JP2009020658A - Bar code compression device, bar code processing system, image data compression device and image data processing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide data processing technology allowing efficient transmission of image data showing a bar code. <P>SOLUTION: In a distribution side device distributing commodity data to an electronic shelf tag, a plurality of modules 520 extending in a first direction D1 generate and transmit partial bar code image data showing a partial image 530 including a part of each of the plurality of modules 520 constituting the bar code 512, with respect to the bar code 512 arranged in parallel along a second direction D2 perpendicular to the first direction D1. The electronic shelf tag receives the partial bar code image data transmitted from the distribution side device, and generates the whole bar code image data showing the whole bar code 512 based on the partial bar code image data. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a barcode compression apparatus that compresses barcode image data, a barcode processing system including the barcode compression apparatus, and image data compression that compresses image data of an image that partially includes the barcode image. The present invention relates to an apparatus and an image data processing system having the image data compression apparatus.

  Conventionally, barcodes are used to identify products and the like, and various techniques for processing data indicating barcodes have been proposed. Patent Document 1 discloses a technique related to a barcode demodulation method for demodulating a dot pattern obtained by reading a barcode with a barcode reader. Patent Document 2 discloses a technique for processing micro barcode data that can compress information contained in a micro barcode and reduce the number of digits of data representing the information.

  Patent Document 3 discloses a technique related to an electronic shelf label system (ESL system / Electronic Shelf Label System) introduced in a supermarket, a convenience store, or the like.

JP 2002-133363 A JP-A-6-20085 Japanese Patent Laid-Open No. 2006-230566

  In many cases, the barcode is used by being printed on paper or the like. However, as described in Patent Document 3, the barcode may be displayed on an electronic display such as a liquid crystal display. is there. In the technique of Patent Document 3, the ESL server generates image data indicating a barcode and transmits it to an electronic shelf label having an electronic display. The electronic shelf label is electronically displayed based on the received image data. A bar code is displayed on the instrument.

  As described above, when transmitting image data indicating a barcode to a communication partner apparatus, it is desired to perform data transmission as efficiently as possible.

  If the image data indicating the barcode can be compressed efficiently, the storage capacity for storing the image data can be reduced and the image data can be transmitted efficiently.

  Accordingly, the present invention has been made in view of the above points, and a first object thereof is to provide a data processing technique capable of efficiently transmitting image data indicating a barcode. A second object of the present invention is to provide a data compression technique capable of efficiently compressing image data indicating a barcode or image data indicating an image partially including a barcode image.

  In order to solve the above problem, the invention of claim 1 is a barcode processing system, wherein a plurality of modules extending in a first direction are arranged in parallel along a second direction perpendicular to the first direction. With respect to the barcode, a transmission device that transmits partial image data indicating a part of each of the plurality of modules, and the partial image data transmitted from the transmission device are received, based on the partial image data, A receiving device that generates whole image data indicating the entire barcode.

  The invention of claim 2 is the barcode processing system according to claim 1, further comprising a display device for displaying the barcode based on the whole image data generated by the receiving device.

  According to a third aspect of the present invention, there is provided the barcode compression apparatus, wherein the plurality of modules extending along the first direction are arranged in parallel along the second direction perpendicular to the first direction. A plurality of pixel data in the image data corresponding to the plurality of pixels arranged in the first direction in the image indicating the bar code, the data compressing unit compressing image data indicating the code; Are compressed together.

  The invention of claim 4 is a barcode processing system, comprising the barcode compression device according to claim 3, and a transmission device for transmitting the image data compressed by the barcode compression device; A receiving device that receives the image data transmitted from the transmitting device and decompresses the image data.

  The invention according to claim 5 is the barcode processing system according to claim 4, further comprising a display device for displaying the barcode based on the image data expanded by the receiving device.

  According to a sixth aspect of the present invention, there is provided an image data compression apparatus comprising a data compression unit for compressing image data representing a certain image, wherein the certain image includes a plurality of modules extending along the first direction. , Partly including an image showing a barcode arranged in parallel along a second direction perpendicular to the first direction, the data compression unit is the same array as a plurality of pixels constituting the certain image, In a case where a plurality of pixel data in the image data corresponding to the plurality of pixels are virtually arranged, the same continuous data is collectively collected when the plurality of pixel data are viewed in order along the first direction. Compress.

  The invention of claim 7 is an image data processing system, comprising the image data compression device according to claim 6, and a transmission device for transmitting the image data compressed by the image data compression device; A receiving device that receives the image data transmitted from the transmitting device and decompresses the image data.

  The invention according to claim 8 is the image data processing system according to claim 7, further comprising a display device for displaying the certain image based on the image data expanded by the receiving device.

  According to the first and second aspects of the invention, the transmitting device transmits partial image data indicating a part of each of the plurality of modules constituting the barcode, and the receiving device is based on the partial image data. Since the entire image data indicating the entire barcode is generated, the image data of the entire barcode can be obtained while performing efficient data transmission. As for the module which is the minimum structural unit in the barcode, the image data indicating the whole can be generated from the image data indicating a part thereof. Therefore, a part of each of the plurality of modules constituting the barcode is shown. From the partial image data, the entire image data indicating the entire barcode can be accurately generated.

  According to the invention of claim 3, a plurality of pixel data corresponding to a plurality of pixels arranged in the first direction in an image showing a barcode are compressed together. Since the same data continues in a plurality of pixel data corresponding to a plurality of pixels arranged along the first direction in which the barcode module extends, the barcode is indicated by compressing the plurality of pixel data together. Image data can be compressed efficiently.

  Moreover, according to the invention of Claim 4 and Claim 5, since the image data which shows a barcode can be compressed efficiently, the said image data can be transmitted efficiently.

