server 100 may receive a sea level image or a wave image request signal from the user terminal 200 while the ocean image is being output to the user terminal 200.

Then, the marine information providing server 100 projects the sea level image data or the wave image data in the sea water area of the ocean image, and then generates the first ocean image (sea image in which the sea level image data or the wave image data is projected) And provides it to the terminal 200. FIG. 10 shows a user terminal when a user connected to a web site operated by a marine information providing server requests to provide a sea level image using a user terminal.

In addition, the marine information providing server 100 may receive a sea floor image request signal from the user terminal while the ocean image is being output to the user terminal 200. [

Then, the marine information providing server 100 projects the submarine texture image data in the submarine area of the marine image, and then generates a second marine image (marine image projected from the sea floor surface data) to the user terminal 200 do. FIG. 11 shows a state of a user terminal when a user connected to a web site operated by a marine information providing server requests to provide a sea floor image using a user terminal.

Meanwhile, the marine information providing server 100 may receive a cloud image, a mist image, or a sunrise sunset image request signal from the user terminal while the marine image is being output to the user terminal 200.

Then, the marine information providing server 100 projects the cloud image data, the mist image data or the sunrise sunset image data to the waiting area of the marine image, and then the third ocean image (the cloud image data or the mist image data, And provides the generated image to the user terminal 200. FIG. 12 shows a user terminal when a user connected to a web site operated by a marine information providing server requests a cloud image providing using a user terminal.

According to the present invention having the above-described configuration, when providing the marine image to the user terminal 200, natural effect images of the marine space (e.g., waves, fog, clouds, sea floor (sand, tidal flats, (Ocean, sea, and ocean), waves, images of sea surface, etc.) to the marine image to provide the user with a lively ocean environment, thereby increasing the interest of the user and increasing the field understanding rate .

Then, the marine information providing server 100 receives the algae information, tide information, wave information, and weather information of the specific ocean space from the National Oceanographic Research Institute server (not shown) and the weather office server (not shown) And updates the information database 120 in real time.

In addition, the marine information providing server 100 collectively converts satellite screens, aerial photographs, multi-beam, single beam, magnetic exploration data, geological exploration data, numerical map, and numerical map into UTM coordinate system, The satellite image, the aerial photograph, the DEM data, and the vector data are analyzed and converted into tiles / pyramids through respective makers, and then the terrain area, the seabed area, the atmospheric area, Dimensional ocean space database 110 and stores the generated three-dimensional ocean space data in the three-dimensional ocean space database 110.

The camera 300 is installed in a specific space (for example, a tidal flat, a beach, etc.) in the marine space, captures the specific space, and transmits the captured image to the marine information providing server 100.

At this time, the marine information providing server 100, when receiving the situation information request signal to receive the site situation information of the specific space from the user terminal 200, determines the time when the situation information request signal is inputted, The user terminal 200 receives the photographed image from one or more cameras 300 that have photographed the specific space from the input point and projects the photographed image to the three-dimensional ocean spatial data, .

Hereinafter, an operation process of a real-time ocean spatial information providing system using web 3D according to the present invention will be described in detail with reference to the drawings.

FIG. 14 is a flowchart illustrating a method for providing real-time marine spatial information using a web 3D according to a preferred embodiment of the present invention.

The method of providing real time marine spatial information providing a marine spatial information to a user terminal according to an embodiment of the present invention is a method for providing marine spatial information to a user terminal, The marine spatial data selected by the terminal 200 is re-processed and transmitted to the marine information providing server 100 in real time (S100).

At this time, it is most preferable to re-process the two-dimensional, three-dimensional and four-dimensional marine spatial data.

Next, the marine information providing server 100 extracts three-dimensional marine spatial data of the marine space corresponding to the re-processed marine spatial data from the marine spatial database from the step S100 (S200).

At this time, the three-dimensional ocean space database 110 stores three-dimensional ocean space data including a land area, a seabed area, an atmospheric area, and a seawater area of the global ocean space.

Next, the marine information providing server generates a marine image to superimpose the marine spatial data re-processed in the step (S100) on the three-dimensional marine spatial data extracted in the step S200, To the user terminal 200 (S300).

That is, every time the re-processed marine spatial data is updated in real time, a new marine image is generated and the marine image is provided to the user terminal 200, so that the user is always provided with new data.

In addition, the marine information providing server 100 receives a marine spatial information transmission signal for receiving information on a specific marine space from the user terminal 200 connected to the web site operated by the marine information providing server 100.

