JP2012104071A - Electronic photo stand, electronic photo exchange system, electronic photo exchange method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic photo stand, an electronic photo exchange system, an electronic photo exchange method and a program that are capable of exchanging image data and displaying unfamiliar photographs.SOLUTION: Image data is exchanged between plural electronic photo stands and displayed on each of them, each electronic photo stand comprising: a display unit 14 that displays images; photographing means 21 that performs photographing; communication means 24 capable of data communication by connecting a communication network; response control means that causes the photographing means to perform photographing, and when receiving a request of image data from outside via the communication means, transmits image data obtained by the photographing; and request control means that transmits, to the outside, a request of image data photographed by another electronic photo stand via the communication means, and when image data is transmitted based on the request, receives the image data to cause the display unit to display it.

Description

  The present invention relates to an electrophotographic stand, an electrophotographic exchange system, an electrophotographic exchange method, and a program that can exchange digital images for display.

  In recent years, an electronic photo frame (also called a digital photo frame) in which a memory card in which image data is written is attached and an image is displayed like a photograph has become widespread.

  Further, as a prior art related to the present invention, Patent Document 1 has a communication function and uploads and stores photo data in the server device, or downloads and stores the stored photo data from the server device. A digital photo frame is disclosed.

JP 2003-169734 A

  It would be very interesting to be able to display an unknown photo taken from a remote location on an electronic photo stand.

  An object of the present invention is to provide an electrophotographic stand, an electrophotographic exchange system, an electrophotographic exchange method, and a program capable of displaying an unknown photograph by exchanging image data.

In order to achieve the above object, the invention according to claim 1
A display unit for displaying images;
Photographing means for photographing,
A communication means capable of data communication by connecting to a communication network;
Response control means for sending image data obtained by the photographing when the photographing means performs photographing and receiving a request for image data from the outside via the communication means;
A request for image data taken by another electronic photo stand is transmitted to the outside via the communication means, and when the image data is sent based on the request, the image data is received and the display unit Request control means to be displayed on,
An electronic photograph stand characterized by comprising:

The invention according to claim 2 is the electrophotographic frame according to claim 1,
Position information acquisition means for acquiring self-position information representing the position of the user;
An input means for inputting origin information regarding the origin position of the requested image data;
Position information transmission means for transmitting the self-position information acquired by the position information acquisition means to the outside via the communication means;
With
The request control means includes
It is characterized by requesting image data of another electrophotographic frame using the position information included in the area corresponding to the origin information input by the input means as the self-position information.

The invention described in claim 3 is the electrophotographic frame according to claim 2,
The position information acquisition unit is a satellite positioning unit that performs positioning by receiving a signal from a positioning satellite.

The invention described in claim 4 is the electrophotographic frame according to claim 2,
The origin information input by the input means is time difference information,
The request control means is an image of another electrophotographic frame in which the position information included in an area that is separated from the self-position information acquired by the position information acquisition means is the self-position information. It is characterized by requesting data.

The invention according to claim 5
A plurality of electrophotographic frames according to any one of claims 1 to 4;
In response to a request for image data from the electronic photo frame, a request for image data is sent to another electronic photo frame, and when image data is sent from the other electronic photo frame based on this request, A server device for transferring image data to the requesting electronic photo frame;
An electrophotographic exchange system characterized by comprising:

The invention according to claim 6 is the electrophotographic exchange system according to claim 5,
The server device is
Position information registration means for registering the plurality of electrophotographic frames and the self-location information in a database in association with each other when the self-location information is received from the plurality of electrophotographic frames;
When a request for image data and the origin information are received from the electronic photo frame, a position included in an area corresponding to the received source information is selected from the plurality of electronic photo frames registered in the database. Search means for searching other electronic photo frames with the information as the self-location information;
An image data transfer means for transmitting a request for image data to the electronic photo frame searched by the search means, and transferring the image data sent based on the request to the electronic photo frame of the request source;
It is characterized by having.

The invention described in claim 7
An apparatus comprising: a display unit that displays an image; an imaging unit that performs imaging; a communication unit that is connected to a communication network and is capable of data communication; and a control unit that controls the display unit, the imaging unit, and the communication unit An electrophotographic exchange method for exchanging and displaying an electrophotographic image,
The control unit causes the photographing unit to perform photographing, and transmits image data obtained by the photographing through the communication unit when receiving a request for image data from the outside through the communication unit. A response control step;
The control unit sends a request for image data taken by another device to the outside via the communication means, and receives image data when image data is sent based on the request. A request control step to be displayed on the display unit;
It is characterized by including.

