KR102120680B1 - 3D BIM object modeling server and 3D BIM object modeling system comprising it - Google Patents

Abstract

The present invention relates to a 3D BIM object modeling server that implements 3D modeling using BIM information and GIS information, and a 3D BIM object modeling system including the same.
3D BIM object modeling server according to an embodiment of the present invention,
A server communication unit performing a function of interworking with a user terminal via a wired or wireless communication network; A server storage unit in which BIM data for virtually modeling a building, geographic data occupying a location in space, and GIS data for processing and processing attribute data related to the geographic data are stored; And, in response to the primary request transmitted from the user terminal to transmit the primary modeling data to the user terminal, when the secondary request for at least one specific object is transmitted from the user terminal receiving the primary modeling data And a server control unit transmitting secondary modeling data for the specific object to the user terminal.

Description

A 3D BIM object modeling server and a 3D BIM object modeling system including the same {3D BIM object modeling server and 3D BIM object modeling system comprising it}

The present invention relates to a 3D BIM object modeling system, and more particularly, to a 3D BIM object modeling server that implements 3D modeling using BIM information and GIS information, and a 3D BIM object modeling system including the same.

In recent years, interest in smart cities called so-called smart cities, which networked public functions of major cities using advanced information and communication technology (ICT), has increased. Smart City refers to a future high-tech city where you can access the Internet anytime, anywhere and freely use advanced IT technologies such as video conferencing. Traffic information can be obtained in real time, reducing travel distance and enabling remote work, making it easier for residents to live and reducing CO2 emissions.

These smart cities are currently used in over 30 cities in Korea, but there is no example of implementing a user interface, especially a 3D modeled user interface, and there are hundreds of smart cities in the world, but user interfaces that consider users. The example of is understood to be extremely rare.

Therefore, there is a need for a user interface to increase the usability of a smart city and implement modeling that reflects user preferences or needs.

Furthermore, it is necessary to develop a 3D BIM object modeling system capable of grasping the user's surroundings at a glance while significantly reducing the amount of data consumed, and obtaining detailed information about a specific object desired by the user.

Korean Registered Patent No. 10-1336013 (2013.11.27)

An object of the present invention is to provide a 3D BIM object modeling server and a 3D BIM object modeling system including the same, which can provide surrounding information and detailed information of an object desired by a user while reducing the amount of data consumed.

3D BIM object modeling server according to an embodiment of the present invention,

A server communication unit performing a function of interworking with a user terminal via a wired or wireless communication network; A server storage unit in which BIM data for virtually modeling a building, geographic data occupying a location in space, and GIS data for processing and processing attribute data related to the geographic data are stored; And, in response to the primary request transmitted from the user terminal to transmit the primary modeling data to the user terminal, when the secondary request for at least one specific object is transmitted from the user terminal receiving the primary modeling data And a server control unit transmitting secondary modeling data for the specific object to the user terminal.

In the 3D BIM object modeling server according to an embodiment of the present invention, the server control unit includes a primary 3D modeling module that generates primary modeling data in response to a primary request transmitted from the user terminal, and the primary A second 3D modeling module may be included to generate second modeling data by mapping response information to the second request to modeling data.

In the three-dimensional BIM object modeling server according to an embodiment of the present invention, the first request is a request for transmitting BIM data and GIS data for an outer form of a building or terrain in a predetermined range centered on the user terminal, wherein The second request may be a request for transmitting BIM data and GIS data for the inner and outer shapes of a specific object selected by the user.

In the 3D BIM object modeling server according to an embodiment of the present invention, the secondary request may include unique information about the specific object.

User terminal according to an embodiment of the present invention,

A communication unit that transmits and receives data to and from a 3D BIM object modeling server via a wired or wireless communication network; An input unit that receives at least one of a key input, a touch input, a voice input, and a gesture input from a user; An output unit that outputs an input result of the input unit, a user interface, and 3D modeling data; After performing primary 3D modeling based on primary modeling data received from the 3D BIM object modeling server, secondary 3D based on secondary modeling data for a specific object received from the 3D BIM object modeling server And a 3D modeling unit that performs modeling.

