JP2007328626A - Building confirmation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system which enables a user to easily and surely recognize statuses of sites of respective apartments in a multiple dwelling building. <P>SOLUTION: A digital camera 10 photographs a QR code 14 having information for specifying each apartment of the apartment building and an on-site picture of each apartment as a subject 12. The QR code 14 is decoded and is transmitted to a mail server 18 in a form of e-mail together with the on-site picture and furthermore transmitted to an ASP server 20. The on-site picture of each apartment is stored in a database in association with the information of the QR code and provided to the user in response to a request from a PC 22. The user can visually recognize the on-site picture of an apartment which the user has purchased, at arbitrary timing. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a building confirmation system, and more particularly to browsing of site photos using a terminal.

  2. Description of the Related Art Conventionally, a system has been proposed that allows a client to browse the building status of a building from a terminal, not the site, via the Internet.

  In Patent Document 1 shown below, a person in charge of a construction company regularly goes to the construction site, where a predetermined place is photographed with a digital camera, and software determined from a terminal in the construction shop is used. It is disclosed that a homepage is automatically created by sending a message. The owner says that his home under construction can be viewed from anywhere via the Internet by entering a password given in advance to this homepage.

JP 2002-108978 A

  However, there are multiple buildings such as apartments, condominiums, buildings, etc. in the building, and the owner of each door is not only the appearance and shared parts of the collective building, but also the building situation of their own door. Often wants to know arbitrarily and easily. Moreover, there is a high demand for protecting the situation of one's door as privacy.

  The objective of this invention is providing the system which can know the condition of the field of each house easily and reliably in a collective building.

  The present invention is a means for capturing a field photograph for each door of a building composed of a plurality of doors, acquiring encoded information for identifying each door, a transmitting means for transmitting the photographed field photograph, and the field Storage means for receiving a photo, classifying and storing the site photo for each house based on the encoded information, and control means for transmitting the site photo to the user terminal in response to a request from a user terminal. The user identification information transmitted from the user terminal is compared with the door identification information assigned to each door, and the on-site photo of the corresponding door only when the user identification information matches the door identification information. Control means for transmitting to the user terminal.

  In addition, the present invention receives a site photograph of each door of a building composed of a plurality of doors and encoded information specifying each door, and classifies the site photograph for each door based on the encoded information. Storage means for storing, and control means for transmitting the on-site photo to the user terminal in response to a request from the user terminal, the user identification information transmitted from the user terminal and the door identification information assigned to each house And control means for transmitting the on-site photo of the corresponding door to the user terminal only when the user identification information matches the door identification information.

  In addition, the present invention captures a site photograph of each door of a building composed of a plurality of doors, and captures and acquires encoded information that identifies each door at the same time as or along with the field photograph. Means, transmitting means for transmitting the photographed field photograph and the encoded information, storage means for receiving the field photograph and classifying and storing the field photograph for each house based on the coded information; In response to a request from the user terminal, the control means for transmitting the site photo to the user terminal, the user identification information transmitted from the user terminal and the door identification information assigned to each door is collated, And control means for transmitting the on-site photo of the corresponding door to the user terminal only when the user identification information matches the door identification information.

  According to the present invention, the user can confirm the construction status by visually recognizing the site photograph for each house.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  In FIG. 1, the system block diagram of the building confirmation system in this embodiment is shown. The digital camera 10, mail server 18, ASP server 20, and personal computer (PC) 22 as a user terminal are connected via the Internet 16.

