JP4686217B2 - Method for displaying two-dimensional code with optimum brightness on data broadcasting screen, program for data broadcasting receiver - Google Patents

Description

The present invention relates to a method for displaying a two-dimensional code suitable for photographing with a camera attached to a mobile phone and a program for a data broadcast receiving apparatus when displaying the two-dimensional code in data broadcasting .

In recent years, as a new broadcasting form of data broadcasting accompanying the spread of digital broadcasting, there is interactive broadcasting using a two-dimensional code represented by QR code (registered trademark, JIS X 0510). Even viewers who are not connected to a telephone line can now use the two-dimensional code interactive function by using a camera-equipped two-dimensional code compatible mobile phone.

In data broadcasting using this two-dimensional code, image processing is performed on the two-dimensional code image when producing content so that the reading accuracy of the mobile terminal is improved. The viewer captures and recognizes the two-dimensional code image displayed on the television screen with a camera-equipped mobile phone equipped with a code reading function.

However, since the display characteristics of the digital broadcast receiving apparatus differ slightly depending on the manufacturer of the receiving apparatus, the display luminance of the two-dimensional code image (background of the two-dimensional code image) is the same even in the same two-dimensional code image. White brightness) will be different. Therefore, in order to capture and correctly decode a two-dimensional code image with a mobile phone terminal, the display brightness setting on the display monitor side must be adjusted as necessary, which hinders user convenience. It was.

The present invention has been made in consideration of such a conventional technique. An object of the present invention is to execute an appropriate two-dimensional code in data broadcasting according to the display characteristics of a receiver device of a receiver manufacturer. And a method for automatically generating and displaying the program, and a program for a data broadcast receiving apparatus .

The present invention solves the above problems by the following means. In other words, the invention described in claim 1 is a digital broadcast receiving apparatus that performs two-dimensional code data, a luminance conversion table for converting a receiving apparatus manufacturer identification number into color information, and operations of the following first to third steps. A data broadcast program including a description of instructions to be executed is broadcasted and received by a digital broadcast receiving apparatus to display a two-dimensional code having an optimum luminance on a data broadcast screen. However, the description of the instruction causes the following series of steps to be executed. First step: Using the receiving device manufacturer identification number held by the digital broadcast receiving device as a key, referring to the receiving device manufacturer identification number in the received luminance conversion table, and matching the receiving device manufacturer identification number with the key 2nd step of extracting color information corresponding to the above: The extracted color information is set to the color information of the pixel in the background white portion of the received 2D code data to generate optimal luminance 2D code data The third step: drawing and displaying the generated optimum luminance two-dimensional code data.

According to the second aspect of the present invention, a character string to be encoded, a luminance conversion table for converting a receiving device manufacturer identification number into color information, and operations of the following first to third steps are executed on the digital broadcast receiving device. A method of displaying a two-dimensional code having an optimum luminance on a data broadcast screen by broadcasting a data broadcast program including the description of the instruction to be transmitted and receiving the program by a digital broadcast receiver. However, the description of the instruction causes the following series of steps to be executed. First step: Using the receiving device manufacturer identification number held by the digital broadcast receiving device as a key, referring to the receiving device manufacturer identification number in the received luminance conversion table, and matching the receiving device manufacturer identification number with the key A second step of: generating two-dimensional code data from the character string to be encoded, and converting the generated two-dimensional code data into color information of pixels in the background white portion of the generated two-dimensional code data The extracted color information is set. Third step: The generated and set two-dimensional code data is drawn and displayed.

The invention according to claim 3 is characterized in that the two-dimensional code data is described by a set of BML tags defined by BML which is a data broadcasting description language, or A method for displaying a two-dimensional code having optimum luminance on the data broadcast screen according to claim 2.

The invention according to claim 4 is characterized in that the description of the command is a script described in a script description language defined by BML which is a data broadcasting description language. 2 is a method for displaying a two-dimensional code having the optimum luminance on the data broadcast screen described in 2.

The invention according to claim 5, the instructions to be executed by the data broadcast receiving apparatus, by describing in scripting language that is defined in a data broadcasting description language BML, data broadcast receiving apparatus having a BML browser A program for a data broadcast receiving apparatus that operates as a data broadcast receiving apparatus used in the method for displaying a two-dimensional code having optimum luminance on the data broadcast screen according to any one of claims 1 to 4. .