In the user terminal according to the embodiment of the present invention, after the 3D modeling unit performs the primary 3D modeling, and when the user's search information is input through the input unit, at least one or more corresponding to the input search information You can highlight specific objects.

In a user terminal according to an embodiment of the present invention, when any one or more specific objects among the highlighted at least one specific object is selected, request secondary modeling data for the selected specific object to the 3D BIM object modeling server And, based on the second modeling data received from the three-dimensional BIM object modeling server may perform a second 3D modeling.

In the user terminal according to the embodiment of the present invention, the secondary modeling data may include BIM data and GIS data for the inner and outer shapes of the specific object, and unique information about the specific object.

3D BIM object modeling system according to an embodiment of the present invention,

A server communication unit that performs a function of interworking with a user terminal via a wired/wireless communication network, BIM data for modeling a building virtually, and GIS data that integrates geographic data occupying a spatial location and attribute data related to the geographic data Is stored in the server storage unit, and in response to the primary request transmitted from the user terminal, the primary modeling data is transmitted to the user terminal and the secondary for at least one specific object from the user terminal receiving the primary modeling data A 3D BIM object modeling server including a server control unit that transmits secondary modeling data for the specific object to the user terminal when a request is transmitted; And a communication unit that transmits and receives data to and from the 3D BIM object modeling server via a wired or wireless communication network, an input unit that receives at least one of a key input, a touch input, a voice input, and a gesture input from a user, and an input result of the input unit. Wow, the user interface, an output unit for outputting 3D modeling data, and performing primary 3D modeling based on the primary modeling data received from the 3D BIM object modeling server, and then from the 3D BIM object modeling server. And a 3D modeling unit that performs secondary 3D modeling based on the received secondary modeling data for a specific object.

In the three-dimensional BIM object modeling system according to an embodiment of the present invention, the first request is a request for transmitting BIM data and GIS data for an outer form of a building or terrain in a predetermined range centered on the user terminal, wherein The second request may be a request for transmitting BIM data and GIS data for the inner and outer shapes of a specific object selected by the user.

In the 3D BIM object modeling system according to an embodiment of the present invention, when the user's search information is input through the input unit after performing the primary 3D modeling, the 3D modeling unit corresponds to the inputted search information Can highlight at least one specific object.

In the 3D BIM object modeling system according to an embodiment of the present invention, when any one or more specific objects are selected from the highlighted at least one specific object, secondary modeling data for the selected specific object may be used as the 3D BIM object. Request to the modeling server, and perform the 2D 3D modeling based on the 2D modeling data received from the 3D BIM object modeling server.

In the 3D BIM object modeling system according to an embodiment of the present invention, the secondary modeling data may include BIM data and GIS data for inner and outer shapes of the specific object, and unique information about the specific object.

Other details of implementations according to various aspects of the present invention are included in the detailed description below.

According to the 3D BIM object modeling server and the 3D BIM object modeling system including the same according to an embodiment of the present invention, it is possible to grasp the user's surroundings at a glance while dramatically reducing the amount of data consumed. It is possible to obtain detailed information about a specific object desired by the user, thereby improving user convenience.

1 is a diagram illustrating a 3D BIM object modeling system according to an embodiment of the present invention.
2 is a diagram illustrating a user terminal according to an embodiment of the present invention.
3 and 4 are views illustrating an example of a user interface displayed through an output unit of a user terminal according to an embodiment of the present invention.
5 is a diagram illustrating a server control unit of a 3D monitoring server according to an embodiment of the present invention.
6 is a flowchart illustrating a 3D BIM object modeling method according to an embodiment of the present invention.
7 is an example of 3D modeling displayed on a user terminal according to an embodiment of the present invention, and is a diagram illustrating a result of performing a primary modeling process.
8 is a diagram illustrating a result of a user inputting search information in FIG. 7.
9 is a view illustrating a CCTV screen around a specific object selected by a user after performing a secondary modeling process.