The invention according to claim 8 is the electrophotographic exchange method according to claim 7,
8. The electrophotographic apparatus according to claim 7, wherein the electrophotographic image is exchanged and displayed by the apparatus including position information acquisition means for acquiring self-position information representing the position of the apparatus and input means for inputting information from outside. An exchange method,
A position information transmission step in which the control unit transmits the self-position information acquired by the position information acquisition means to the outside via the communication means;
A source information input step in which the control unit inputs source information regarding the source position of the requested image data via the input means;
Including
The request control step includes:
It is characterized by requesting image data of another electrophotographic frame using the position information included in the area corresponding to the origin information input by the input means as the self-position information.

The invention according to claim 9 is the electrophotographic exchange method according to claim 8,
The origin information input by the origin information input step is time difference information,
In the request control step, an image of another electrophotographic frame in which the position information included in an area that is different from the time difference information by the time difference information from the self position information acquired by the position information acquisition unit is the self position information. It is characterized by requesting data.

The invention according to claim 10 is:
A computer that controls a display unit that performs image display, a photographing unit that performs photographing, and a communication unit that is connected to a communication network and can perform data communication.
A response control function for transmitting image data obtained by the imaging through the communication unit when the imaging unit performs imaging and receiving a request for image data from the outside through the communication unit;
A request for image data taken by another device is transmitted to the outside via the communication means, and when image data is sent based on the request, the image data is received and displayed on the display unit. A request control function,
It is a program that realizes.

The invention according to claim 11 is the program according to claim 10,
Furthermore, the computer for controlling the position information acquisition means for acquiring the self-position information representing the position of the self, and the input means for inputting information from the outside,
A position information transmission function for transmitting the self-position information acquired by the position information acquisition means to the outside via the communication means;
A source information input function for inputting source information regarding the source position of the requested image data via the input means;
Realized,
The request control function is:
It is characterized by requesting image data of another electrophotographic frame using the position information included in the area corresponding to the origin information input by the input means as the self-position information.

The invention according to claim 12 is the program according to claim 11,
The origin information input by the origin information input function is time difference information,
The request control function is an image of another electrophotographic frame in which the position information included in an area that is separated by the time difference of the time difference information from the self position information acquired by the position information acquisition unit is the self position information. It is characterized by requesting data.

  According to the present invention, image data can be appropriately exchanged between a plurality of devices, and this image can be displayed on each device. Thereby, it is possible to provide an electrophotographic display function that is very interesting.

1 is a block diagram illustrating a configuration of an electrophotographic frame and an electrophotographic exchange system according to an embodiment of the present invention. The external appearance of the electrophotographic frame of embodiment is shown, (a) is the perspective view of the front side, (b) is a perspective view of the back side. It is a figure which shows an example of the optimal placement method of the electrophotographic frame of embodiment. It is a 1st part of the flowchart of the control processing performed by CPU of an electrophotographic stand. It is a 2nd part of the flowchart of a control process same as the above. It is a 3rd part of the flowchart of a control process same as the above. 4 is a fourth part of the flowchart of the control process. FIG. 9 is a fifth part of the flowchart of the control process. FIG. 10 is a sixth part of the flowchart of the control process. FIG. It is a 1st part of the flowchart of the server process performed by CPU of a server. FIG. 6 is a second part of a flowchart of server processing.

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

  FIG. 1 is a block diagram showing the configuration of an electrophotographic stand 1 and an electrophotographic exchange system according to an embodiment of the present invention, and FIG. 2 is a block diagram showing the appearance of the electrophotographic stand 1.

  The electrophotographic exchange system according to this embodiment includes an electrophotographic stand 1 and a server 40 connected to a plurality of electrophotographic stands 1 via a communication network 30 such as the Internet.

  As shown in FIG. 1 and FIG. 2, the electronic photo frame 1 includes a CPU (central processing unit) 10 that controls the entire apparatus, and an internal memory such as a flash memory that stores image data 11a and 11b received from the outside. 11, a ROM (Read Only Memory) 12 in which a control program executed by the CPU 10 and control data are stored, a RAM (Random Access Memory) 13 that provides a working memory space to the CPU 10, and a liquid crystal that displays an image A display panel 14, a display control unit 15 that performs display control of the liquid crystal display panel 14, a touch panel 16 and a key input unit 17 that input an operation command from the outside, and a key input control unit 18 that performs input control of the operation command are provided. ing. In addition, a memory card 19 in which image data or the like is written and inserted / removed, a memory card interface 20 that reads / writes data from / to the memory card 19, an image sensor such as a CCD (Charge Coupled Device), and a lens that connects the image are provided. A camera unit 21 that shoots and generates image data; a GPS antenna 22 that receives a signal from a GPS (Global Positioning System) satellite; and a GPS control that demodulates a signal from the GPS satellite and calculates a current position. A communication control unit 24 that performs data communication by connecting to a communication network 30 such as the Internet, a power control unit 25 that supplies power to each unit, and the like.