  According to the invention of claim 6, when compressing image data of an image partially including a barcode image, a barcode module extends a plurality of pixel data constituting the image data. In this case, the number of the same data is increased. Therefore, more pixel data can be compressed together, and image data of an image including a barcode image as a part can be efficiently compressed.

  Further, according to the seventh and eighth aspects of the invention, the image data of the image including the barcode image as a part can be efficiently compressed, so that the image data can be transmitted efficiently.

  As described in Patent Document 3 described above, an electronic shelf label system in which a portable electronic shelf label that displays product data relating to a product such as a selling price is arranged corresponding to each product has been known. ing. Below, the case where the barcode processing technique which concerns on this invention is applied to an electronic shelf label system is demonstrated as an example.

<Embodiment 1>
FIG. 1 is a diagram illustrating a state in which an electronic shelf label 5 provided in the electronic shelf label system 1 according to Embodiment 1 of the present invention is arranged on a product shelf 60 in a store. In the electronic shelf label system 1, a portable electronic shelf label 5 that displays product data relating to a product such as a selling price is arranged corresponding to each product 6. And the communication signal containing the data which shows the selling price based on a goods master is transmitted to each electronic shelf label 5 from the delivery side apparatus which distributes information, and the selling price is displayed on each electronic shelf label 5. Thereby, the correct selling price that matches the selling price at the time of settlement is displayed on the electronic shelf label 5, and the correct selling price is transmitted to the customer.

  As shown in FIG. 1, the product shelf 60 is divided into a space called a face 61, and the same type of products 6 are collected and placed on each face 61. The electronic shelf label 5 is attached to the frame 62 of the product shelf 60 at a position corresponding to each face 61. That is, each electronic shelf label 5 is associated with one product 6 (more precisely, one product type), and a frame 62 in the vicinity of the corresponding product 6 (generally, the lower side of the product 6). Placed in. Each electronic shelf label 5 is provided with a display, on which the selling price of the corresponding product 6 is displayed. The customer (consumer) of the store recognizes the selling price of the product 6 by such display of the electronic shelf label 5.

  The electronic shelf label 5 is a portable device, and can be removed from the frame 62 and rearranged at another position so as to cope with the change in the arrangement of the product 6. In the first embodiment, a plurality of product shelves 60 as shown in FIG. 1 are arranged in a sales space in the store.

  FIG. 2 is a diagram illustrating a configuration example of a store information system 100 including the electronic shelf label system 1 applied to a store. As shown in FIG. 2, the store information system 100 includes a store controller 2 and a POS system 3 along with the electronic shelf label system 1. The POS server 31 included in the POS system 3 and the ESL server 10 included in the electronic shelf label system 1 are connected to the store controller 2 via the LAN 21. Thereby, data communication is enabled among the store controller 2, the POS system 3, and the electronic shelf label system 1.

  The store controller 2 is composed of a general computer and functions as a device that manages the store information system 100 in an integrated manner. In addition, the store controller 2 is connected to an external network such as the Internet, and can communicate with a computer such as a server device disposed in a headquarter center that manages the store through the external network.

  The POS system 3 is a system that collects and analyzes information related to the sale of products at the time of sale, and includes a plurality of registers 32 that perform product settlement together with a POS server 31 that collectively manages the POS system 3. ing. The POS server 31 and the register 32 are connected by a dedicated communication cable.

  The POS server 31 is composed of a general computer, and the hard disk stores a product master 301 indicating various information related to products such as selling prices. In each of the plurality of registers 32, the product is settled based on the selling price described in the product master 301.

  Information related to all products in the store is centrally managed by the product master 301. The information described in the product master 301 includes a product code that is product identification information, a product name that is the name of the product, a normal price that is a normal selling price, a special price that is a special selling price, and a period during which the special sale is performed. A certain sale period, the number of sales, the number of stocks, the number of orders that are delivered in one order, and the like are included.

  The electronic shelf label system 1 is roughly divided into the above-described plurality of electronic shelf labels 5 and a distribution-side device 40 that distributes the selling price of products to be displayed on the electronic shelf labels 5.

  The distribution-side device 40 that is an information distribution unit includes an ESL server 10 that is a server device that collectively manages the electronic shelf label system 1 and a plurality of communication devices 4. The ESL server 10 and the plurality of communication devices 4 are connected to each other via a dedicated communication cable 22 so that data communication is possible between them. Each communication device 4 performs infrared communication with the electronic shelf label 5. The communication device 4 is arranged at substantially constant distances on the ceiling of the sales space 90 so that it can communicate with all the electronic shelf labels 5 arranged in the sales space 90.

  The configuration of the ESL server 10 as hardware is the same as that of a general computer. FIG. 3 is a diagram showing the configuration of the ESL server 10. The ESL server 10 includes a control circuit 11 composed of a CPU that performs various arithmetic processes, a ROM 12 that stores basic programs, a RAM 13 that serves as a work area for arithmetic processes, a hard disk 14 that stores programs and various data files, and various types. A display 15 for displaying, an input unit 16 including a keyboard and a mouse, a data communication unit 17 having a data communication function via the LAN 21, and an interface 18 for communicating with the communication device 4 are provided. A signal indicating product data to be transmitted to the electronic shelf label 5 is transmitted to the communication device 4 via the interface 18.

  A dedicated operation program is stored in advance in the hard disk 14 of the ESL server 10, and various functions as the ESL server 10 are realized by the CPU of the control circuit 11 performing arithmetic processing according to the operation program. The control circuit 11 includes an image data generation unit 110 and an image data compression unit 120 as functional blocks when the CPU included therein executes an operation program. The image data generation unit 110 generates image data indicating an image to be displayed on the electronic shelf label 5. The image data compression unit 120 compresses the image data generated by the image data generation unit 110 using, for example, an MH (Modified Huffman) encoding method. The operations of the image data generation unit 110 and the image data compression unit 120 will be described in detail later.