The present invention can be applied to various transformations and can have various embodiments, and thus, specific embodiments will be illustrated and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all conversions, equivalents, and substitutes included in the spirit and scope of the present invention.

The terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present invention, terms such as'include' or'have' are intended to indicate that there are features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, and one or more other features. It should be understood that the existence or addition possibilities of fields or numbers, steps, operations, components, parts or combinations thereof are not excluded in advance.

Spatial information for 3D modeling can be largely divided into indoor spatial information and outdoor spatial information, and indoor spatial information is generally represented by BIM data, and outdoor spatial information can be represented by GIS data.

BIM (Building Information Modeling) refers to the process of virtually modeling facilities in planning, design, engineering (structure, facilities, electricity, etc.), construction, and even maintenance and disposal in a multidimensional virtual space. In particular, it enables the design and construction of the latest issues, the cutting-edge design and eco-friendly low-cost buildings, and is a concept similar to the multi-dimensional virtual design construction (VDC).

BIM can create numerical data by dataizing buildings, and can see the effect of 3D display. Rather than a simple line or face operation, data of the length connecting the start and end points of the line is generated, and the area is dataized based on the closed face.

The Geographic Information System (GIS) is a computer system designed to collect and use hardware, software and geographic data of computers designed to effectively collect, store, update, adjust, analyze, and present all types of geographically referenced information. .

GIS stores, extracts, manages, and analyzes information by linking topographical information that spatially expresses location with reference to various earth surface information and non-graphical attribute information that complements its shape and function with the management functions of graphics and databases. It is an information system related technology, and it is also a comprehensive analysis means for expressing the spatial relationship of maps by adding characteristic (attribute) information of topographic information. Geographic data occupying a position in space and attribute data related thereto are integrated and processed. GIS can be widely used in land information management, facility management, transportation, urban planning and management, environment, weather forecasting, agriculture, disaster and disaster, education, and population forecasting.

The BIM data used in this specification may mean all information on buildings used to implement BIM, such as roads, bridges, and structures, and GIS data also includes street lights, pedestrian crossings, in addition to geographic information such as ordinary rivers and parks. Information including parking facilities, Internet of Things (IOT) facilities for measuring air pollution, CCTV, etc. may be collectively referred to.

Hereinafter, a 3D BIM object modeling server and a 3D BIM object modeling system including the same will be described with reference to the drawings.

1 is a diagram illustrating a 3D BIM object modeling system according to an embodiment of the present invention.

As shown in FIG. 1, a 3D BIM object modeling system according to an embodiment of the present invention may include a user terminal 100 and a 3D BIM object modeling server 200.

The user terminal 100 refers to a terminal capable of transmitting and receiving data to and from a 3D BIM object modeling server (hereinafter referred to as a'modeling server') through a wired or wireless communication network, a personal computer (PC), a notebook computer, It may be any one of a personal digital assistant (PDA) and a mobile communication terminal. The user terminal 100 is equipped with a web browser for accessing the 3D BIM object modeling server 200 via a wired or wireless communication network, a memory for storing a program, a microprocessor for executing a program, and controlling and controlling the program. Means a terminal.

In addition, the user terminal 100 may receive BIM and GIS data from the modeling server 200 and drive a 3D modeling program to provide 3D modeling to the user.

2 is a diagram illustrating a user terminal according to an embodiment of the present invention. As illustrated in FIG. 2, the user terminal 100 includes a control unit 110, a communication unit 120, an input unit 130, an output unit 140, a storage unit 150, and a 3D modeling unit 160. Can be.

The communication unit 120 serves to support transmission and reception of various information with the modeling server 200 through a wired/wireless communication network N. The communication unit 120 transmits information input by the input unit 130 to the modeling server 200 under the control of the control unit 110 and receives BIM and GIS data transmitted from the modeling server 200.

