KR102193975B1 - Method And System For Providing 3D Indoor Space - Google Patents

Abstract

The present invention provides a real-time service of indoor space temperature, humidity, security, and gas safety, while conveniently checking the installation location of the camera device, and 2D images collected through two or more camera devices, and a camera device. It relates to a '3D indoor space service method and system using a cloud that enables real-time check of indoor space' that can service realistic 3D indoor space images through the installation location coordinates.
In the present invention, a temperature sensor 51, a humidity sensor 52, an infrared sensor 53, and a gas measuring sensor 54 installed in the indoor space (S) to install any one or more Step and; A camera device installation step of installing at least two or more camera devices 10 in an indoor space (S); A reference stand installation step of installing the reference stand 10 in the indoor space S so as to be included in the shooting angle of each camera device 10; A reference table photographing step of driving each camera device 10 to photograph the reference table 10; The camera installation position measurement module 33 of the 3D indoor space image production server 30 includes a horizontal distance (d) between the reference table 20 and the camera device 10, and a camera device received from the camera device 10 ( 10) a camera device installation position measuring step of calculating the installation position coordinates of each camera device 10 based on the shooting angle; A reference stage removal step of removing the reference stage 10 installed in the reference stage photographing stage; An indoor space photographing step of photographing an indoor space through the camera device 10 installed in the camera device installation step; The 3D indoor space image production module 34 of the 3D indoor space image production server 30 has a 2D indoor space photographed image from each camera device 10 and each calculated by the camera installation position measurement module 33 A 3D indoor space image production step of producing a 3D indoor space image in which an object in the indoor space S photographed by the camera device 10 is three-dimensionally expressed through the coordinates of the installation position of the camera device 10 of the; In the 3D indoor space image production server 30, receiving sensing data measured by each sensor in the installation step of the indoor space checking device, and transmitting the sensing data or a 3D indoor space image produced in the 3D indoor space image production step. And transmitting sensing data and 3D indoor space image.
In addition, the present invention, the temperature sensor 51 installed in the indoor space (S) to measure the temperature of the indoor space (S), and the humidity installed in the indoor space (S) to measure the humidity of the indoor space (S) The sensor 52, the infrared sensor 53 installed in the indoor space (S) to check the security status in the indoor space (S), and the infrared sensor 53 installed in the indoor space (S) to check the gas in the indoor space (S) An indoor space checking device 50 equipped with one or more of the gas measurement sensors 54 and outputting sensing data of each sensor; and at least two camera devices installed in the indoor space S to enable angle adjustment (10) and: a reference stand (20) installed in the indoor space (S) and located within the shooting angle of each camera device (10), and: receiving sensing data of each sensor from the indoor space checking device (50) And, transmitting the sensing data to the terminal 40, receiving a 2D indoor space shooting image from each camera device 10, and receiving the shooting angle of the camera device 10 from each camera device 10 On the other hand, a transceiver 31 for transmitting a 3D indoor space image stored in the storage DB (32); A storage DB that stores the horizontal distance (d) between the reference table 20 and the camera device 10, a 2D indoor space photographed image from the transceiver 31, and a photographing angle of the camera device 10 from the transceiver 31 ( 32) and; Receives the horizontal distance (d) and the shooting angle of the camera device 10 from the storage DB 32, calculates the installation position coordinates of each camera device 10, and stores the camera installation position in the storage DB 32 Module 33 and; Receives a 2D indoor space shot image from the storage DB 32, receives the installation location coordinates of each camera device 10 from the storage DB 32, and receives a 2D indoor space shot image from each camera device 10 And, the object in the indoor space S photographed by the camera device 10 is three-dimensionally expressed through the installation location coordinates of each camera device 10 calculated by the camera installation location measurement module 33 A 3D indoor space image production server 30 equipped with a 3D indoor space image production module 34 that produces 3D indoor space images and stores the produced 3D indoor space images in a storage DB 32 and: 3D indoor space image production It characterized in that it comprises a terminal 40 for receiving the sensing data and the 3D indoor space image from the transceiver 31 of the server 30.

