JP6441987B2 - Electronic shelf label terminal - Google Patents

Description

Embodiments described herein relate generally to an electronic shelf label terminal .

  The electronic shelf label terminal is usually attached to the front of the product shelf in order to display the price of the product displayed on the product shelf to the shopper. In such an electronic shelf label terminal, one that can switch from a first screen that displays the price of a product to a second screen that displays other information is already known.

  If the second screen can be used to display information having an advertising effect on the customer (hereinafter referred to as customer information), the electronic shelf label terminal can be used more effectively. However, since the electronic shelf label terminal is small in size and the amount of information that can be displayed is limited, it is difficult to display customer information with a large amount of information on one electronic shelf label terminal. When the amount of customer information is large, it is conceivable to display customer information separately on a plurality of electronic shelf label terminals. In this case, it is necessary to simultaneously switch the display screens of the plurality of electronic shelf label terminals to the second screen. For that purpose, for example, a synchronization signal is distributed from a server that manages each electronic shelf label terminal, and each electronic shelf label terminal that receives this synchronization signal switches the display screen from the first screen to the second screen. do it.

  However, in the method of distributing the synchronization signal, each electronic shelf label terminal must be in a state where it can always receive the synchronization signal. The standby state for receiving the synchronization signal consumes power. Usually, an electronic shelf label terminal is equipped with a battery as a main power source, and power consumption due to a standby state for receiving a synchronization signal leads to shortening of the battery life. For this reason, the method for distributing the synchronization signal cannot be applied.

No. 2008-123046

Problems to be Solved one embodiment, while suppressing the power consumption, is intended to provide an electronic shelf label terminal displays the pair customer information using a plurality of electronic shelf label terminal can be realized.

The electronic shelf label terminal of one embodiment includes a display unit, a first storage unit, a second storage unit, and a control unit. The first storage unit stores information related to the first character string. A 2nd memory | storage part memorize | stores the information regarding one character assembly of the 2nd character string different from a 1st character string divided | segmented by predetermined number . The control unit displays the first character string based on the information stored in the first storage unit, and then stores the information stored in the second image storage unit according to the end of the predetermined first display period. In response to the end of the second display period in which the character set is displayed based on the length of the first display period set to a length equal to or greater than a predetermined number of times, the information stored in the first storage unit is displayed. based display the first string, thereby that controls the display and display unit to repeat the display of the character clusters of the first string.

The whole block diagram of an electronic shelf label system. The perspective view which shows an example of the goods shelf with which the electronic shelf label terminal was attached. The front view which shows an example of an electronic shelf label terminal. The block diagram which shows the principal part structure of an electronic shelf label terminal. Explanatory drawing of the 1st image displayed on an electronic shelf label terminal, and a 2nd image. The flowchart which shows the control procedure which the controller of an electronic shelf label terminal performs. The schematic diagram which shows the example of a transition of the image displayed on an electronic shelf label terminal. The block diagram which shows the principal part structure of a shelf label server. The schematic diagram which shows the data structure of the shelf label record stored in a shelf label database. The schematic diagram which shows the data structure of the goods shelf record stored in a goods shelf database. The schematic diagram which shows the data structure of the update file delivered to a shelf label server from a POS server. The schematic diagram which shows the data structure of the 2nd image file delivered to a shelf label server from a POS server. The flowchart which shows the procedure of the reception process which CPU of the shelf label server which received the update file performs. The flowchart which shows the procedure of the reception process which CPU of the shelf label server which received the 2nd image file performs. The flowchart which shows the procedure of the reception process which CPU of the shelf label server which received the 2nd image file performs.

Hereinafter, an embodiment of an electronic shelf label system will be described with reference to the drawings.
[Description of electronic shelf label system]
FIG. 1 is an overall configuration diagram of an electronic shelf label system 1. The system 1 includes a shelf label server 11, a plurality of wireless repeaters 12, and a plurality of electronic shelf label terminals 13. The system 1 includes a network 14 such as a LAN (Local Area Network), and the network 14 connects the shelf label server (electronic shelf label server) 11 and the wireless repeater 12 so that they can communicate with each other. Furthermore, this system constructs a radio communication network 15 having a plurality of electronic shelf label terminals 13 as slave stations and any one of the radio repeaters 12 as a master station. Thus, the shelf label server 11 performs data communication with each electronic shelf label terminal 13 via the network 14, the wireless repeater 12, and the wireless communication network 15.

  Further, the shelf label server 11 is connected to a POS system server (hereinafter referred to as a POS server) 22 through a server-to-server network 21. The POS server 22 is associated with a product code for identifying each product, product-specific information such as the name (product name) and price (unit price) of the product, point-of-sale information such as the number of goods received, the number of products sold, and the number of stock Is managed. For example, when the price of a product is changed, the POS server 22 transmits the price information to the shelf label server 11 via the inter-server network 21. The shelf label server 11 specifies the electronic shelf label terminal 13 displaying the information of the product whose price has been changed by a known method, and transmits the changed price information to the electronic shelf label terminal 13. The electronic shelf label terminal 13 that has received the changed price information changes the price displayed on the display unit to the changed price.

[Description of electronic shelf label terminal]
As shown in FIG. 2, each electronic shelf label terminal 13 is attached to the front of a product shelf 30 on which each product is displayed. In the product shelf 30, each product is classified and displayed for each item, and each electronic shelf label terminal 13 is arranged on the product shelf 30 so that one electronic shelf label terminal 13 is assigned to one item. Is done. FIG. 2 shows a product shelf 30 that can display a total of nine items by dividing a three-stage shelf into three sections. In such a commodity shelf 30, nine electronic shelf label terminals 13 (13a to 13i) are arranged in a 3 × 3 matrix.