According to the present invention, in data broadcasting, a two-dimensional code image with appropriate luminance can be dynamically generated and displayed according to the display characteristics of a digital broadcast receiving device viewed by the viewer. Taking a two-dimensional code will result in correct decoding and the ability to use interactive services. At the same time, a two-dimensional code with optimal brightness is displayed, which may hinder broadcast viewing. It is now possible to view comfortable broadcast programs.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the drawings. FIG. 1 is an overall configuration diagram of a two-dimensional code optimum display system that broadcasts and receives a data broadcast program that embodies the method of the present invention. The broadcast transmission facility 70 transmits broadcast waves to the digital broadcast receiver 10 via the satellite 71b and the radio tower 71c. The cellular phone 71 and the data broadcasting WEB site 75 are connected via bidirectional communication via the Internet. The broadcast transmission facility 70 broadcasts the data broadcast program on the broadcast wave 70a. The data broadcast program includes a two-dimensional code group composed of a plurality of two-dimensional code data and a BML script group composed of a plurality of BML scripts. The digital broadcast receiver 10 receives a data broadcast program. The central processing unit built in the digital broadcast receiving apparatus 10 interprets the received BML script, thereby realizing each unit of the system described later. The digital broadcast receiving apparatus 10 includes a nonvolatile memory area. The display monitor 10a displays the main broadcast and the data broadcast. The viewer captures the displayed two-dimensional code image with the mobile phone 71 and decodes information included in the captured two-dimensional code image. The data broadcasting WEB site 75 provides an interactive service for data broadcasting programs.

FIG. 2 is an explanatory diagram of a two-dimensional code in which a BML tag is described. The two-dimensional code is a gradation image in which black and white pixels are arranged vertically and horizontally. Therefore, a two-dimensional code in which black and white pixels are described with BML tags is composed of a set of BML tags. As shown by the partial enlargement unit 30 of the two-dimensional code image of FIG. 2A, the display of the two-dimensional code is composed of a combination of a black portion pixel 30a and a background white portion pixel 30b.

FIG. 2A illustrates the color palette. The color palette 31 includes a color information table for designating the colors of the black pixel 30a and the background white pixel 30b using the palette symbol as a reference key. Usually, the content manufacturer's identification number and the white background color, which are unique identification symbols given to the receiving device manufacturer, are displayed in the area where the content creator can freely set the color (operator setting area). Set and register in association. For example, in the “pallet symbol 151” of the color palette 31, the color of the background white portion pixel 30b for the receiving device manufacturer identification number “ID = 11” is associated 31a and registered. Similarly, in “pallet symbol 152”, the color of the pixel 30b of the background white portion for the receiving device manufacturer identification number “ID = 12” is associated and registered, and in “pallet symbol 153”, The color of the pixel 30b in the white background portion for the receiving device manufacturer identification number “ID = 13” is registered in association with each other.

Here, the receiving device manufacturer identification number is held in the non-volatile memory area of the digital broadcast receiving device 10 and is used to specify the color information (pixel value) of the pixel in the white background portion of the two-dimensional code image. . That is, when the two-dimensional code is displayed on the display monitor 10a in which the two-dimensional code data 20 and the digital broadcast receiving apparatus 10 have the same receiving device manufacturer identification number, the two-dimensional code data 20 is displayed with the optimum luminance.

  As shown in FIG. 2D, the description method of the color of the two-dimensional code by the BML tag is “backgroundColor: <pallet symbol>”. For example, since the palette symbol “151” of the color palette 31 is designated, the color of the pixel 30b in the background white portion of the receiving device manufacturer identification number “ID = 11” is described as “backgroundColor: 151” 32b. Similarly, the color of the pixel 30b in the background white portion of the receiving device manufacturer identification number “ID = 12” is “backgroundColor: 152”, and when the receiving device manufacturer identification number “ID = 13”, “backgroundColor: 153”. ”And the corresponding palette symbol is specified.

Further, as shown in FIG. 2C, the description method of the BML tag of the color of the black portion 30a is “backgroundColor: black” 32a, and the color palette symbol “black” of the color palette 31 is designated.

