KR101420055B1 - Illuminance simulation system for indoor environment and illuminance simulating method - Google Patents

Abstract

The disclosed technique relates to an indoor illumination simulation system and a method thereof. In the indoor illumination simulation system according to the disclosed technology, a space to be analyzed is defined through a sensor, and spatial information about a defined space and additional information about the space are inputted And transmitting the analyzed result to the analysis server, receiving the illumination analysis result from the analysis server and displaying the received illumination analysis result on a screen, and analyzing the illuminance of the corresponding space based on the spatial information and the additional information received from the mobile terminal, To the terminal.

Description

TECHNICAL FIELD The present invention relates to an indoor illumination simulation system and an indoor illumination simulation system,

The present invention relates to an indoor illumination simulation system and a method thereof, and more particularly, to an indoor illumination simulation system which can simulate illumination of a room based on information measured through a portable terminal such as a smart phone, And a method thereof.

As the quality of life improves, the demand for a pleasant environment is increasing. Especially, as the time for people to stay indoors is getting longer, the demand for the indoor environment such as the residential environment and the working environment is greatly increasing. This is reflected in the design and construction of buildings such as houses and buildings.

Temperature, airflow, thermal comfort, air quality, light, etc. can be considered as conditions for a pleasant environment of the room. Among these, light has been an important factor in the design, construction, and management of buildings from the past as a factor affecting residents' mood and work efficiency.

Prior to the design, construction, and management of a building, the illumination can be simulated to determine the light environment of the interior space of the building. According to the simulation results, the light environment of the indoor space in the building can be predicted in advance, and the prediction result can be used for designing, construction, and management.

As an example of a technique for confirming the light environment, there are disclosed techniques for measuring the illuminance of the LED illumination, as described in Korean Patent Laid-Open Publication No. 10-2012-0014273 (2012.02.17) 'Method of measuring illuminance of LED illumination' .

However, the conventional art requires a separate measuring means, which has a problem in that the versatility of the system is poor.

Korean Patent Publication No. 10-2012-0014273, Feb. 17, 2012

The indoor illumination simulation system and method according to the disclosed technology can provide information to a user by simulating the illuminance of a room based on information measured using a mobile terminal having a sensor such as a smart phone or a tablet PC.

Also, the indoor illumination simulation system and method according to the disclosed technology can control the heating / cooling system or household appliances in connection with the energy simulation system of the building, the network system of the building, and the like.

Also, the indoor illumination simulation system and method according to the disclosed technology can not only grasp the current illumination condition through the simulation result, but also predict the indoor illumination.

For example, based on the simulation result, the simulation result time information, the predetermined rate of change in illuminance per time, etc., it is possible to grasp the illuminance amount (particularly, the amount of sunlight) at a specific time in the user's peripheral area. Simulation results can also be used to predict the change in illuminance for one year (365 days x 24 hours) based on the simulation results, the simulation result time information, and the predetermined annual illumination change rate. It can suggest seat layout or furniture layout that can feel the most comfortable light environment of office resident one year, and can be applied to other applications related to indoor light. For example, it can help determine how much glare is caused by sunlight, or about the health problems that can occur due to sunlight (such as the occurrence of overdose skin, undercurrent vitamins production, etc.) .

The indoor illumination simulation system according to the disclosed technique defines a space to be analyzed through a sensor, receives spatial information about the defined space and additional information about the space, transmits the input information to the analysis server, receives the illumination analysis result from the analysis server And an analysis server for analyzing illuminance of the space based on the spatial information and the additional information received from the mobile terminal and transmitting the analyzed result to the mobile terminal.

The mobile terminal selects one of a two-dimensional spatial analysis mode and a three-dimensional spatial analysis mode, and defines an analysis target space according to the selected mode.

When the two-dimensional spatial analysis mode is selected, the mobile terminal photographs the space to be analyzed through the camera, receives the reference point from the photographed photograph, measures the illuminance value of the selected reference point, And the illuminance value of the reference point to the analysis server.

When the 3D spatial analysis mode is selected, the mobile terminal measures the 3D analysis target space through the sensor, measures the window position and the window space structure within the measured analysis target space, receives the surface information, The target space structure, the window position, the window space structure, and the surface information to the analysis server.

In addition, the mobile terminal receives the type of the lighting device, the position of the lighting device, and the brightness of the lighting device in the analysis target space, the type of the lighting device, the position of the lighting device, send.

The analysis server provides a two-dimensional roughness plot or a three-dimensional roughness grid as an analysis result.