  As shown in FIG. 3, each electronic shelf label terminal 13 includes a display 132 as a display unit in front of a terminal main body 131 having a tag shape. The display 132 displays the name and price of the corresponding product as the first screen. Also, customer information that has an advertising effect on the customer can be displayed as the second screen.

  FIG. 4 is a block diagram showing a main configuration of the electronic shelf label terminal 13. In addition to the display device 132, the electronic shelf label terminal 13 includes a memory 133, a wireless circuit 134, a clock oscillator 135, a controller 136, and a battery 137. The battery 137 is a power source for driving the display 132, the memory 133, the wireless circuit 134, and the controller 136.

  The electronic shelf label terminal 13 forms at least a shelf label ID area 41, a first image area 42, a second image area 43, a set time area 44 and a multiple area 45 in the memory 133. The shelf label ID area 41 is an area for storing a unique terminal ID set for each terminal in order to identify each electronic shelf label terminal 13 individually. The first image area 42 and the second image area 43 are areas for storing first image data and second image data distributed from the shelf label server 11, respectively. The set time area 44 is an area for storing an arbitrary time T set as the display time of the first image data. The multiple area 45 is an area for storing a multiple n distributed from the shelf label server 11. The initial value of the multiple n is “0”, and a value of “2” or more is appropriately distributed from the shelf label server 11.

  The first image data is data for displaying an image specifying a product displayed on the product shelf 30 on which the electronic shelf label terminal 13 is arranged. The second image data is data for displaying an image of customer information. The image of customer information is divided into n parts, and each is displayed on each display 132 of n (n ≧ 2) electronic shelf label terminals 13 arranged in one direction at the same time. An image of customer information is established. Here, the first image area 42 functions as a first image storage unit, and the second image area 43 functions as a second image storage unit. The multiple area 45 functions as a numerical value storage unit that variably stores the multiple n.

  An example of the first image based on the first image data and the second image based on the second image data is shown in FIG. In this example, as a second image formed by simultaneously displaying on each of the display devices 132a, 132b, 132c of the three electronic shelf label terminals 13a, 13b, 13c, a character notifying that today is a special sale date This is the case of the image of the column “Today's Special Sale Day!”.

  When the character string “Today's special sale date !!” is displayed on the display unit 132 of one electronic shelf label terminal 13, the character is small and unnoticeable, so it is not appropriate. Therefore, in the example of FIG. 5, the character string “Today's special sale date !!” is divided into two to three characters from the beginning to the end of the sentence, and three character groups “Today”, “Special sale”, and “Day!” create. Then, for the three electronic shelf label terminals 13a, 13b, and 13c adjacent to each other, the character assembly “today” is displayed on the left electronic shelf label terminal 13a, and the character assembly is displayed on the central electronic shelf label terminal 13b. “Special sale” is displayed on the electronic shelf label terminal 13c on the right side, and the character aggregate “Sun!” Is displayed. By doing so, the character string “Today's special sale date !!” is displayed in large characters on the display devices 132a, 132b, 132c of the electronic shelf label terminals 13a, 13b, 13c.

  FIG. 6 is a flowchart showing a control procedure of the controller 136. This procedure is executed according to a control program installed in advance. The control program is activated when an activation command is received from the shelf label server 11. The activation command is distributed from the shelf label server 11 to each electronic shelf label terminal 13 at a preset time of one day, for example.

  When the control program is activated, the controller 136 first resets the timer counter t to “0” (Act1). Further, the controller 136 reads the first image data from the first image area 42, and causes the display 132 to display the first image based on this data (Act2). Note that the processing procedure of Act1 and Act2 may be reversed.

  When the first image data is displayed on the display 132, the controller 136 waits for a clock signal to be input from the clock oscillator 135 (Act3). When the clock signal is input (YES in Act 3), the controller 136 increments the timer counter t by “1” (Act 4). Then, the controller 136 determines whether or not the timer counter t has reached the time T set in the set time area 44 (Act 5). If the timer counter t has not reached time T (NO in Act 5), the controller 136 returns to the processing of Act 3 and waits for the next clock signal to be input. If the clock signal is input (YES in Act 3), the controller 136 increments the timer counter t by “1” (Act 4), and determines whether or not the time T has been reached (Act 5).

  In this way, the controller 136 counts up the timer counter t each time a clock signal is input, and waits for the timer counter t to reach time T. If timer counter t reaches time T (YES in Act 5), controller 136 determines whether multiple n in multiple area 45 is greater than “0” (Act 6). When the multiple n is “0” (NO in Act 6), the controller 136 returns to the process of Act 1.

  On the other hand, if the multiple n is not “0”, that is, “2” or more (YES in Act 6), the controller 136 reads the second image data from the second image area 43, and the second image data based on this data. Two images are displayed on the display 132 (Act7).

  When the second image data is displayed on the display device 132, the controller 136 waits for a clock signal to be input from the clock oscillator 135 (Act8). When the clock signal is input (YES in Act 8), the controller 136 increments the timer counter t by “1” (Act 9). Then, the controller 136 determines whether or not the timer counter t has reached the minimum display time nT of the second image (Act 5). The minimum display time nT of the second image is a value obtained by multiplying the time T set in the set time area 44 by the multiple n stored in the multiple area 45.

