JP2016028471A - Receiving device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a receiving device capable of appropriately displaying the images and videos output from an application on a screen even when video resolution of television broadcast changes, and a program.SOLUTION: A receiving unit 11 receives a broadcast signal. A separation unit 12 separates a video signal from the broadcast signal. A video and audio processing unit 21 restores the separated video signal as a displayable video. An application execution unit 17 executes an application. An application information table (AIT) acquisition unit 14 acquires an AIT which is information related to the application. An application control unit 15 retrieves information related to output resolution of the application from the AIT. A presentation control unit 22 matches resolution of the video with resolution of an output image from the application on the basis of information related to output resolution of the application retrieved by the application control unit 15 and the resolution of the video restored by the video and audio processing unit 21.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a receiving apparatus for receiving a broadcast signal such as a television.

  A technique of running an application program in a television broadcast receiving apparatus and displaying an output from the application program on the same screen as a television image is becoming common. For example, FIG. 2 of Patent Document 1 describes a configuration in which the output from the video recorder (35) and the output from the application control unit (42) are combined in the combining unit (36) and output to the display. .

JP 2013-150089 A

  In order to synthesize a TV broadcast video and an output from an application, it is necessary that the resolutions of both videos (images) are consistent. When the resolution of the TV broadcast video is constant, it is only necessary to match the resolution of the output from the application with the resolution of the TV video. However, when the resolution of the video of the television broadcast can change, the resolution of the output from the application may not match well with the television video. If the resolutions of the two do not match, there may arise a problem that they cannot be arranged on the television screen in a balanced manner. Note that the case where the resolution of the TV broadcast video can be changed is, for example, when the broadcast video is intentionally reduced for multi-organization or the like, or in the situation where hierarchical transmission is being performed. This is a case where the video resolution dynamically changes depending on the propagation state of the video.

  Although it is conceivable to design an application so that the resolution of an image or the like output from the application can be switched, there is a problem in that the amount of application development increases. In addition, when the resolution of the video of the television broadcast changes dynamically, it is difficult to perform control so that the output resolution from the application follows the change of the resolution of the television broadcast without delay.

  The present invention has been made based on the above problem recognition, and can receive images and video output from an application on a screen appropriately even if the resolution of the video of a television broadcast changes. A device is provided.

  [1] In order to solve the above problem, a receiving device according to an aspect of the present invention includes a receiving unit that receives a broadcast signal, a separating unit that separates a video signal from the broadcast signal received by the receiving unit, A video processing unit that restores the video signal separated by the separation unit as displayable video, an application execution unit that executes an application, and an application that is information about the application from the broadcast signal or from outside through communication An application information table acquisition unit that acquires an information table, an application control unit that extracts information about the output resolution of the application from the application information table acquired by the application information table acquisition unit, and the application that is extracted by the application control unit And information about the output resolution of Deployment, based on the resolution of the reconstructed the image by the image processing unit comprises a, and a presentation control unit to match the resolution of the output image from the said video applications.

  [2] Further, according to one aspect of the present invention, in the reception device, the application control unit extracts information related to the output resolution of the application from an application profile area in the application information table. And

  [3] A receiving device according to an aspect of the present invention is separated by a receiving unit that receives a broadcast signal, a separating unit that separates a video signal from the broadcast signal received by the receiving unit, and the separating unit. A video processing unit that restores a video signal as a displayable video, an application execution unit that executes an application, and an MH-data encoding scheme descriptor acquisition unit that acquires an MH-data encoding scheme descriptor from the broadcast signal An application control unit that extracts information about the output resolution of the application from the MH-data encoding scheme descriptor acquired by the MH-data encoding scheme descriptor acquisition unit, and the application extracted by the application control unit Information on the output resolution of the video, and the resolution of the video restored by the video processor Based on, for anda presentation control unit to match the resolution of the output image from the said video applications.

