JP2014197878A - Transmission and reception system and transmission and reception method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reception apparatus and a reception method which improve convenience for a user by allowing recognition that a program to be received is a 3D program.SOLUTION: In a digital broadcasting of both 3D video program contents and 2D video program contents, a transmission apparatus generates a digital signal obtained by multiplexing, scrambling, and modulating a video of a coded program content with identification information to identify if the program content is a 3D video program content or a 2D video program content and transmits the generated digital signal as a digital broadcast signal. A reception apparatus receives the transmitted digital broadcast signal and determines if the received program content is a 3D video program content or a 2D video program content on the basis of the identification information on the received program content.

Description

The technical field relates to a three-dimensional (three-dimensional) video broadcast receiving apparatus, receiving method, and transmitting / receiving method.

Patent Document 1 “Provides a digital broadcast receiving apparatus capable of actively notifying that a program requested by a user starts on a certain channel” (Patent Document 1 [00
05]), and as means for solving the problem, “a means for extracting program information contained in a digital broadcast wave and selecting a notification target program using selection information registered by the user; And a means for interrupting and displaying a message indicating the presence on the currently displayed screen ”(see Patent Document 1 [0006]).

JP2003-9033

However, Patent Document 1 does not disclose the viewing of 3D content. for that reason,
There is a problem that it is not possible to recognize that a program that the receiver is currently receiving or will receive in the future is a 3D program.

In order to solve the above-described problems, an embodiment of the present invention may use, for example, the technical idea described in the claims.

According to the above means, it becomes possible to recognize that a program that the receiver is currently receiving or that will be received in the future is a 3D program, and the convenience of the user can be improved.

An example of a block diagram showing a system configuration example An example of a block diagram showing a configuration example of the transmission apparatus 1 Example of stream format type assignment Example component descriptor structure Example of component contents and component types that are components of a component descriptor Example of component contents and component types that are components of a component descriptor Example of component contents and component types that are components of a component descriptor Example of component contents and component types that are components of a component descriptor Example of component contents and component types that are components of a component descriptor An example of the structure of a component group descriptor Example of component group type Component group identification example Billing unit identification example Example of 3D program details descriptor structure The figure which shows the example of 3D / 2D classification The figure which shows the example of the system classification of 3D Example service descriptor structure Examples of service type types Example service list descriptor structure An example of a sending operation rule in the component descriptor sending apparatus 1 It is an example of the transmission operation rule in the transmission apparatus 1 of a component group descriptor. An example of a transmission operation rule in the transmission device 1 for a 3D program detail descriptor An example of a transmission operation rule in the service descriptor transmission apparatus 1 An example of a transmission operation rule in the transmission device 1 of the service list descriptor Example of processing for each field of component descriptor in receiving apparatus 4 An example of processing for each field of the component group descriptor in the receiving device 4 Example of processing for each field of 3D program detail descriptor in receiving apparatus 4 Example of processing for each field of service descriptor in receiving apparatus 4 Example of processing for each field of service list descriptor in receiving apparatus 4 Example of configuration diagram of receiving apparatus of the present invention An example of a schematic diagram of an internal functional block diagram of a CPU in the receiving apparatus of the present invention An example of a flowchart of 2D / 3D video display processing based on whether or not the next program is 3D content Example of message display Example of message display Example of message display Example of message display An example of the flowchart of the system controller at the start of the next program Example of message display Example of message display An example of a block diagram showing a system configuration example An example of a block diagram showing a system configuration example Explanatory drawing of an example of 3D playback / output / display processing of 3D content Explanatory drawing of an example of 2D playback / output / display processing of 3D content Explanatory drawing of an example of 3D playback / output / display processing of 3D content Explanatory drawing of an example of 2D playback / output / display processing of 3D content An example of a flowchart of 2D / 3D video display processing based on whether or not the current program is 3D content Example of message display Example of display processing flowchart after user selection Example of message display An example of a flowchart of 2D / 3D video display processing based on whether or not the current program is 3D content Example of message display Example of stream combination during 3D video transmission

Hereinafter, examples (examples) of the preferred embodiments of the present invention will be described. However, the present invention is not limited to this embodiment. The present embodiment mainly describes the receiving apparatus and is suitable for implementation in the receiving apparatus, but does not hinder application to other than the receiving apparatus. Moreover, it is not necessary to employ all the configurations of the embodiment, and can be selected.

<System>
FIG. 1 is a block diagram illustrating a configuration example of a system according to the present embodiment. The case where information is transmitted / received by broadcast and recorded / reproduced is illustrated. However, it is not limited to broadcasting but may be VOD by communication, and is also collectively referred to as distribution.