  In addition, the hard disk 14 of the ESL server 10 stores a product file 101 that is a data file indicating various information related to the product.

  FIG. 4 is a diagram illustrating an example of the product file 101. As shown in FIG. 4, the product file 101 has a table format, and each record 102 indicates information related to one product. Specifically, for each record 102, a product code, a product name, a normal price, a special sale price, a special sale period, the number of sales, the number of stocks, the number of orders, and the like are registered. These pieces of information are the same information as the product master 301 stored in the POS system 3 described above, and are registered based on the information in the product master 301 through communication between the ESL server 10 and the POS system 3. For this reason, the information in the product file 101 and the information in the product master 301 match.

  Further, in each record 102 of the product file 101, one device code that is a hardware ID unique to each of the plurality of electronic shelf labels 5 provided in the electronic shelf label system 1 is registered. Thereby, the product and the electronic shelf label 5 are associated with each other in a one-to-one relationship (linked). By using this device code, the selling price of a certain product is transmitted to the electronic shelf label 5 corresponding to the product.

  The ESL server 10 having the above configuration generates transmission data to be transmitted to each electronic shelf label 5 by the control circuit 11 and outputs the transmission data to each communication device 4 through the interface 18. Each communication device 4 outputs a communication signal including the input transmission data to each electronic shelf label 5 with which it can communicate. As a result, the same transmission data is input from the distribution side device 40 to each electronic shelf label 5 arranged in the sales space 90. The transmission data transmitted from the ESL server 10 includes product data such as a normal price and a sale price in the product file 101, a device code, and the like. In the first embodiment, the product data is transmitted as image data from the distribution side device 40 to the electronic shelf label 5, and the electronic shelf label 5 displays the product data based on the image data.

  Next, the configuration of the communication device 4 will be described in detail. FIG. 5 is a diagram illustrating a configuration of the communication device 4. As shown in FIG. 5, each communication device 4 includes a control unit 41, a light emitting unit 42 configured by, for example, an LED, and a light receiving unit 43 configured by, for example, a photodiode and an amplifier.

  The control unit 41 controls the light emitting unit 42 based on the transmission data input from the ESL server 10. As a result, the light emitting unit 42 outputs an infrared signal IR1 modulated with transmission data.

  The light receiving unit 43 receives the infrared signal IR2 output from the electronic shelf label 5. The infrared signal IR2 is modulated by transmission data from the electronic shelf label 5 to the ESL server 10. The light receiving unit 43 converts the received infrared signal IR2 into an electric signal and outputs it to the control unit 41. The control unit 41 performs a detection process or the like on the electric signal input from the light receiving unit 43 to reproduce the transmission data generated by the electronic shelf label 5. Then, the control unit 41 outputs the reproduced transmission data to the ESL server 10. The transmission data from the electronic shelf label 5 is also encoded, and the ESL server 10 performs a decoding process on the transmission data received from the communication device 4.

  Next, the configuration of the electronic shelf label 5 will be described in detail. FIG. 6 is a diagram showing the configuration of the electronic shelf label 5. As shown in FIG. 6, on the front surface of the electronic shelf label 5, a display 51 that displays product data and a communication unit 54 that is responsible for communication with the distribution side device 40 are arranged.

  The communication unit 54 includes a light emitting unit 52 that outputs an infrared signal IR2, and a light receiving unit 53 that receives the infrared signal IR1 from the communication device 4, converts it into an electrical signal, and outputs it. The light emitting unit 52 is configured by, for example, an LED, and the light receiving unit 53 is configured by, for example, a photodiode and an amplifier.

  The display 51 is a non-volatile display unit of a dot matrix system, and is composed of, for example, electronic paper. In a non-volatile display unit such as electronic paper, display contents can be held without applying driving power. Since the display 51 is a dot-matrix display unit, it can display not only numerical values indicating the selling price of goods but also characters, symbols, figures, and the like. On the display screen SC of the display 51, for example, as shown in FIG. 6, together with the selling price 513 of the product with which the device is associated, information that can specify the product (hereinafter referred to as “product specifying information”). A product name 510 is displayed. In the case where only the selling price 513 is displayed without displaying the product identification information on the display 51, it is difficult to grasp which product the electronic shelf label 5 is associated with. With the display, the electronic shelf label 5 and the product are visually associated with each other. Furthermore, on the display screen SC of the display 51, a character string 511 that represents a product code with a number and a barcode 512 that represents the product code are displayed side by side in the direction in which the barcode 512 extends.

  In the electronic shelf label 5 according to the first embodiment, the shape of the display screen SC is, for example, a rectangle. The electronic shelf label 5 is arranged so that the short side direction and the long side direction of the display screen SC are the vertical direction and the horizontal direction, respectively. A first direction D1 in FIG. 6 indicates a short direction of the display screen SC, and a second direction D2 perpendicular to the first direction D1 indicates a longitudinal direction of the display screen SC.

  In the electronic shelf label 5 according to the first embodiment, the image displayed on the display screen SC is composed of a plurality of pixels arranged in a matrix, and in the image, the first direction D1 and the first direction More than 100 pixels are arranged in each of the two directions D2. Hereinafter, an image displayed on the entire display screen SC is referred to as a “full-screen image”.

  Inside the electronic shelf label 5, there are provided a small battery 56 that supplies power to the electronic shelf label 5 and a control unit 57 that comprehensively controls the operation of the electronic shelf label 5. FIG. 7 is a block diagram showing the configuration of the control unit 57. As shown in FIG. 7, the control unit 57 includes a control circuit 570 that comprehensively controls the operation of the control unit 57 and a storage unit 571 that stores various types of information.