  [4] In addition, according to one aspect of the present invention, in the reception apparatus, when the resolution of the video and the output resolution of the application are different, the presentation control unit is configured to detect the video from the application so as to match the resolution of the video. The resolution of the output image is changed to match the video and the output image from the application.

  [5] One embodiment of the present invention is a program for causing a computer to function as any of the above-described receiving devices.

  ADVANTAGE OF THE INVENTION According to this invention, an appropriate display can be performed corresponding to the various resolutions of an image | video, and the various resolutions of the output from an application.

It is a functional block diagram which shows schematic function structure of the receiver by embodiment of this invention. It is the schematic which shows the structure of the application information table (AIT) by the embodiment. It is an example of a screen for demonstrating the overlay process performed by the presentation control part by the embodiment. It is a figure which shows the correspondence for the presentation control part by the same embodiment to perform the resolution adjustment between content, and shows the case where the output resolution from an application is match | combined with the resolution of a broadcast video. It is a figure which shows the correspondence for the presentation control part by the same embodiment to perform the resolution adjustment between content, and shows the case where the resolution of a broadcast image is match | combined with the output resolution from an application. It is a figure which shows the correspondence for the presentation control part by the same embodiment to perform the resolution adjustment between content, and shows the case where an image (video) with a higher resolution is matched with a lower resolution. It is a figure which shows the correspondence for the presentation control part by the same embodiment to perform the resolution adjustment between content, and shows the case where an image (video) with a lower resolution is matched with a higher resolution. It is a functional block diagram which shows schematic function structure of the receiver by one of the modifications of the embodiment.

Next, an embodiment of the present invention will be described with reference to the drawings.
[Embodiment]
FIG. 1 is a functional block diagram showing a schematic functional configuration of the receiving apparatus according to the present embodiment. The receiving apparatus 1 receives a television broadcast signal and outputs video and audio, and has a function of acquiring and executing an application program (hereinafter referred to as “application” or “application”). As illustrated, the receiving apparatus 1 includes a receiving unit 11, a separating unit 12, an AIT acquisition unit 14, an application control unit 15, an application acquisition unit 16, an application execution unit 17, and a video / audio processing unit 21. And a presentation control unit 22 and an output unit 23.

  The receiving unit 11 receives an external broadcast signal. At this time, the receiving unit 11 receives only a broadcast signal of a specific broadcast channel. A channel received by the reception unit 11 is selected by a channel selection unit (not shown). The broadcast signal is transmitted from a transmission facility on the broadcasting station side and transmitted as a radio wave or an electric signal of cable television broadcasting. The broadcast signal received by the receiving unit 11 is a digital signal that is multiplexed including video, audio, text (caption and character super), data (data broadcast, etc.), and control information. The reception unit 11 demodulates the received broadcast signal and passes it to the separation unit 12.

  The separating unit 12 separates the broadcast signal received by the receiving unit 11 into video, audio, text, data, control information, and the like. The separation unit 12 passes the separated video signal and audio signal to the video / audio processing unit 21. Further, the separation unit 12 passes an application information table (AIT, Application Information Table) extracted from the broadcast signal to the AIT acquisition unit 14. In addition, the separation unit 12 passes the application code transmitted as part of the broadcast signal to the application acquisition unit 16.

The AIT acquisition unit 14 acquires the AIT passed from the separation unit 12. The AIT is a table that holds information about applications. The AIT acquisition unit 14 passes information included in the acquired AIT to the application control unit 15. The information passed from the AIT acquisition unit 14 to the application control unit 15 includes information regarding the resolution of image (video) output for each application.
In addition, the AIT acquisition unit 14 passes information (application identification information, information indicating the location of the application, etc.) described in the AIT and necessary for acquisition of the application to the application acquisition unit 16. The information indicating the location of the application is information indicating the position where the application code exists in the broadcast signal. The AIT is transmitted as part of the control information in the broadcast signal. Alternatively, the AIT is transmitted as SI (Service Information or SIgnaling Information) information. Alternatively, AIT is transmitted as part of data broadcasting.