Then, the marine information providing server 100 extracts the three-dimensional marine spatial data of the selected specific marine space from the marine spatial database 110 and extracts detailed information of the marine environment for the selected specific marine space (for example, From the detailed information database 120, time information, tide information, current component information, wave information, weather information, seabed quality distribution information, buoy information, survey data, salinity and sub-similarity (SS) information.

Thereafter, the marine information providing server 100 generates a marine image for superimposing marine environment detailed information on the extracted marine space on the extracted three-dimensional marine spatial data, and processes the marine image to be provided to the user terminal 200 do.

Meanwhile, while the ocean image is being output to the user terminal 200, the ocean information providing server 100 may receive a sea level image or a wave image request signal from the user terminal 200.

Then, the marine information providing server 100 extracts the sea water area of the ocean image, projects the sea water surface image data or the wave image data to the sea water area, and then outputs the first ocean image (sea surface image data or wave image data, And provide the generated image to the user terminal 200. [0050]

Also, while the marine image is being output to the user terminal 200, the user may receive a bottom image request signal from the user terminal 200.

Then, the marine information providing server 100 extracts a submarine region of the marine image, projects the marine texture image data to the submarine region, and then generates a second marine image (marine image projected from the sea floor image data) And provides it to the user terminal.

Also, while the ocean image is being output to the user terminal 200, a cloud image, a mist image, or a sunrise sunset image request signal may be received from the user terminal 200.

Then, the marine information providing server 100 extracts the atmospheric region of the ocean image and projects the cloud image data, the mist image data, or the sunrise sunset image data to the waiting region, and then the third ocean image (the cloud image data or the mist image Data or a sunset image in which sunrise sunset image data is projected) to the user terminal.

Meanwhile, while the ocean image is being output to the user terminal 200, the user terminal 200 may receive a situation information request signal to receive the site information of a specific space in the ocean space.

Then, the marine information providing server 100 receives the photographed image of the specific space from the time when the marine information providing server 100 receives the situation information request signal from the camera 300 in the specific space selected from the user terminal 200.

Thereafter, the marine information providing server 100 projects the provided photographed image onto the three-dimensional marine spatial data to generate a scene situation image, and provides the same to the user terminal 200.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

100: marine information providing server 110: marine spatial database
112: detailed information database 113: natural effect database
114: real-time data linking module 120: basic current information map generating section
130: Sub-current information map generating unit
140: Second sub-current information map generation unit
150: output unit 200: user terminal
300: camera

Claims (9)