The digital camera 10 captures an overall appearance photo of a collective building under construction, a site photo of a shared part, and a site photo of each house. The digital camera 10 may be a so-called camera-equipped mobile phone, and any device having a photographing function can be used. The digital camera 10 shoots the subject 12 such as the appearance of a collective building, the floor, wall, or ceiling of each door, and the QR code 14 as encoded information. For example, when photographing a house A with a collective building, a paper or board on which a QR code 14 is printed is placed at a specific location on the door A, and the subject is placed so that the paper or board is included in the angle of view. 12 is photographed. For example, when photographing a wall of a certain door, a paper on which a QR code 14 is printed is attached to a part of the wall, and photographing is performed so that the QR code 14 is positioned at the right corner within the angle of view. The QR code 14 is an example of a two-dimensional code in which optical gray patterns are two-dimensionally arranged and information is provided in the vertical direction and the horizontal direction, and other two-dimensional codes may be used. The QR code 14 includes information necessary for specifying each house such as the room number of each house if it is an apartment. Of course, the information included in the QR code 14 varies depending on the subject 12 on which the QR code 14 is installed, that is, the subject 12 photographed together with the QR code 14. If the subject 12 is a shared part, information for specifying the shared part is included, and if the subject 12 is a part in each door, information for specifying each door and its part is included. The information of the QR code 14 is exemplified as follows.
"Overall appearance"
"Entrance part"
"Corridor part"
"Room 505"
"Living in room 504"
"Bathroom in room 304"
Etc. Direction information at the time of shooting can also be included in the QR code 14. For example,
"Room 103 living room facing east"
Etc. “Toward the east” means that the orientation when the living room is photographed with the digital camera 10 is eastward. In this sense, it can be said that the QR code 14 includes information indicating the shooting direction. It may contain information identifying shared or private ownership. The general data format is
QR code 14 = (shared / private identification, location, room number, room, direction)
It becomes. The QR code 14 is created in advance and brought to the site, or printed and created on site. The digital camera 10 has a QR code reading function such as a QR code reader, reads the QR code 14 included in the angle of view at the time of shooting, and decodes the encoded information to acquire information for identifying each house. Then, the subject 12 photographed together with the decrypted information, that is, a construction site photograph is transmitted to the mail server 18 via the Internet 16 in the form of an electronic mail. The on-site photo mail format transmitted from the digital camera 10 is a predetermined format, and is transmitted with predetermined data added.

  FIG. 2 shows an e-mail format transmitted from the digital camera 10 to the mail server 18. An email is composed of a header, a subject, a body, and an attached file. The subject is automatically described by the CPU of the digital camera 10 in a specific format, and consists of A ..., B ..., C ..., D ..., E ..., F ..., G .... . Here, A ·· is a number uniquely given to the digital camera 10 and is a number for specifying the digital camera 10 or its user. B ·· is the destination number, C ·· is the folder project number, D ·· is the file serial number, E ·· is the shooting date, F ·· is the folder serial number, and G ·· is the total number of files in the folder. . The photographed site photos are managed for each folder and transmitted for each folder. A project number is uniquely assigned to each folder. Each site photo is numbered 1, 2, 3, ... in the folder. The text is also automatically described by the CPU, and information for identifying each house read by the QR code 14 is described. For example, if it is a field photograph of room number 304, “304” is described in the text. Although the decoded information is described in the text, the encoded information before decoding may be described in the text as it is. In this case, the server that receives the e-mail decrypts it. Information of the QR code 14 may be included in the subject or may be an attached file.

  Returning to FIG. 1 again, the mail server 18 receives an electronic mail transmitted via the Internet 16 and classifies and manages the received electronic mail based on the subject and the data included in the body of the electronic mail. The subject and body of the email contain the project number and QR code 14 information as described above, and the field photos attached to the email are mainly classified based on these data. “Project number # 1, room number 304, images 1, 2, 3”, “project number # 1, room number 505, images 1, 2, 3” and so on. There may be a single on-site photograph having the same project number and the same QR code information, or a plurality of photographs. In a plurality of cases, as will be described in detail later, it is an on-site photo of a different orientation or direction of each door or a different room, an east-facing photo, a living photo, etc. The mail server 18 transmits the classified site photo data to the ASP server 20. The mail server 18 and the ASP server 20 may be connected via a dedicated line or may be connected via the Internet.