  The storage unit 571 stores in advance an operation program used by the control circuit 570 and a device code of the own device. The control circuit 570 is configured by a CPU or the like, and various functions as the control circuit 570 are realized by the CPU executing an operation program in the storage unit 571. In the control circuit 570, when the CPU executes the operation program, a barcode reproducing unit 670 and an image data decompressing unit 680 are formed as functional blocks.

  The electrical signal generated by the light receiving unit 53 of the communication unit 54 is input to the control circuit 570. The control circuit 570 reproduces the transmission data output from the communication device 4 based on the electric signal, and decodes the transmission data. Then, the control circuit 570 extracts image data and device code indicating product data from the decrypted transmission data, and stores them in the storage unit 571.

  As will be described later, regarding the barcode 512 displayed on the display screen SC, the distribution side device 40 transmits image data indicating a part thereof (hereinafter referred to as “partial barcode image data”) without compression. It is input to the electronic shelf label 5. Based on the partial barcode image data sent from the distribution side device 40 in the barcode reproduction unit 670, the control circuit 570 displays image data indicating the entire barcode 512 (hereinafter referred to as “all barcode image data”). ) Is generated.

  Further, as will be described later, the distribution side device 40 uses the image data compression unit 120 of the ESL server 10 to store image data indicating a full screen image excluding the barcode 512 (hereinafter referred to as “partial screen image data”). It compresses and transmits to the electronic shelf label 5. In the image data decompression unit 680, the control circuit 570 decompresses the partial screen image data after data compression transmitted from the distribution side device 40 and acquires the original partial screen image data.

  The control circuit 570 drives the display 51 based on the generated entire barcode image data and partial screen image data. As a result, various product data such as the selling price 513 as shown in FIG. 6 is displayed on the display screen SC of the display 51.

  The control circuit 570 generates transmission data for the ESL server 10 and encodes the transmission data. Then, the control circuit 570 drives the light emitting unit 52 based on the encoded transmission data. As a result, the light emitting unit 52 outputs an infrared signal IR2 modulated with transmission data for the ESL server 10.

  Next, the operation of the electronic shelf label system 1 until product data is displayed on the electronic shelf label 5 will be described. In the electronic shelf label system 1, the distribution of the product data from the distribution side device 40 to the electronic shelf label 5 is performed when the system is activated and when the selling price displayed on the electronic shelf label 5 is updated. Here, when the selling price is updated, the normal price of the product master 301 is changed, or when the selling price is changed from the normal price to the special selling price in executing the special sale. When the system is activated, the product data is distributed to all the electronic shelf labels 5 in the store. On the other hand, when the selling price is updated, the product data is distributed only to the electronic shelf label 5 corresponding to the target product. In this way, by distributing the product data as necessary, the selling price displayed on the electronic shelf label 5 and the selling price at the time of settlement by the register 32 are always matched. Below, the operation | movement which concerns on delivery of the merchandise data regarding one goods is demonstrated. In the following description, a product for which product data is distributed is referred to as a “target product”.

  First, in the control circuit 11 of the ESL server 10 in the distribution-side device 40, the record 102 relating to the target product in the product file 101 is referred to, and product data such as the selling price (normal price or special price), product code, and product name. And a device code are obtained. Then, the control circuit 11 generates image data indicating the acquired product data in the image data generation unit 110. Specifically, the control circuit 11 generates partial barcode image data and partial screen image data. Thereafter, the control circuit 11 compresses the partial screen image data in the image data compression unit 120.

  The image data and device code obtained by the ESL server 10 are transmitted to the communication device 4 through the communication cable 22 as electrical signals. Then, the communication device 4 outputs an infrared signal IR1 including image data and a device code.

  The infrared signal IR1 output from the communication device 4 is received by the communication unit 54 of the electronic shelf label 5 and converted into an electrical signal, and the control circuit 570 converts the transmission data from the communication device 4 based on the electrical signal. Reproduce. The control circuit 570 decodes the acquired transmission data, and acquires image data and a device code included in the decoded transmission data.

  Next, the control circuit 570 determines whether or not the obtained device code matches the device code of its own device stored in advance in the storage unit 571. If the acquired device code does not match that of the own device, the control circuit 570 determines that the received transmission data is a signal for another electronic shelf label 5 and ends the processing.

  On the other hand, when the acquired device code matches that of the own device, the control circuit 570 determines that the received transmission data is a signal for the own device, and converts all barcode image data from the partial barcode image data. At the same time, the data expansion processing is performed on the compressed partial screen image data. Thereafter, the control circuit 570 displays the full screen image on the display screen SC of the display 51 based on the entire barcode image data and the partial screen image data, and updates the selling price displayed on the display 51.

  The product data is distributed from the distribution side device 40 to the electronic shelf label 5 by the operation as described above.

  When the display on the display 51 is updated, the control circuit 570 generates and encodes ACK data indicating that the product data has been normally received. Thereafter, in the electronic shelf label 5, an infrared signal IR <b> 2 modulated with ACK data is output from the light emitting unit 52. This infrared signal IR2 is received by the communication device 4. In the communication device 4, the encoded ACK data generated by the electronic shelf label 5 is reproduced from the infrared signal IR 2, and the ACK data is transmitted to the ESL server 10. The ESL server 10 performs a decoding process on the input ACK data. Thereby, the ESL server 10 of the delivery side apparatus 40 can confirm whether the delivered merchandise data is normally received by the electronic shelf label 5 or not. Therefore, for example, when the infrared signal IR2 is not output from the electronic shelf label 5, it is determined that the distributed product data has not been normally received by the electronic shelf label 5, and the ESL server 10 returns the infrared signal IR2. It is possible to perform processing such as repeatedly delivering product data. Thereby, the display of the electronic shelf label 5 can be reliably updated, and the reliability of the system can be greatly improved.