The input unit 130 transmits various information such as numeric and character information input from a user, various function settings, and a signal input in relation to function control of the user terminal 100 to the control unit 110.

The input unit 130 includes at least one of a key input means such as a keyboard or a key pad, a touch input means such as a touch sensor or a touch pad, a voice input means, a gyro sensor, a geomagnetic sensor, an acceleration sensor and a proximity sensor, and a camera. It may include a gesture input means comprising the above.

The output unit 140 outputs the input result of the input unit 130, and when driving the 3D modeling unit 160, outputs a user interface (see FIGS. 3 and 4). Also, 3D modeling data modeled by the 3D modeling unit 160 is output. The user interface will be described later.

The storage unit 150 stores various data, programs, and applications required for driving the user terminal. In addition, depending on the selection, specific BIM and GIS data transmitted from the modeling server 200 may be stored, and 3D modeling data modeled using the BIM and GIS data may be stored.

The 3D modeling unit 160 performs 3D modeling based on BIM data and GIS data. The 3D modeling unit 130 may be implemented as various models, apps or programs that perform 3D modeling based on object information. For example, the 3D modeling unit 130 can create and share 3D models similar to Google SketchUp or Google SketchUp, where users can create 3D spatial models directly in Google Earth. It can be implemented with applications such as Google Building Maker that can be combined with satellite maps. However, it is apparent that the 3D modeling unit 130 is not limited to the above-described Google sketch-up or Google building maker, and can be implemented with various modeling tools that typically implement 3D modeling.

In addition, the 3D modeling unit 130 may model a specific building or road in a specific color according to preset color information. For example, depending on the user's choices or presets, fire departments may be colored red, hospitals may be white or highlight certain streets in frequently visited areas. That is, the 3D modeling unit 130 may model a specific object with a specific color according to preset color information. This also corresponds to one aspect of providing a user interface, through which the user's experience index can be increased.

Meanwhile, in one embodiment of the present invention, the 3D modeling unit 130 may perform 3D modeling in two steps. After the primary modeling is performed by the primary request for requesting the transmission of only the outer shape of the object to be described later, when the user's search information is input through the input unit 130, the 3D modeling unit 130 corresponds to the input search information Can highlight at least one object. That is, a specific object may be highlighted by displaying a thick outline of a specific object corresponding to the search information, displaying a specific color, or blinking.

In addition, in one embodiment of the present invention, the 3D modeling unit 130, after the primary modeling, requests the detailed BIM/GIS data for a specific object selected by the user for the second time, from the modeling server 200 to the second request. Secondary modeling is performed by receiving the corresponding secondary BIM/GIS data. Secondary modeling is a modeling process that displays internal and external shapes of specific objects selected by the user and unique information about the objects in the primary modeling data. This will be described later with the 3D BIM object modeling method.

The control unit 110 performs overall control of the user terminal 100, and is loaded with at least one processor and at least one memory loading data including a CPU (Central Processing Unit)/MPU (Micro Processing Unit) in hardware. The execution memory (eg, a register and/or random access memory (RAM)) and a bus (BUS) for inputting and outputting at least one or more data to the processor and memory.

In order to perform the functions defined in the user terminal 100 in software, it may be made by including a predetermined program routine (Routine) or program data loaded into the execution memory from a predetermined recording medium and processed by the processor. . In other words, in order to perform 3D modeling according to an embodiment of the present invention, a software-processable component among functions provided in the user terminal 100 may be determined as a function of the controller 110.

The control unit 110 of the present invention is functionally connected to at least one or more components provided to support 3D modeling. That is, the control unit 110 is functionally connected to the communication unit 120, the input unit 130, the output unit 140, the storage unit 150, and the 3D modeling unit 160, and supplies power to each component and functions. The signal flow for performance is controlled.

Next, the user interfaces I and II output from the output unit 140 will be described with reference to FIGS. 3 and 4. 3 and 4 are views illustrating an example of a user interface displayed through the output unit 140 of a user terminal according to an embodiment of the present invention.