  The ASP server 20 is a server that provides a user with a site photo browsing service, and has storage means for storing the site photos transmitted from the mail server 18 in a classified state. When there is a new site photo uploaded from the digital camera 10, the ASP server 20 additionally stores the received site photo data in the storage means and transmits a reception completion notification to the user terminal via the Internet 16. The user receives a reception completion notice at a personal computer (PC) 22 as a user terminal, and transmits a request for viewing a field photograph to the ASP server 20 at an arbitrary timing. In response to a request from the PC 22, the ASP server 20 reads the field photo data from the storage means and transmits it.

  FIG. 3 shows a processing flowchart of the present embodiment. Processing flowcharts in the digital camera 10, the mail server 18, the ASP server 20, and the PC 22 are shown in parallel.

  The digital camera 10 photographs a QR code 14 installed in the vicinity of a subject to be photographed with a subject 12 together with the subject 12, reads information encoded by a built-in QR code reader, and stores the information in a working memory in the digital camera 10. (S101, S102). The working memory can be a flash memory. In the figure, the shooting of the QR code 14 and the shooting of the subject 12 are performed in time series, but they may be executed simultaneously. In the case of simultaneous execution, the QR code 14 may be included in the angle of view for photographing the subject 12 as described above. The shooting order of the QR code 14 and the subject 12 may be determined as a rule in advance, and the QR code 14 may be associated with the subject and stored in the working memory. For example, assuming that the QR code 14 is first photographed and then the subject 12 is photographed, the CPU of the digital camera 10 assumes that the information of the first photographed QR code 14 is information related to the subject 12 to be continuously photographed. Processes the information of the QR code 14 and the on-site photograph of the subject 12 in association with each other. After photographing the QR code 14 and the subject 12, the on-site photo of the subject 12 is transmitted as an attached file, and the decoded information of the QR code 14 is transmitted in the form of e-mail as body data (S103). The digital camera 10 may automatically execute a series of batch processing from shooting to transmission in an e-mail format, or may be executed according to a user's manual operation. When the QR code 14 is photographed together with the subject 12, since the QR code 14 is included in the on-site photograph as photographing data, the QR code 14 may be transmitted as it is without being decoded.

  The mail server 18 receives the e-mail transmitted from the digital camera 10 (S104), sorts the e-mail using the unique number, project number, shooting date and time, and QR code 14 information of the digital camera 10, and creates a field photograph. Is sent to the ASP server 20 (S105). If the decryption information of QR code 14 is included in the text, the information is used as it is, and if the QR code 14 is reflected in the on-site photo, the QR code is not included in the text, mail is sent. The server 18 decodes the QR code in the field photograph and sorts using the decoded QR code information.

  The ASP server 20 receives the data transmitted from the mail server 20 (S106), and transmits a reception completion notification to the PC (S107). The unique number of the digital camera 10 can be referred to as the transmission destination of the reception completion notification. That is, the ASP server 20 stores user data for using the service in advance as a database, and stores the user data and the unique number of the digital camera 10 in association with each other. The ASP server 20 specifies user data from the unique number of the digital camera 10 and transmits a reception completion notification to the mail address of the PC 22 included in the user data. After the reception completion notification, the site photo is edited as appropriate and stored in the storage means (S108). The root directory is a folder project number, and below this, the shooting date and time, the unique number of the digital camera 10 and the like are arranged in a hierarchy.

  The PC 22 receives the reception completion notification from the ASP server 20 (S109), and recognizes that browsing is possible. The user operates the PC 22 to access the ASP server 20 (S110). Regardless of whether the access method is wired or wireless, any protocol such as TCP / IP may be used. As an example, the user starts the Web browser of the PC 22 and accesses the ASP server 22. The ASP server 20 requests the accessed user to input an ID and password, and authenticates the ID and password input by the user by collating them with user data stored in a database in advance. Send the on-site photo data to the authenticated user.