FIG. 3 is an explanatory diagram of a rough operation flow of the two-dimensional code optimum display system. The broadcast transmission facility 70 puts a data broadcast program including a BML script group composed of a plurality of BML scripts that operate as each unit of the system described later, two-dimensional code data, and a luminance conversion table on a broadcast wave 70a. (Fig. 3 (a)). When the digital broadcast receiving apparatus 10 receives the data broadcast program, the built-in central processing unit interprets the BML script group and makes preparations so that each BML script can operate (same (A)).

First, the optimum luminance selection BML script reads a receiving device manufacturer identification number (for example, an ID value) held by the digital broadcast receiving device 10. Next, the optimum luminance selection BML script uses the read device manufacturer identification number as a key and refers to the receiving device manufacturer identification number in the received luminance conversion table, and matches the received receiver manufacturer identification number with the key. Select color information with. Next, the two-dimensional code generation BML script sets the selected color information to the pixel value of the background white portion of the two-dimensional code of the received two-dimensional code data, and the two-dimensional code described in BML. -Generate data. Finally, the BML browser (details will be described later) draws a two-dimensional code from the two-dimensional code data described in BML and displays it on the display monitor 10a ((c)).

Here, the viewer captures the two-dimensional code with the mobile phone 71 (same ((D))) The mobile phone 71 decodes the information included in the captured two-dimensional code (same ((e)). The viewer transmits the decrypted information to the data broadcasting WEB site 75 using the mobile phone 71 and receives the interactive service of the data broadcasting program ((f)).

FIG. 4 is a structural diagram of the luminance conversion table. The luminance conversion table 65a is a table in which the receiving device manufacturer identification number is associated with the color information of the pixel 30b of the background white portion of the two-dimensional code, and gives color information specifying the color of the background white portion. The luminance conversion table 65 a includes an ID / pallet symbol corresponding unit 65 b and the color palette 31. The ID / pallet symbol correspondence unit 65b represents the correspondence between the receiving device manufacturer identification number and the color palette symbol. As described with reference to FIG. 2, the color palette unit 31 includes a color information table using palette symbols as reference keys.

FIG. 5 is an example of one luminance conversion table. The ID / pallet symbol corresponding unit 65b indicates the correspondence between the receiving device manufacturer identification number and the palette symbol of the color palette. “ID = 11: Pallet symbol 151”, “ID = 12: Pallet symbol 152”, “ID” = 13: It is described as a palette symbol 153 ″. In the color palette 31, as described in FIG. 2A, for example, “pallet symbol 151” stores the color information of the background white portion of the receiving device manufacturer identification number “ID = 11”.

FIG. 6 is a detailed configuration diagram of a digital broadcast receiving apparatus and a mobile phone of a two-dimensional code optimum display system in data broadcasting according to the present invention. The digital broadcast receiving apparatus 10 includes an optimum luminance selection unit 14, a storage unit 15, a two-dimensional code generation unit 17, and a BML browser 16.
The storage device 15 of the digital broadcast receiving apparatus 10 stores the receiving apparatus manufacturer identification number 63a and the luminance conversion table 65a. The cellular phone 71 includes a photographing unit 73 and a two-dimensional code decoding unit 72.

The optimum luminance selecting means 14 executes the aforementioned optimum luminance selection BML script included in the BML script group of the received data broadcast program after being interpreted by a central processing unit built in the digital broadcast receiving apparatus 10. It functions by. Similarly, the two-dimensional code generation means 17 interprets the above-described two-dimensional code generation BML script included in the BML script group of the received data broadcast program by a central processing unit built in the digital broadcast receiving apparatus 10. It works by executing.

The storage unit 15 is a non-volatile memory area built in the digital broadcast receiving apparatus 10. The BML browser 16 is a program stored in a ROM built in the digital broadcast receiving apparatus 10. The receiving device manufacturer identification number 63a is data. The photographing means 73 is a camera device attached to the mobile phone. The two-dimensional code decoding means 72 is a program built in the mobile phone 71.

The optimum brightness selecting means 14 matches the key by referring to the ID / pallet symbol corresponding section 65b of the received brightness conversion table 65a using the receiving device manufacturer identification number 63a held in the storage means 15 as a key. The pallet symbol indicated by the receiving device manufacturer identification number is acquired, and the color information of the pallet symbol that matches the key is acquired by referring to the pallet symbol of the color palette 31 using the acquired pallet symbol as a key. .

The two-dimensional code generation means 17 sets the acquired color information as the pixel value of the background white portion of the received BML tag two-dimensional code data.