According to the disclosed indoor illumination simulation method, the mobile terminal selects one of a two-dimensional spatial analysis mode and a three-dimensional spatial analysis mode. In accordance with the selected mode, the mobile terminal defines a target space through a sensor, The mobile terminal transmits the spatial information and the additional information about the space to the analysis server. The analysis server analyzes the spatial information and the supplementary information received from the mobile terminal, Analyzing the illuminance of the space based on the analysis result, transmitting the analyzed result to the mobile terminal, and displaying the received illuminance analysis result on a screen.

A step of receiving an analysis target space by photographing an analysis target space through a camera when the two-dimensional spatial analysis mode is selected, and receiving a reference point from the photographed photograph and measuring and inputting a selected illumination intensity of the reference point The photographed photograph, the position information of the reference point, and the illuminance value of the reference point.

Measuring a three-dimensional analysis target space through a sensor when the three-dimensional spatial analysis mode is selected, measuring a window position and a window space structure in the measured analysis target space, and inputting surface information about the analysis target space Receiving the three-dimensional analysis target space structure, the window position, the window space structure, and the surface information to the analysis server.

As described above, the indoor illumination simulation system and method according to the disclosed technology simulate the illuminance of a room based on information measured using a mobile terminal having a sensor such as a smart phone or a tablet PC, . For example, the indoor illumination simulation system and method according to the disclosed technology may use an illumination sensor connected to a smartphone or a tablet PC, or a light intensity sensor or a camera basically provided in a smartphone or a tablet PC.

In addition, the indoor illumination simulation system and method according to the disclosed technology can provide information that can reduce energy of a building in connection with an energy simulation system of a building and the like.

In addition, the indoor illumination simulation system and method according to the disclosed technology may control the heating / cooling system or household appliances in connection with the network system of the building.

Also, the indoor illumination simulation system and method according to the disclosed technology can not only grasp the current illumination condition through the simulation result, but also predict the indoor illumination.

For example, based on the simulation result, the simulation result time information, the predetermined rate of change in illuminance per time, etc., it is possible to grasp the illuminance amount (particularly, the amount of sunlight) at a specific time in the user's peripheral area. Simulation results can also be used to predict the change in illuminance for one year (365 days x 24 hours) based on the simulation results, the simulation result time information, and the predetermined annual illumination change rate. It can suggest seat layout or furniture layout that can feel the most comfortable light environment of office resident one year, and can be applied to other applications related to indoor light. For example, it can help determine how much glare is caused by sunlight, or about the health problems that can occur due to sunlight (such as the occurrence of overdose skin, undercurrent vitamins production, etc.) .

In addition, the indoor illumination simulation system and method according to the disclosed technology can predict the light environment habit of each individual by using a mobile terminal that is usually carried and can help improve the individual light environment.

1 is a schematic view illustrating an application installation process according to the disclosed technology.
2 is a block diagram for explaining a two-dimensional spatial analysis mode in the indoor illumination simulation system according to the disclosed technique.
3 is a view for explaining a process of photographing a two-dimensional analysis target space and selecting a reference point.
4 is a view for explaining the display of the analysis result of the two-dimensional spatial analysis mode.
FIG. 5 is a diagram for explaining a three-dimensional spatial analysis mode in the indoor illumination simulation system according to the disclosed technology.
6 is a view for explaining a process of measuring a spatial structure of a space to be analyzed in the three-dimensional spatial analysis mode.
7 is a view for explaining a process of measuring the height of a space to be analyzed in the three-dimensional spatial analysis mode.
8 is a view for explaining a process of measuring a window position and a window space structure in a three-dimensional spatial analysis mode.
9 is a view for explaining the display of the analysis result of the three-dimensional spatial analysis mode.
10 is a flowchart for explaining an indoor illumination simulation method according to the disclosed technique.
11 is a flowchart specifically illustrating a two-dimensional spatial analysis mode in the indoor illumination simulation method of FIG.
12 is a flowchart specifically illustrating a three-dimensional spatial analysis mode in the indoor illumination simulation method of FIG.

The description of embodiments of the disclosed technique is merely illustrative for the structural and functional explanations of the disclosed technology, and thus the scope of the disclosed technology should not be construed as limited by the embodiments described herein. In other words, it should be understood that the embodiments of the disclosed technology are capable of various changes and various forms, and therefore, are capable of implementing the technical idea of the disclosed technology.

It is to be understood that the singular forms "a", "an", ",", "an", "an" , Parts or combinations thereof, and does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof .

Each step described in the disclosed technique may take place differently from the stated order unless explicitly stated in the context of the specific order. That is, each step may occur in the same order as described, may be performed substantially concurrently, or may be performed in reverse order.

Hereinafter, the pattern matching system and the pattern matching method of the network security apparatus according to the present invention will be described in detail.

1 is a schematic view illustrating an application installation process according to the disclosed technology.

Referring to FIG. 1, a mobile terminal 110 accesses a server 140 through a network 130, and downloads and installs an application from the server 140. The installed application 120 can be displayed on the screen of the mobile terminal.

The mobile terminal 110 may connect to the network 130 via a mobile communication network (e.g., 3G, 4G network) or a local area network (e.g., WLAN, Wifi, For example, the mobile terminal 110 may include a smart phone, a tablet PC, a PDA, and the like.

The server 140 includes an application storage server provided by a communication company, an application service company, a terminal manufacturer, or the like. The application creator can register the application to be distributed in the server 140 and provide it to the user. In one embodiment, the administrator of the server 140 may determine whether to register the application through a predetermined review.

The indoor illumination simulation system according to the disclosed technique can be implemented through a mobile terminal equipped with an indoor illumination simulation application. Therefore, the user downloads the indoor illumination simulation application registered in advance in the server 140 and installs the indoor illumination simulation application in the mobile terminal 110. [ The user can run the indoor illumination simulation installed in the mobile terminal 110 to drive the simulation system.

When the indoor illumination simulation is performed, the mobile terminal 110 provides a plurality of analysis modes and performs analysis according to the selected analysis mode. For example, the mobile terminal 110 may provide a two-dimensional spatial analysis mode for analyzing the roughness of the two-dimensional space and a three-dimensional spatial analysis mode for analyzing the roughness of the three-dimensional space.

The user can select one of the two-dimensional spatial analysis mode and the three-dimensional spatial analysis mode, and collect information for spatial analysis according to the sequence of application guidance.

By using the mobile terminal 110, which is owned by many users, in the indoor illumination simulation system, the accessibility of the system can be enhanced and the user can save the system implementation cost since the user does not have to purchase any additional equipment.

2 is a block diagram for explaining a two-dimensional spatial analysis mode in the indoor illumination simulation system according to the disclosed technique.

2, the indoor illumination simulation system includes a mobile terminal 230 and an analysis server 250, and the mobile terminal 230 and the analysis server 250 can be connected through a network 240. [ The building 210 to be subjected to roughness analysis may have a window 220.

The mobile terminal 230 defines an analysis object space through the provided sensors, receives spatial information about the defined space and additional information about the space, and transmits the spatial information to the analysis server 250. The analysis result is received from the analysis server 250 and displayed on the screen.

The mobile terminal 230 may connect to the network 240 via a mobile communication network or a local area network.

The analysis server 250 analyzes the illuminance of the space based on the spatial information and the additional information received from the mobile terminal 230 and transmits the analyzed result to the mobile terminal 230.

Hereinafter, the operation when the user selects the two-dimensional spatial analysis mode will be described with reference to FIG.

When the indoor illumination simulation application installed in the mobile terminal 230 is executed and the two-dimensional spatial analysis mode is selected, the mobile terminal 230 defines a two-dimensional analysis target space, As shown in Fig.

In one embodiment, when the two-dimensional spatial analysis mode is selected, the application of the mobile terminal 230 prepares to photograph the analysis target space by operating the camera with guidance that the analysis target space is photographed.

The user can move the mobile terminal 230 and take a picture of the analysis target space. When the user takes a picture of the space to be analyzed, the application of the mobile terminal 230 displays the photographed image and receives confirmation of the photographed area from the user. When the user cancels the confirmation, the application of the mobile terminal 230 operates the camera again and prepares to photograph the analysis target space. When the user confirms the photographed area, the application of the mobile terminal 230 defines the photographed area as the analysis target space and stores the corresponding image.

3 is a view for explaining a process of photographing a two-dimensional analysis target space and selecting a reference point.

When the space to be analyzed is determined, the application of the mobile terminal 230 displays the corresponding image on the screen and receives the reference point from the user. When the user selects a reference point in the image displayed on the screen, the application of the mobile terminal 230 stores the location information of the corresponding point. For example, the application of the mobile terminal 230 may store the position of the point with respect to the axis with the horizontal axis of the image as the X axis and the vertical axis as the Y axis. The application of the mobile terminal 230 may re-select the reference point through user's confirmation.