  In this embodiment, the site photos of each house in the collective building are stored as a database and provided to the user. There is no problem with allowing the users related to the collective building to see the appearance and shared parts of the collective building, but the private part of each door restricts the viewing of others by privacy, and purchase of the door It is desirable that only the owner or the owner is permitted to view. In the present embodiment, since the information for identifying each door is given as the QR code 14 to each field photograph, it is easy to control the access right to each door. The ID and password held by the user are shared with the shared part and private part of the collective building, and the user can view both the shared part and the private part with a single ID and password. When a specific arrangement is included in the user ID and password part, browsing of the shared part is permitted, and when all of the ID and password are a specific arrangement, browsing of the private part is permitted. Each house is assigned an ID and password, and only when the user ID and password match the ID and password assigned to each house, it is possible to view the on-site photo data of each house specified by the QR code 14. Become.

  4 and 5 show detailed processing flowcharts of the digital camera 10. This is a process in which the QR code 14 is first photographed and then the subject is photographed. When the power of the digital camera 10 is turned on (S201), the setting parameters are read from the flash memory (S202). The setting parameters are parameters necessary for a series of processing from on-site photography to transmission by e-mail, and include resolution, compression format, unique number of the digital camera 10, and the like. Next, the mode is switched from the photographing mode to a mode for reading the QR code 14 (S203). Specifically, the optical system and the signal processing system for processing the photographed image are switched from the subject photographing mode to the QR code reading mode. Since the QR code is a monochrome binary pattern unlike the subject, color signal processing and brightness adjustment are not required. The basic function of the QR code reading mode is to convert the two-dimensional grayscale pattern of the QR code into an electrical signal with an image sensor such as a CCD or CMOS, and binarize it with an appropriate threshold value to read the encoded information and read the binary The decryption information is collated with a code table or the like and decrypted (or decrypted). The QR code 14 arranged in the vicinity of the subject 12 is photographed (S204), and the information of the photographed QR code 14 is decoded (S205). The decoded QR code 14 information is stored in the working memory.

  Next, the mode is switched to the photographing mode, and the subject 12 is photographed to obtain an on-site photograph (S206). The mode may be switched manually or automatically on the digital camera 10 side. That is, the CPU of the digital camera 10 switches the mode from the QR code reading mode to the photographing mode after the decoding of the QR code 14 is completed and stored in the memory. In the photographing mode, color signal processing, luminance adjustment, white balance adjustment, γ correction, edge enhancement processing, and the like are executed. After photographing the subject, the CPU associates the on-site photograph that is the photographed image with the information of the QR code 14 acquired in S205 and stores it in the flash memory (S207). Specifically, the information of the QR code 14 and the field photograph associated with each other are stored in a transmission destination folder created in advance in the flash memory. The transmission destination folder is a folder for collectively managing data or files to be transmitted, and transmission destination information is defined by the setting parameters read in S202. By the association, it is specified which of the houses in the collective building is the photographed site photograph. When taking a plurality of site photographs, the processes of S203 to S207 are repeatedly executed. Basically, one QR code 14 is associated with one site photo, but a plurality of site photos may be associated with one QR code 14. For example, the QR code 14 does not include direction information but includes only a room number and a room, and a plurality of site photographs are taken in the room.

  FIG. 5 shows a process flowchart at the time of transmission following the photographing process. This is a process when the user transmits manually. The user operates the transmission button of the digital camera 10 to shift to the transmission mode (S301). Since the on-site photo and the information of the QR code 14 are stored in the transmission destination folder, the user designates the SOF that is the transmission start image and the EOF that is the transmission end image in the transmission destination folder (S302). SOF and EOF are the same when sending a field photo one by one. Then, it connects to the Internet 16 and accesses the mail server 18 (S303). The parameters for accessing the mail server 18 are the setting parameters read in S202. After accessing the mail server 18, an electronic mail having the format shown in FIG. 2 is created (S304), and the electronic mail is transmitted (S305). After the transmission, the transmitted image data (site photo) is deleted in order to secure the capacity of the flash memory (S306). Through the above processing, the information on the site photo and the QR code 14 is transmitted to the mail server 18.