The application control unit 15 controls the execution of the application according to the information acquired from the AIT acquisition unit 14. For example, the application control unit 15 follows the life cycle control information of the application included in the AIT (PRESENT (acquisition), PREFETCH (acquires and caches in advance), AUTOSTART (automatic activation), KILL (end), etc.) Control the app lifecycle.
In addition, the application control unit 15 extracts information related to the output resolution from the application from the AIT passed from the AIT acquisition unit 14, and passes the information related to the resolution to the presentation control unit 22.

  The application acquisition unit 16 acquires an application code from the separation unit 12 according to information received from the AIT acquisition unit 14. Moreover, the application acquisition part 16 preserve | saves the acquired application code as needed. The application code is a data file described using, for example, HTML5 (5th edition of the hypertext markup language) and JavaScript (registered trademark).

  The application execution unit 17 executes the application based on control from the application control unit 15. The application execution unit 17 receives application code to be executed from the application acquisition unit 16. The application execution unit 17 is realized, for example, as a web browser that interprets and displays HTML5 or executes a JavaScript (registered trademark) code. The application execution unit 17 passes data representing the content to be displayed on the screen to the presentation control unit 22.

  The video / audio processing unit 21 decodes the video and audio signals passed from the separation unit 12 and passes them to the presentation control unit 22. That is, the video / audio processing unit 21 restores the video signal separated by the separation unit 12 as a displayable video and restores the audio signal as audio.

The presentation control unit 22 superimposes (overlays) the data of the video (television broadcast video) received from the video / audio processing unit 21 and the display content data received from the application execution unit 17, on the output unit 23. hand over. In addition, the presentation control unit 22 passes the analog-converted audio signal to the output unit 23 based on the audio data received from the video / audio processing unit 21.
The presentation control unit 22 adjusts the resolution of the video of the television broadcast and the resolution of the output from the application, and overlays both. Specifically, the presentation control unit 22 outputs from the video and the application based on the information related to the output resolution of the application extracted by the application control unit 15 and the video resolution restored by the video / audio processing unit 21. Processing to match the resolution with the image is performed. Details of the resolution adjustment will be described later. Note that since the output resolution information of the application used by the presentation control unit 22 is acquired from the AIT, the resolution information can be recognized before the application is actually read.
The output unit 23 outputs the video passed from the presentation control unit 22 to the screen. Moreover, the output part 23 outputs the audio | voice delivered from the presentation control part 22 from a speaker etc.

Next, information regarding the output resolution from the application will be described. In the present embodiment, resolution information of an image (video) output from an application is stored in the AIT and transmitted from the broadcast station side to the receiving device 1. The transmitting device on the broadcast station side transmits AIT in a state multiplexed in the broadcast signal, and the receiving device 1 receives it.
FIG. 2 is a schematic diagram showing the configuration of the AIT according to the present embodiment. The AIT is a table that holds information related to one or more applications.

  As shown in the figure, the AIT includes an application information descriptor loop area including a plurality of application information descriptors. Each application information descriptor type in the application information descriptor loop is identified by a descriptor tag. One of the descriptors included in the application information descriptor loop is an application descriptor. The application descriptor includes an application profile loop. The application profile loop includes a plurality of application profiles. Each application profile is a 16-bit unsigned integer. In this embodiment, one application profile represents the output resolution from the application. An output resolution value is set for each application.

  As an example, the profile indicating the output resolution from the application holds the value of the number of pixels in the horizontal direction. For example, if the output resolution from the application is 1920 (horizontal direction) × 1080 (vertical direction), the profile value is “1920” (“0x0780” in hexadecimal). When the output resolution is 3840 (horizontal direction) × 2160 (vertical direction), the profile value is “3840” (“0x0F00” in hexadecimal). Further, when the output resolution is 7680 (horizontal direction) × 4320 (vertical direction), the value of the profile is set to “7680” (“0x1E00” in hexadecimal).