After storing the location information, the application of the mobile terminal 230 measures the illumination value for the corresponding reference point. In one embodiment, the application of the mobile terminal 230 may direct the user to locate the mobile terminal 230 in the actual space corresponding to the reference point. When the user places the mobile terminal 230 in the actual space corresponding to the reference point, the application of the mobile terminal 230 can operate the illuminance sensor and measure the illuminance value at the corresponding position. The application of the mobile terminal 230 may relocate the mobile terminal 230 and measure the illuminance value through confirmation of the user.

In one embodiment, the application of the mobile terminal 230 may measure the illuminance through an illuminance sensor connected to the mobile terminal 230, or may be illuminated through a screen brightness adjustment sensor or camera built in the mobile terminal 230, May be measured. For example, the illuminance at a specific time can be measured based on the brightness value obtained through the screen brightness adjustment sensor or the camera.

In one embodiment, the application of the mobile terminal 230 may receive the illumination value of the pre-measured reference point directly from the user through other means. In this case, the user can directly input the illuminance value value through the key input means of the terminal.

When the space to be analyzed and the additional information are determined, the application of the mobile terminal 230 transmits the information to the analysis server 250. For example, the application of the mobile terminal 230 may transmit the image of the analysis target space, the reference point location information, and the illumination value to the analysis server 250.

The analysis server 250 analyzes the illuminance of the corresponding space based on the spatial information and the additional information received from the mobile terminal 230.

The analysis server 250 may analyze the illuminance at each point in the image based on the received image, the location of the reference point in the image, and the illuminance value of the reference point. The analysis server 250 can analyze the illuminance in units of pixels of the image. In one embodiment, the analysis server 250 may compare the pixel value of the reference point with the pixel value of another pixel to estimate the illuminance, and estimate the illuminance of another pixel according to the ratio of the pixel value. For example, the roughness value of another pixel can be estimated by multiplying the roughness value of the reference point by a linear value or a nonlinear value according to the ratio of the pixel value based on the ratio of the pixel value and the roughness value of the reference point. However, the analysis algorithm may be different for the implementation system, and the analysis server 250 may update the analysis algorithm or change it to another algorithm. In one embodiment, if the analysis algorithm is changed, the analysis server 250 may request the mobile terminal for other information needed for the analysis algorithm.

The analysis server 250 estimates the illuminance value for each pixel in the image and generates an illuminance plot of the image based on the estimated value. For example, the analysis server 250 may generate a plot showing each pixel of the image in a color corresponding to the illumination value. In addition, the analysis server 250 may generate statistical values such as an illuminance value average, a minimum value, and a maximum value based on illuminance values of respective pixels.

The analysis server 250 transmits the analyzed result to the mobile terminal 230. For example, the analysis server 250 may transmit the illumination plot file and statistics values to the mobile terminal 230.

4 is a view for explaining the display of the analysis result of the two-dimensional spatial analysis mode.

The application of the mobile terminal 230 may display the received illuminance plots and statistical values on the screen and provide them to the user. In another embodiment, the analysis server 250 sends the illumination values and statistics of each pixel of the image to the mobile terminal 230, and the application of the mobile terminal 230 generates an illumination plot based on the received result information You may.

In one embodiment, the application of the mobile terminal 230 may augment all or a portion of the received illumination plot to a previously captured image and display it on the screen. For example, an illuminance plot corresponding to a selected region or a selected object from a user among images can be added to the image and displayed on the screen.

In another embodiment, the application of the mobile terminal 230 may augment the received illumination value with the previously captured image and display it on the screen. In one embodiment, an illuminance value corresponding to a selected region or a selected point in the image may be added to the image and displayed on the screen.

FIG. 5 is a diagram for explaining a three-dimensional spatial analysis mode in the indoor illumination simulation system according to the disclosed technology.

5, the indoor illumination simulation system includes a mobile terminal 530 and an analysis server 550, and the mobile terminal 530 and the analysis server 550 can be connected through a network 540. [ The building 510 to be subjected to roughness analysis may have a window 520.

Hereinafter, the operation when the user selects the three-dimensional spatial analysis mode will be described with reference to FIG.

When the indoor illumination simulation application installed in the mobile terminal 530 is executed and the three-dimensional spatial analysis mode is selected, the mobile terminal 230 defines a three-dimensional analysis target space, As shown in Fig.

In one embodiment, when the three-dimensional spatial analysis mode is selected, the application of the mobile terminal 530 prepares to measure the space to be analyzed by operating an accelerometer with guidance that the space to be analyzed is measured. The user can move the mobile terminal 530 and measure the space to be analyzed.