  FIG. 6 shows an example of a screen displayed on the display device of the PC 22 when the user accesses the ASP server 20 by operating the PC 22. It is a screen at the time when the user's ID and password are authenticated and access to the shared part of the collective building is permitted. On the screen, the appearance 50 of the collective building is shown, and the room number of each house is displayed. Each house stores a field photograph associated with the information of the QR code 14 as described above in the database 52. For example, the room number “304” is composed of image 1, image 2, image 3, and image 4. An on-site photograph 54 is stored. Image 1 is the living room in room 304, image 2 is the bathroom in room 304, image 3 is the bedroom in room 304, and the like. Alternatively, image 1 is an eastward image of the living room of room 304, image 2 is a southward image of the living room of room 304, image 3 is a westward image of room 304, and the like. When the user clicks 304, if the user's ID and password match the ID and password set in advance for each house, the ASP server 20 responds to the user's request with the image 1 constituting the site photo 54, 2, 3, and 4 are transmitted to PC22. The user can easily see not only the shared part but also the site photograph of the house he / she purchased to check the current state of the construction. Even if the user who does not have the access right 304 clicks 304, the ASP server 22 does not transmit the site photograph 54 to the PC 22.

In this embodiment, it is assumed that both the shared part and the private part of the collective building can be accessed with a single ID and password. However, the ID and password for accessing the collective building and the private part are accessed. IDs and passwords may be distinguished. In the latter case, when the user clicks the room number “304” in FIG. 6, the user is requested to input the ID and password again, and the ID and password input by the user are authenticated.
Even during the construction of the collective building, the user can obtain a sense of accessing the room purchased by the user in the same procedure as after the construction of the building is completed.

  In the present embodiment, the information of the QR code 14 includes the shooting direction or direction as necessary. However, the shooting is not necessarily performed in this direction or direction. Therefore, an orientation sensor or a position sensor may be provided in the digital camera 10 itself, and it may be added to the photographed on-site photograph and transmitted. In addition, instead of photographing the QR code 14 with the digital camera 10, the QR code 14 may be created with the digital camera 10 and associated with the on-site photograph.

  FIG. 7 shows a configuration block diagram of the digital camera 10 in this case. The image sensor 10a is composed of a CCD, a CMOS, or the like, and the operation is controlled by the CPU 10f to output a subject image as an analog image signal. The analog image signal is subjected to correlated double sampling by a CDS (not shown), then converted to a digital signal by A / D and supplied to the DSP 10e.

  The GPS 10b detects the current position of the digital camera 10. The current position is detected as latitude and longitude data and supplied to the CPU 10f.

  The direction sensor 10c detects the direction in which the photographing lens of the digital camera 10 faces, that is, the photographing direction, and supplies the detected direction to the CPU 10f. The accuracy of the shooting direction is arbitrary, but at least it should be accurate enough to identify east, west, south, and north. It is desirable to be able to identify northeast, southeast, southwest, and northwest in addition to east, west, south, and north. The various buttons 10d include a power button, a mode switching button (including switching between a QR code reading mode and a photographing mode), a transmission button, and the like. An operation signal accompanying the button operation is supplied to the CPU 10f.

  The DSP 10e performs γ correction, edge enhancement processing, and the like of the on-site photograph supplied from the image sensor 10a. The information of the decoded QR code 14 and the processed field photograph are stored in the flash memory 16m via the memory interface I / F. The on-site photograph is JPEG compressed by the JPEG codec 10h and stored in the flash memory 16m.

  The flash memory 16m includes a ROM and a RAM, and various setting parameters such as a unique number and a transmission destination address of the digital camera 10 are stored in the ROM. The RAM stores information of the decoded QR code 14, a field photograph, current position data detected by the GPS 10b, and direction data detected by the direction sensor 10c. The on-site photograph is supplied to the signal processor 10j via the video interface I / F 10i, converted into the NTSC format or the like, and displayed on the liquid crystal screen 10k. In addition, when it is not necessary to confirm the captured image on the liquid crystal, the video I / F 10i, the signal processor 10j, and the liquid crystal screen 10k are unnecessary.