Description

Cloud-based 3D indoor space service method and system that can check indoor space in real time {Method And System For Providing 3D Indoor Space}

The present invention provides a real-time service of indoor space temperature, humidity, security, and gas safety, while conveniently checking the installation location of the camera device, and 2D images collected through two or more camera devices, and a camera device. It relates to a '3D indoor space service method and system using a cloud capable of real-time confirmation of indoor space' that can service realistic 3D indoor space images through the installation location coordinates of.

General real estate relay sites, as well as various services that provide other indoor structures and shapes, and specialized companies and organizations (hereinafter referred to as'service providers'), take pictures of the indoors directly to check the structure and shape of the room. Provided to users with simple photographed images as shown in 1.

In order to compensate for this, a 3D indoor space image was produced using a lidar device and provided to the user.

However, since the LiDAR device used in the prior art is a relatively expensive device, there is an economic burden for the service provider to lease or purchase it, and the LiDAR device scans the indoor space while moving the interior space and proceeds to scan for each point. Since the current location of the device has to be grasped, the inconvenience and trouble in use were also considerable.

In addition, conventionally, since it is not possible to check the temperature, humidity, security status, etc. in an indoor space of a building in real time, there is a limitation in efficiently providing information according to the indoor space condition of a building.

Republic of Korea Patent Publication No. 10-2013-0123041

The present invention for solving the above problems, while being able to service the indoor space temperature, humidity, security, and gas safety status in real time, conveniently checks the installation location of the camera device, so that two or more camera devices can be used. A solution to providing a '3D indoor space service method and system using a cloud that enables real-time check of indoor space' that can service realistic 3D indoor space images through the 2D images collected through and the coordinates of the installation location of the camera device. Make it the task you want to do.

The means for solving the first task according to the 3D indoor space service method of the present invention for solving the above problems,
An indoor space checking device installation step of installing at least one of a temperature sensor, a humidity sensor, an infrared sensor, and a gas measurement sensor in the indoor space;
A camera device installation step of fixing at least two camera devices to a ceiling edge of an indoor space;
A reference stand installation step of installing a reference stand in an indoor space so as to be included in the shooting angle of each camera device;
A reference table photographing step of driving each camera device to photograph a reference table;
Camera installation position measurement module of the 3D indoor space image production server calculates the installation position coordinates of each camera device based on the horizontal distance between the reference table and the camera device and the shooting angle of the camera device received from the camera device. Measuring the installation position;
A reference base removal step of removing the reference base installed in the reference base photographing step;
An indoor space photographing step of photographing an indoor space through a camera device installed in the camera device installation step;
The 3D indoor space image production module of the 3D indoor space image production server 30 mediates the 2D indoor space photographed image from each camera device and the installation position coordinates of each camera device calculated by the camera installation position measurement module. A 3D indoor space image production step of producing a 3D indoor space image in which an object in the indoor space photographed by a camera device is three-dimensionally expressed;
In the 3D indoor space image production server, sensing data for receiving sensing data measured by each sensor in the indoor space checking device installation step, and transmitting the sensing data or a 3D indoor space image produced in the 3D indoor space image production step, and 3D indoor space image transmission stage
Including,
In the step of installing the reference stand
Each camera device transmits the camera view of the camera device to the 3D indoor space image production server, the display of the 3D indoor space image production server outputs the camera view, and the 3D indoor space image so that the reference stand is located within the camera view. The camera controller of the production server controls the shooting angle of each camera device,
In the indoor space shooting stage,
The shooting angle of each camera device is controlled by the camera controller of the 3D indoor space image production server, and each camera device captures the indoor space.

It is characterized by that.