  When the timer counter t has not reached the minimum display time nT (NO in Act5), the controller 136 returns to the process of Act8 and waits for the next clock signal to be input. If the clock signal is input (YES in Act 8), the controller 136 increments the timer counter t by “1” (Act 4), and determines whether or not the minimum display time nT has been reached (Act 5). ).

  In this way, the controller 136 counts up the timer counter t each time a clock signal is input, and waits for the timer counter t to reach the minimum display time nT. If timer counter t has reached minimum display time nT (YES in Act 10), controller 136 returns to the processing of Act1. That is, the controller 136 resets the timer counter t to “0”. Further, the controller 136 reads the first image data from the first image area 42 and causes the display 132 to display the first image based on this data.

  Here, the controller 136 causes the display device 132 to display the first image stored in the first image area 42 for a predetermined time T, and then stores the second image stored in the second image area 43. The control unit is configured to repeat the control of displaying the image continuously for a time nT that is n times or more of a certain interval.

Here, as a specific example of the second image, as shown in FIG. 5, a case where the character string “Today's special sale date !!” is displayed using the three electronic shelf label terminals 13a, 13b, and 13c will be described.
In this case, with respect to the three electronic shelf label terminals 13a, 13b, and 13c adjacent to each other, the image data of “product A 500 yen” is stored as the first image data in the left electronic shelf label terminal 13a. Image data of the character aggregate “today” is stored as the second image data. In the central electronic shelf label terminal 13b, image data of “product B 400 yen” is stored as the first image data, and image data of the character aggregate “sale” is stored as the second image data. In the electronic shelf label terminal 13c on the right side, image data of “product C 250 yen” is stored as the first image data, and image data of the character aggregate “day !!” is stored as the second image data. Further, “3” is stored as a multiple n in the multiple area 45 of each electronic shelf label terminal 13a, 13b, 13c. In this state, the controller 136 of each electronic shelf label terminal 13a, 13b, 13c controls each part in the procedure shown in FIG.

  That is, after the controller 136 of the electronic shelf label terminal 13a displays the first image “product A 500 yen” for the time T on the display 132a, the second image “today” is continuously displayed for the time 3T. Repeat the control. The controller 136 of the electronic shelf label terminal 13b causes the display 132b to display the first image “product B 400 yen” for the time T and then continuously display the second image “special sale” for the time 3T. Repeat control. The controller 136 of the electronic shelf label terminal 13c displays the first image “Product C 250 Yen” for the time T on the display 132c, and then continuously displays the second image “Sun!” For the time 3T. Repeat the display control.

  7A to 7D are transition examples of images displayed on the display devices 132a, 132b, and 132c of the electronic shelf label terminals 13a, 13b, and 13c each time the time T elapses. In FIG. 7, symbol D1 indicates a first image, and symbol D2 indicates a second image.

  In the case of FIG. 7A, the electronic shelf label terminal 13a displays the first image “product A 500 yen” at the timing of time T = 1, 5, 9 and time T = 2-4, 6-8, The second image “Today” is displayed at a timing of 10 to 12. At the electronic shelf label terminal 13b, the first image “product B 400 yen” is displayed at the timing of time T = 2, 6, 10, and at the timing of time T = 1, 3-5, 7-9, 11-12. The second image “special sale” is displayed. At the electronic shelf label terminal 13c, the first image “product C 250 yen” is displayed at the timing of time T = 3, 7, 11 and at the timing of time T = 1-2, 4-6, 8-10, 12. The second image “Sun!” Is displayed. Therefore, during the period of time T = 4, 8, 12, the second images are displayed on the display devices 132a, 132b, 132c of the electronic shelf label terminals 13a, 13b, 13c, respectively. Is displayed.

  In the case of FIG. 7B, the electronic shelf label terminal 13a displays the first image “product A 500 yen” at time T = 1, 5, 9 and time T = 2-4, 6-8, The second image “Today” is displayed at a timing of 10 to 12. At the electronic shelf label terminal 13b, the first image “product B 400 yen” is displayed at the timing of time T = 2, 6, 10, and at the timing of time T = 1, 3-5, 7-9, 11-12. The second image “special sale” is displayed. At the electronic shelf label terminal 13c, the first image “product C 250 yen” is displayed at the timing of time T = 4, 8, 12 and the second image is displayed at the timing of time T = 1-3, 5-7, 9-11. The image “Sun!” Is displayed. Accordingly, during the period of time T = 3, 7, and 11, the second images are displayed on the display devices 132a, 132b, and 132c of the electronic shelf label terminals 13a, 13b, and 13c, respectively. Is displayed.

  In the case of FIG. 7C, the electronic shelf label terminal 13a displays the first image “product A 500 yen” at the timing of time T = 1, 5, 9, and time T = 2-4, 6-8, The second image “Today” is displayed at a timing of 10 to 12. At the electronic shelf label terminal 13b, the first image “product B 400 yen” is displayed at the timing of time T = 3, 7, 11 and at the timing of time T = 1-2, 4-6, 8-10, 12. The second image “special sale” is displayed. At the electronic shelf label terminal 13c, the first image “product C 250 yen” is displayed at the timing of time T = 4, 8, 12 and the second image is displayed at the timing of time T = 1-3, 5-7, 9-11. The image “Sun!” Is displayed. Therefore, during the period of time T = 2, 6, and 10, the second image is displayed on each of the display devices 132a, 132b, and 132c of the electronic shelf label terminals 13a, 13b, and 13c. Is displayed.