In one embodiment, the application of the mobile terminal 530 may provide a pre-stored representative spatial model and measure the analysis subject space based on the model selected by the user in the representative spatial model. For example, if a hexahedral spatial model is selected by the user, the application of the mobile terminal 530 may guide to measure the width, height and height of the space to be analyzed.

FIG. 6 is a view for explaining a process of measuring a spatial structure of a space to be analyzed in the three-dimensional spatial analysis mode, and FIG. 7 is a view for explaining a process of measuring a height of the space to be analyzed in the three- dimensional spatial analysis mode.

Assuming that the space to be analyzed is a hexahedral space, the user can move the mobile terminal 530 and measure the length and height of the space to be analyzed. The application of the mobile terminal 530 may measure the length of the analysis subject space based on the movement speed and the movement time of the mobile terminal 530 measured through the acceleration sensor.

After measuring the horizontal length and vertical length of the space to be analyzed, the application of the mobile terminal 530 can measure the height of the analysis target space through a clinometer. For example, an application can select two points of the space to be analyzed through an inclinometer, measure the angle between two points, and measure the height of two points based on the measured angle and the distance to the point.

The application of the mobile terminal 530 may re-select the length and height of the analysis target space through confirmation of the user.

After the analysis target space is defined, the application of the mobile terminal 530 guides the input of the window position and the window space structure within the measured analysis target space. In one embodiment, the application may display the measured analysis target space and receive a location from the user where the window is located. When the position of the window is input, the application guides the measurement of the window space structure.

8 is a view for explaining a process of measuring a window position and a window space structure in a three-dimensional spatial analysis mode.

The application of the mobile terminal 530 prepares to measure the window space structure by operating the acceleration sensor. The user can move the mobile terminal 530 to measure the window space. For example, the user can move the mobile terminal 530 to measure the length and the length of the analysis target space. The application can also measure window space again by user confirmation.

In one embodiment, the application of the mobile terminal 530 may add the type of illuminating device, the position of the illuminating device, and the brightness of the illuminating device to the analysis target space, and reflect the influence of the artificial illumination to the illuminance analysis. For example, the application models the analysis target space, the position of the window, and the window space, and displays the information on the screen, and receives information (for example, type of illumination device, brightness, etc.) have. When the user selects a location to add the lighting device, the application guides the user to select the type and brightness of the lighting device. In one embodiment, the application may analyze the indoor illumination only by the lighting device by selecting the evening time zone option without influence of natural light in the analysis target space.

When the analysis target space, the position of the window, and the window space are set (optionally, the information (position, type, brightness) of the illumination device can be additionally set). In one embodiment, the application may receive information about the color and material of the walls, floor, roof, and window as surface information. For example, the application can model the analysis target space, the position of the window, and the window space, and display it on the screen, and receive surface information of the surface (e.g., wall, floor, roof, window) selected by the user. When the user selects a surface to input surface information, the application guides the user to select the color and the material.

In one embodiment, the application of the mobile terminal 530 may directly input the horizontal and vertical lengths and angles of the analysis target space and the window space from the user. In this case, the user can directly input the previously measured length or angle value through the key input means of the terminal.

(Location, type, brightness) of the illumination device can be additionally set), the application of the mobile terminal 530 transmits the information to the analysis server 550 . For example, the application of the mobile terminal 530 may be used by the analysis server 550 to analyze the spatial spatial structure, the location of the window, the window space structure, and the surface information (optionally, Lt; / RTI >

The analysis server 550 analyzes the illuminance of the space based on the spatial information and the additional information received from the mobile terminal 530.

The analysis server 550 analyzes each of the points in the analysis target space based on the received analysis space space structure, the window position, the window space structure, and the surface information (additionally, information (position, Can be analyzed. The analysis server 550 estimates the illuminance value by simulating the amount of light at each point in the analysis target space. For example, the roughness value can be estimated by calculating light arriving directly at a specific point and light arriving at a specific point based on the window position, window size, and surface information. The analysis server 550 can use an analysis algorithm that defines the amount of light according to the position of the window and the size of the window, semi-specification according to the surface information, and the like. However, the analysis algorithm may be different for the implementation system, and the analysis server 550 may update the analysis algorithm or change it to another algorithm. In one embodiment, if the analysis algorithm is changed, the analysis server 550 may request other information needed for the analysis algorithm from the mobile terminal.

The analysis server 550 estimates the illumination value for each point in the space to be analyzed and generates an illumination grid of the image based on the estimated value. For example, the analysis server 550 may generate a three-dimensional grid represented by a color corresponding to the illumination value of each point in the analysis target space. In addition, the analysis server 550 may generate statistical values such as an illuminance value average, a minimum value, and a maximum value based on illuminance values of respective pixels.