  The CPU 10f performs overall control of each unit, particularly creates a QR code in which the current position data detected by the GPS 10b and the direction data detected by the direction sensor 10c are embedded, and stores them in the flash memory 16m in association with the on-site photo. The data is read from the flash memory 16m and transmitted to the mail server 18. The association method is arbitrary, but for example, the association is performed by embedding a QR code at a predetermined angle of view position of the field photograph.

  The communication interface I / F 16n transmits the on-site photograph and the QR code 14 information stored in the flash memory 16m to the mail server 18.

  FIG. 8 shows a process flowchart of the digital camera 10. When the user turns on the power (S401), the GPS 10b built in the digital camera 10 starts receiving GPS signals from GPS satellites (S402). In this state, when the user operates the release button to photograph the subject 12 (S403), the subject is photographed (S404a), GPS information, that is, current position information is determined by the GPS 10b (S404b), and the direction sensor 10c. Thus, the shooting direction of the digital camera 10 is determined (S404c). A field photograph that is a captured image is stored in a memory (S405), and GPS information (current position information) and a shooting direction are supplied to the CPU 10f and converted into a QR code (S406). The CPU 10f embeds and adds the created QR code to the on-site photograph that is the captured image, and stores it in the flash memory 16m (S407). As described above, the QR code is embedded in the field photograph, and the current position and the shooting direction at the time of shooting are encoded in the QR code. Although the current position and shooting direction can function as information for specifying each door of the collective building, the room number of each door may be acquired by an arbitrary method and included in the QR code. In the current position information by GPS, the latitude and longitude can be specified, but the height is unknown. If it is difficult to specify each house by this alone, room number data is additionally inputted. The paper on which the room number is drawn or the QR code including the room number may be photographed and acquired. The acquired room number is encoded into a QR code together with GPS information and direction information. The site photograph in which the QR code is embedded is transmitted to the mail server 18 by e-mail, and further transmitted to the ASP server 20. The mail server 18 decodes the QR code embedded in the site photo, and sorts the site photo using the current position information and direction information included in the QR code. The ASP server 20 stores the site photograph in the database in association with the QR code decoding information. In the above example, the QR code 14 information is described in the body of the e-mail, but in this example, the QR code is embedded in the field photo and transmitted as an attached file, so other data is described in the body. Is done.

  FIG. 9 shows an example of a screen displayed on the display device of the PC 22 when the user accesses the ASP server 20 by operating the PC 22 and the ID and password are authenticated. FIG. 9A shows an on-site photo image 60, and a QR code 62 created and embedded by the digital camera 10 exists at the lower right. When the user clicks on the QR code 62, the ASP server 20 transmits information obtained by decoding the QR code 62 to the PC 22. FIG. 9B shows an example of a screen on which information from the ASP server 20 is displayed. The latitude and longitude are displayed as the current position information, and the direction is displayed as the direction information. The user can recognize where the on-site photo shown in FIG. 9A is taken and in which direction. However, there are cases where it is difficult to understand only by latitude and longitude and direction. Therefore, when the user clicks “Map” in FIG. 9B, the ASP server 20 transmits data indicating the current position information and direction in relation to the floor plan of each house to the PC 22. FIG. 9C shows an example of a screen on which data from the ASP server 20 is displayed. A floor plan 68 is displayed, and an arrow 70 indicating the direction specified by the direction information is displayed at the position specified by the current position information. The user can understand at a glance from the arrow 70 where the on-site photo shown in FIG. 9A is taken from which direction. The floor plan data 68 is stored in the database of the ASP server 20 as basic data of each house.

  As described above, in this embodiment, the site worker takes a site photograph of each house of the collective building and transmits it to the mail server 18 and further to the ASP server 20, and the user uses the PC 22 to collect the building. As well as the shared parts, it is possible to easily check on-site photos of each secured house.