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In addition, the means for solving the second task according to the 3D indoor space service method of the present invention,
In the step of installing the reference table,
The reference stand is installed while being moved to a plurality of points in the indoor space so as to be located within the shooting angle of at least two or more camera devices,
In the step of measuring the installation position of the camera device,

The camera installation position measurement module calculates the installation position coordinates of the camera device based on the horizontal distance between the moved reference base and the camera device and the camera device shooting angle received from the camera device whenever the reference base is moved. doing

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It features.

In addition, the means for solving the third task according to the 3D indoor space service system of the present invention,
A temperature sensor installed in the indoor space to measure the temperature of the indoor space, a humidity sensor installed in the indoor space to measure the humidity of the indoor space, an infrared sensor installed in the indoor space to check the security status in the indoor space, and indoor An indoor space check device that is equipped with one or more of the gas measurement sensors installed in the space to check the gas in the indoor space and outputs sensing data of each sensor:
At least two camera devices fixedly installed at the ceiling edge of the indoor space to enable angle adjustment, and:
A reference stand that is installed in the indoor space but located within the shooting angle of each camera device:
Receiving the sensing data of each sensor from the indoor space checking device, transmitting the sensing data to the terminal, receiving a 2D indoor space photographed image from each camera device, and receiving the shooting angle of the camera device from each camera device. Meanwhile, a transceiver for transmitting a 3D indoor space image stored in a storage DB; A storage DB for storing a horizontal distance between the reference table and the camera device, a 2D indoor space captured image from the transceiver, and a camera device shooting angle from the transceiver; A camera installation location measurement module for receiving the horizontal distance and the camera device shooting angle from a storage DB, calculating the installation location coordinates of each camera device, and storing it in a storage DB; Receives 2D indoor space shot images from the storage DB, receives the installation location coordinates of each camera device from the storage DB, and receives the 2D indoor space shot images from each camera device, and each calculated by the camera installation location measurement module. Produces a 3D indoor space image in which objects in the indoor space photographed by the camera device are three-dimensionally expressed by means of the coordinates of the installation location of the camera device, and stores the 3D indoor space image in the storage DB. 3D indoor space video production server with production module and:
Terminal receiving the sensing data and the 3D indoor space image from the transceiver of the 3D indoor space image production server
Including,

The 3D indoor space video production server outputs a display that receives and outputs a camera view from a camera device via a transceiver and a camera control signal to the camera device via a transceiver to control the shooting angle of the camera device and to the camera device. It characterized in that it is further equipped with a camera controller to take the picture.

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The present invention can produce a 3D indoor space image even without using an expensive lidar device.

In addition, the present invention installs the reference base 20 so that the reference base 20 is positioned within the shooting angle of at least two or more camera devices 10 without the need for the operator to individually measure the installation position of the camera device 10 By doing so, the installation position of each camera device 10 can be easily measured, and a 3D indoor space can be conveniently manufactured using the camera device 10.

In addition, the present invention uses the reference table 10 when measuring the installation position of the camera device 10, so that when the operator makes each camera device 10 collimate the same point, collimation work is convenient. That is, when a plurality of cover objects (for example, partitions, etc.) exist in the indoor space (S) and it is difficult for the camera device 10 to collimate the same point, the collimation operation can be conveniently performed through the reference table 10. .

In addition, in the present invention, when producing a 3D indoor space image for an indoor space (S) having a complex structure, a plurality of camera devices 10 are installed. In this case, each camera device ( Since the installation location of 10) can be easily measured, it is possible to easily produce a 3D indoor space image for a complex structured indoor space (S).

In addition, in the present invention, when it is found that there is a problem in the installation of the reference table 20 after the first installation of the reference table 20, the operator controls the shooting angle of the camera apparatus 10, While checking the reference base 20 through the camera view, the reference base 20 can be adjusted to be positioned within the shooting angle of each camera device 10, so even if there is a problem with the initial installation of the reference base 20, it is not restricted. You can continue to produce 3D indoor space video without it.