  As shown in FIG. 2B, the back of the electrophotographic frame 1 has an insertion / extraction portion 20a of the memory card 19, connection connectors 24a and 24b of communication cables of the communication control portion 24, a lens 21a of the camera portion 21, etc. Is provided.

  In FIG. 3, the figure showing an example of the optimal arrangement | positioning of the electrophotographic stand 1 is shown.

  For example, as shown in FIG. 3, the electronic photo frame 1 is placed on a window or the like, the liquid crystal display panel 14 on which an image is displayed and output is directed indoors, and the lens 21a of the camera unit 21 is directed outdoor. Used.

  In the ROM 12, a control process for displaying and outputting an image photographed by the camera unit 21 as a photograph or exchanging image data with a plurality of electronic photograph stands 1 and displaying the image as a photograph. The program is stored. In addition to being stored in the ROM 12, the program can be stored in a non-volatile memory such as a portable recording medium such as an optical disk or a flash memory, for example, which can be read by the CPU 10 via a data reader. is there. In addition, a form in which such a program is downloaded to the electronic photo frame 1 via a communication line using a carrier wave as a medium can be applied.

  The server 40 is a general-purpose computer including a CPU, a storage device in which a control program and a database 41 are stored, and a communication interface.

  In the database 41, each piece of identification information of the plurality of electronic photo stands 1 connected to the server 40 is registered in association with self-location information representing the current position of the self sent from each of the electronic photo stands 1. It has become so.

[Operation overview]
Next, the operation of the electrophotographic exchange system configured as described above will be described.

  The operation mode of the electronic photo stand 1 includes a self-photo display mode for displaying an image taken by itself and an external photo display mode for displaying an image taken by another electronic photo stand 1.

  In the self-photo display mode, photographing is performed by the camera unit 21 every predetermined time by automatic control of the electronic photo frame 1, and an image obtained by this photographing is displayed on the liquid crystal display panel 14. With this self-photo display mode, the user can display and enjoy outdoor scenery images like photographs.

  In the external photo display mode, the user operates the touch panel 16 or the key input unit 17 to designate a region (source information) where image data is requested, so that the electronic photo frame 1 in this region is sent from the electronic photo frame 1 to the server 40. A request for image data shot at 1 is sent.

  Upon receiving this image data request, the server 40 searches the database 41 for the electronic photo frame 1 in the corresponding area, and transmits the image data request to the searched electronic photo frame 1. When image data is sent based on this request, the server 40 transfers the image data to the requesting electronic photo frame 1.

  When the image data is transferred from the server 40, the electronic photo frame 1 as the request source of the image data receives it and stores it in the internal memory 11, and causes the liquid crystal display panel 14 to display this image.

  In the external photo display mode, there are two types of methods for specifying the area for which image data is requested. One is a position input method for inputting the position of the area by latitude and longitude, and the other is a time difference input method for designating the area from the current position and the time difference. In the case of the time difference input method, the GPS control unit 23 measures its own position, and transmits its own position information and time difference information input by the user to the server 40. Then, the server 40 calculates the image request destination area from the position information and the time difference information.

  With such an external photo display mode, the user can display and enjoy an unknown landscape image of a remote area like a photo.

  The electronic photo frame 1 confirms command reception to determine whether there is a request for image data from the server 40 in both the self-photo display mode and the external photo display mode. If there is a request for image data, the camera unit 21 captures the image and transmits the image data obtained by the capture to the server 40.

  As a result of such command reception confirmation and image data transmission processing, when another electronic photo frame 1 requests image data of its own region, the image data is provided to the other electronic photo frame 1. Realized.

[Control procedure]
Next, operations of the above-described electrophotographic frame 1 and the server 40 will be described in detail according to flowcharts.

  4 to 9 show flowcharts of control processing executed by the CPU 10 of the electrophotographic frame 1.

  This control process is started when the electrophotographic stand 1 is turned on. When the control process is started, first, the CPU 10 performs an initialization process for initializing various flag values and variable values (step S1). Then, the process proceeds to a branch process (steps S2, S8, S17, S29, S41) according to the value of the mode flag “MF”, and each process according to the branch is executed.