The analysis server 550 transmits the analyzed result to the mobile terminal 530. For example, the analysis server 550 may transmit the illumination grid file and statistics values to the mobile terminal 530.

9 is a view for explaining the display of the analysis result of the three-dimensional spatial analysis mode.

The application of the mobile terminal 530 may display the received illumination grid and statistics on a screen and provide the same to the user. In another embodiment, the analysis server 550 may transmit the illuminance values and statistical values of each point of the analysis target space to the mobile terminal 530, and the application of the mobile terminal 530 may transmit, May be generated.

In one embodiment, the application of the mobile terminal 530 may augment all or a portion of the received illumination grid onto the photographed image and display it on the screen. For example, an illumination grid corresponding to an area selected from a user or an object selected from an image may be added to the image and displayed on the screen.

In another embodiment, the application of the mobile terminal 530 may augment the received illumination value to a measured spatial space model of interest and display it on the screen. In one embodiment, an illumination value corresponding to a selected region or a selected point in the image may be added to the analysis target spatial space model and displayed on the screen.

10 is a flowchart for explaining an indoor illumination simulation method according to the disclosed technique.

Referring to FIG. 10, the mobile terminal executes an application according to a user's control (step S1010). The mobile terminal can access the server where the application is stored in advance and download and install the indoor illumination simulation application.

The application of the mobile terminal provides a two-dimensional spatial analysis mode for analyzing the illuminance of the two-dimensional space and a three-dimensional spatial analysis mode for three-dimensionally analyzing the illuminance of the three-dimensional space. Mode is selected (step S1020).

When the two-dimensional space analysis mode is selected, the application of the mobile terminal defines the space to be analyzed, and receives spatial information about the defined space and additional information about the space. For example, the application captures an image of a space to be analyzed, receives a reference point in the image, and measures an illuminance value of the reference point (step S1030).

The application transmits spatial information (image) and additional information (reference point, roughness value of the reference point) to the analysis server, and the analysis server analyzes the indoor roughness based on the received spatial information and the additional information (step S1040). After analyzing the indoor illuminance, the analysis server transmits the analysis result to the mobile terminal, and the application of the mobile terminal displays the received result on the screen (step S1050). For example, the application may display received illumination plots, or may generate and display illumination plots based on the analyzed illumination values.

When the 3D spatial analysis mode is selected, the application of the mobile terminal defines a space to be analyzed, and receives spatial information about the defined space and additional information about the space. For example, the application measures the space to be analyzed, measures the position of the window and the structure of the window space, and inputs the surface information of the space to be analyzed (optionally, additional information (position, type, brightness) (Step S1060).

The application transmits the spatial information (analysis target space) and the additional information (window position, window space structure, surface information (optionally, information (location, type, brightness) The indoor illuminance is analyzed based on the received spatial information and the additional information (step S1070). After analyzing the indoor illuminance, the analysis server transmits the analysis result to the mobile terminal, and the application of the mobile terminal displays the received result on the screen (step S1080). For example, the application may display the received illumination grid, or may generate and display an illumination grid based on the analyzed illumination values.

11 is a flowchart specifically illustrating a two-dimensional spatial analysis mode in the indoor illumination simulation method of FIG.

Referring to FIG. 11, when the two-dimensional spatial analysis mode is selected, the application of the mobile terminal drives a camera to capture a photograph of a space to be analyzed (step S1110). The application may also take a picture of the space to be analyzed by user confirmation.

When the space to be analyzed is determined, the application displays the corresponding image on the screen and receives the reference point from the user (step S1120). The application may re-select the reference point through user confirmation.

After storing the position information of the reference point, the application drives the illuminance sensor and measures the illuminance value for the reference point (step S1130). The application may re-select the reference point through user confirmation.

When the space to be analyzed and the additional information are determined, the application transmits the information to the analysis server (step S1140). For example, the application can transmit the image of the space to be analyzed, the reference point location information, and the illumination value to the analysis server.

The analysis server analyzes the illuminance of the space based on the spatial information and the additional information received from the mobile terminal (step S1150), and transmits the illuminance analysis result to the mobile terminal (step S1160). In one embodiment, the analysis server may transmit the illumination plot and statistics values to the mobile terminal as an analysis result. Alternatively, the analysis server may transmit the illumination value and the statistical value for each point to the mobile terminal as an analysis result.

The application of the mobile terminal displays the received analysis result on the screen (step S1170). For example, an application can display an illuminance plot and statistics on the screen. In one embodiment, the application may augment and display all or a portion of the illuminance plot on the pre-stored image.