  In the case of FIG. 7D, the electronic shelf label terminal 13a displays the first image “product A 500 yen” at the timing of time T = 4, 8, 12, and time T = 1-3, 5-7, The second image “Today” is displayed at timings 9 to 11. At the electronic shelf label terminal 13b, the first image “product B 400 yen” is displayed at the timing of time T = 2, 6, 10, and at the timing of time T = 1, 3-5, 7-9, 11-12. The second image “special sale” is displayed. At the electronic shelf label terminal 13c, the first image “product C 250 yen” is displayed at the timing of time T = 3, 7, 11 and at the timing of time T = 1-2, 4-6, 8-10, 12. The second image “Sun!” Is displayed. Therefore, during the period of time T = 1, 5, and 9, the second image is displayed on the display devices 132a, 132b, and 132c of the electronic shelf label terminals 13a, 13b, and 13c, respectively. Is displayed.

  Thus, according to the present embodiment, it is possible to display customer information with a large amount of information using a plurality of electronic shelf label terminals 13. In this case, the electronic shelf label terminal 13 does not necessarily have to be in a state where it can always receive the synchronization signal, and therefore there is no concern that the power of the electronic shelf label terminal 13 is consumed due to the reception standby state. Thus, it is possible to provide the electronic shelf label system 1 that can realize the display of customer information using the plurality of electronic shelf label terminals 13 while suppressing the power consumption of the electronic shelf label terminal.

[Description of shelf label server]
FIG. 8 is a block diagram showing a main configuration of the shelf label server 11. As illustrated, the shelf label server 11 includes a CPU (Central Processing Unit), a ROM (Read Only Memory) 112, a RAM (Random Access Memory) 113, an auxiliary storage device 114, a first communication interface 115, and a second communication interface. 116 is included. The shelf label server 11 connects the CPU 111, the ROM 112, the RAM 113, the auxiliary storage device 114, the first communication interface 115, and the second communication interface 116 via a bus line 117 such as an address bus or a data bus. A control circuit is configured.

  The CPU 111 corresponds to the central part of the computer. The CPU 111 controls each unit to implement various functions as the shelf label server 11 according to the operating system and application programs.

  The ROM 112 corresponds to a main storage portion of the computer. The ROM 112 stores the above operating system and application programs. The ROM 112 may store data necessary for the CPU 111 to execute processing for controlling each unit.

  The RAM 113 corresponds to the main storage portion of the computer. The RAM 113 stores data necessary for the CPU 111 to execute processing. The RAM 113 is also used as a work area where information is appropriately rewritten by the CPU 111.

  The auxiliary storage device 114 corresponds to the auxiliary storage portion of the computer. The auxiliary storage device 114 is, for example, an EEPROM (Electric Erasable Programmable Read-Only Memory), an HDD (Hard Disc Drive), or an SSD (Solid State Drive). The auxiliary storage device 114 stores data used when the CPU 111 performs various processes, and data generated by the process in the CPU 111. The auxiliary storage device 114 may store the above application program.

  The first communication interface 115 performs data communication with the POS server 22 connected via the inter-server network 21 according to a predetermined communication protocol. The second communication interface 116 performs data communication with each wireless relay device 12 connected via the network 14 according to a predetermined communication protocol.

  The shelf label server 11 stores the shelf label database 51 and the commodity shelf database 52 in the auxiliary storage device 114.

  The shelf label database 51 stores shelf label records 51R created for each electronic shelf label terminal 13. The data structure of the shelf label record 51R is shown in FIG. As illustrated, the shelf label record 51R includes items of shelf label ID, shelf classification, product code, first image data, and second image data.

  The shelf label ID is an ID stored in the shelf label ID area 41 of the electronic shelf label terminal 13 corresponding to the shelf label record 51R.

  The shelf classification is data specifying the location of the product shelf 30 where the electronic shelf label terminal 13 corresponding to the shelf label record 51R is arranged. The shelf classification includes a shelf number i, a column number j, and a section number k. The shelf number i is a serial number from “1” uniquely assigned to each product shelf 30. The stage number j is a serial number from “1” assigned to each stage of the product shelf 30 one by one from the top. The section number k is a serial number from “1” assigned to the section in the commodity shelf 30 in which one item of goods at each stage is displayed in order from the left side toward the commodity shelf 30. For example, in FIG. 2, when the shelf number i of the product shelf 30 on the left side is set to “1”, the shelf label record 51R for the electronic shelf label terminal 13a arranged in the leftmost section in the uppermost stage of the product shelf 30 is displayed. The shelf classification [i, j, k] is [1, 1, 1]. Further, the shelf classification [i, j, k] of the shelf label record 51R for the electronic shelf label terminal 13b arranged in the left section becomes [1, 1, 2], and the electronic shelf label arranged in the right end section. The shelf classification [i, j, k] of the shelf label record 51R for the terminal 13c is [1, 1, 3].

  The product code is an identification code of a product displayed in a section of the product shelf 30 where the electronic shelf label terminal 13 corresponding to the shelf label record 51R is arranged.

  The first image data and the second image data are image data stored in the first image area 42 and the second image area 43 of the electronic shelf label terminal 13 corresponding to the shelf label record 51R, respectively.

  Here, the shelf label database 51 functions as a shelf label position storage unit that stores position information (shelf classification) of the plurality of electronic shelf label terminals 13 with respect to the product shelf 30.

  The product shelf database 52 stores product shelf records 52 </ b> R created for each product shelf 30. The data structure of the merchandise shelf record 52R is shown in FIG. As shown in the figure, the merchandise shelf record 52R includes a pair of data of a shelf number i, a step number J, and step numbers 1 to J corresponding to the number of steps and division numbers K1 to KJ.