  Next, operations of the image data generation unit 110 and the image data compression unit 120 of the ESL server 10 will be described in detail. The image data generation unit 110 refers to the product file 101 in the hard disk 14 and acquires the selling price, product name, and product code related to the target product. Then, the image data generation unit 110 generates partial screen image data based on the acquired selling price, product name, and product code.

  The image data generation unit 110 generates partial barcode image data indicating a part of the barcode 512 representing the product code based on the acquired product code. FIG. 8 is a diagram for explaining this process.

  As shown in FIG. 8, the barcode 512 displayed on the display screen SC is configured by arranging a plurality of modules 520 each extending in the first direction D1 in parallel along the second direction D2. ing. Here, the module 520 is a minimum structural unit in the barcode 512, and there are two types of a bar 520a having a minimum width and a space 520b having a minimum width. In the JAN code standard known as a bar code standard, one character is composed of seven modules.

  In the barcode 512, a plurality of minimum width bars 520a are arranged adjacent to each other to form a thick bar as a whole, and a plurality of minimum width spaces 520b are arranged adjacent to each other to form a thick space as a whole. Is done. As shown in FIG. 8, the bar code 512 is composed of a plurality of bars having different thicknesses and a plurality of spaces having different thicknesses by arranging the minimum width bar 520a and the space 520b in combination. Has been.

  Regarding the barcode 512 having the above configuration, the image data generation unit 110 according to the first embodiment generates image data indicating a part of each of the plurality of modules 520 as partial barcode image data. Specifically, the image data generation unit 110 includes pixels for several rows (for example, three rows) from the top along the first direction D1 among the plurality of matrix-like pixels constituting the barcode 512 image. Image data indicating the configured partial image 530 is generated and used as partial barcode image data.

  In the bar code 512, the length of each module 520 is constant even when the product code indicated by the bar code 512 is changed. Therefore, the length of each module 520 is stored in advance in the electronic shelf label 5. Thus, for each module 520, the image data of the entire module 520 can be generated from a part of the image data. Therefore, by transmitting image data indicating a part of each of the plurality of modules 520 from the distribution side device 40 to the electronic shelf label 5, the electronic shelf label 5 generates image data indicating the entire barcode 512. be able to.

  As described above, since the length of each module 520 is constant even when the product code is changed, theoretically, it corresponds to one row among a plurality of pixels constituting the image of the barcode 512. By transmitting image data corresponding to the pixels to the electronic shelf label 5, the electronic shelf label 5 can generate image data of the entire barcode. However, in the communication path between the distribution side device 40 and the electronic shelf label 5, a data error occurs in the image data transmitted from the distribution side device 40, and the image data generated by the distribution side device 40 is converted into the electronic shelf. If the image data corresponding to one line of pixels may be transmitted to the electronic shelf label 5, the entire image of the barcode 512 may be displayed on the electronic shelf label 5. Sometimes it cannot be played back correctly.

  Therefore, as described above, the image data corresponding to the pixels for several lines in the entire image of the barcode 512 is transmitted to the electronic shelf label 5. Thereby, a plurality of pixel data for each module 520 can be transmitted to the electronic shelf label 5. Therefore, the barcode reproducing unit 670 of the electronic shelf label 5 can reproduce each module 520 based on a plurality of pixel data instead of one pixel data. Therefore, each module 520 can be accurately reproduced.

  For example, in the image data generation unit 110, image data corresponding to pixels for three rows among a plurality of pixels constituting the entire image of the barcode 512 is generated, and the image data is transmitted from the distribution side device 40. In this case, three pixel data are input to the electronic shelf label 5 for each module 520. In this case, the barcode reproducing unit 670 of the electronic shelf label 5 takes the majority of the three pixel data for each module 520 and adopts the largest value among them as the pixel data value of the corresponding module 520. For example, if each pixel data is composed of 1 bit and the three pixel data indicate “1”, “1”, “0”, respectively, the corresponding pixel data value of the module 520 is “ Adopt 1 ″. Then, based on the adopted value, image data indicating the entire module 520 is generated. For example, when “1” is adopted, image data of the entire bar 520a having the minimum width is generated, and when “0” is adopted, image data of the entire space 520b having the minimum width is generated. Thereby, the barcode 512 can be accurately reproduced.

  FIG. 9 is a diagram for explaining the operation of the image data compression unit 120. When the image data compression unit 120 performs data compression on the partial screen image data 600 generated by the image data generation unit 110, first, as shown in FIG. A plurality of pixel data PD corresponding to the plurality of pixels are virtually arranged in the same arrangement as the plurality of pixels constituting the pixel. In the first embodiment, for example, a black and white image is displayed on the display screen SC of the electronic shelf label 5, and one pixel data PD is composed of 1 bit as shown in FIG.

  Here, when the image displayed on the display screen SC is viewed from the front (front), the column to which the pixel located on the leftmost side belongs is the first column, and as it goes to the right along the second direction D2, Assume that the column number increases. Further, when the image displayed on the display screen SC is viewed from the front, the row to which the uppermost pixel belongs is the first row, and the row number increases toward the lower side along the first direction D1. Shall be.

  The image data compression unit 120 compresses a plurality of virtually arranged pixel data PD in units of rows. The image data compressing unit 120 looks at the pixel data PD along the second direction D2 in order from the first column for each row for the plurality of arranged pixel data PD, and uses the MH encoding method. The pixel data PD is encoded.