The user may be provided with various graphic interfaces through the user interfaces (I, II) of the user terminal 100, through which various options or symbols for 3D modeling can be set.

For example, the user is provided with a graphical interface window (I) as shown in FIG. 3, BIM data setting for selecting at least one individual BIM data among BIM data, and selecting at least one individual GIS data among GIS data The GIS data setting, the BIM data to be received from the server, and the data size setting for limiting the size of the GIS data, and additionally, setting for a specific situation may be performed. The BIM data setting, GIS data setting, and data size setting may be one type of situation setting, and when there is no setting for them, it may be defaulted so that minimal data is consumed.

The user may select at least one individual BIM data among vast BIM data stored in the modeling server 200 or select at least one individual GIS data among GIS data. For example, the user may perform 3D modeling by selecting only the outer shape of the building as individual BIM data or only specific terrain or road such as a mountain or river as individual GIS data.

In addition, when setting the BIM and GIS data, the user may be set to receive BIM and GIS data in a certain area around the current location of the user terminal 100. For example, it can be set to receive BIM and GIS data on topography of buildings, mountains, rivers, and roads within a radius of 5 km from the current location. In other words, BIM and GIS data for a certain area of a building, terrain, etc. are received based on the current location, but only outlines and outlines that indicate building topography are set to be received, so that 3D modeling necessary with minimal data is performed. Can be.

In addition, the user may perform 3D modeling as before, but limit the amount of data transmitted from the modeling server 200. When the data size setting is requested from the user terminal 100, the modeling server 200 may transmit only minimal data for graphicization among BIM data and GIS data or select only key data and provide it to the terminal 100. .

Through this user setting, since a large amount of data can be reduced from the data necessary for 3D modeling, the speed of communication increases, and the user can see the desired 3D modeling result more quickly and effectively.

Meanwhile, the user may set a situation for a specific situation. The situation setting for a specific situation is for a special situation in which 3D modeling is required. When the user selects'setting the situation' in the graphic interface (I) of FIG. 3, a sub graphic interface (II) as shown in FIG. 4 may be provided. For example, the user may select at least one of a CCTV situation, a road traffic light display situation, and a building selection situation defining a specific building as a situation setting.

When the user sets the situation, when requesting the first BIM data and GIS data from the user terminal 100 to the modeling server 200, the part corresponding to the situation information set in the minimum outline information of the building/topography is set in a preset color. It can be highlighted. For example, depending on the user's selection or preset, the fire department may be displayed in red, the hospital in white, and the CCTV/IOT sensor in blue.

If the user has not set the situation, when requesting the first BIM data and GIS data, only the data for the minimum outline shape of the building/topography can be transmitted from the modeling server 200 to the user terminal 100.

The graphic interface windows (I, II) provided to the user are not limited to FIGS. 3 and 4, and the user setting that the user can select for 3D modeling is not limited thereto. These user settings may be accumulated as data and stored in the storage unit 150 or the server storage unit 230.

The modeling server 200 includes a server communication unit 210, a server control unit 220, and a server storage unit 230. The server communication unit 210 is a communication means for performing a function of interworking with the user terminal 100 via a wired or wireless communication network, and performs a function of transmitting and receiving various data.

The server storage unit 230 stores various data necessary for driving the modeling server 200. In addition, the server storage unit 230 stores BIM data for modeling a structure virtually, geographic data occupying a location in space, and GIS data processing the attribute data related to the geographic data. Here, the BIM data for structure modeling may be not only a building, but also means for observing, monitoring, and detecting a specific area and a specific object, such as a CCTV or an IOT sensor, as an object of the BIM data. That is, the object 3D modeled in the present invention includes a building and monitoring means for detecting various situations.