The present invention can produce an excellent 3D indoor space image while reducing cost. Therefore, when the present invention is applied to a room introduction such as real estate, it is possible to provide a structure, interior, etc. of a room close to the actual appearance to consumers at low cost.

In addition, the present invention allows the user of the terminal 40 or the administrator of the 3D indoor space image production server 30 to check the status (temperature, humidity, security, gas safety, etc.) of the indoor space (S) in real time. Information on the indoor space (S) can be efficiently guided, and management of the indoor space (S) of a building can be efficiently performed.

In particular, according to the present invention, the temperature, humidity, and gas safety status of the indoor space (S) that the user wants to see can be known in real time, thereby improving the safety reliability of the indoor space (S).

1 is a view for explaining the prior art,
2 is a system configuration diagram for explaining the present invention,
3 is a perspective view showing the camera device of the present invention,
4 is a partial plan view showing the installation state of the reference stand and the camera device in the present invention,
5 is a partial front cross-sectional view showing an installation state of a reference stand and a camera device in the present invention,
6 to 10 are diagrams for explaining the operation (method) of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the present invention with respect to the present invention.

2 is a system configuration diagram for explaining the present invention, FIG. 3 is a perspective view showing a camera device of the present invention, and FIG. 4 is a partial plan view showing an installation state of a reference stand and a camera device in the present invention. , FIG. 5 is a partial front cross-sectional view showing an installation state of a reference stand and a camera device in the present invention, and a configuration of a 3D indoor space service system according to the present invention will be described with reference to FIGS. 2 to 5.

The 3D indoor space service system according to the present invention includes an indoor space checking device 50, a camera device 10, a reference table 20, a 3D indoor space image production server 30, and a terminal 40. do.

The indoor space checking device 50 includes a temperature sensor 51 installed in the indoor space S to measure the temperature of the indoor space S, and the indoor space S, which is installed in the indoor space S to measure the humidity of the indoor space S. The humidity sensor 52 to measure, the infrared sensor 53 installed in the indoor space (S) to check the security status in the indoor space (S), and the gas in the indoor space (S) installed in the indoor space (S) Equipped with any one or more of the gas measurement sensor 54 to check, and outputs the sensing data of each sensor. In this embodiment, the indoor space checking device 50 is illustrated as having both a temperature sensor 51, a humidity sensor 52, an infrared ray 53, and a gas measurement sensor 54. Meanwhile, in the present embodiment, the four sensors are provided, but various sensors for monitoring the state of the indoor space S may be further provided. In addition, in the present embodiment, the installation positions of each sensor may be installed in various positions of the indoor space (S). In this embodiment, the infrared sensor 53 is installed in the camera device 10, but the function of the infrared sensor 53 may be mounted in the camera device 10. In addition, in this embodiment, the gas measurement sensor 54 can measure oxygen, carbon monoxide, carbon dioxide, and the like.

The camera device 10 is installed in the indoor space S so that the angle can be adjusted. In this embodiment, at least two camera devices 10 are provided. Meanwhile, in the present embodiment, the camera device 10 has six camera devices 10; 10a to 10f installed in the indoor space S as shown in FIG. 3.

Here, in this embodiment, the camera device 10 includes a camera 11 and a first hanger 12 for rotatably supporting the camera 11, and the camera 11 is rotated on the first hanger 12 The first drive motor 13 is driven to rotate, the second hanger 14 rotatably supporting the first hanger 12, and the first hanger 12 is driven to rotate from the second hanger 14. It includes a second driving motor 15 and a rotation angle sensor 16 for sensing rotation angles of the camera 11 and the first hanger 12, respectively. In this embodiment, the camera device 10 is installed on the upper wall of the indoor space S via the bracket 17.

On the other hand, in the camera device 10 of the present embodiment, the first hanger 12 is installed so that the camera 11 rotates vertically, and the second hanger 14 is installed so that the first hanger 12 rotates horizontally, Conversely, the design may be changed so that the first hanger 12 rotates the camera 11 horizontally, and the second hanger 14 rotates the first hanger 12 vertically.