The BML browser 16 draws an image from the objects of the white background portion and the black background portion of the two-dimensional code described in BML and displays the image on the screen.

The luminance conversion table 65a is received as a part of digital broadcast program data received by digital broadcasting and held in the storage unit 15.

The imaging means 73 captures the displayed two-dimensional code image and converts it into two-dimensional code binary image data. The two-dimensional code decoding means 72 decodes information included in the converted two-dimensional code binary image.

FIG. 7 is a flowchart of a method for optimally displaying a two-dimensional code on a data broadcast screen according to the present invention.
(1) The broadcast transmission facility 70 broadcasts a data broadcast program including two-dimensional code data, a BML script group, and a luminance conversion table 65a on a broadcast wave 71a. (Step S360 0)
(2) The digital broadcast receiving apparatus 10 receives a data broadcast program including the two-dimensional code data on the broadcast wave 71a, the BML script group, and the luminance conversion table 65a. (Step S361) The central processing unit built in the digital broadcast receiving apparatus 10 interprets the received BML script group and prepares to operate as each means.
(3) The optimum luminance selecting unit 14 reads out the receiving device manufacturer identification number 63a from the storage unit 15. (Step S362)
(4) The optimum luminance selecting means 14 refers to the received receiving device manufacturer identification number 63a of the ID / pallet symbol corresponding portion 65d of the luminance conversion table 65a received as described above. The pallet symbol corresponding to the receiving device manufacturer identification number that matches the key is acquired. Using this acquired palette symbol as a key, the color information corresponding to the palette symbol matching the key is acquired by referring to the palette symbol of the color palette 31. (Step S363)
(5) The two-dimensional code generation means 17 sets the acquired color information as the pixel value of the background white portion of the received two-dimensional code data. (Step S364)
(6) The BML browser 16 draws and displays the set two-dimensional code data. (Step S365)
(7) The viewer captures the displayed two-dimensional code having the optimum luminance with the mobile phone 71. (Step S366)
(8) The information included in the two-dimensional code is decoded. (Step S367)

FIG. 8 is an example of selecting and displaying a two-dimensional code having optimum luminance according to the present invention. FIG. 8A shows a two-dimensional code 41 described in BML received by data broadcasting.

As shown in FIGS. 8A and 8B, the optimum luminance determination means 14 converts the receiving device manufacturer identification number 63a “ID = 13” into a pallet symbol “153”. More specifically, as shown in FIG. 8 (c), the optimum luminance determination means 14 uses the receiving device manufacturer identification number 63a “ID = 13” held in the storage means 15 as a key to change the luminance. With reference to the ID of the ID / pallet symbol corresponding portion 65d in the table, the palette symbol “153” having the ID that matches the key is acquired. Next, as shown in FIG. 8 (K), the optimum luminance determination means 14 refers to the palette symbol of the color palette 31 using this palette symbol “153” as a key, and matches the palette symbol with the key. The color information 31c possessed by is acquired.

Next, as shown in (e) of FIG. 8, the two-dimensional code generation means 17 sets the color information 31c to the pixel value of the background white portion of the received two-dimensional code 41, and optimizes the BML description. Luminance BML tag description two-dimensional code data 41c is created.
As shown in FIG. 8 (G), the BML browser 16 draws the created BML tag description two-dimensional code data having the optimum luminance, and configures and displays it on the two-dimensional code display screen 45.

(Modification 1)
An example will be described in which a character string to be encoded is broadcast instead of a two-dimensional code, two-dimensional code data is generated by the digital broadcast receiving apparatus 10, and a two-dimensional code with optimum luminance is displayed. At this time, similarly to, the luminance conversion table 65a is received by data broadcasting. The character string 24 to be encoded is character information embedded in the two-dimensional code data.

The configuration of the data broadcasting two-dimensional code optimum display system in the first modification is the same as the configuration of the data broadcasting two-dimensional code optimum display system in FIG.

The two-dimensional code generation means 17 encodes the received character string 24 to be encoded into two-dimensional code data of the BML tag description, sets color information in the pixel value of the white background portion, and converts the two-dimensional code into the two-dimensional code data. Generate. The operation of other means is the same as that of FIG.