  That is, if “MF = 0”, the process of the self-photo display mode of FIG. 4 and the response process to the server 40 of FIG. 9 are executed, and if “MF = 1”, the process in the external photo display mode of FIG. The processing for causing the user to select the region designation method and the response processing for the server 40 in FIG. 9 are executed. If “MF = 2”, the latitude / longitude position input is performed by the user in FIG. And a response process to the server 40 of FIG.

  Further, if “MF = 3”, the time difference input is performed by the user of FIG. 7 to receive the image data from the outside and the response process to the server 40 of FIG. 9 is executed. If “MF = 4”, 8. The process for displaying the image received from the outside in FIG. 8 and the response process for the server 40 in FIG. 9 are executed.

  When the processing according to each branch is executed as described above, the process returns to step S2 again, and branch processing (steps S2, S8, S17, S29, S41) according to the mode flag “MF” and this branch are performed. Repeat each process.

  Specifically, when “MF = 0” and the process proceeds to “YES” in step S2 of FIG. 4, the CPU 10 first causes the camera unit 21 to capture and capture image data (step S3). Subsequently, the image data is output to the display control unit 15 for display output (step S4). Next, it is confirmed whether or not the mode changeover switch is turned on to the key input control unit 18 (step S5). If there is an on operation, the value of the mode flag “MF” is changed to “1” (step S6). The display output is cleared (step S7), and the process proceeds to a response process for the server 40 in FIG. On the other hand, if there is no ON operation, the process directly proceeds to the response process of FIG.

  When the process shifts to the response process to the server 40 in FIG. 9, first, the CPU 10 determines whether or not a command is received from the server 40 via the communication control unit 24 (step S46). Return to (Step S2).

  On the other hand, if it is determined in step S46 that a command has been received, the command content is determined (step S47). If the command is an image request command, the camera unit 21 performs shooting to acquire image data (step S49). ), And transmits the image data to the server 40 (step S50). And it returns to the branch process of step S2.

  If it is determined in the determination processing in step S47 that the command is “none” indicating that there is no image data according to the request, “none” is displayed on the liquid crystal display panel 14 (step S48). The process returns to the branch process in step S2. This “none” display processing is performed in the external photo display mode. As a result of requesting image data by designating the area to the server 40, there is no registration of another electronic photo frame 1 in this area, and the requested image is displayed. This is a process for indicating this to the user when there is no data.

  The series of processes in steps J2 to J7 and J46 to J50 are repeatedly executed unless the mode is switched in steps S5 to S7, and the operation in the self-photo display mode and the process for responding to the image request from the server 40 are performed. Is realized. When the above-described series of processing is repeatedly executed without switching the mode, the shooting and image display processing in steps S3 and S4 is not executed every time, but is performed for a predetermined time (for example, 5 by setting a timer or the like). It may be configured to be executed every minute to 30 minutes.

  When the mode is switched to “MF = 1”, the process proceeds to “YES” in step S8 of FIG. Then, first, the CPU 10 performs screen display that allows the user to select a method for designating a requested area of image data (step S9). Then, it is determined whether or not a selection operation has been input via the touch panel 16 (step S10). If there is no input, it is determined whether or not the mode changeover switch of the key input unit 17 has been turned on (step S14). If there is no ON operation, the process returns to step S10, and the loop process of steps S10 and S14 is repeated until an input is received.

  If there is a time difference input selection operation during the above loop processing, the process proceeds to the “time difference” side in step S10, and the value of the mode flag “MF” is changed to “3” (step S12). On the other hand, if there is a position input selection operation based on latitude and longitude, the process proceeds to the “position” side in step S10, and the value of the mode flag “MF” is changed to “2” (step S11). Then, the display output is cleared (step S13), and the process proceeds to a response process for the server 40 in FIG.

  If there is a mode switching operation during the loop processing, the process proceeds to “YES” in step S14, and the value of the mode flag “MF” is changed to “0” (the value of the self-photo display mode). (Step S15). Then, the display output is cleared (step S16), and the process proceeds to a response process for the server 40 in FIG.

  The subsequent response process for the server 40 in FIG. 9 is as described above. When this response process is completed, the process returns to the branch process (steps S2, S8, S17, S29, S41) based on the value of the mode flag “MF” again.

  When the position input selection operation is performed and “MF = 2” is obtained, the process proceeds to “YES” in step S17 of FIG. Then, first, the CPU 10 displays a screen for allowing the user to input latitude and longitude (step S18). And it is discriminate | determined whether the latitude longitude input was performed via the touch panel 16 (step S19), and if not yet, it will be discriminate | determined whether there has been ON operation of the mode change switch of the key input part 17 (step S26). If there is no ON operation, the process returns to step S19, and the loop process of steps S19 and S26 is repeated until an input is received.