The reference stand 20 is installed in the indoor space (S), but is installed to be located within the shooting angle of each camera device (10). In the present embodiment, the reference table 20 has a pole shape, but the shape may be variously modified.

The 3D indoor space image production server 30 is equipped with a transceiver 31, a storage DB 32, a camera position measurement module 33, and a 3D indoor space image production module 34.

The transceiver 31 receives sensing data of each sensor from the indoor space checking device 50, transmits the sensing data to the terminal 40, and receives a 2D indoor space photographed image from each camera device 10. And, while receiving the shooting angle of the camera device 10 from each of the camera device 10, while transmitting the 3D indoor space image stored in the storage DB (32). Meanwhile, in the present embodiment, communication in the transceiver 31 may be wired or wireless.

The storage DB 32 includes a horizontal distance d between the reference table 20 and the camera device 10, a 2D indoor space photographed image from the transceiver 31, and the camera device 10 from the transceiver 31. Save the shooting angle. Here, the horizontal distance (d) is measured in advance and stored in the storage DB (32). In addition, in the present embodiment, the storage DB 32 may store sensing data of each sensor from the indoor space checking device 50. Meanwhile, in this embodiment, the storage DB 32 may store data in a cloud manner.

The camera installation location measurement module 33 receives the horizontal distance (d) and the shooting angle of the camera device 10 from the storage DB 32, calculates the installation location coordinates of each camera device 10, and stores the DB Save it to (32).

The 3D indoor space image production module 34 receives a 2D indoor space photographed image from the storage DB 32, receives the installation position coordinates of each camera device 10 from the storage DB 32, and receives each camera. The indoor space photographed by the camera device 10 through the 2D indoor space photographed image from the device 10 and the installation position coordinates of each camera device 10 calculated by the camera installation position measurement module 33 A 3D indoor space image in which an object in the space S is expressed in three dimensions is produced, and the produced 3D indoor space image is stored in the storage DB 32.

In this embodiment, the 3D indoor space image production module 34 receives a plurality of 2D indoor space photographed images from the storage DB 32, finds matching points between the 2D indoor space photographed images, and matches the 2D indoor space photographed images. (Connect) and produce a 3D indoor space image having a three-dimensional effect by analyzing the relationship between objects in the 2D indoor space photographed image. At this time, the 3D indoor space image production module 34 includes the installation location of the camera device 10, the relationship of the installation location between each camera device 10, and the shooting angle of the corresponding camera device 10 that has captured a 2D indoor space image. Through this, 3D indoor space images are produced.

Meanwhile, in the present embodiment, the 3D indoor space image production server 30 receives and outputs a camera view from the camera device 10 via the transceiver 31 and the transceiver 31 A camera controller 36 is further provided to output a camera control signal to the camera device 10 to control the shooting angle of the camera device 10.

The terminal 40 receives and outputs the sensing data and the 3D indoor space image from the transceiver 31 of the 3D indoor space image production server 30. In this embodiment, the terminal 40 may be formed of a terminal such as a smartphone, a tablet PC, or a computer.

6 is a flowchart illustrating a 3D indoor space service method according to the present invention, FIGS. 7 and 8 are diagrams for explaining movement of a reference stand installation position in the 3D indoor space service method according to the present invention, and FIG. 9 An image showing a 3D indoor space image produced according to the 3D indoor space service method according to the present invention as an example, and FIG. 10 is a view showing the checking of sensing data through a terminal in the 3D indoor space service method according to the present invention. A 3D indoor space service method according to the present invention will be described with reference to FIGS. 6 to 10 as follows.

The operator installs an indoor space checking device 50 composed of a temperature sensor 51, a humidity sensor 52, an infrared sensor 53 and a gas measurement sensor 54 in the indoor space (S) as shown in FIG. do.