1 is a transmission device installed in an information providing station such as a broadcasting station, 2 is a relay device installed in a relay station or a broadcasting satellite, 3 is a public line network connecting a general household and the broadcasting station such as the Internet, and the user's home 4 is a receiving device, and 10 is a reception recording / reproducing unit built in the receiving device 4. The reception recording / reproducing unit 10 can record and reproduce the broadcast information, or reproduce the content from a removable external medium.

The transmission device 1 transmits the modulated signal radio wave via the relay device 2. As shown in the figure, in addition to transmission by satellite, for example, transmission by cable, transmission by telephone line, transmission by terrestrial broadcasting, transmission via a network such as the Internet via the public network 3, etc. can also be used. As will be described later, the signal radio wave received by the receiving device 4 is demodulated into an information signal and then recorded on a recording medium as necessary. Alternatively, when the data is transmitted via the public line network 3, the data is converted into a format such as a data format (IP packet) conforming to a protocol suitable for the public line network 3 (for example, TCP / IP), and the received data is received. The device 4 decodes the information signal and records it on a recording medium as a signal suitable for recording if necessary. In addition, the user can watch the video and audio indicated by the information signal by connecting the receiving device 4 and a display (not shown) when the receiving device 4 has a built-in display, and connecting the receiving device 4 to a display (not shown). Can do.

<Transmitter>
FIG. 2 is a block diagram illustrating a configuration example of the transmission device 1 in the system of FIG.

11 is a source generation unit, 12 is an encoding unit that compresses MPEG2 or H.264 and adds program information, 13 is a scramble unit, 14 is a modulation unit, 15 is a transmission antenna, and 16 is management information. Part. Information such as video and audio generated by the source generation unit 11 including a camera and a recording / playback device is compressed by the encoding unit 12 so that it can be transmitted in a smaller occupied band. If necessary, the scrambler 13 performs transmission encryption so that a specific viewer can view. The modulation unit 14 uses OFDM, TC8PSK,
After being modulated to become a signal suitable for transmission, such as QPSK and multi-level QAM, the signal is transmitted from the transmission antenna 15 to the relay device 2 as a radio wave. At this time, the management information adding unit 16 sets program identification information such as content attributes created by the source generation unit 11 (for example, video and audio encoding information, audio encoding information, program configuration, 3D video Or not)
In addition, program arrangement information created by the broadcasting station (for example, the configuration of the current program and the next program, the format of the service, the configuration information of the program for one week, etc.) is also given. The program specifying information and the program arrangement information are collectively referred to as program information below.

In many cases, a plurality of pieces of information are multiplexed in one radio wave by a method such as time division or spread spectrum. Although not shown in FIG. 2 for simplicity, in this case, there are a plurality of systems of the source generation unit 11 and the encoding unit 12, and a multiplex for multiplexing a plurality of pieces of information between the encoding unit 12 and the scramble unit 13. Part (multiplexing part) is placed.

Similarly, a signal transmitted via the public network 3 is encrypted so that a signal generated by the encoding unit 12 can be viewed by a specific viewer by an encryption unit 17 as necessary. It becomes. After being encoded by the communication path encoding unit 18 so as to be a signal suitable for transmission through the public line network 3, the signal is transmitted from the network I / F (Interface) unit 19 toward the public line network 3.

<3D transmission system>
There are roughly two types of transmission methods for 3D programs transmitted from the transmission apparatus 1. One method is a method in which video for the left eye and right eye is stored in one image by utilizing an existing 2D program broadcasting method. This method is an existing MPEG2 (Moving Picture) video compression method.
Experts Group 2) and H.C. H.264 AVC is used, and its features are compatible with existing broadcasts, can use existing relay infrastructure, and can be received by existing receivers (STB, etc.). Half (vertical or horizontal) 3D video transmission. For example, as shown in FIG. 39A, one image is divided into left and right images (L
) And right-eye video (R) each have a horizontal width of about half that of a 2D program, and a vertical width of 2D.
The “Side-by-Side” method with the same screen size as the program and the horizontal width of each of the left-eye video (L) and right-eye video (R) are divided into 2D programs. Equivalent to the “Top-and-Bottom” method with a vertical size that is about half the screen size of a 2D program, the “Field alternative” method that uses interlace, and the left eye for each scanning line. There are a “Line alternative” method in which videos for the right eye are alternately stored, and a “Left + Depth” method in which two-dimensional (one side) video and depth (distance to the subject) information for each pixel of the video are stored. Since these methods divide one image into a plurality of images and store a plurality of viewpoint images, the encoding method itself is MPEG2 or H.264 which is not originally a multi-view video encoding method. H.264 AVC (M
The encoding method (except VC) can be used as it is, and there is an advantage that 3D program broadcasting can be performed by utilizing the existing 2D program broadcasting method. In addition, for example, when a 2D program can be transmitted with a screen size of 1920 dots in the maximum horizontal direction and 1080 lines in the vertical direction, one piece is required when 3D program broadcasting is performed in the “Side-by-Side” format. The left-eye video (L) and the right-eye video (R) are each stored in a screen size of 960 dots in the horizontal direction and 1080 lines in the vertical direction and transmitted. Similarly in this case, "Top-and-Bo
When 3D program broadcasting is performed using the “ttom” method, a single image is divided into upper and lower left video (L
) And the video for the right eye (R) may be transmitted with a screen size of 1920 dots in the horizontal direction and 540 lines in the vertical direction.