  The number of stages J is the number of stages of the commodity shelf 30 specified by the shelf number i of the commodity shelf record 52R. The paired data includes the stage numbers 1 to J assigned to the respective stages of the product shelf 30 specified by the shelf number i of the product shelf record 52R, and the partition number K1 of the stage specified by the stage numbers 1 to J. ~ KJ.

[About product shelf management]
Information on what products are displayed in each section of the product shelf 30 is managed by the POS server 22. Specifically, the POS server 22 sets the shelf classification [i, j, k] of the section in which the product is displayed together with the product name and price of the product in association with the product code of each product. Has a product data file. For example, when there is a change in the display location of the product, the POS server 22 changes the shelf classification associated with the product code of the product. Further, when there is a change in the price of the product, the POS server 22 changes the price associated with the product code of the product. The POS server 22 distributes the update file 61 to the shelf label server 11 when the data (shelf category or price) of the product data file is changed. As shown in FIG. 11, the update file 61 includes a total number M of products whose data has been changed, and update data for the total number M. The update data includes the product code, the shelf category, the product name, and the price of the product whose shelf category or price has been changed.

  The CPU 111 of the shelf label server 11 that has received the update file 61 starts reception processing of the procedure shown in the flowchart of FIG. This processing procedure is in accordance with a program stored in the ROM 112 or the auxiliary storage device 114. Note that the contents of the process shown in FIG. 13 and described below are merely examples, and various processes capable of obtaining similar results can be used as appropriate.

  First, the CPU 111 detects the total number M from the update file 61 and sets it as the initial value of the subtraction counter c (Act 21). Next, the CPU 111 detects update data m (1 ≦ m ≦ M) from the update file 61 (Act 22). Then, the CPU 111 searches the shelf label database 51 with the shelf classification of the update data m (Act 23), and determines whether there is a shelf label record 51R with the same shelf classification (Act 24).

  When the corresponding shelf label record 51R does not exist (YES in Act 24), the CPU 111 proceeds to the process of Act 27 without executing the processes of Act 25 and Act 26. If the corresponding shelf label record 51R exists (YES in Act 24), the CPU 111 executes the processing of Act 25 and Act 26, and then proceeds to the processing of Act 27.

  In Act 25, the CPU 111 changes the product code of the corresponding shelf label record 51R to the product code of the update data m. In Act 26, the CPU 111 changes the first image data of the corresponding shelf label record 51R to an image including the product name and price of the update data m. Note that the processing procedure of Act 25 and Act 26 may be reversed. Further, when the update item of the update data m is only the shelf classification, the process of Act 26 may be omitted, and when the update item is only the price, the process of Act 25 may be omitted. However, in that case, the CPU 111 needs to be configured to identify whether the update item of the update data m is either the shelf classification or the price.

In Act 27, the CPU 111 counts down the subtraction counter c by “1”. Then, the CPU 111 checks whether or not the subtraction counter c has become “0” (Act 28).
When subtraction counter c is greater than “0” (NO in Act 28), unprocessed update data m exists in the update file. Therefore, the CPU 111 returns to the processing of Act22. That is, the CPU 111 detects unprocessed update data m from the update file, and executes the processes of Act23 to Act28 again using the update data m.

  When the processing of Act 23 to Act 28 is executed for all the update data m included in the update file, the subtraction counter c becomes “0”. When subtraction counter c becomes “0” (YES in Act 28), CPU 111 executes shelf label communication processing. That is, the CPU 111 distributes each shelf label record 51R in the shelf label database 51 to the electronic shelf label terminal 13 identified by the shelf label ID of the shelf label record 51R (Act 29). When the shelf label communication process ends, the CPU 111 ends the reception process.

  Thus, in the electronic shelf label terminal 13 in which the product displayed in the corresponding section is replaced, the product name and price of the replaced product are displayed as the first image. In addition, in the electronic shelf label terminal 13 in which the price of the product displayed in the corresponding section is changed, the price displayed in the first image is updated to the changed price.

[Management of customer information]
Customer information displayed using a plurality of electronic shelf label terminals 13 is also managed by the POS server 22. That is, the POS server 22 accepts input of customer information via the input device. The customer information includes divided image data G1 to GN for the number N of connections, the connection direction XorY, and the number N of connections. The number N of connections is the number of electronic shelf label terminals 13 necessary for displaying customer information. The connection direction XorY is an arrangement direction of the N electronic shelf label terminals 13 that display customer information. In the present embodiment, the direction parallel to the top surface of the shelf of the product shelf 30 is defined as the X direction, and the perpendicular direction is defined as the Y direction. The divided image data G1 to GN are data obtained by dividing customer information by the number N of connections. When receiving the customer information input, the POS server 22 transmits the second image file 62 storing the customer information to the shelf label server 11 as shown in FIG.

  The CPU 111 of the shelf label server 11 that has received the second image file 62 starts reception processing of the procedure shown in the flowcharts of FIGS. This processing procedure is in accordance with a program stored in the ROM 112 or the auxiliary storage device 114. Note that the contents of the processes illustrated in FIGS. 14 and 15 and described below are merely examples, and various processes capable of obtaining similar results can be used as appropriate.

  First, the CPU 111 detects information on the connecting direction XorY from the second image file 62, and determines the direction XorY specified by this information (Act31). When the connecting direction is the X direction, the CPU 111 executes the processes of Act32 to Act45 shown in FIG. 14, and when the connecting direction is the Y direction, the CPU 111 executes the processes of Act51 to Act65 shown in FIG.