  In the present embodiment, the detected current position information and azimuth information may be embedded in a field photograph as a one-dimensional code (bar code) instead of a two-dimensional code such as a QR code. In addition, information for identifying each door such as the room number of each door is created separately from the QR code and described in the body of the e-mail. The QR code is simply used to specify the shooting position and shooting direction in each room. It may be used.

It is a system configuration figure of an embodiment. It is mail format explanatory drawing of embodiment. It is a whole processing flowchart of an embodiment. It is a photographing processing flowchart of the digital camera. It is a transmission processing flowchart of a digital camera. It is screen display explanatory drawing. It is a block diagram of a digital camera according to another embodiment. It is a processing flowchart in other embodiments. It is screen display explanatory drawing in other embodiment.

Explanation of symbols

  10 digital camera, 12 subject, 14 QR code, 16 internet, 18 mail server, 20 ASP (application service provider) server, 22 PC.

The present invention is a means for capturing a field photograph for each door of a building composed of a plurality of doors and simultaneously acquiring a two-dimensional code as encoded information for identifying each door by the photographing, and the photographed field photograph Transmitting means for transmitting the field photo, storage means for receiving the site photo, classifying and storing the site photo for each house based on the encoded information, and the site photo in response to a request from a user terminal Control means for transmitting to a user terminal, wherein the user identification information transmitted from the user terminal is compared with each door identification information assigned to each door, and the user identification information matches the door identification information. And a control means for transmitting the on-site photo of the corresponding door to the user terminal.

In addition, the present invention receives a two-dimensional code as encoded information for identifying each house photograph taken and acquired at the same time as the field photograph of each building of a building composed of a plurality of houses, and the coding Storage means for classifying and storing the on-site photos for each house based on information, and control means for transmitting the on-site photos to the user terminal in response to a request from the user terminal, transmitted from the user terminal Control means for comparing the user identification information and the door identification information assigned to each door, and transmitting the on-site photo of the corresponding door to the user terminal only when the user identification information matches the door identification information. It is characterized by having.

Further, the present invention is to shoot the scene photos per each apartment building including a plurality of doors, by photographing the two-dimensional code as coded information for identifying each door to the site photos simultaneously obtain Means for transmitting, a transmission means for transmitting the photographed field photograph and the encoded information, a storage means for receiving the field photograph and classifying and storing the field photograph for each house based on the coded information; The control means for transmitting the on-site photo to the user terminal in response to a request from the user terminal, the user identification information transmitted from the user terminal and the door identification information assigned to each house is collated, Control means for transmitting the on-site photo of the corresponding door to the user terminal only when the user identification information matches the door identification information.

The present invention is a means for capturing a field photograph for each door of a building composed of a plurality of doors and simultaneously acquiring a two-dimensional code as encoded information for identifying each door by the photographing, and the photographed field photograph Transmitting means for transmitting the field photo, storage means for receiving the site photo, classifying and storing the site photo for each house based on the encoded information, and the site photo in response to a request from a user terminal Control means for transmitting to a user terminal, wherein the user identification information transmitted from the user terminal is compared with each door identification information assigned to each door, and the user identification information matches the door identification information. the site photos of the relevant door have a control means for transmitting to the user terminal only, the encoded information includes shooting direction information of said site photos, the storage unit, each door to door, or The above in situ each imaging direction of the photographic scene photograph classification and stored, the control means, and transmits the photographing direction information of said site photos to the user terminal.

In addition, the present invention receives a two-dimensional code as encoded information for identifying each house photograph taken and acquired at the same time as the field photograph of each building of a building composed of a plurality of houses, and the coding Storage means for classifying and storing the on-site photos for each house based on information, and control means for transmitting the on-site photos to the user terminal in response to a request from the user terminal, transmitted from the user terminal Control means for comparing the user identification information and the door identification information assigned to each door, and transmitting the on-site photo of the corresponding door to the user terminal only when the user identification information matches the door identification information. possess the door, the encoded information includes shooting direction information of said site photos, the storage unit, each door to door, and stored by classifying the scene photograph every photographing direction of said site photos, before Control means, and transmits the photographing direction information of said site photos to the user terminal.