In addition, under the control of the server control unit 220, the server storage unit 230 may store user setting contents as data. This user information can be used in various ways. For example, before introducing the operation of the actual smart city, it is possible to measure the user's characteristics, daily life, perspective or perception in multiple ways, and accumulate dictionary information. In addition, the accumulated information can be used as data to verify the effectiveness of the IOT sensors installed in the building.

The server control unit 220 controls the overall function of the modeling server 200, and the BIM data and GIS data corresponding to user settings or user requests among the BIM data and GIS data stored in the server storage unit 230 are user terminals. (100). The server control unit 220 may provide the user terminal 100 with only a minimum amount of data corresponding to a user setting or a user request among a large amount of BIM data and GIS data stored in the server storage unit 230. Through this, 3D modeling of the entire city can be implemented while the amount of data can be drastically reduced, enabling faster and more immediate 3D modeling as well as saving resources.

The server control unit 220 may include a primary 3D modeling module 221 and a secondary 3D modeling module 222.

The primary 3D modeling module 221 generates primary modeling data in response to the primary request transmitted from the user terminal 100 and transmits it to the user terminal 100 through the server communication unit 210. Here, the primary request may be a request for BIM data and GIS data for an outer form such as a building/topography in a certain area around the user terminal 100, which is first transmitted from the user terminal 100. Here, the primary modeling data may be data in which only the outer shape of a building/topography in a certain area around the user terminal 100 is displayed. If the user has set the situation, only the part corresponding to the situation setting may be data that is highlighted with a specific color or the like.

In addition, the secondary 3D modeling module 222 generates secondary modeling data in response to the secondary request transmitted from the user terminal 100 and transmits it to the user terminal 100. The second request is a request transmitted by information additionally input to the input unit 130 after the user checks the 3D modeling information generated using the primary modeling data, and may be a search request for a specific building/topography. For example, it may be a request that a user inputs and transmits to a “shopping mall” in 3D modeling information in which only the outline of a building is displayed. The input method may be performed in various ways, such as text input and voice input.

After receiving the secondary request, the secondary 3D modeling module 222 generates secondary modeling data by mapping the search information transmitted to the primary modeling data and information on a specific building/topography corresponding to the secondary modeling data, and then generates a server communication unit ( 210) to the user terminal 100.

Next, a 3D BIM object modeling method according to an embodiment of the present invention will be described with reference to FIG. 6. 6 is a flowchart illustrating a 3D BIM object modeling method according to an embodiment of the present invention.

First, the user inputs a user setting for implementing 3D modeling through a user interface provided through the output unit 140 of the user terminal. (S10)

The user setting includes BIM data setting for selecting at least one individual BIM data among BIM data, GIS data setting for selecting at least one individual GIS data among GIS data, data limiting the size of BIM data and GIS data to be received from a server. It may include at least one of the size settings.

In addition, it may optionally include setting a situation for a specific situation. Here, the situation setting may include at least one of a CCTV situation, a road traffic light display situation, and a building selection situation defining a specific building.

In addition, BIM and GIS data for a certain area of a building, terrain, etc. are received based on the current location, but only outlines and outlines that indicate building topography are set to be received, so that 3D modeling necessary with minimal data is performed. Can be.

The BIM data setting, GIS data setting, and data size setting may be one type of situation setting, and when there is no setting for them, it may be defaulted so that minimal data is consumed.

When the user inputs the user setting, the user terminal 100 requests (primary request) the primary BIM data and GIS data corresponding to the user setting to the modeling server 200. (S20)

The modeling server 200 receiving the primary request provides primary BIM data and GIS data corresponding to the primary request from the stored BIM data and GIS data to the terminal. (S30)

Next, the 3D modeling unit 160 of the user terminal receiving the primary BIM data and the GIS data performs primary 3D modeling based on the received primary BIM data and GIS data. (S40) At this time, the 3D modeling data primarily performed, as illustrated in FIG. 7, may only display the outline of the building/terrain.