As another method, there is a method of transmitting the left-eye video and the right-eye video in separate streams (ES). In this embodiment, this method is hereinafter referred to as “3D2 viewpoint-specific ES transmission”.
As an example of this method, for example, H., which is a multi-view video encoding method. There is a transmission system based on H.264 MVC. The feature is that high-resolution 3D video can be transmitted. Using this method,
There is an effect that high-resolution 3D video can be transmitted. The multi-view video encoding method is
A standardized encoding method for encoding multi-view video, which can encode multi-view video without dividing one image for each viewpoint, and encodes another image for each viewpoint. It is.

When transmitting 3D video in this manner, for example, the encoded image for the left-eye viewpoint may be used as the main viewpoint image, and the encoded image for the right eye may be transmitted as another viewpoint image. In this way, the main viewpoint image can be compatible with the existing 2D program broadcasting system. For example,
As a multi-view video encoding system, H.264 is used. When H.264 MVC is used, H.264 is used. For the base substream of H.264 MVC, the main viewpoint image is H.264. H.264 AVC 2D images can be kept compatible, and the main viewpoint image can be displayed as a 2D image.

Furthermore, in the embodiment of the present invention, the following scheme is also included as another example of the “3D2 viewpoint-specific ES transmission scheme”.

As another example of “3D2 viewpoint-specific ES transmission method”, an encoded image for the left eye is used as a main viewpoint image, and M
H.264 is encoded with PEG2 and the encoded image for the right eye is set as another viewpoint image. H.264 AVC is encoded and included in a separate stream. According to this method, the main viewpoint image is MP.
Since it becomes compatible with EG2 and can be displayed as a 2D image, it is possible to maintain compatibility with an existing 2D program broadcasting system in which MPEG2-encoded images are widely used.

As another example of “3D2 viewpoint-specific ES transmission method”, an encoded image for the left eye is used as a main viewpoint image, and M
It includes a method of encoding with PEG2 and encoding the right-eye encoded image with MPEG2 as another viewpoint image to form separate streams. In this method, since the main viewpoint image is compatible with MPEG2 and can be displayed as a 2D image, it is possible to maintain compatibility with an existing 2D program broadcasting method in which encoded images based on MPEG2 are widely used.

As another example of the “3D2 viewpoint-specific ES transmission method”, an encoded image for the left eye is used as a main viewpoint image, and H.264 AVC or H.264. It is possible to encode with H.264 MVC and encode with MPEG2 the encoded image for the right eye as another viewpoint image.

Apart from the “3D2 viewpoint-specific ES transmission scheme”, MPEG2 and H.264 which are not originally defined as multi-view video encoding schemes. Even with an encoding method such as H.264 AVC (excluding MVC), 3D transmission is also possible by generating a stream in which left-eye video and right-eye frames are alternately stored.

<Program information>
Program identification information and program arrangement information are referred to as program information.
The program specific information is also called PSI (Program Specific Information), and is information necessary for selecting a required program, and specifies a packet identifier of a TS packet that transmits a PMT (Program Map Table) related to the broadcast program. (Program Association Table), a PMT that specifies a packet identifier of a TS packet that transmits each encoded signal constituting a broadcast program, and a packet identifier of a TS packet that transmits common information among related information of pay broadcasting,
NIT (Network In) that transmits information relating the transmission channel information such as the modulation frequency to the broadcast program
formation Table), consisting of four tables of CAT (Conditional Access Table) that specifies the packet identifier of TS packet that transmits individual information among the related information of pay broadcasting,
It is defined in the MPEG2 system standard. For example, it includes video encoding information, audio encoding information, and program configuration. In the present invention, information indicating whether or not the video is a 3D video is newly included. The PSI is added by the management information adding unit 16.