In addition, the present invention is a means for capturing and obtaining a two-dimensional code as coding information for identifying each door simultaneously with the field photograph while photographing a field photograph for each door of a building composed of a plurality of doors. Transmitting means for transmitting the photographed field photograph and the encoded information; storage means for receiving the field photograph and classifying and storing the field photograph for each house based on the encoded information; and a user Control means for transmitting the site photo to the user terminal in response to a request from the terminal, wherein the user identification information transmitted from the user terminal is collated with each door identification information assigned to each house, and the user have a control means for identification information to transmit the site photos corresponding door only if it matches the each household identification information to the user terminal, the encoding information, shooting direction information of said site photos Wherein the said memory means, each door to door, and stored by classifying the scene photograph every photographing direction of said site photos, the control means transmits the shooting direction information of said site photos to the user terminal It is characterized by that.

Claims (12)

Means for taking an on-site photo of each building of a building composed of a plurality of doors and obtaining encoded information identifying each door;
A transmission means for transmitting the photographed on-site photograph;
Storage means for receiving the site photo and classifying and storing the site photo for each house based on the encoded information;
In response to a request from the user terminal, the control means for transmitting the site photo to the user terminal, the user identification information transmitted from the user terminal and the door identification information assigned to each door is collated, Control means for transmitting the on-site photo of the corresponding door to the user terminal only when the user identification information matches the door identification information;
The building confirmation system characterized by having. The apparatus of claim 1.
The building confirmation system, wherein the encoded information is acquired by photographing. The apparatus of claim 1.
The building confirmation system, wherein the encoded information is a two-dimensional code. The apparatus of claim 1.
The building verification system, wherein the encoded information includes a door number. The apparatus of claim 1.
The encoded information includes a building number and a room identification information. The apparatus of claim 1.
The encoded information includes at least one of shooting position information or shooting direction information of the on-site photo,
The storage means classifies and stores the site photos for each door and for each shooting position or shooting direction of the site photos,
The said control means transmits the photography position information or photography direction information of the said field photograph to the said user terminal. The building confirmation system characterized by the above-mentioned. Storage means for receiving a site photograph for each door of a building composed of a plurality of doors and encoded information for identifying each door, and classifying and storing the site photos for each door based on the encoded information;
In response to a request from the user terminal, the control means for transmitting the site photo to the user terminal, the user identification information transmitted from the user terminal and the door identification information assigned to each door is collated, Control means for transmitting the on-site photo of the corresponding door to the user terminal only when the user identification information matches the door identification information;
The building confirmation system characterized by having. The apparatus of claim 7.
The building verification system, wherein the encoded information includes a door number. The apparatus of claim 7.
The encoded information includes a building number and a room identification information. The apparatus of claim 7.
The encoded information includes at least one of shooting position information or shooting direction information of the on-site photo,
The storage means classifies and stores the site photos for each door and for each shooting position or shooting direction of the site photos,
The said control means transmits the photography position information or photography direction information of the said field photograph to the said user terminal. The building confirmation system characterized by the above-mentioned. Means for taking and obtaining a site photograph for each door of a building composed of a plurality of doors, and photographing and acquiring encoded information for identifying each door at the same time as the site photograph, or
Transmitting means for transmitting the photographed field photograph and the encoded information;
Storage means for receiving the site photo and classifying and storing the site photo for each house based on the encoded information;
In response to a request from the user terminal, the control means for transmitting the site photo to the user terminal, the user identification information transmitted from the user terminal and the door identification information assigned to each door is collated, Control means for transmitting the on-site photo of the corresponding door to the user terminal only when the user identification information matches the door identification information;
The building confirmation system characterized by having. The apparatus of claim 11.
The control means collates the user identification information transmitted from the user terminal with the collective building identification information assigned to the collective building, and further when the user identification information matches the collective building identification information. The building confirmation system, wherein the user identification information and the door identification information are collated.

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