  If the latitude and longitude are input during the loop process, the process proceeds to “YES” in step S19, and the CPU 10 activates the GPS antenna 22 and the GPS control unit 23 to execute the positioning process (step S20). ). Then, the latitude and longitude data of the current position (referred to as the current position) is acquired from the GPS control unit 23 (step S21). The current position data and the latitude and longitude data input in step S19 are obtained. It transmits to the server 40 (step S22).

  The data transmission in step S22 is for requesting an image, presenting information indicating the requested area, and registering its own location information. That is, the image request and the information on the requested area are represented by the transmission of the latitude and longitude data representing the requested area. Further, by transmitting the data of the current position, the position information of itself is registered in the database of the server 40, and an image request can be accepted.

  If data transmission is performed to the server 40, the reception process of the data transmitted from the server 40 will be performed until completion (step S23). Here, if there is requested image data, the image data is sent from the server 40. When the reception is completed, the display output is cleared (step S24), and the value of the mode flag “MF” is changed to “4” (step S25).

  On the other hand, if the mode selector switch is turned on during the loop processing of steps S19 and S26, the value of the mode flag “MF” is changed to “1” (step S27), and the display output is cleared (step S28). .

  Thereafter, the response process for the server 40 in FIG. 9 described above is executed, and the process returns to the branch process (steps S2, S8, S17, S29, and S41) based on the value of the mode flag “MF”.

  On the other hand, when a time difference input selection operation is performed in the selection process of step S10 and “MF = 3” is established, the process proceeds to “YES” in step S29 of FIG. First, the CPU 10 displays a screen for allowing the user to input a time difference for designating the image request destination area (step S30). Next, it is determined whether or not a time difference has been input via the touch panel 16 (step S31). If not, it is determined whether or not the mode changeover switch of the key input unit 17 has been turned on (step S38). If there is no ON operation, the process returns to step S31, and the loop process of steps S31 and S38 is repeated until an input is made.

  If a time difference is input during the above loop processing, the process proceeds to “YES” in step S31, and the GPS antenna 22 and the GPS control unit 23 are activated to perform positioning processing (step S32). Then, the latitude and longitude data of the current position (referred to as the current position) is acquired from the GPS control unit 23 (step S33), and the current position data and the time difference data input in step S31 are stored in the server 40. Transmit (step S34).

  The data transmission in step S34 is for requesting an image, presenting information indicating the requested area, and registering its own location information. In other words, the image request and the information on the requested area are represented by the time difference representing the requested area and the data transmission of the current position. Here, the requested area is represented as an area that is separated from the current position by a time difference. Further, by transmitting the data of the current position, the position information of itself is registered in the database of the server 40, and an image request can be accepted.

  If data transmission is performed to the server 40, the reception process of the data transmitted from the server 40 will be performed until completion (step S35). Here, if there is requested image data, the image data is sent from the server 40. When reception is completed, the display output is cleared (step S36), and the value of the mode flag “MF” is changed to “4” (step S37).

  On the other hand, if the mode switch is turned on during the loop processing of steps S31 and S38, the value of the mode flag “MF” is changed to “1” (step S39), and the display output is cleared (step S40). .

  Thereafter, the response process for the server 40 in FIG. 9 described above is executed, and the process returns to the branch process (steps S2, S8, S17, S29, and S41) based on the value of the mode flag “MF”.

  When data is received from the server 40 and “MF = 4” is obtained through steps S23 to S25 (FIG. 6) and S35 to S37 (FIG. 7), the “YES” side in step S41 of FIG. Migrate to Then, first, if there is image data received from the server 40, the CPU 10 sends this image data to the display control unit 15 to display it on the liquid crystal display panel 14 (step S42).

  Next, it is confirmed whether the mode selector switch of the key input unit 17 is turned on (step S43). If there is an on operation, the display output is cleared (step S44), and the value of the mode flag “MF” is set to “0”. To "" (step S45). Thereafter, the process proceeds to a response process for the server 40 of FIG. On the other hand, if the mode switch is not turned on, the process directly proceeds to the response process for the server 40 in FIG.

  When the response process described above is executed, the process returns to the branch process (steps S2, S8, S17, S29, and S41) based on the value of the mode flag “MF”.