  As another example, the profile indicating the output resolution from the application holds an integer value indicating the output resolution. For example, when the output resolution from the application is 1920 (horizontal direction) × 1080 (vertical direction), the value of the profile is “1” (“0x0001” in hexadecimal). When the output resolution is 3840 (horizontal direction) × 2160 (vertical direction), the value of the profile is “2” (“0x0002” in hexadecimal). When the output resolution is 7680 (horizontal direction) × 4320 (vertical direction), the profile value is “3” (“0x0003” in hexadecimal).

As another example, a predetermined digit in the profile (for example, the lowest digit in the hexadecimal representation) holds a value indicating the output resolution. For example, when the output resolution from the application is 1920 (horizontal direction) × 1080 (vertical direction), the lowest digit of the profile in hexadecimal notation is set to “0”. When the output resolution is 3840 (horizontal direction) × 2160 (vertical direction), the lowest digit of the profile expressed in hexadecimal is set to “1”. When the output resolution is 7680 (horizontal direction) × 4320 (vertical direction), the lowest digit of the profile expressed in hexadecimal is set to “2”.
In the above three examples, the case where there are three types of output resolution is illustrated, but the number of types of output resolution is not limited to three, and may be different.

Next, details of the process of overlaying the broadcast video and the output from the application will be described.
FIG. 3 is a diagram of a screen example for explaining the overlay processing by the presentation control unit 22. FIG. 2A shows a video image of television broadcasting. FIG. 5B shows an example of a screen output from the application. FIG. 3C shows a state in which a television broadcast video and a screen output from the application are displayed in an overlapping manner. The difference between (a) and (c) is a horizontally long rectangular area arranged at the bottom of the screen, and this area is the output from the application. In the example shown in FIG. 5C, the output from the application includes a news headline text, a weather forecast, a menu for instructing the application program, and the like.

  The producer of a television broadcast program produces this video with the intention of displaying this video on the entire screen. In addition, the creator of the application (multimedia content) shown in FIGS. 5B and 5C creates the application with the intention that the output from the application is appropriately arranged on the entire screen. The presentation control unit 22 controls the overlay method so that even when the resolution of the TV broadcast video and the output resolution from the application are different, both are displayed in a good balance as shown in FIG. To do. In other words, as a result of such control by the presentation control unit 22, the content having the lower resolution is prevented from being reduced and displayed on the screen.

When the video resolution and the output resolution from the application are different, the presentation control unit 22 changes the resolution of the output from the application so as to match the video resolution. Conversely, the presentation control unit 22 may change the resolution of the video so as to match the resolution of the output from the application. In these cases, the presentation control unit 22 appropriately upsamples or downsamples the content to be changed.
4 and 5 show the correspondence relationship of the resolution adjustment of the content by the presentation control unit 22. FIG. 4 is a correspondence diagram when the presentation control unit 22 matches the output resolution from the application with the resolution of the broadcast video. FIG. 5 is a correspondence diagram when the presentation control unit 22 matches the resolution of the broadcast video with the output resolution from the application. The presentation control unit 22 may use either method of FIG. 4 or FIG.