A real-time ocean spatial information providing system for providing ocean spatial information to a user terminal,
A three-dimensional ocean spatial database storing three-dimensional ocean spatial data including a land area, a seabed area, an atmospheric area, and a seawater area of a specific ocean space;
A real-time data linking module for re-processing marine spatial data selected by the user terminal among the tidal forecast data, tidal data, algae prediction data, weather satellite data, weather data, and typhoon data; And
Extracting three-dimensional marine spatial data corresponding to the marine spatial data corresponding to the re-processed marine spatial data from the real-time data linking module in the three-dimensional marine spatial database, A marine information providing server for generating a marine image to be overlapped and providing the marine image to the user terminal in real time; Lt; / RTI >
The marine spatial database includes an observation information DB for receiving and storing marine information including a direction of an ocean current and flow velocity information from a pre-established marine information collecting device,
The marine information providing server includes:
The method includes generating an ocean current electronic map according to a predetermined basic scale size after dividing the entire area of the marine area where the marine information is collected into basic unit grids, A basic current information map generation unit for extracting current vector information for each unit grid and generating a basic current information map allocated to each of the basic unit grid of the ocean current electronic map;
The entire region of the basic current information map is divided into a plurality of predetermined division regions each of which is formed of a group of a plurality of adjacent basic unit grid regions and an enlarged map of the plurality of divided regions is provided, A sub current information map generation unit for calculating sub current vector information according to the preprogrammed current vector information of the basic unit grid constituting the zone and generating a sub current information map allocated to each of the sub zones;
Dividing regions into a plurality of predetermined sub-division regions, providing sub-expansion maps for the plurality of sub-division regions, and providing sub-division regions for each sub-division region, A second sub-current information map generation unit for generating a second sub-current information map allocated to each sub-sub-region by calculating second sub-current vector information according to preprogrammed sub-current vector information of the sub-region constituting the sub-region;
The method includes receiving ocean float information from a marine image information collecting apparatus constructed to capture a water surface image of a marine area where marine information is collected, tracing a moving path of the marine floating object from the ocean current vector information inversely, A suspension movement path tracking management unit for determining a movement path and an occurrence point;
A main current information map generating unit connected to the basic current information map generating unit, the sub current information map generating unit and the second sub current information map generating unit, for outputting the basic current information map on the screen according to the selection information inputted through the user terminal, Extracts a portion of the selected submarine information map from the selected subarea and outputs it to the screen or extracts a portion of the selected subarea from the second subarea information map and outputs the extracted portion to the user terminal, An output management unit for providing the user terminal with a movement path and a generation point information of the marine suspended matter determined by the management unit; Lt; / RTI >
The sub-
An average vector value of the current vector information of the basic unit grid constituting the divided region or a vector value having the largest size among the current vector information of the basic unit grid constituting the divided region, And any one vector value arbitrarily selected from the current vector information of the lattice,
In the sub current information map,
The first unit lattice which is a basic unit lattice in which the direction of the current flow of the basic unit lattice differs from the direction of the current of the sub-current vector information for the corresponding divided area and the predetermined tolerance range, Information about the specific basic unit grid is displayed,
Wherein the first unit lattice of the basic unit lattice included in each of the subdivisions includes a second unit lattice which is different from the current rate of sub-current vector information for the corresponding subdivision area by a predetermined tolerance range or more, Information about the specific basic unit grid is displayed,
When the first specific fundamental unit grid or the second specific fundamental unit grid is selected on the screen, basic current vector information for the first specific fundamental unit grid or the second specific fundamental unit grid is displayed on the screen,
Wherein each of the divisional regions includes a basic unit grid assigned with a size of the sub-current vector information and a current vector information of a predetermined error size range or more among the current unit vector information of the basic unit grid constituting the divided region, And the current ocean spatial information providing system using web 3D.
delete delete delete delete The method according to claim 1,
A detailed information database storing detailed marine environment information of a specific marine space; And
A natural effect database storing natural effect image data of a land area, a seabed area, an atmospheric area, and a seawater area; Further comprising:
The marine information providing server includes:
When receiving a marine spatial information transmission signal to receive information on a specific marine space from a user terminal, extracts three-dimensional marine spatial data for the marine space from the three-dimensional marine spatial database, The method comprising: extracting marine environment detailed information corresponding to a space, generating a marine image for superimposing detailed information of the marine environment on the three-dimensional marine spatial data, providing the marine image to the user terminal,
Wherein the natural effect image data comprises:
Wherein the sea-level image data, the wave image data, the seabed texture image data, the cloud image data, the mist image data, and the sunrise sunset image data are provided.
The method according to claim 6,
The marine information providing server includes:
When receiving the sea level image or the wave image request signal from the user terminal while the sea image is being output to the user terminal, the sea level image data or the wave image data is projected to the sea water area of the ocean image, To the user terminal,
When a sea floor image request signal is received from a user terminal while the sea image is being output to the user terminal, the sea water texture image data is projected to a submarine region of the sea image, and then a second sea image is generated and provided to the user terminal do or,
If the cloud image, the fog image, or the sunrise sunset image request signal is input from the user terminal during the output of the ocean image to the user terminal, the cloud image data, the mist image data, or the sunrise sunset image data And generating a third ocean image and providing the third ocean image to the user terminal.
The method according to claim 1,
The marine information providing server includes:
A satellite image, a satellite image, an aerial photograph, a multi-beam, a single beam, a magnetic exploration data, a geological exploration data, a numerical map, and a numerical chart into a UTM coordinate system, Photographs, DEM data, and vector data are respectively analyzed and pre-processed to be tiled / pyramidized through respective makers, and then three-dimensional ocean spatial data including land areas, seabed areas, atmospheric areas and seawater areas are generated And a real time ocean spatial information providing system using web 3D.
The method according to claim 1,
The real-time ocean spatial information providing system using the web 3D includes:
And one or more cameras for photographing the specific space in a specific space of the ocean space,
The marine information providing server includes:
When receiving a situation information request signal to receive the scene information of the specific space from the user terminal, judges the time when the situation information request signal is inputted, and from one or more cameras And providing the captured image to a user terminal by projecting the received photographed image onto the three-dimensional ocean spatial data to generate a site scene image, and providing the site image to the user terminal.

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