  As a result of the above-described control process of the electronic photo stand 1, while the user selects the self-photo display mode, the electronic photo stand 1 displays and outputs an image taken by itself. On the other hand, when the user switches to the external photo display mode and inputs to specify the image request destination area, the server 40 requests image data of this area, and when image data is sent based on this request. The image data is received and the display of the image is output.

  In the above flowchart, in the external photo display mode, when the user designates the image request destination area, the image request and the image data are received, and thereafter, this mode is changed to the self-photo display mode. The display of the received image is sometimes continued, but it may be changed as follows. For example, when the user designates an image request destination area, an image request and image data are received every predetermined time (for example, every 5 minutes to 1 hour), and an image to be displayed and output is switched. It may be configured. Further, it may be configured such that the user can select a time interval at which the request for the image is performed.

  10 and 11 show flowcharts of server processing executed by the CPU of the server 40. FIG.

  When this server process is started, first, the CPU of the server 40 repeats the monitoring process (step J1) to determine whether or not there is a signal received from the electronic photo stands 1 at various locations.

  If there is a reception and the process proceeds to the next, the CPU first determines whether or not the data of the current position has been received (step J2). If it is not this data, it determines whether or not the time difference data representing the image request destination area has been received. If it is not this data (step J6), it is determined whether or not position data representing the image request destination area has been received (step J14). If it is not this data, it is determined whether or not image data has been received (step J17). .

  As a result, if it is determined that the current position data has been received, the process proceeds to the “YES” side of step J2, and the CPU of the server 40 acquires the current position information from the received data (step J3), and the database It is confirmed whether it is already registered in 41 (step J4). If it is not registered, it is registered in the database 41 as new current position information (step J5: position information registration means). At the time of registration, registration is performed in association with identification information that identifies the electronic photo frame 1 of the data transmission source and enables data communication. Thereafter, the process returns to step J1. On the other hand, if already registered, the process directly returns to step J1.

  If the time difference data is received in the signal reception at step J1, it is determined at step J6, and the process proceeds to “YES” in step J6. Then, the CPU first searches the database 41 to determine whether or not information on the current position of the electronic photograph stand 1 as the data transmission source has been received (step J7). As a result, if it has not been received, the process returns to step J1 without responding to the image request.

  On the other hand, if the current position information has been received, the time zone including the current position is searched (step J8), and the time zone of the image request destination separated by the time difference received from this time zone is calculated ( Step J9). Then, the position information included in the time zone of the image request destination is searched from the database 41 (step J10: search means). Then, the presence / absence of position information included in this time zone is determined (step J11). If there is position information, an image request command is transmitted to the electronic photo frame 1 associated with the searched position information ( Step J12), returning to step J1. On the other hand, if there is no position information, a “none” command indicating that there is no requested image data is transmitted to the electronic photo frame 1 that has transmitted the time difference data (step J13), and the process returns to step J1.

  When a plurality of pieces of position information included in the time zone of the image request destination are found from the database 41 in the search process of step J10, one piece of position information is randomly extracted from these and is associated with this position information. In step J12, an image request command is transmitted to the electronic photo frame 1.

  If the same image request is repeatedly made at predetermined time intervals in the external photo display mode in the electronic photo frame 1, 1 is selected from among a plurality of position information included in the time zone of the image request destination. It is also possible to select one position information from one end to the other end so as to change in order at an appropriate interval, and to transmit an image request command to the electronic photo frame 1 of the selected position information. With this configuration, the electronic photo frame 1 can display a photograph of a designated area as an image request destination while gradually changing from a west side to an east side or vice versa.

  On the other hand, when the position data of the latitude and longitude representing the image request destination area is received by the signal reception in step J1, it is determined in step J14, and the process proceeds to “YES” in step J14. Then, the CPU first searches the database 41 to determine whether or not information on the current position of the electronic photograph stand 1 as the data transmission source has been received (step J15). As a result, if it has not been received, the process returns to step J1 without responding to the image request.

  If it is determined in step J15 that the image has been received, the CPU searches the database 41 for the position information that is the same as the image request destination received or included in a predetermined range from this position (step J16: Search means). Then, the process proceeds to step J11 to determine the presence / absence of position information. If there is, the image request command is transmitted to the corresponding electronic photo frame 1, and if not, the “none” command is sent to the data transmission source electronic photo frame 1. Transmit (step J13). Then, the process returns to step J1.

  If the image data is received by the signal reception in step J1, it is determined in step J17, and the process proceeds to “YES” in step J17. Then, the CPU transfers the image data to the electronic photo frame 1 to which the current position information and time difference data or position data has been sent (step J18: image data transfer means). Then, the process returns to step J1.