FIG. 4 shows a two-dimensional table. The horizontal direction corresponds to the output resolution from the application, and the vertical direction corresponds to the resolution of the broadcast video. In this example, both the output resolution from the application and the resolution of the broadcast video are 1920 pixels × 1080 pixels (so-called “2K”), 3840 pixels × 2160 pixels (so-called “4K”), 7680 pixels × vertical. There are three types of 4320 pixels (so-called “8K”). However, the types of resolution are not limited to these three types, and other resolutions may be used. When the correspondence relationship of FIG. 4 is used, the output from the application is appropriately upsampled or downsampled to match the resolution of the broadcast video. If the output resolution from the application and the resolution of the broadcast video are originally equal, overlay is performed without changing the resolution. As shown in FIG. 4, (4-1) when the resolution of the broadcast video is 1920 pixels wide × 1080 pixels high, the resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is 1920 pixels wide × 1080 vertical. Pixel. Further, (4-2) when the resolution of the broadcast video is horizontal 3840 pixels × vertical 2160 pixels, the resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is horizontal 3840 pixels × vertical 2160 pixels. Further, (4-3) when the resolution of the broadcast video is horizontal 7680 × vertical 4320, the resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is horizontal 7680 pixels × vertical 4320 pixels.
That is, when the video resolution and the output resolution of the application are different, the presentation control unit 22 matches the video and the output image from the application by changing the resolution of the output image from the application to match the video resolution. Let

FIG. 5 is also a two-dimensional table similar to FIG. 4, and has three resolutions: horizontal 1920 pixels × vertical 1080 pixels, horizontal 3840 pixels × vertical 2160 pixels, and horizontal 7680 pixels × vertical 4320 pixels. 5 is used, the presentation control unit 22 adjusts the broadcast video to the resolution from the application by appropriately up-sampling or down-sampling the broadcast video. If the output resolution from the application is equal to the resolution of the broadcast video, overlay is performed without changing the resolution. As shown in FIG. 5, when the resolution of the output from the application is 1920 horizontal pixels × 1080 vertical pixels, the resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is 1920 horizontal pixels × The vertical length is 1080 pixels. (5-2) When the resolution of the output from the application is horizontal 3840 pixels × vertical 2160 pixels, the resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is horizontal 3840 pixels × vertical 2160 pixels. is there. Further, (5-3) when the resolution of the output from the application is horizontal 7680 × vertical 4320, the resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is horizontal 7680 pixels × vertical 4320 pixels.
That is, when the video resolution and the output resolution of the application are different, the presentation control unit 22 matches the video and the output image from the application by changing the video resolution to match the resolution of the output image from the application. Let

Further, the presentation control unit 22 may determine which content resolution is dynamically adjusted according to the actual resolution of each content.
6 and 7 show the correspondence relationship of the resolution adjustment of the content by the presentation control unit 22. FIG. 6 is a correspondence diagram when the presentation control unit 22 matches an image (video) with a higher resolution to a lower resolution. FIG. 7 is a correspondence diagram when the presentation control unit 22 matches an image (video) having a lower resolution with a higher resolution. The presentation control unit 22 may use the method of FIG. 6 or 7 instead of the method of FIG. 4 or FIG.

FIG. 6 shows a two-dimensional table, where the horizontal direction corresponds to the output resolution from the application, and the vertical direction corresponds to the resolution of the broadcast video. In this example, both the output resolution from the application and the resolution of the broadcast video are 1920 pixels × 1080 pixels (so-called “2K”), 3840 pixels × 2160 pixels (so-called “4K”), 7680 pixels × vertical. There are three types of 4320 pixels (so-called “8K”). However, the types of resolution are not limited to these three types, and other resolutions may be used. When the correspondence relationship of FIG. 6 is used, the presentation control unit 22 of the output from the application and the output from the broadcast video matches the lower resolution by down-sampling the higher resolution image (video). . If the output resolution from the application is equal to the resolution of the broadcast video, overlay is performed without changing the resolution. As shown in FIG. 6, (6-1) an image (video) passed from the presentation control unit 22 to the output unit 23 when either the resolution from the application or the resolution of the broadcast video is 1920 pixels wide × 1080 pixels high. The resolution is 1920 pixels wide × 1080 pixels vertical. (6-2) When either one of the resolution from the application or the resolution of the broadcast video is horizontal 3840 pixels × vertical 2160 pixels, and the other resolution is horizontal 3840 pixels × vertical 2160 pixels or more The resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is horizontal 3840 pixels × vertical 2160 pixels. (6-3) When both the resolution from the application and the resolution of the broadcast video are 7680 × vertical 4320, the resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is 7680 × horizontal 4320 pixels. It is.
That is, when the video resolution and the output resolution of the application are different, the presentation control unit 22 matches the video and the output image from the application by changing the resolution of the video or the image to match the lower resolution. .