And, the operator installs at least two or more camera devices 10 in the indoor space (S) as shown in FIG. In this embodiment, as shown in FIG. 4, six camera devices 10 (10a to 10f) are installed in the indoor space (S) as shown in FIG. 4.

Thereafter, the operator installs the reference stand 10 in the indoor space S so as to be included in the shooting angle of the camera devices 10a, 10b, and 10c as shown in FIG. 7.

At this time, the operator checks the camera views of each of the camera devices 10a, 10b, 10c through the display 35 of the 3D indoor space image production server 30, and checks whether the reference table 10 is located in the camera view. I can confirm. In addition, the operator adjusts the shooting angle of the camera devices 10a, 10b, 10c or adjusts the shooting angle of the camera devices 10a, 10b, 10c when the reference base 10 does not clearly enter the camera view of all three camera devices 10a, 10b, and 10c. By adjusting the installation position of 20), the reference stand 20 can be installed in the camera view of all of the camera devices 10a, 10b, and 10c.

And, the operator measures each horizontal distance (d) between the reference table 20 and the camera devices (10a, 10b, 10c) and stores it in the storage DB (32) of the 3D indoor space image production server (30). . In this embodiment, the operator may measure the horizontal distance (d) through a laser distance meter or a tape measure.

When the reference table 20 is installed in this way, the operator drives the camera devices 10a, 10b, and 10c to take a picture of the reference table 10.

Then, the camera installation position measurement module 33 of the 3D indoor space image production server 30, each horizontal distance (d) between the reference base 20 and the camera devices (10a, 10b, 10c), the camera device ( The installation position coordinates of each camera device 10 are calculated based on the shooting angles of the camera devices 10a, 10b, and 10c received from 10).

Thereafter, the operator removes the reference table 10 and installs the reference table 20 at another location of the indoor space S as shown in FIG. 8. Then, the operator measures the installation position of the camera device 10d by analyzing the relationship between the camera devices 10c and 10d by the above method.

Meanwhile, the operator continuously moves the reference table 20 and measures the installation positions of the remaining camera devices 10e and 10f in the same manner as described above.

In this way, when the installation positions of each of the camera devices 10a to 10f are measured, the operator controls each of the camera devices 10a to 10f to take a picture of the indoor space (S).

And, when the shooting work of the indoor space (S) is completed, the 3D indoor space image production module 34 of the 3D indoor space image production server 30, 2D indoor space shooting from each of the camera devices 10a-10f. Using the image and the installation location coordinates of each of the camera devices 10a to 10f calculated by the camera installation location measurement module 33, while producing a 3D indoor space image, 3D objects in the 3D indoor space image have a three-dimensional effect. Produce indoor space video.

The 3D indoor space image produced in this way is stored in the storage DB 32 of the 3D indoor space image production server 30.

On the other hand, the user who owns the terminal 40 passes through an authentication procedure (for example, log in) to view the 3D indoor space image stored in the storage DB 32 of the 3D indoor space image production server 30 as shown in FIG. I can confirm.

In other words, the user with the terminal 40 outputs the 3D indoor space image of the building to be viewed on the terminal 40 through the input means and output means of the terminal 40, and sees the interior of the building to be viewed as if I can.

In addition, in this embodiment, sensing data from each sensor of the indoor space checking device 50 is transmitted to the 3D indoor space image production server 30, and the 3D indoor space image production server 30 stores the sensing data. Stored in 32 or transmitted to terminal 40 in real time.

At this time, the sensing data stored in the storage DB 32 of the 3D indoor space image production server 30 can be used to check the change in sensing data of the indoor space S. (For example, the change of sensing data is graphed. Check through)

On the other hand, the user of the terminal 40 connects to the 3D indoor space image production server 30 through the terminal 40 (access through login), and then enters the 3D indoor space image production server 30 to a certain indoor space (S). Upon requesting sensing data information for, the 3D indoor space image production server 30 transmits the sensing data for the indoor space S to the terminal 40. In this embodiment, the sensing data transmitted to the terminal 40 is preferably temperature, humidity, and gas information of the indoor space (S). At this time, the user of the terminal 40 may receive a 3D indoor space image of the same indoor space S and the sensing data together as shown in FIG. 10 through the terminal 40.