  By such server processing, data of each current position is received from a plurality of electronic photo stands 1 and registered in the database 41 in association with each identification information, or a request for image data is received from the electronic photo stand 1 Each process such as issuing a request for image data to another corresponding electronic photo frame 1 or receiving the image data sent in response to the request and transferring it to the requesting electronic photo frame 1 is realized. It has become.

  As described above, according to the electrophotographic stand 1 and the electrophotographic exchange system of this embodiment, the image data obtained by photographing through the communication network is exchanged between the plurality of electrophotographic stands 1 and each photo is taken. Can be displayed. With this function, the user can display and enjoy an unknown landscape image like a photograph, and can deliver his or her own proud landscape image to other users.

  Further, according to the electrophotographic frame 1 and the electrophotographic exchange system of the above embodiment, each electrophotographic frame 1 transmits its own current position data, and the current position of the electrophotographic frame 1 that can exchange image data is determined. At the same time, the user requests the image data by designating the image request destination area. Therefore, the user can request and display a landscape image of a desired region from all over the country. With this function, for example, by requesting and displaying a landscape image of a travel destination before a trip, it becomes possible to check various local conditions such as the climate and clothes. In addition, when a mountain climber or an earth marathon runner is equipped with the electronic photo frame 1, it is possible to receive and display a rare landscape image that the user cannot go to.

  Further, since the current position of the electronic photo stand 1 is acquired by GPS positioning, it is possible to register the current position more accurately and without error than the configuration in which the user inputs it.

  In addition, to specify the image request destination area, a method of inputting the time difference and specifying the area can be selected. By selecting this specifying method, the user can easily specify the area. .

  In addition, since the server 40 is interposed between the plurality of electronic photo frames 1 and image data is exchanged, it is possible to reduce the load of communication processing of each electronic photo frame 1. Security management of the electronic photo stand 1 can also be easily performed.

  In addition, a database 41 in which data of current positions of a plurality of electronic photo stands 1 and identification information are registered in association with each other is provided in the server 40. From the database 41, the electronic photo stands 1 in the image request destination area are provided. Since the image data is requested after being searched, the exchange of the image data based on the area designation can be realized with easy control.

  The present invention is not limited to the above-described embodiment, and various modifications can be made. For example, in the above-described embodiment, an example in which the camera unit 21 is provided integrally with the main body of the electrophotographic stand 1 has been described. However, the camera unit is configured to be connected to the main body via a wired cable or wirelessly. The installation position of the main body where the image display is performed and the shooting position by the camera unit may be set apart from each other.

  In the above embodiment, the system configuration in which the image data is exchanged via the server 40 is illustrated. However, the plurality of electronic photo stands 1 directly send a request for image data, or in response to this request. Image data can also be exchanged and configured directly.

  In the above embodiment, the image data captured when the image data request is made is exchanged. However, the image data prepared in advance by photographing the electronic photo frame 1 is exchanged as required. It is good also as a structure made.

  Moreover, in the said embodiment, although it was set as the structure which acquires the data of the present position of the electronic photo stand 1 by GPS positioning, it is good also as a structure which inputs a present position by a user. In the above embodiment, the data of the current position of the electronic photo frame 1 is registered in the server 40 so that a request for image data can be received from the electronic photo frame 1. When image data obtained by photographing from 1 is sent to the server 40 and is determined to be a normal image, a request for image data from the electronic photo frame 1 may be accepted. Further, the image data to be exchanged may be stored in advance in the server 40, and image data corresponding to the request may be extracted from the stored image data and sent to the request source.

  In addition, the detailed configuration and the detailed method shown in the embodiments can be appropriately changed without departing from the spirit of the invention.

1 Electrophotographic frame 10 CPU (response control means, request control means, position information transmission means)
11 Internal memory 12 ROM
13 RAM
14 Liquid crystal display panel (display unit)
15 Display control part 16 Touch panel (input means)
17 Key input part (input means)
18 Key input control unit 21 Camera unit (photographing means)
21a Lens 22 GPS antenna 23 GPS control unit (position information acquisition means, satellite positioning means)
24 Communication control unit (communication means)
30 communication network 40 server 41 database

Claims (12)