FIG. 7 is also a two-dimensional table similar to FIG. 6, and has three resolutions: horizontal 1920 pixels × vertical 1080 pixels, horizontal 3840 pixels × vertical 2160 pixels, and horizontal 7680 pixels × vertical 4320 pixels. When the correspondence relationship of FIG. 7 is used, the presentation control unit 22 of the output from the application and the output from the broadcast video matches the higher resolution by upsampling the lower resolution image (video). . If the output resolution from the application is equal to the resolution of the broadcast video, overlay is performed without changing the resolution. As shown in FIG. 7, (7-1) an image (video) passed from the presentation control unit 22 to the output unit 23 when either the resolution from the application or the resolution of the broadcast video is 7680 pixels wide × 4320 pixels long. The resolution is 7680 pixels by 4320 pixels. (7-2) When one of the resolution from the application and the resolution of the broadcast video is horizontal 3840 pixels × vertical 2160 pixels, and the other resolution is horizontal 3840 pixels × vertical 2160 pixels or less. The resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is horizontal 3840 pixels × vertical 2160 pixels. (7-3) When both the resolution from the application and the resolution of the broadcast video are 1920 × 1080 in vertical, the resolution of the image (video) passed from the presentation control unit 22 to the output unit 23 is 1920 × 1080 pixels in horizontal. It is.
That is, when the video resolution and the output resolution of the application are different, the presentation control unit 22 matches the video and the output image from the application by changing the resolution of the video or the image to match the higher resolution. .

The configuration and operation of the receiving apparatus have been described above. Here, the transmitting apparatus will be described. The transmission equipment on the broadcasting station side sets the output resolution information for each application in the AIT. The transmission facility multiplexes video, audio, data, control information, etc., and transmits it as a digital broadcast signal. The digital broadcast signal includes the AIT described above.
A specific apparatus configuration example for setting the output resolution information in the AIT is as follows. An application production apparatus for producing an application outputs a file having an application code produced by the creator. The application production apparatus outputs a file having information on the output resolution set when the application is produced. These files may be common. The application creating apparatus transmits a file including an application code and a file including output resolution information to the outside by a predetermined data exchange method. These files are received by the application registration device. The application registration device receives these files by the data exchange method described above. Then, the application registration device sets various information related to the application in predetermined areas in the AIT. At this time, the application registration apparatus also sets the output resolution information from the application in a predetermined area in the AIT. The AIT created in this way is multiplexed together with other data and transmitted as part of the broadcast signal.

  As described above, in this embodiment, output resolution information for each application is set in the AIT. Then, the AIT acquisition unit 14 in the reception device 1 extracts the AIT from the signal separated by the separation unit 12. The extracted AIT is passed to the application control unit 15. The application control unit 15 passes information on the output resolution of the application to the presentation control unit 22. The presentation control unit 22 adjusts between the video resolution of the broadcast program and the output resolution of the application based on the information passed from the application control unit 15. Specifically, this adjustment is processing in which the presentation control unit 22 matches the resolution of the broadcast video with the output resolution from the application. At this time, when the two resolutions are different from each other, the presentation control unit 22 matches the content with the higher resolution (broadcast video or output from the application) with the lower resolution or the content with the lower resolution. Either adjust to the higher resolution or adjust by either method. The receiving device 1 extracts information related to the resolution of the broadcast video from the broadcast signal.