  That is, when the connection direction is the X direction, the CPU 111 initializes the shelf number counter i to “0” (Act 32). Next, the CPU 111 counts up the shelf number counter i by “1” (Act 33). Then, the CPU 111 determines whether or not the shelf number counter i exceeds the maximum value imax of the shelf number (Act 34).

  The shelf number i is a serial number from “1” uniquely assigned to each product shelf 30 as described above. Therefore, the maximum value imax of the shelf number corresponds to the total number of product shelves. That is, when the shelf number counter i exceeds the maximum value imax of the shelf number (YES in Act 34), the processing after Act 35 is executed for all the product shelf records 52R managed in the product shelf database 52. Means that.

When the shelf number counter i does not exceed the maximum value imax (NO in Act 34), that is, when there is an unprocessed product shelf record 52R, the CPU 111 obtains the value of the shelf number counter i from the product shelf database 52 as the shelf number. The product shelf record 52R is detected (Act35).
Further, the CPU 111 initializes the stage number counter j to “0” (Act 36). In addition, the processing order of Act35 and Act36 is not limited to this, The front and back may be reverse.

  Next, the CPU 111 increments the stage number counter j by “1” (Act 37). Then, the CPU 111 determines whether or not the stage number counter j exceeds the stage number J of the commodity shelf record 52R (Act 38). When the stage number counter j does not exceed the stage number J (NO in Act 38), the CPU 111 obtains the partition number Kj of a pair of data having the stage number value as the stage number from the product shelf record 52R, and this partition number Kj. Is greater than or equal to the number N of connections of the second image file 62 (Act 39).

  If the number of sections Kj is less than the number of connections N, the electronic shelf label terminals 13 necessary for displaying customer information of the number N of connections are not arranged in the horizontal direction on the shelf with the column number j. Therefore, when the partition number Kj is less than the connection number N (NO in Act 39), the CPU 111 returns to the process of Act 37. That is, the CPU 111 further increments the stage number counter j by “1”, and determines whether or not the electronic shelf label terminals 13 having the number N or more connected are arranged in the horizontal direction on the shelf of the next stage.

  If the section number Kj is equal to or greater than the connection number N, the electronic shelf label terminals 13 necessary for displaying the customer information of the connection number N are arranged on the shelf with the column number j. Therefore, when the number of partitions Kj is equal to or greater than the connection number N (YES in Act 39), the CPU 111 initializes the partition number counter k and the data number counter d to “0” (Act 40). Next, the CPU 111 increments the partition number counter k by “1” (Act 41). Further, the CPU 111 increments the data number counter d by “1” (Act 42). Then, the CPU 111 searches the shelf label database 51, and as the second image data for the shelf label record 51R whose shelf classification (i, j, k) matches the shelf number counter i, the stage number counter j, and the section number counter k. Then, the image division data Gd of the second image file 62 is set (Act 43: determination means). The processing order of Act 41 and Act 42 is not limited to this, and the order may be reversed.

  Thereafter, the CPU 111 determines whether or not the data number counter d has reached the connection number N (Act 44). Until the data number counter d reaches the connection number N, the allocation of the image division data Gd included in the second image file 62 to the electronic shelf label terminal 13 is not completed. Therefore, when data number counter d has not reached connection number N (NO in Act 44), CPU 111 returns to the processing of Act 41. That is, the CPU 111 increments the partition number counter k and the data number counter d by “1”. The CPU 111 sets the image division data Gd for the shelf label record 51R in which the shelf classification (i, j, k) matches the shelf number counter i, the stage number counter j, and the section number counter k.

  When the data number counter d reaches the connection number N, the allocation of the image division data Gd included in the second image file 62 to the electronic shelf label terminal 13 is completed. Therefore, when the data number counter d reaches the connection number N (YES in Act 44), the CPU 111 returns to the process of Act 37. That is, the CPU 111 further increments the stage number counter j by “1”. Thus, the CPU 111 repeatedly executes the processes of Act39 to Act44 until the stage number counter j exceeds the stage number J.

  If the stage number counter j exceeds the stage number J (YES in Act 38), the CPU 111 returns to the process of Act 33. That is, the CPU 111 further increments the shelf number counter i by “1”. Thus, the CPU 111 repeatedly executes the processes after Act 35 until the shelf number counter i exceeds the maximum value imax.

  If shelf number counter i exceeds maximum value imax (YES in Act 34), CPU 111 executes shelf label communication processing. That is, the CPU 111 distributes each shelf label record 51R of the shelf label database 51 to the electronic shelf label terminal 13 identified by the shelf label ID of the shelf label record 51R (Act 45: distribution means). When the shelf label communication process ends, the CPU 111 ends the reception process.

  Thus, when the connection direction is X, N divided images for N electronic shelf label terminals 13 arranged in the horizontal direction from the left toward the same shelf in the product shelf 30 are divided. Data G1 to GN are respectively set as second image data.

  On the other hand, when the connecting direction is the Y direction, the CPU 111 initializes the shelf number counter i to “0” (Act 51). Next, the CPU 111 counts up the shelf number counter i by “1” (Act 52). Then, the CPU 111 determines whether or not the shelf number counter i exceeds the maximum value imax of the shelf number (Act 53).