  In the MH encoding method, a unique codeword is assigned in advance for each of binary codes “1” and “0” in accordance with the number of consecutive identical values. Then, the data compression is performed by converting the multi-bit data in which the same value is continuous into the assigned codeword in accordance with the value indicated by the data and the number of times of the continuous data. In the MH encoding method, even when the same data is not continuous, a unique code word is assigned in advance to the 1-bit data, and the 1-bit data is also converted into the code word. The Accordingly, the image data compression unit 120 scans the pixel data PD for each row in the second direction D2 in order from the first column for each row of the plurality of arranged pixel data PD. If the same data is not arranged adjacent to the PD, the single pixel data PD is converted into a code word. If the same pixel data PD is continuous, the pixel data PD is converted into a code word collectively. To do.

  As described above, in the image data compression unit 120, the same continuous data is compressed together when the plurality of pixel data PD is viewed in order along the second direction D2.

  In the MH encoding method, when the same data is not continuous or when the number of continuous times of the same data is small, the data length after data compression may be longer, so the same data continues for a predetermined number or more. Data compression may be performed only when it is done.

  The partial screen image data 600 compressed by the image data compression unit 120 is transmitted from the distribution side device 40 to the electronic shelf label 5 together with the partial barcode image data. The electronic shelf label 5 displays a full screen image on the display 51 based on the received two types of image data.

  As can be understood from the above description, in the electronic shelf label system 1 according to the first embodiment, a barcode processing system for processing the image data of the barcode 512 is constructed. The distribution-side device 40 functions as a transmission device in the barcode processing system, and image data indicating a part of each of the plurality of modules 520 constituting the barcode 512 is transmitted from the transmission device. The electronic shelf label 5 functions as a receiving device in the barcode processing system, and the receiving device generates image data indicating the entire barcode 512 based on the image data from the distribution side device 40. By operating the electronic shelf label system 1 in this way, the data can be transmitted more efficiently than when the image data of the entire barcode 512 is transmitted from the distribution side device 40 to the electronic shelf label 5. Meanwhile, the image data of the entire barcode 512 can be obtained.

  As described above, the electronic shelf label 5 can accurately generate image data indicating the entire barcode 512 from image data indicating a part of each of the plurality of modules 520 constituting the barcode 512. Therefore, the barcode 512 can be accurately reproduced.

  In the first embodiment, the image data generation unit 110 generates partial barcode image data based on the product code. However, the partial barcode image data may be stored in the hard disk 14 in advance. .

  In the first embodiment, the display unit 51 displays a barcode 512 in which a plurality of modules 520 each extending in the first direction D1 are arranged in parallel along the second direction D2. However, instead of the bar code 512, a bar code 512 in which a plurality of modules 520 each extending in the second direction D2 are arranged in parallel along the first direction D1 is displayed on the display 51. May be displayed. That is, instead of displaying a bar code 512 extending in the short direction of the display screen SC (hereinafter referred to as “vertical bar code 512”) as shown in FIGS. 6 and 8, it extends in the longitudinal direction of the display screen SC. A bar code 512 (hereinafter referred to as “horizontal bar code 512”) may be displayed. In this case, the ESL server 10 may generate the partial barcode image data of the horizontal barcode 512 and transmit it to the electronic shelf label 5, or generate the partial barcode image data of the vertical barcode 512. After transmitting to the electronic shelf label 5 and reproducing the vertical barcode 512 in the electronic shelf label 5, the vertical barcode 512 may be converted into the horizontal barcode 512 and displayed on the display 51.

<Embodiment 2>
FIG. 10 is a diagram showing a configuration of the ESL server 10 according to the second embodiment of the present invention. As shown in FIG. 10, in the ESL server 10 according to the second embodiment, the CPU of the control circuit 11 executes the operation program in the hard disk 14 to generate image data as a functional block in the control circuit 11. A unit 210 and an image data compression unit 220 are formed.

  The image data generation unit 210 refers to the product file 101 in the hard disk 14 and acquires the selling price, product name, and product code related to the target product. Then, the image data generation unit 210 generates image data indicating a full screen image (hereinafter referred to as “full screen image data”) based on the acquired selling price, product name, and product code.

  The image data compression unit 220 extracts the entire barcode image data 700 that is the image data of the entire barcode 512 from the full-screen image data generated by the image data generation unit 210, and the entire barcode image data 700 is extracted. Perform data compression processing. FIG. 11 is a diagram for explaining this process.

  First, as shown in FIG. 11, the image data compression unit 220 converts the plurality of pixel data PD constituting the acquired entire barcode image data 700 into the same arrangement as the plurality of pixels constituting the barcode 512 image. Virtually arranged in a matrix. Then, the image data compression unit 220 compresses the arrayed pixel data PD in units of columns. Specifically, the image data compression unit 220 sequentially looks at the pixel data PD along the first direction D1 from the first row for each column of the plurality of arranged pixel data PD, and selects the MH code. The pixel data PD is encoded using the encoding method.

  In each module 520 of the barcode 512, a plurality of pixels constituting the image have the same color. Therefore, in the entire barcode image data 700, as shown in FIG. 11, in each column, in the first direction D1. The plurality of arranged pixel data PD have the same value. When the pixel data PD is viewed along the first direction D1 in order from the first row for each of the plurality of pixel data PD arranged in a matrix, the same value as the number of rows is obtained. The plurality of pixel data PD having it is continuous. Therefore, when pixel data PD is encoded for each column using the MH encoding method, a plurality of pixel data PD arranged in the first direction can be collectively converted into a code word, The image data 700 can be efficiently compressed.