  According to the present embodiment, the receiving device 1 can appropriately overlay the output from the application (multimedia content) and display it on the screen regardless of the resolution of the broadcast video. When the application is described as HTML and a style sheet (cascading style sheet, CSS), it cannot be said that the receiving apparatus 1 can estimate the output from the application by analyzing the data. can not cut. However, as in the present embodiment, obtaining the output resolution information of the application from the AIT can ascertain the resolution faster and more reliably than obtaining the resolution from the application itself (HTML or style sheet). That is, according to the present embodiment, the output resolution information from the application is transmitted by the AIT, and therefore the output resolution information from the application can be recognized in advance when the application is activated. Thereby, for example, the presentation control unit 22 according to the present embodiment can adjust the resolution between the broadcast video and the application output without delay.

  In the present embodiment, information on the output resolution of the application is stored in the application profile in the AIT. With such a configuration, it is not necessary to newly define a descriptor in the AIT. Further, it is not necessary to provide a new area other than the application descriptor. Moreover, it is not necessary to provide a new table.

  In addition, you may make it implement | achieve a part of function of the receiver in embodiment mentioned above with a computer. In that case, it is realized by recording a program for realizing the internal functions of the receiving apparatus on a computer-readable recording medium, causing the computer system to read and execute the program recorded on the recording medium. Also good. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible disk, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, a “computer-readable recording medium” dynamically holds a program for a short time, like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory inside a computer system serving as a server or a client in that case may be included, and a program that holds a program for a certain period of time. The program may be a program for realizing a part of the above-described functions, or may be a program that can realize the above-described functions in combination with a program already recorded in a computer system.

Although the embodiment has been described above, the present invention can also be implemented in the following modified example. In addition, you may implement combining the some of the modification described below.
[Modification 1]
In the above embodiment, the AIT acquisition unit 14 acquires the AIT extracted from the broadcast signal. In this modification, the AIT acquisition unit 14 acquires an AIT from an external computer server device via a communication line such as the Internet. In this case, the receiving device 1 includes a communication input / output unit (not shown). The communication input / output unit can communicate with an external device using an Internet protocol (IP) or the like. Note that the AIT acquisition unit 14 may acquire the AIT from a broadcast signal or from an external computer server device via a communication line.

[Modification 2]
In the above embodiment, the application acquisition unit 16 acquires the application code extracted from the broadcast signal. In this modification, the application acquisition unit 16 acquires an application code from an external computer server device via a communication line such as the Internet. Also in this case, the receiving apparatus 1 includes a communication input / output unit as in the first modification.

[Modification 3]
In the above embodiment, the output resolution information of the application is stored in the application profile area in the AIT. In this modification, a new descriptor is provided for storing output resolution information of the application. As a further modification, the output resolution information of the application may be stored in another field in the AIT.

  In the above-mentioned “Modification 3”, the case of “providing a new descriptor for storing output resolution information of an application” has been described. A specific example is as follows. In this example, the transmission apparatus on the broadcast station side transmits a broadcast signal by including information on the output resolution of the application in the MH-data encoding scheme descriptor in the MPT. “MPT” is an abbreviation for “MMT package table”. “MMT” is an abbreviation for “MPEG media transport”. “MH” is an abbreviation for “MPEG-H”.

  FIG. 8 is a block diagram showing a schematic functional configuration of the receiving apparatus according to this example. As shown in the figure, the receiving device 2 includes an MH-data encoding scheme descriptor acquiring unit 31 in addition to the units included in the receiving device 1 (FIG. 1).

  The MH-data encoding scheme descriptor acquisition unit 31 acquires an MH-data encoding scheme descriptor from the signals separated by the separation unit 12. And the application control part 15 takes out the information regarding the output resolution of an application from the MH-data encoding system descriptor which the MH-data encoding system descriptor acquisition part 31 acquired. As an example, the application control unit 15 obtains information on the output resolution of the application from the additional information (additional identification information) in the MH-data encoding scheme descriptor acquired by the MH-data encoding scheme descriptor acquisition unit 31. Take out. Then, the presentation control unit 22 outputs the video and the output from the application based on the information regarding the output resolution of the application extracted by the application control unit 15 and the resolution of the video restored by the video / audio processing unit 21. Match the resolution with the image.