  When the shelf number counter i does not exceed the maximum value imax (NO in Act 53), the CPU 111 detects a product shelf record 52R having the shelf number counter i as the shelf number from the product shelf database 52 (Act 54). Then, the CPU 111 determines whether or not the stage number J of the merchandise shelf record 52R is equal to or greater than the connection number N of the second image file 62 (Act 55). If the number of steps J is less than the number N of connections, the electronic shelf label terminals 13 necessary for displaying customer information of the number N of connections are not arranged in the vertical direction on the product shelf 30 with the shelf number i. . Therefore, when stage number J is less than connection number N (NO in Act 55), CPU 111 returns to the process of Act 52. That is, the CPU 111 further counts up the shelf number counter i by “1”, and determines whether or not the electronic shelf label terminals 13 having the number N of connections or more are arranged in the vertical direction on the product shelf 30 of the next shelf number. To do.

  When the number of stages J is equal to or greater than the number of connections N (NO in Act 55), the CPU 111 detects the minimum value Kmin of the number of sections from the pair of data included in the merchandise shelf record 52R (Act 56). Further, the CPU 111 initializes the partition number counter k to “0” (Act 57). Note that the processing order of Act 56 and Act 57 is not limited to this, and the order may be reversed.

  Next, the CPU 111 increments the partition number counter k by “1” (Act 58). Then, the CPU 111 determines whether or not the partition number counter k exceeds the partition number minimum value Kmin (Act 59).

  Until the number-of-compartments counter k reaches the minimum number-of-compartments value Kmin, at least the electronic shelf label terminals 13 arranged on each stage of the product shelf 30 are aligned vertically. Therefore, when the partition number counter k does not exceed the partition number minimum value Kmin (NO in Act 59), the CPU 111 initializes the stage number counter j and the data number counter d to “0” (Act 60). Next, the CPU 111 increments the stage number counter j by “1” (Act 61). Further, the CPU 111 increments the data number counter d by “1” (Act 62). Then, the CPU 111 searches the shelf label database 51, and as the second image data for the shelf label record 51R whose shelf classification (i, j, k) matches the shelf number counter i, the stage number counter j, and the section number counter k. Then, the image division data Gd of the second image file is set (Act 63: determination means). Note that the processing order of Act 61 and Act 62 is not limited to this, and the order may be reversed.

  Thereafter, the CPU 111 determines whether or not the data number counter d has reached the connection number N (Act 64). Until the data number counter d reaches the connection number N, the allocation of the image division data Gd included in the second image file 62 to the electronic shelf label terminal 13 is not completed. Therefore, when data number counter d has not reached connection number N (NO in Act 64), CPU 111 returns to the processing of Act 61. That is, the CPU 111 increments the partition number counter k and the data number counter d by “1”. The CPU 111 sets the image division data Gd for the shelf label record 51R in which the shelf classification (i, j, k) matches the shelf number counter i, the stage number counter j, and the section number counter k.

  When the data number counter d reaches the connection number N, the allocation of the image division data Gd included in the second image file 62 to the electronic shelf label terminal 13 is completed. Therefore, when the data number counter d reaches the connection number N (YES in Act 64), the CPU 111 returns to the processing of Act 58. That is, the CPU 111 further increments the partition number counter k by “1”. In this way, the CPU 111 repeatedly executes the processes of Act60 to Act64 until the partition number counter k exceeds the partition number minimum value Kmin.

  If the number of partitions counter k exceeds the minimum number of partitions Kmin (YES in Act 59), the CPU 111 returns to the processing of Act 52. That is, the CPU 111 further increments the shelf number counter i by “1”. Thus, the CPU 111 repeatedly executes the processes after Act 54 until the shelf number counter i exceeds the maximum value imax.

  If shelf number counter i exceeds maximum value imax (YES in Act 53), CPU 111 executes shelf label communication processing. That is, the CPU 111 distributes each shelf label record 51R of the shelf label database 51 to the electronic shelf label terminal 13 identified by the shelf label ID of the shelf label record 51R (Act 65: distribution means). When the shelf label communication process ends, the CPU 111 ends the reception process.

  Thus, when the connecting direction is Y, the N electronic shelf label terminals 13 arranged in the vertical direction from the left to the bottom in each stage of the product shelf 30 are divided into N parts. Image data G1 to GN are respectively set as second image data.

  As described above, according to the present embodiment, the number of connections N, the connection direction XorY, and the number N of connected images, that is, the customer information including the divided image data G1 to GN for the number of connections N is input to the POS server 22. The image data G1 to GN are automatically set as the second image data for the N electronic shelf label terminals 13 arranged in alignment in the X direction or the Y direction. Therefore, the setting work of the second image data necessary for displaying customer information using a plurality of electronic shelf label terminals can be simplified.

  In the embodiment, the display time of the second image is nT time, but is not necessarily limited to nT time. If the time is longer than the nT time, the plurality of electronic shelf label terminals 13 can simultaneously display the second image, thereby creating a time zone in which the customer information is displayed on the product shelf 30.

  Further, the transfer of the shelf label server 11 is generally performed in a state where a program such as a control program is stored in the ROM. However, the present invention is not limited to this, and a control program or the like assigned separately from the computer apparatus may be written in a writable storage device included in the computer apparatus in accordance with an operation of a user or the like. The transfer of the control program or the like can be performed by recording on a removable recording medium or by communication via a network. The recording medium may be in any form as long as it can store a program such as a CD-ROM or a memory card and can be read by the apparatus. Further, the function obtained by installing or downloading the program may be realized in cooperation with an OS (operating system) in the apparatus.