12 is a flowchart specifically illustrating a three-dimensional spatial analysis mode in the indoor illumination simulation method of FIG.

Referring to FIG. 12, when the 3D spatial analysis mode is selected, the application of the mobile terminal measures the spatial structure of the analysis target space using an acceleration sensor and an inclinometer (step S1210).

In one embodiment, the application may provide a pre-stored representative spatial model and measure the analysis subject space based on the model selected by the user in the representative spatial model. The application can measure the length and width of the space to be analyzed through the acceleration sensor and measure the height of the space using an inclinometer.

After the analysis target space is defined, the application receives the position of the window within the measured analysis target space and measures the window space structure (step S1220). The application can measure the window space structure through the acceleration sensor, and the window space structure can be measured again by the user's confirmation.

When the analysis target space, the position of the window, and the window space are set (optionally, the information (position, type, brightness) of the illumination device can be additionally set), the application receives the surface information of the analysis target space (step S1230). In one embodiment, the application may receive information about the color and material of the walls, floor, roof, and window as surface information.

(Location, type, brightness) of the illumination device can be additionally set), the application of the mobile terminal transmits the information to the analysis server (step S1240). For example, the application may send to the analysis server the spatial space structure to be analyzed, the location of the window, the window space structure, and the surface information (optionally additional information (location, type, brightness) about the illuminator).

The analysis server analyzes the illuminance of the space based on the spatial information and the additional information received from the mobile terminal (step S1250), and transmits the illuminance analysis result to the mobile terminal (step S1260). In one embodiment, the analysis server may transmit the illumination grid and statistical values to the mobile terminal as an analysis result. Alternatively, the analysis server may transmit the illumination value and the statistical value for each point to the mobile terminal as an analysis result.

The application of the mobile terminal displays the received analysis result on the screen (step S1270). For example, the application can display the illuminance grid statistic value on the screen. In one embodiment, the application may augment and display all or a portion of the illuminance grid on the pre-stored analyzing space model.

An indoor illumination simulation system and method according to the disclosed technique may provide illumination analysis results to other systems. For example, the analysis server may provide illumination analysis results to a building's energy simulation system or to a building's network system. For example, building heating and air conditioning systems can use the received illumination analysis results to identify areas that require a lot of electricity in the space or to reflect them in building energy consumption calculations.

Also, the indoor illumination simulation system and method according to the disclosed technology can not only grasp the current illumination condition through the simulation result, but also predict the indoor illumination.

For example, based on the simulation result, the simulation result time information, the predetermined rate of change in illuminance per time, etc., it is possible to grasp the illuminance amount (particularly, the amount of sunlight) at a specific time in the user's peripheral area. Simulation results can also be used to predict the change in illuminance for one year (365 days x 24 hours) based on the simulation results, the simulation result time information, and the predetermined annual illumination change rate. In this way, it is possible to suggest a seating arrangement or furniture layout that can feel the most comfortable light environment of the office resident one year, and the building operation / management system can provide lighting control system, Home appliances and the like can be controlled. For example, if the average illuminance in the space is higher or lower than the reference value, the brightness of a nearby lamp can be controlled or the blind or curtain of the window can be controlled. It can also be used in other applications related to indoor light. For example, it can help determine how much glare is caused by sunlight, or about the health problems that can occur due to sunlight (such as the occurrence of overdose skin, undercurrent vitamins production, etc.) .

In addition, the indoor illumination simulation system and method according to the disclosed technology can predict the light environment habit of each individual by using a mobile terminal that is usually carried and can help improve the individual light environment.

As described above, the indoor illumination simulation system and method according to the disclosed technology can provide information to the user by simulating the illuminance of a room based on the measured information using a mobile terminal having a sensor such as a smart phone .

In addition, the indoor illumination simulation system and method according to the disclosed technology can provide information that can reduce energy of a building in connection with an energy simulation system of a building and the like.

In addition, the indoor illumination simulation system and method according to the disclosed technology may control the heating / cooling system or household appliances in connection with the network system of the building.