  When a plurality of applications are operated in the receiving device 2, which of the following methods (a) to (d) determines which application the output resolution information of the application in the MH-data encoding scheme descriptor is associated with. Depending on.

(A) In this method, only one type of application output resolution information is provided in the MH-data encoding scheme descriptor, and the output resolution is applied to all applications.
(B) In this method, a plurality of sets of information are stored in the MH-data encoding scheme descriptor in such a manner that identification information for each application and output resolution information of the application are associated with each other. Then, for each application, information on the corresponding output resolution is acquired from the identification information, and the output resolution is applied.
(C) In this method, a plurality of sets of information are obtained by associating application attribute information (attribute information other than the identification information) with application output resolution information in the MH-data encoding descriptor. Store. Then, for each attribute of the application, the corresponding output resolution information is acquired and the output resolution is applied. Here, the attribute of the application is information such as, for example, the provider of the application or whether it is a broadcast managed application.
(D) Note that information of a plurality of output resolutions corresponding to the application may be stored in the MH-data encoding scheme descriptor and transmitted by a method other than the above (a) to (c). .

In this example, any of the methods shown in FIGS. 4, 5, 6, and 7 may be used to match the resolution of the broadcast video with the resolution of the image output from the application. .
For example, when the method shown in FIG. 4 is used, the presentation control unit 22 changes the resolution of the output image from the application to match the video resolution when the video resolution and the output resolution of the application are different. Align the video with the output image from the application.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

  The present invention can be used for a television broadcast receiver or the like.

1, 2 Receiving device 11 Receiving unit 12 Separating unit 14 AIT obtaining unit (application information table obtaining unit)
15 Application control unit (application control unit)
16 Application acquisition unit (application acquisition unit)
17 Application execution part (application execution part)
21 Video / Audio Processing Unit (Video Processing Unit)
22 presentation control unit 23 output unit 31 MH-data encoding scheme descriptor acquisition unit

Claims (5)

A receiver for receiving broadcast signals;
A separation unit for separating a video signal from the broadcast signal received by the reception unit;
A video processing unit for restoring the video signal separated by the separation unit as a displayable video;
An application execution unit for executing the application;
An application information table acquisition unit that acquires an application information table that is information related to the application from the broadcast signal or from outside through communication;
An application control unit that extracts information on the output resolution of the application from the application information table acquired by the application information table acquisition unit;
Presentation that matches the resolution of the video and the output image from the application based on the information regarding the output resolution of the application retrieved by the application control unit and the resolution of the video restored by the video processing unit A control unit;
A receiving apparatus comprising: The application control unit extracts information on the output resolution of the application from an application profile area in the application information table;
The receiving apparatus according to claim 1. A receiver for receiving broadcast signals;
A separation unit for separating a video signal from the broadcast signal received by the reception unit;
A video processing unit for restoring the video signal separated by the separation unit as a displayable video;
An application execution unit for executing the application;
An MH-data encoding scheme descriptor acquisition unit that acquires an MH-data encoding scheme descriptor from the broadcast signal;
An application control unit that extracts information on the output resolution of the application from the MH-data encoding scheme descriptor acquired by the MH-data encoding scheme descriptor acquisition unit;
Presentation that matches the resolution of the video and the output image from the application based on the information regarding the output resolution of the application retrieved by the application control unit and the resolution of the video restored by the video processing unit A control unit;
A receiving apparatus comprising: When the resolution of the video and the output resolution of the application are different, the presentation control unit changes the resolution of the output image from the application to match the resolution of the video, and outputs from the video and the application Align with the image,
The receiving device according to any one of claims 1 to 3, wherein   A program for causing a computer to function as the receiving device according to any one of claims 1 to 4.

Images