In addition, although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.
The invention described in the scope of the original claims of the present application will be added below.
[Appendix 1] In an electronic shelf label system in which a plurality of electronic shelf label terminals are arranged in a product shelf in at least one direction,
The plurality of electronic shelf label terminals are respectively
A display unit;
A first image storage unit that stores a first image including a price of a product displayed on a product shelf on which the electronic shelf label terminal is disposed;
A second image storage unit for storing a second image formed by being simultaneously displayed on each display unit of n (n ≧ 2) electronic shelf label terminals arranged in one direction;
After the first image stored in the first image storage unit is displayed on the display unit for a predetermined interval, the second image stored in the second image storage unit is displayed at the predetermined interval. A control unit that repeats the control to display continuously for the time of n times or more;
An electronic shelf label system comprising:
[Appendix 2] The plurality of electronic shelf label terminals are respectively
A numerical value storage unit that variably stores the numerical value n;
The electronic shelf label system according to claim 1, wherein the control unit sets a time obtained by multiplying the time of the predetermined interval by a numerical value n stored in the numerical value storage unit as a minimum display time of the second image.
[Appendix 3] An electronic shelf label server that communicates with the plurality of electronic shelf label terminals,
The electronic shelf label server
Shelf label position storage means for storing position information of the plurality of electronic shelf label terminals with respect to the product shelf;
Based on the position information of the plurality of electronic shelf label terminals with respect to the product shelf stored in the shelf label position storage means, the n electronic shelf label terminals arranged in at least one direction are arranged. determining means for determining the allocation of the second image divided into n;
Distribution means for distributing the second image to the n electronic shelf label terminals arranged in at least one direction according to the assignment determined by the determination means;
The electronic shelf label system according to appendix 1 or 2, characterized by comprising:
[Supplementary Note 4] Display section;
A first image storage unit that stores a first image including the price of a product displayed on the product shelf;
A second image storage unit for storing a second image formed by being simultaneously displayed on n (n ≧ 2) display units arranged in one direction;
A numerical value storage unit for variably storing a numerical value n;
After the first image stored in the first image storage unit is displayed on the display unit for a predetermined interval, the second image stored in the second image storage unit is displayed at the predetermined interval. A control unit that repeats control to continuously display the time equal to the time obtained by multiplying the time n by the numerical value n stored in the numerical value storage unit,
An electronic shelf label terminal comprising:
[Supplementary Note 5] Communication means for communicating with a plurality of electronic shelf label terminals arranged in at least one direction with respect to the commodity shelf;
Shelf label position storage means for storing position information of the plurality of electronic shelf label terminals with respect to the product shelf;
First distribution means for distributing a first image including a price of a commodity displayed on the commodity shelf on which the electronic shelf label terminal is disposed to the plurality of electronic shelf label terminals via the communication means; ,
Determining means for determining allocation of the second image divided into n based on position information of the plurality of electronic shelf label terminals stored in the shelf label position storage means with respect to the product shelf;
Second distribution means for distributing the second image to the n electronic shelf label terminals arranged in at least one direction via the communication means according to the assignment determined by the determination means. When,
An electronic shelf label server comprising:
[Appendix 6] Communication means for communicating with a plurality of electronic shelf label terminals arranged in at least one direction with respect to the product shelf, and shelf label position storage means for storing position information of the plurality of electronic shelf label terminals with respect to the product shelf To the electronic shelf label server equipped with
A first distribution function for distributing a first image including a price of a commodity displayed on the commodity shelf on which the electronic shelf label terminal is disposed, to the plurality of electronic shelf label terminals via the communication unit;
A determination function for determining allocation of the second image divided into n based on position information of the plurality of electronic shelf label terminals stored in the shelf label storage means with respect to the product shelf; and
A second distribution function for distributing the second image to the n electronic shelf label terminals arranged in at least one direction via the communication means according to the allocation determined by the determination function. ,
Control program to realize.

DESCRIPTION OF SYMBOLS 1 ... Electronic shelf label system, 11 ... Shelf label server (electronic shelf label server), 12 ... Relay machine, 13 ...
Electronic shelf label terminal, 22 ... POS server, 23 ... Product database, 30 ... Product shelf, 51 ... Shelf label database, 52 ... Product shelf database, 132 ... Display, 133 ... Memory, 134
... wireless circuit, 135 ... clock transmitter, 136 ... controller, 137 ... battery.

Claims (4)

A display unit;
A first storage unit for storing information on the first character string;
A second storage unit that stores information relating to one character group among a predetermined number of second character strings that are different from the first character string;
After pre-Symbol to display the first character string based on the information stored in the first storage unit, a first display period of a predetermined in response to is finished and before Symbol information stored in the second storage unit based to display the character assembly, further wherein the first display period in response to the second display period is set to a length of more than the length obtained by multiplying by the predetermined number is completed, stored in the first storage unit A control unit for controlling the display unit to display the first character string based on the information and thereby to repeat the display of the first character string and the display of the character aggregate;
Electronic shelf label terminal equipped with. A timing unit that counts up every predetermined time from the time when the control unit displays the first character string on the display unit;
And the said control part makes it the end of the said 1st display period when the count value of the said time measuring part is a predetermined value,
The electronic shelf label terminal according to claim 1. The second storage unit stores information about the extracted character assembly from the second string to include without dividing the characters constituting the word included in the second character string, according to claim 1 or The electronic shelf label terminal according to claim 2 . A multiple storage unit that variably stores multiples;
And the control unit, the multiple stored by previous SL multiple storage unit as the predetermined number,
The electronic shelf label terminal as described in any one of Claims 1-3 .