210: Building 220: Window
230: mobile terminal 240: network
250: Analysis Server

Claims (9)

A system for simulating and providing indoor illumination,
A mobile terminal for defining a space to be analyzed through a sensor, receiving spatial information about a defined space and additional information about the space, transmitting the input information to the analysis server, receiving the illumination analysis result from the analysis server, and displaying the result on the screen; And
And an analysis server for analyzing illuminance of the space based on the spatial information and the additional information received from the mobile terminal and transmitting the analyzed result to the mobile terminal,
Analysis of illuminance according to two-dimensional spatial analysis mode
The mobile terminal photographs the space to be analyzed through the camera, receives the reference point from the photographed photograph, measures the illuminance value of the selected reference point, and calculates the illuminance of the photographed photograph, the reference point, To the analysis server,
The analysis server analyzes an illumination value of another point in the photograph based on the illumination value of the reference point
Indoor illumination simulation system. The method of claim 1, wherein the mobile terminal
An indoor illumination simulation system for selecting one of a two-dimensional spatial analysis mode and a three-dimensional spatial analysis mode, and defining a space to be analyzed according to the selected mode. delete A system for simulating and providing indoor illumination,
A mobile terminal for defining a space to be analyzed through a sensor, receiving spatial information about a defined space and additional information about the space, transmitting the input information to the analysis server, receiving the illumination analysis result from the analysis server, and displaying the result on the screen; And
And an analysis server for analyzing illuminance of the space based on the spatial information and the additional information received from the mobile terminal and transmitting the analyzed result to the mobile terminal,
Analysis of illuminance according to three-dimensional spatial analysis mode
The mobile terminal measures a space of a three-dimensional analysis object through a space measurement sensor and a user interface, measures a window position and a window size in the measured three-dimensional analysis space, inputs each surface information, The spatial structure, the window position, the window size, and each surface information to the analysis server,
The analysis server analyzes the illuminance of the three-dimensional analysis target space
Indoor illumination simulation system. 5. The method of claim 4, wherein the mobile terminal
The type of the illuminating device, the position of the illuminating device, and the brightness of the corresponding illuminating device are further input into the analysis target space,
An indoor illuminance simulation system for transmitting the input type of lighting equipment, the position of the lighting equipment, and the brightness of the lighting equipment to the analysis server. The system of claim 1, wherein the analysis server
An indoor illumination simulation system that provides a 2D illumination plot or a 3D illumination grid as an analysis result. In the indoor illumination simulation method,
The mobile terminal selecting one of a two-dimensional spatial analysis mode and a three-dimensional spatial analysis mode;
According to the selected mode, the mobile terminal defines the analysis target space through the sensor, receives the spatial information about the defined space and the additional information about the space,
The mobile terminal transmitting the space information and the additional information about the space to the analysis server;
Analyzing the illuminance of the space based on the spatial information and the additional information received from the mobile terminal;
The analysis server transmitting the analyzed result to the mobile terminal; And
The mobile terminal may include displaying the received illumination analysis results on a screen
Analysis of illuminance according to two-dimensional spatial analysis mode
Receiving spatial information about the defined space and additional information about the space, the method comprising the steps of: capturing an analysis object space through a camera and inputting the analysis object space; And receiving a reference point from the photographed photograph and measuring and inputting an illuminance value of the selected reference point,
The step of transmitting the spatial information and the additional information about the space to the analysis server includes transmitting the photographed photograph, the position information of the reference point, and the illuminance value of the reference point,
The step of analyzing the illuminance of the space based on the received spatial information and the additional information may include analyzing the illuminance value of another point in the photograph based on the illuminance value of the reference point
Wherein the indoor illuminance simulation method comprises: delete In the indoor illumination simulation method,
The mobile terminal selecting one of a two-dimensional spatial analysis mode and a three-dimensional spatial analysis mode;
According to the selected mode, the mobile terminal defines the analysis target space through the sensor, receives the spatial information about the defined space and the additional information about the space,
The mobile terminal transmitting the space information and the additional information about the space to the analysis server;
Analyzing the illuminance of the space based on the spatial information and the additional information received from the mobile terminal;
The analysis server transmitting the analyzed result to the mobile terminal; And
The mobile terminal may include displaying the received illumination analysis results on a screen
Analysis of illuminance according to three-dimensional spatial analysis mode
The step of receiving spatial information on the defined space and the additional information on the space includes: measuring a three-dimensional analysis target space through a spatial measurement sensor and a user interface; Measuring a position of a window and a window space structure within the measured three-dimensional analysis target space; And receiving surface information about the space to be analyzed,
The step of transmitting the spatial information and the additional information about the space to the analysis server may include transmitting the 3D structure, the window position, the window structure, and the surface information to the analysis server
Wherein the step of analyzing the illuminance of the space based on the received spatial information and the additional information includes the step of simulating the spatial information of the three-dimensional analysis target space and the additional information of the target space as input values, Analyzing step
Wherein the indoor illuminance simulation method comprises:

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