Program sequence information, also called SI (Service Information), is a variety of information defined for the convenience of program selection, including MPEG-2 system standard PSI information, program name, broadcast date, program content, etc. , EIT (Event Information) that contains information about the program
Table), organization channel name, broadcaster name, etc., and SDT (Service Description Table) in which information on organization channel (service) is described.

For example, the management information adding unit 16 includes information indicating the configuration of the currently broadcast program, the program to be broadcast next, the format of the service, and the program configuration information for one week.

The program information includes a component descriptor, a component group descriptor, a 3D program detail descriptor, a service descriptor, a service list descriptor, and the like, which are constituent elements of the program information. These descriptors are PMT, EIT [schedule basic / schedule extended / present / followin
g], NIT, and SDT.

As the usage of the PMT and EIT tables, for example, since only information on programs currently broadcast is described for PMT, information on programs broadcast in the future cannot be confirmed. However, since the transmission cycle from the transmission side is short, the time until the reception is completed is short, and the reliability is high in the sense that the information is not changed because it is information on the currently broadcast program. On the other hand, for EIT [schedule basic / schedule extended], information up to 7 days ahead can be acquired in addition to the currently broadcasted program, but the time until the reception is completed because the transmission cycle from the transmission side is longer than the PMT. There is a demerit such as low reliability in the sense that it requires a long storage area and may be changed due to a future event. As for EIT [following], information on the program of the next broadcast time can be acquired.

The program specific information PMT uses a table structure defined by ISO / IEC13818-1, and stream_type (stream format type) which is 8-bit information described in the 2nd loop (loop for each ES (Elementary Stream)). Thus, the ES format of the broadcast program can be indicated. In the embodiment of the present invention, the ES format is increased from the conventional one, for example,
As shown in FIG. 3, the ES format of the program to be broadcast is assigned.

First, the base-view sub-bitstream (main viewpoint) of a multi-view video encoding (eg H.264 / MVC) stream is defined by the existing ITU-T recommendation H.264 | ISO / IEC 14496-10 video AVC
The same 0x1B as the video stream is allocated. Next, a sub-bit stream (other viewpoint) of a multi-view video encoded stream (for example, H.264 MVC) that can be used for a 3D video program is assigned to 0x20.

Also, the existing ITU-T recommendation for the H.262 (MPEG2) system base-view bitstream (main viewpoint) when using the "3D2 viewpoint-specific ES transmission system" that transmits multiple viewpoints of 3D video in separate streams. H.262 | ISO / IEC 13818-2 Assign 0x02 which is the same as video. Where 3D
The base view bitstream (main view) of the H.262 (MPEG2) method when transmitting multiple viewpoints of video in separate streams is the H.262 only of the main viewpoint video among the multiple viewpoint videos of 3D video. (M
This is a stream encoded by the (PEG2) method.

Furthermore, H.262 (MPEG2) when transmitting multiple viewpoints of 3D video in different streams to 0x21.
Allocate bitstreams for other aspects of the method.

Furthermore, ITU-T Recommendation H.2 for transmitting multiple viewpoints of 3D video in different streams to 0x22
64 | Another viewpoint bitstream of AVC stream format specified by ISO / IEC 14496-10 video
Allocates a bit stream of (stream format type 0x23).

In this description, H.262 (MPEG2) in the case of assigning a sub-bit stream of a multi-view video encoded stream that can be used for a 3D video program to 0x20 and transmitting multiple viewpoints of 3D video in separate streams. Assign the bitstream of the other view of the scheme to 0x21,
ITU-T recommendation H.264 | ISO / IEC 14496-10 for transmitting multiple viewpoints of 3D video in separate streams
An AVC stream defined by video is assigned to 0x22, but 0x23 to 0x7E
It may be assigned to any of the above. Further, the MVC video stream is merely an example, and a video stream other than H.264 / MVC may be used as long as it represents a multi-view video encoded stream that can be used for a 3D video program.

As described above, by assigning the bit of stream_type (stream format type),
When the broadcaster on the transmission device 1 side transmits (broadcasts) the 3D program, in the embodiment of the present invention, for example, it is possible to transmit by a combination of streams as shown in FIG.

In combination example 1, multi-view video encoding (eg, H.264) is performed as a main-view (left-eye) video stream.
/ MVC) stream base view sub-bitstream (main view) (stream format type 0x1B
) And another viewpoint sub-bit stream (stream format type 0x20) of the multi-view video encoding (eg, H.264 / MVC) stream is transmitted as the sub-view (for right eye) video stream.