FIG. 9 is a flowchart of the two-dimensional code optimum display method according to the first modification.
(1) The broadcast transmission facility 70 broadcasts the data broadcast program including the character string 24 to be encoded, the BML script group, and the luminance conversion table 65a on the broadcast wave 71a. (Step S380)
(2) The digital broadcast receiving apparatus 10 receives the data broadcast program including the character string 24 to be encoded, the BML script group, and the brightness conversion table 65a. (Step S381)
(3) Same as step S362 in FIG. (Step S382)
(4) Same as step S363 in FIG. (Step S383)
(5) The two-dimensional code generation means 17 encodes the received character string 24 to be encoded into two-dimensional code data of the BML tag description, sets color information to the pixel value of the white background portion, Generate dimension code. (Step S384)
(6) Same as step S365 in FIG. (Step S385)
(7) Same as step S366 in FIG. (Step S386)
(8) Same as step S367 in FIG. (Step S387)

The character string to be encoded into the two-dimensional code may include a character string input by the viewer using the digital broadcast input device or a character string selected from the screen menu. As a result, since the information decoded from the two-dimensional code includes information corresponding to the viewer's reaction, it is possible to provide a fine service.

(Modification 2)
An example in which the two-dimensional code image data of the two-dimensional code group is composed of JPEG images will be described. JPEG is an abbreviation for Joint Photographic Experts Group, and is an image format for compressing bitmap still image data recorded as a collection of points.

FIG. 10 is an explanatory diagram of the data structure of the two-dimensional code in the second modification. The two-dimensional code group 41 includes a plurality of two-dimensional code data 20. The two-dimensional code data 20 includes data including two-dimensional code image data 21 (JPEG two-dimensional code image data) and a receiving device manufacturer identification number 23. The JPEG two-dimensional code image data 21 constituting the two-dimensional code data 20 is configured with different luminances.

The configuration of the two-dimensional code optimum display system in the second modification is the same as that of the two-dimensional code optimum display system in FIG. 6 except for the luminance conversion table 65a held in the two-dimensional code creation means 17 and the storage means 15. It is.

The optimum luminance selecting means 14 matches the key by referring to the receiving device manufacturer identification number 23 of the received two-dimensional code group 41 using the receiving device manufacturer identification number 63a held by the storage means 15 as a key. The JPEG two-dimensional code image data 21 of the two-dimensional code data 20 having the receiving device manufacturer identification number 23 is selected. The BML browser 16 decodes and displays the JPEG two-dimensional code image data. The function of the other constituent means is the same as in FIG.

FIG. 11 is a flowchart of a method for optimally displaying a two-dimensional code on the data broadcast screen in the second modification.
(1) The broadcast transmission facility 70 broadcasts a two-dimensional code group and a BML script on a broadcast wave. (Step S390)
(2) The digital broadcast receiving apparatus 10 receives a two-dimensional code group and a BML script. (Step S391)
(3) Same as step S362 in FIG. (Step S392)
(4) The optimum luminance selecting means 14 refers to the receiving device manufacturer identification number 23 of the received two-dimensional code group using the receiving device manufacturer identification number 63a held by the storage means 15 as a key, and The JPEG two-dimensional code image data 21 of the two-dimensional code data 20 having the receiving device manufacturer identification number 23 that matches the key is selected and passed to the BML browser. (Step S393)
(5) The BML browser 16 analyzes and displays the two-dimensional code JPEG image data having the optimum luminance. (Step S394)
(6) Steps S395 to S397 are the same as steps S365 to S367 in FIG.

In the second modification, the two-dimensional code is described as JPEG image data, but the same result can be obtained with image digital data such as a bitmap image or TIFF.

As described above in detail, according to the present invention, in data broadcasting, a two-dimensional code image with appropriate brightness can be displayed according to the display characteristics of the digital broadcast receiving device viewed by the viewer. If a person captures a two-dimensional code, it will be decoded correctly, and it will be possible to use interactive services. At the same time, a two-dimensional code with optimal brightness will be displayed, which will hinder viewing of the broadcast. It became possible to watch a comfortable broadcast program.