If the user selects and inputs a situation setting, a CCTV situation, a road traffic light display situation, a specific building, etc. may be displayed in a highlighted color. Here, the CCTV, the road traffic light display situation, and the IOT sensor monitoring a specific building are also objects of 3D modeling, so that the user can select a specific CCTV or IOT sensor. When a specific CCTV or IOT sensor is selected, the corresponding CCTV or IOT sensor is activated to output a screen provided by the corresponding CCTV or IOT sensor through the output unit 140 of the user terminal, and the user can view the current situation in real time. Can recognize.

Then, the user inputs search information through the input unit 130 of the user terminal. When search information is input, the 3D modeling unit of the user terminal may highlight at least one or more objects corresponding to the inputted search information, as illustrated by symbols A and B in FIG. 8. (S50) That is, a specific object may be highlighted by a method such as displaying a thick outline of a specific object corresponding to search information, displaying a specific color, or blinking. From this, the user can grasp the location of the object desired by the user at a glance around the current location.

Then, the user selects any one or more of the highlighted at least one specific object, and transmits a secondary request for detailed BIM/GIS data for the selected specific object to the modeling server 200. (S60, S70)

The modeling server 200 that receives the secondary request transmitted from the user terminal 100 transmits secondary BIM/GIS data corresponding to the secondary request to the user terminal 100. (S80)

The secondary BIM/GIS data is detailed BIM/GIS data about the inner and outer shapes of the object. The secondary BIM/GIS data may include not only shape, but also unique information of the corresponding object. For example, when a user searches a shopping mall from the primary modeling data and a plurality of shopping malls are highlighted, and a second shopping request is made by selecting any one of them, the modeling server 200 stores the server 230 ) Extracts unique information about the shopping mall such as CCTV around the shopping mall, as well as inside and outside shapes of the shopping mall, handling goods of the shopping mall, the price of the goods, or, as illustrated in FIG. 9, the user terminal 100 Can be transferred to.

Next, the 3D modeling unit 160 of the user terminal receiving the secondary BIM data and the GIS data performs secondary 3D modeling based on the received secondary BIM data and GIS data. (S40) At this time, the 2D 3D modeling data, the internal and external shapes and unique information of the object selected by the user may be displayed.

From the 2D 3D modeling data, the user can check detailed information about the desired object, the CCTV situation around the object, and the road traffic light display situation.

According to the 3D BIM object modeling server and the 3D BIM object modeling system including the same according to an embodiment of the present invention, it is possible to grasp the user's surroundings at a glance while dramatically reducing the amount of data consumed. In addition, it is possible to obtain detailed information about a specific object desired by the user, thereby improving user convenience.

As described above, one embodiment of the present invention has been described, but those skilled in the art can add, change, delete, or add components within the scope of the present invention as described in the claims. The present invention may be variously modified and changed by the like, and it will be said that this is also included within the scope of the present invention.

100: user terminal
110: control unit 120: communication unit
130: input unit 140: output unit
150: storage unit 160: 3D modeling unit
200: 3D BIM object modeling server

Claims (13)