  In contrast to this, for a plurality of arranged pixel data PD, for each row, the pixel data PD is viewed along the second direction D2 in order from the first column, and the MH encoding method is used. When the pixel data PD is encoded, the entire barcode image data 700 cannot be efficiently compressed. Since the barcode 512 is configured by alternately arranging bars and spaces, the display color is not the same among the pixels arranged in the second direction D2 in the image of the barcode 512, and the black color is black. And the white color changes frequently. Therefore, when the pixel data PD is viewed along the second direction D2 for each row with respect to the plurality of pixel data PD constituting the entire barcode image data 700, only the width of the bar or the width of the space is the same. The data is not continuous and not much of the same data is continuous. As described above, in the MH encoding method, when the number of continuous times of the same data is small, the data length after data compression may be long. Therefore, when a plurality of pixel data PD constituting the entire barcode image data 700 is compressed in units of rows, it cannot be efficiently compressed. Therefore, it is very effective to compress a plurality of pixel data PD in units of columns as in the second embodiment.

  Of the full screen image data, the full barcode image data 700 is compressed as described above. On the other hand, the remaining data of the full screen image data, that is, the partial screen image data is compressed as in the first embodiment. Similar to the image data compression unit 120 according to the first embodiment, the image data compression unit 220 has a plurality of pixels corresponding to the plurality of pixels in the same arrangement as the plurality of pixels constituting the full-screen image excluding the barcode 512. Pixel data PD is virtually arranged. Then, the image data compressing unit 220 looks at the pixel data PD along the second direction D2 in order from the first column for each row with respect to the plurality of arranged pixel data PD, and uses the MH encoding method. Then, the pixel data PD is encoded. Other operations of the ESL server 10 according to the second embodiment are the same as those of the ESL server 10 according to the first embodiment.

  The entire barcode image data and partial screen image data compressed by the image data compression unit 220 are transmitted to the electronic shelf label 5 through the communication device 4 and input to the control unit 57 of the electronic shelf label 5.

  FIG. 12 is a block diagram showing the configuration of the control unit 57 of the electronic shelf label 5 according to Embodiment 2 of the present invention. As shown in FIG. 12, in the control unit 57 according to the second embodiment, the CPU of the control circuit 570 executes the operation program in the storage unit 571, so that the control circuit 570 expands image data as a functional block. Part 780 is formed. The image data decompression unit 780 performs decompression processing on all the barcode image data after compression from the distribution side device 40, and acquires the original all barcode image data. Further, the image data decompression unit 780 performs decompression processing on the compressed partial screen image data from the distribution-side device 40 and acquires the original partial screen image data. The control circuit 570 drives the display 51 based on the entire barcode image data and the partial screen image data acquired by the image data decompression unit 780 and displays the full screen image on the display 51. Other operations of the control unit 57 according to the second embodiment are the same as those of the control unit 57 according to the first embodiment.

  As described above, in the second embodiment, a plurality of pixel data PD corresponding to a plurality of pixels arranged in the first direction D1 in the image of the barcode 512 are compressed together. Since the same data continues in a plurality of pixel data PD corresponding to a plurality of pixels arranged along the first direction D1 in which each module of the bar code 512 extends, the plurality of pixel data PD are compressed together. The image data of the barcode 512 can be efficiently compressed.

  In the second embodiment, the entire barcode image data is generated by the image data generation unit 210. However, the entire barcode image data may be stored in the hard disk 14 in advance.

  Further, instead of displaying the vertical barcode 512 on the electronic shelf label 5, a horizontal barcode 512 may be displayed. In this case, the entire barcode image data indicating the horizontal barcode 512 may be generated in the ESL server 10 and transmitted to the electronic shelf label 5, or the entire barcode image indicating the vertical barcode 512 in the ESL server 10. Data may be generated and transmitted to the electronic shelf label 5, and the electronic shelf label 5 may reproduce the vertical barcode 512 and then convert the vertical barcode 512 into the horizontal barcode 512 and display it on the display 51. .

<Embodiment 3>
FIG. 13 is a block diagram showing a configuration of the ESL server 10 according to Embodiment 3 of the present invention. As shown in FIG. 13, in the ESL server 10 according to the third embodiment, the CPU of the control circuit 11 executes an operation program in the hard disk 14 to generate image data as a functional block in the control circuit 11. A unit 310 and an image data compression unit 320 are formed.

  Similar to the image data generation unit 210 according to the second embodiment, the image data generation unit 310 is a full screen image that is image data indicating a full screen image based on the selling price, the product name, and the product code acquired from the product file 101. Data 800 is generated.

  The image data compression unit 320 performs data compression processing on the full-screen image data 800 generated by the image data generation unit 310 using the MH encoding method. FIG. 14 is a diagram for explaining data compression processing in the image data compression unit 320.

  First, as shown in FIG. 14, the image data compression unit 320 virtually displays a plurality of pixel data PD constituting the full-screen image data 800 in the same array as the plurality of pixels constituting the full-screen image. Array. Then, the image data compression unit 320 compresses the arrayed pixel data PD in units of columns. Specifically, the image data compression unit 320 starts from the first row along the first direction D1 in which each module 520 of the barcode 512 extends for each column of the arrayed pixel data PD. The pixel data PD is sequentially viewed, and the pixel data PD is encoded using the MH encoding method.

  In the entire barcode image data 700 that is a part of the entire screen image data 800, as shown in FIG. 11 described above, in each column, the plurality of pixel data PD arranged in the first direction D1 have the same value. . Accordingly, when the pixel data PD is sequentially captured from the first row along the first direction D1 for each of the plurality of pixel data PD arranged in a matrix in the full-screen image data 800, the barcode In a column including 512 pixel data PD, the number of the same pixel data PD is increased. Therefore, if pixel data PD is encoded for each column using the MH encoding method, more pixel data PD can be collectively converted into a code word, and full-screen image data 800 is efficiently compressed. can do.