1 is a diagram showing the overall configuration of a two-dimensional code optimum display system that broadcasts and receives a data broadcast program that embodies the method of the present invention. Color setting method and rendered two-dimensional code in BML tag image data Explanatory diagram of rough operation flow of 2D code optimum display system Structure diagram of luminance conversion table according to the present invention Example of one luminance conversion table Configuration diagram of a two-dimensional code optimum display system in data broadcasting according to the present invention Flowchart of two-dimensional code optimum display method according to the present invention Example of selection and display of optimum size and brightness of two-dimensional code according to the present invention Flowchart of Optimal Display Method for Two-Dimensional Code According to Modification 1 (Modification 1: When receiving a character string to be two-dimensionally encoded) Explanatory drawing of the data structure of the two-dimensional code in Modification 2 (Modification 2: When the two-dimensional code image data is composed of JPEG images) Flowchart of a method for optimally displaying a two-dimensional code on the data broadcasting screen in Modification 2

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Digital broadcast receiver 10a Display monitor 11 Display size determination screen presentation means 12 Optimal display size information reception storage means 13 Optimal display size information selection means 14 Optimal brightness selection means 15 Storage means 15a Optimal display size information 15b Receiving device manufacturer identification number 16 BML browser 17 Two-dimensional code generation means 20 Two-dimensional code data 21 Two-dimensional code image data 22 Display size information 23 Receiving device manufacturer identification number 24 Character string 30 to be encoded Partial enlarged portion 30a of two-dimensional code image Black portion Pixel 30b Background white portion pixel 31 Color palette 31a Pallet symbol and receiving device manufacturer identification number correspondence 32a Black portion pixel description 32b Background white portion pixel description 41 Two-dimensional code group 41e received by data broadcasting Optimal Two-dimensional code with high brightness Data 45 Two-dimensional code display screen 63a Receiving device manufacturer identification number 65a Luminance conversion table 65b ID palette symbol corresponding section 67a Display size information list 70 Broadcast transmission equipment 70a Broadcast wave 71 Cell phone 72 Two-dimensional code decoding means 73 Imaging means 75 WEB site for data broadcasting

Claims (5)

It includes two-dimensional code data, a luminance conversion table for converting the receiving device manufacturer identification number into color information, and a description of instructions for causing the digital broadcast receiving device to execute the operations of the following first to third steps. A method of displaying a two-dimensional code having an optimum luminance on a data broadcasting screen by broadcasting a data broadcasting program and receiving it by a digital broadcasting receiver. However, the description of the instruction causes the following series of steps to be executed.
First step: Using the receiving device manufacturer identification number held by the digital broadcast receiving device as a key, referring to the receiving device manufacturer identification number in the received luminance conversion table, and matching the receiving device manufacturer identification number with the key Extract color information corresponding to
Second step: The extracted color information is set to the color information of the pixels of the white background portion of the received two-dimensional code data to generate optimum luminance two-dimensional code data.
Third step: The generated optimum luminance two-dimensional code data is drawn and displayed. It includes a character string to be encoded, a luminance conversion table for converting the receiving device manufacturer identification number into color information, and a description of instructions for causing the digital broadcast receiving device to execute the operations of the following first to third steps. A method of displaying a two-dimensional code having an optimum luminance on a data broadcasting screen by broadcasting a data broadcasting program and receiving it by a digital broadcasting receiver. However, the description of the instruction causes the following series of steps to be executed.
First step: Using the receiving device manufacturer identification number held by the digital broadcast receiving device as a key, referring to the receiving device manufacturer identification number in the received luminance conversion table, and matching the receiving device manufacturer identification number with the key Extract color information corresponding to
Second step: Two-dimensional code data is generated from the character string to be encoded, and the extracted color information is set in the color information of the pixel in the white background portion of the generated two-dimensional code data. ,
Third step: The generated and set two-dimensional code data is drawn and displayed. 3. The data broadcasting screen according to claim 1, wherein the two-dimensional code data is described by a set of BML tags defined by BML which is a data broadcasting description language. To display a two-dimensional code with the optimum brightness. The description of the command is a script described in a script description language defined in BML, which is a data broadcasting description language, and is optimal for a data broadcasting screen according to claim 1 or 2. To display a two-dimensional code with high brightness. Instructions to be executed by the data broadcast receiving apparatus, by describing in scripting language that is defined in a data broadcasting description language BML, the data broadcast receiving apparatus having a BML browser of claims 1 to 4 A program for a data broadcast receiving apparatus that is operated as a data broadcast receiving apparatus used in the method for displaying a two-dimensional code having an optimum luminance on the data broadcast screen according to any one of the items.

Images