A server communication unit performing a function of interworking with a user terminal via a wired or wireless communication network;
A server storage unit in which BIM data for virtually modeling a building, geographic data occupying a location in space, and GIS data for processing and processing attribute data related to the geographic data are stored; And,
The primary modeling data is transmitted to the user terminal in response to the primary request, which is a request to transmit BIM data and GIS data for the outer shape of a building or terrain in a predetermined range centered on the user terminal, transmitted from the user terminal. Secondary modeling data for the specific object when a second request for the inner and outer shapes of at least one specific object selected by the user is transmitted from the user terminal that has performed the primary 3D modeling using the primary modeling data. Server control unit transmitting the data to the user terminal
3D BIM object modeling server comprising a.
The method according to claim 1, The server control unit,
A primary 3D modeling module that generates primary modeling data in response to the primary request transmitted from the user terminal;
Secondary 3D modeling module that generates secondary modeling data by mapping response information to the secondary request to the primary modeling data
3D BIM object modeling server comprising a.
delete The method according to claim 1,
The second request is a three-dimensional BIM object modeling server, characterized in that it contains unique information about the specific object.
A communication unit that transmits and receives data to and from a 3D BIM object modeling server via a wired or wireless communication network;
An input unit that receives at least one of a key input, a touch input, a voice input, and a gesture input from a user;
An output unit that outputs an input result of the input unit, a user interface, and 3D modeling data;
After performing primary 3D modeling based on primary modeling data received from the 3D BIM object modeling server, secondary 3D based on secondary modeling data for a specific object received from the 3D BIM object modeling server Includes a 3D modeling unit that performs modeling,
The primary modeling data is data for a primary request transmitted to the 3D BIM object modeling server, and the primary request is a request for transmitting BIM data and GIS data for an outer shape of a building or terrain in a predetermined range. And
The secondary modeling data is data for a secondary request transmitted to the 3D BIM object modeling server, and the secondary request is inside and outside of at least one specific object selected by a user after performing the primary 3D modeling. User terminal, characterized in that the data transmission request for the shape.
The method according to claim 5, The 3D modeling unit,
After performing the primary 3D modeling, when a user's search information is input through the input unit, a user terminal characterized by highlighting at least one specific object corresponding to the input search information.
The method according to claim 6,
When any one or more specific objects among the highlighted at least one specific object is selected, the secondary modeling data for the selected specific object is requested to the 3D BIM object modeling server and received from the 3D BIM object modeling server. A user terminal characterized in that the second 3D modeling is performed based on the second modeling data.
The method according to claim 7,
The secondary modeling data is a user terminal characterized in that it comprises BIM data and GIS data for the inside and outside shape of the specific object, and unique information about the specific object.
A server communication unit that performs a function of interworking with a user terminal through a wired or wireless communication network, BIM data for modeling a building virtually, and GIS data for processing geographic data occupying a spatial location and attribute data related to the geographic data The server storage unit is stored, and the primary response in response to the primary request, which is a request to transmit BIM data and GIS data for the outer shape of a building or terrain within a predetermined range centered on the user terminal, transmitted from the user terminal. Modeling data is transmitted to the user terminal, and when the secondary request for the inner and outer shapes of at least one or more specific objects selected by the user is transmitted from the user terminal performing the primary 3D modeling using the primary modeling data, the specific A 3D BIM object modeling server including a server controller that transmits secondary modeling data for an object to the user terminal; And,
A communication unit that transmits and receives data to and from the 3D BIM object modeling server via a wired or wireless communication network; an input unit that receives at least one of a key input, a touch input, a voice input, and a gesture input from a user; and an input result of the input unit, After performing the first 3D modeling based on the user interface, the output unit for outputting 3D modeling data, and the primary modeling data received from the 3D BIM object modeling server, the 3D BIM object modeling server receives Includes a 3D modeling unit that performs secondary 3D modeling based on secondary modeling data for a specific object,
The primary modeling data is data for the primary request, and the primary request is a request for transmitting BIM data and GIS data for an outer shape of a building or terrain in a predetermined range,
The secondary modeling data is data for the secondary request, and the secondary request is a request for data transmission for internal and external shapes of at least one specific object selected by a user after performing the primary 3D modeling. User terminal
3D BIM object modeling system comprising a.
delete The method according to claim 9, The 3D modeling unit,
After performing the primary 3D modeling, when a user's search information is input through the input unit, a 3D BIM object modeling system characterized by highlighting at least one specific object corresponding to the inputted search information.
The method according to claim 11,
When any one or more specific objects among the highlighted at least one specific object is selected, the secondary modeling data for the selected specific object is requested to the 3D BIM object modeling server and received from the 3D BIM object modeling server. A 3D BIM object modeling system characterized by performing 2D 3D modeling based on 2D modeling data.
The method according to claim 12,
The second modeling data is a 3D BIM object modeling system, characterized in that it comprises BIM data and GIS data for the inner and outer shapes of the specific object, and unique information about the specific object.

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