A display unit for displaying images;
Photographing means for photographing,
A communication means capable of data communication by connecting to a communication network;
Response control means for sending image data obtained by the photographing when the photographing means performs photographing and receiving a request for image data from the outside via the communication means;
A request for image data taken by another electronic photo stand is transmitted to the outside via the communication means, and when the image data is sent based on the request, the image data is received and the display unit Request control means to be displayed on,
An electronic photo stand characterized by comprising: Position information acquisition means for acquiring self-position information representing the position of the user;
An input means for inputting origin information regarding the origin position of the requested image data;
Position information transmission means for transmitting the self-position information acquired by the position information acquisition means to the outside via the communication means;
With
The request control means includes
2. The electronic apparatus according to claim 1, further comprising requesting image data of another electrophotographic frame using the position information included in the area corresponding to the origin information input by the input means as the self-position information. Picture Frames.   3. The electrophotographic frame according to claim 2, wherein the position information acquisition means is satellite positioning means for receiving a signal from a positioning satellite and performing positioning. The origin information input by the input means is time difference information,
The request control means is an image of another electrophotographic frame in which the position information included in an area that is separated from the self-position information acquired by the position information acquisition means is the self-position information. The electrophotographic frame according to claim 2, wherein data is requested. A plurality of electrophotographic frames according to any one of claims 1 to 4;
In response to a request for image data from the electronic photo frame, a request for image data is sent to another electronic photo frame, and when image data is sent from the other electronic photo frame based on this request, A server device for transferring image data to the requesting electronic photo frame;
An electrophotographic exchange system characterized by comprising: The server device is
Position information registration means for registering the plurality of electrophotographic frames and the self-location information in a database in association with each other when the self-location information is received from the plurality of electrophotographic frames;
When a request for image data and the origin information are received from the electronic photo frame, a position included in an area corresponding to the received source information is selected from the plurality of electronic photo frames registered in the database. Search means for searching other electronic photo frames with the information as the self-location information;
An image data transfer means for transmitting a request for image data to the electronic photo frame searched by the search means, and transferring the image data sent based on the request to the electronic photo frame of the request source;
The electrophotographic exchange system according to claim 5, further comprising: An apparatus comprising: a display unit that displays an image; an imaging unit that performs imaging; a communication unit that is connected to a communication network and is capable of data communication; and a control unit that controls the display unit, the imaging unit, and the communication unit An electrophotographic exchange method for exchanging and displaying an electrophotographic image,
The control unit causes the photographing unit to perform photographing, and transmits image data obtained by the photographing through the communication unit when receiving a request for image data from the outside through the communication unit. A response control step;
The control unit sends a request for image data taken by another device to the outside via the communication means, and receives image data when image data is sent based on the request. A request control step to be displayed on the display unit;
An electrophotographic exchange method comprising: 8. The electrophotographic apparatus according to claim 7, wherein the electrophotographic image is exchanged and displayed by the apparatus including position information acquisition means for acquiring self-position information representing the position of the user and input means for inputting information from the outside. An exchange method,
A position information transmission step in which the control unit transmits the self-position information acquired by the position information acquisition means to the outside via the communication means;
A source information input step in which the control unit inputs source information regarding the source position of the requested image data via the input means;
Including
The request control step includes:
8. The electronic apparatus according to claim 7, further comprising requesting image data of another electrophotographic frame using the position information included in the area corresponding to the origin information input by the input means as the self-position information. Photo exchange method. The origin information input by the origin information input step is time difference information,
In the request control step, an image of another electrophotographic frame in which the position information included in an area that is different from the time difference information by the time difference information from the self position information acquired by the position information acquisition unit is the self position information. 9. The electrophotographic exchange method according to claim 8, wherein data is requested. A computer that controls a display unit that performs image display, a photographing unit that performs photographing, and a communication unit that is connected to a communication network and can perform data communication.
A response control function for transmitting image data obtained by the imaging through the communication unit when the imaging unit performs imaging and receiving a request for image data from the outside through the communication unit;
A request for image data taken by another device is transmitted to the outside via the communication means, and when image data is sent based on the request, the image data is received and displayed on the display unit. A request control function,
A program that realizes Furthermore, the computer for controlling the position information acquisition means for acquiring the self-position information representing the position of the self, and the input means for inputting information from the outside,
A position information transmission function for transmitting the self-position information acquired by the position information acquisition means to the outside via the communication means;
A source information input function for inputting source information regarding the source position of the requested image data via the input means;
Realized,
The request control function is:
11. The program according to claim 10, further comprising requesting image data of another electrophotographic frame using the position information included in the area corresponding to the origin information input by the input means as the self-position information. . The origin information input by the origin information input function is time difference information,
The request control function is an image of another electrophotographic frame in which the position information included in an area that is separated by the time difference of the time difference information from the self position information acquired by the position information acquisition unit is the self position information. 12. The program according to claim 11, wherein the program requests data.

Images