In addition, in the present embodiment, when the administrator finds that a problem has occurred in the security of the indoor space (S) through the 3D indoor space image production server 30, the administrator is the camera controller 36 of the 3D indoor space image production server 30. By controlling the camera device 10 through ), it is possible to carefully examine the indoor space (S), so that it is possible to quickly cope with the occurrence of a security problem in the indoor space (S).

The present invention as described above can produce a 3D indoor space image even without using an expensive lidar device.

In addition, the present invention installs the reference base 20 so that the reference base 20 is positioned within the shooting angle of at least two or more camera devices 10 without the need for the operator to individually measure the installation position of the camera device 10 By doing so, the installation position of each camera device 10 can be easily measured, and a 3D indoor space can be conveniently manufactured using the camera device 10.

In addition, the present invention uses the reference table 10 when measuring the installation position of the camera device 10, so that when the operator makes each camera device 10 collimate the same point, collimation work is convenient. That is, when a plurality of cover objects (for example, partitions, etc.) exist in the indoor space (S) and it is difficult for the camera device 10 to collimate the same point, the collimation operation can be conveniently performed through the reference table 10. .

In addition, in the present invention, when producing a 3D indoor space image for an indoor space (S) having a complex structure, a plurality of camera devices 10 are installed. In this case, each camera device ( Since the installation location of 10) can be easily measured, it is possible to easily produce a 3D indoor space image for a complex structured indoor space (S).

In addition, in the present invention, when it is found that there is a problem in the installation of the reference table 20 after the first installation of the reference table 20, the operator controls the shooting angle of the camera apparatus 10, While checking the reference base 20 through the camera view, the reference base 20 can be adjusted to be positioned within the shooting angle of each camera device 10, so even if there is a problem with the initial installation of the reference base 20, it is not restricted. You can continue to produce 3D indoor space video without it.

The present invention can produce an excellent 3D indoor space image while reducing cost. Therefore, when the present invention is applied to a room introduction such as real estate, it is possible to provide a structure, interior, etc. of a room close to the actual appearance to consumers at low cost.

In addition, the present invention allows the user of the terminal 40 or the administrator of the 3D indoor space image production server 30 to check the status (temperature, humidity, security, gas safety, etc.) of the indoor space (S) in real time. Information on the indoor space (S) can be efficiently guided, and management of the indoor space (S) of a building can be efficiently performed.

In particular, according to the present invention, the temperature, humidity, and gas safety status of the indoor space (S) that the user wants to see can be known in real time, thereby improving the safety reliability of the indoor space (S).

On the other hand, specific examples of the embodiments of the present invention are for explaining the present invention, and are not limited thereto, and various modifications can be made within the scope of the claims and the detailed description of the invention, and this It is natural to fall within the scope of the invention.

10; Camera device 11; camera
12; First hanger 13; 1st drive motor
14; Second hanger 15; 2nd drive motor
16; Rotation angle sensor 17; Brackets
20; Reference zone 30; 3D indoor space video production server
31; Transceiver 32; Storage DB
33; Camera installation position measurement module 34; 3D indoor space image production module
35; Display 36; Camera controller
40; Terminal 50; Indoor space check device
51; Temperature sensor 52; Humidity sensor
53; Infrared sensor 54; Gas measurement sensor
S; Indoor space

Claims (5)