  The full screen image data 800 compressed as described above is transmitted to the electronic shelf label 5 through the communication device 4 and input to the control unit 57 of the electronic shelf label 5. Other operations of the ESL server 10 according to the third embodiment are the same as those of the ESL server 10 according to the first embodiment.

  FIG. 15 is a block diagram showing the configuration of the control unit 57 of the electronic shelf label 5 according to Embodiment 3 of the present invention. As shown in FIG. 15, in the control unit 57 according to the third embodiment, the CPU of the control circuit 570 executes the operation program in the storage unit 571, so that the control circuit 570 expands image data as a functional block. Part 880 is formed. The image data decompression unit 880 performs decompression processing on the compressed full-screen image data from the distribution-side device 40, and acquires the original full-screen image data. The control circuit 570 drives the display 51 based on the full screen image data acquired by the image data decompression unit 880 and displays the full screen image on the display 51. Other operations of the control unit 57 according to the third embodiment are the same as those of the control unit 57 according to the first embodiment.

  As described above, in the third embodiment, when the full-screen image data is compressed, the plurality of pixel data PD are scanned along the first direction D1 in which each module 520 of the barcode 512 extends. . That is, the scan direction of the pixel data PD when compressing the full-screen image data is made to coincide with the direction in which the barcode 512 included in the full-screen image extends. As a result, when data compression is performed, the number of consecutive identical data increases, so that more pixel data PD can be compressed together, and full-screen image data can be efficiently compressed.

  Note that the entire barcode image data may be stored in the hard disk 14 in advance, and the image data generation unit 310 may generate the entire screen image data using the entire barcode image data.

  When the horizontal bar code 512 is displayed on the electronic shelf label 5 and the image data indicating the horizontal bar code 512 is included in the full-screen image data, the full-screen image data is compressed. In addition, the plurality of pixel data PD are scanned along the second direction D1 in which each module 520 of the horizontal barcode 512 extends. Thereby, the full-screen image data including the image data of the horizontal barcode 512 can be efficiently compressed.

It is a figure which shows a mode that the electronic shelf label with which the electronic shelf label system which concerns on Embodiment 1 of this invention is provided is arrange | positioned. It is a figure which shows the structural example of the shop information system containing the electronic shelf label system which concerns on Embodiment 1 of this invention. It is a figure which shows the structure of the ESL server which concerns on Embodiment 1 of this invention. It is a figure which shows the example of a goods file. It is a figure which shows the structure of the communication apparatus which concerns on Embodiment 1 of this invention. It is a figure which shows the structure of the electronic shelf label which concerns on Embodiment 1 of this invention. It is a figure which shows the structure of the control part of the electronic shelf label which concerns on Embodiment 1 of this invention. It is a figure for demonstrating operation | movement of the image data generation part which concerns on Embodiment 1 of this invention. It is a figure for demonstrating operation | movement of the image data compression part which concerns on Embodiment 1 of this invention. It is a figure which shows the structure of the ESL server which concerns on Embodiment 2 of this invention. It is a figure for demonstrating operation | movement of the image data compression part which concerns on Embodiment 2 of this invention. It is a figure which shows the structure of the control part of the electronic shelf label which concerns on Embodiment 2 of this invention. It is a figure which shows the structure of the ESL server which concerns on Embodiment 3 of this invention. It is a figure for demonstrating operation | movement of the image data compression part which concerns on Embodiment 3 of this invention. It is a figure which shows the structure of the control part of the electronic shelf label which concerns on Embodiment 3 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electronic shelf label system 5 Electronic shelf label 40 Delivery side apparatus 51 Display 120,220,320 Image data compression part 512 Barcode 520 Module 680,780,880 Image data expansion part 700 All barcode image data 800 Full screen image data PD Pixel data

Claims (8)

A plurality of modules extending in the first direction transmit partial image data indicating a part of each of the plurality of modules with respect to a barcode arranged in parallel along a second direction perpendicular to the first direction. A transmitting device to
A barcode processing system comprising: a reception device that receives the partial image data transmitted from the transmission device and generates overall image data indicating the entire barcode based on the partial image data. The barcode processing system according to claim 1,
A barcode processing system further comprising: a display device that displays the barcode based on the whole image data generated by the receiving device. A plurality of modules extending along the first direction includes a data compression unit that compresses image data indicating barcodes arranged in parallel along a second direction perpendicular to the first direction,
The barcode compression apparatus, wherein the data compression unit collectively compresses a plurality of pixel data in the image data corresponding to a plurality of pixels arranged in the first direction in an image indicating the barcode. A transmission device comprising the barcode compression device according to claim 3 and transmitting the image data compressed by the barcode compression device;
A barcode processing system comprising: a reception device that receives the image data transmitted from the transmission device and decompresses the image data. The barcode processing system according to claim 4,
A barcode processing system, further comprising: a display device that displays the barcode based on the image data expanded by the receiving device. A data compression unit for compressing image data representing a certain image;
The certain image includes, in part, an image showing a barcode in which a plurality of modules extending along a first direction are arranged in parallel along a second direction perpendicular to the first direction,
The data compression unit
In a case where a plurality of pixel data in the image data corresponding to the plurality of pixels are virtually arranged in the same arrangement as the plurality of pixels constituting the certain image, the plurality of pixel data are arranged in the first direction. An image data compression apparatus that collectively compresses the same continuous data when viewed in sequence. A transmission device comprising the image data compression device according to claim 6 and transmitting the image data compressed by the image data compression device;
An image data processing system comprising: a receiving device that receives the image data transmitted from the transmitting device and decompresses the image data. The image data processing system according to claim 7,
An image data processing system further comprising: a display device that displays the certain image based on the image data expanded by the receiving device.

Images