An indoor space checking device installation step of installing at least one of a temperature sensor, a humidity sensor, an infrared sensor, and a gas measurement sensor in the indoor space;
A camera device installation step of fixing at least two camera devices to a ceiling edge of an indoor space;
A reference stand installation step of installing a reference stand in an indoor space so as to be included in the shooting angle of each camera device;
A reference table photographing step of driving each camera device to photograph a reference table;
Camera installation position measurement module of the 3D indoor space image production server calculates the installation position coordinates of each camera device based on the horizontal distance between the reference table and the camera device and the shooting angle of the camera device received from the camera device. Measuring the installation position;
A reference base removal step of removing the reference base installed in the reference base photographing step;
An indoor space photographing step of photographing an indoor space through a camera device installed in the camera device installation step;
The 3D indoor space image production module of the 3D indoor space image production server 30 mediates the 2D indoor space photographed image from each camera device and the installation position coordinates of each camera device calculated by the camera installation position measurement module. A 3D indoor space image production step of producing a 3D indoor space image in which an object in the indoor space photographed by a camera device is three-dimensionally expressed;
In the 3D indoor space image production server, sensing data for receiving sensing data measured by each sensor in the indoor space checking device installation step, and transmitting the sensing data or a 3D indoor space image produced in the 3D indoor space image production step, and 3D indoor space image transmission stage
Including,
In the step of installing the reference stand
Each camera device transmits the camera view of the camera device to the 3D indoor space image production server, the display of the 3D indoor space image production server outputs the camera view, and the 3D indoor space image so that the reference stand is located within the camera view. The camera controller of the production server controls the shooting angle of each camera device,
In the indoor space shooting stage,
The shooting angle of each camera device is controlled by the camera controller of the 3D indoor space image production server, and each camera device captures the indoor space.
3D indoor space service method, characterized in that.
The method of claim 1,
In the step of installing the reference table,
The reference stand is installed while being moved to a plurality of points in the indoor space so as to be located within the shooting angle of at least two or more camera devices,
In the step of measuring the installation position of the camera device,
The camera installation position measurement module calculates the installation position coordinates of the camera device based on the horizontal distance between the moved reference base and the camera device and the camera device shooting angle received from the camera device whenever the reference base is moved. doing
3D indoor space service method, characterized in that.
A temperature sensor installed in the indoor space to measure the temperature of the indoor space, a humidity sensor installed in the indoor space to measure the humidity of the indoor space, an infrared sensor installed in the indoor space to check the security status in the indoor space, and indoor An indoor space check device that is equipped with one or more of the gas measurement sensors installed in the space to check the gas in the indoor space and outputs sensing data of each sensor:
At least two camera devices fixedly installed at the ceiling edge of the indoor space to enable angle adjustment, and:
A reference stand that is installed in the indoor space but located within the shooting angle of each camera device:
Receiving the sensing data of each sensor from the indoor space checking device, transmitting the sensing data to the terminal, receiving a 2D indoor space photographed image from each camera device, and receiving the shooting angle of the camera device from each camera device. Meanwhile, a transceiver for transmitting a 3D indoor space image stored in a storage DB; A storage DB for storing a horizontal distance between the reference table and the camera device, a 2D indoor space captured image from the transceiver, and a camera device shooting angle from the transceiver; A camera installation location measurement module for receiving the horizontal distance and the camera device shooting angle from a storage DB, calculating the installation location coordinates of each camera device, and storing it in a storage DB; Receives 2D indoor space shot images from the storage DB, receives the installation location coordinates of each camera device from the storage DB, and receives the 2D indoor space shot images from each camera device, and each calculated by the camera installation location measurement module. Produces a 3D indoor space image in which objects in the indoor space photographed by the camera device are three-dimensionally expressed by means of the coordinates of the installation location of the camera device, and stores the 3D indoor space image in the storage DB. 3D indoor space video production server with production module and:
Terminal receiving the sensing data and the 3D indoor space image from the transceiver of the 3D indoor space image production server
Including,
The 3D indoor space video production server outputs a display that receives and outputs a camera view from a camera device via a transceiver and a camera control signal to the camera device via a transceiver to control the shooting angle of the camera device and to the camera device. 3D indoor space service system, characterized in that further equipped with a camera controller that allows the shooting to take place. delete delete

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