In this case, both the main-viewpoint (left-eye) video stream and the sub-viewpoint (right-eye) video stream use multi-viewpoint video encoding (eg, H.264 / MVC) format streams. Multi-view video coding (example:
The H.264 / MVC) method is originally a method for transmitting multi-viewpoint video, and can transmit a 3D program most efficiently among the combinations shown in FIG.

Further, when 3D display (output) of a 3D program, the receiving apparatus processes both the main viewpoint (for left eye) video stream and the sub-viewpoint (for right eye) video stream to reproduce the 3D program. Is possible.

When the receiving apparatus displays (outputs) a 3D program in 2D, it can display (output) as a 2D program by processing only the main-viewpoint (left-eye) video stream.

Since the multi-view video encoding method H.264 / MVC base-view sub-bit stream and the existing H.264 / AVC (excluding MVC) video stream are compatible, both are as shown in FIG. By assigning the same stream format type to 0x1B, the following effects are obtained. That is, 3
Even if a receiving apparatus that does not have the function of 3D display (output) of a D program receives the 3D program of Combination Example 1, an existing H.264 / AVC (excluding MVC) video stream (ITU) -T recommendation
H.264 | ISO / IEC 14496-10 video (AVC video stream defined by video) (with the ability to display (output)), the main view (for the left eye) video stream of the program based on the stream format type The H.264 / AVC (except MVC) video stream can be recognized and displayed (output) as a normal 2D program.

In addition, since the sub-viewpoint (for the right eye) video stream is assigned a stream format type that has not been used in the past, it is ignored by existing receivers. This allows the sub-viewpoint (
(For right eye) It is possible to prevent display (output) of the video stream unintended by the broadcasting station.

Therefore, even if the 3D program broadcast of Combination Example 1 is newly started, the existing H.264 / AVC (MV
It is possible to avoid a situation in which an existing receiving apparatus having a function of displaying (outputting) a video stream (except for C) cannot display (output). As a result, CM (commercial message)
) Etc., the 3D program broadcast was newly started by broadcasting operated by advertising revenue, etc.
Since the receiving apparatus that does not support the 3D display (output) function can be viewed, it is possible to avoid a decrease in the audience rating due to the restriction of the function of the receiving apparatus, and there is a merit on the broadcasting station side.

In combination example 2, an H.262 (MPEG2) base-view bit stream (main viewpoint) (stream format type 0x02) when transmitting multiple viewpoints of 3D video as separate streams as the main viewpoint (left-eye) video stream , And subviewpoint (for the right eye), when multiple viewpoints of 3D video are transmitted as separate streams, a bitstream of another viewpoint of the H.262 (MPEG2) system is assigned to 0x21, and multiple viewpoints of 3D video ITU-T recommendation H.2 when transmitting the data in a separate stream
64 | ISO / IEC 14496-10 AVC stream (stream format type 0x23) specified by video is transmitted.

As in the combination example 1, when the 3D program is displayed (output) in 3D, the receiving device
It is possible to process both the video stream for the left eye) and the sub-viewpoint (for the right eye) video stream to reproduce the 3D program, and when the receiving apparatus displays (outputs) the 3D program in 2D, the main viewpoint If only the video stream (for the left eye) is processed, it can be displayed (output) as a 2D program.

In addition, the H.262 (MPEG2) base-view bitstream (main viewpoint) when multiple viewpoints of 3D video are transmitted as separate streams is converted into the existing ITU-T recommendation H.262 | ISO / IEC 13818-2 video. The stream is compatible with the stream, and the stream format type of both is the same 0 as shown in FIG.
If the receiving device has a function to display (output) an existing ITU-T recommendation H.262 | ISO / IEC 13818-2 video stream by assigning to x1B, the receiving device does not have a 3D display (output) function However, it can be displayed (output) as a 2D program.

Further, as in the combination example 1, the sub-viewpoint (for the right eye) video stream is assigned a stream format type that has not been conventionally used, and thus is ignored by existing receiving apparatuses. As a result, the broadcast station side does not intend to display (output) the sub-viewpoint (for the right eye) video stream on the existing receiver.
Can be prevented.

Receiving devices with a display (output) function for existing ITU-T Recommendation H.262 | ISO / IEC 13818-2 video streams are widely used. Therefore, it is possible to realize the most preferable broadcasting for the broadcasting station.

Furthermore, the sub-viewpoint (for the right eye) is changed to the AVC stream (stream format type 0x23) specified by the ITU-T recommendation H.264 | ISO / IEC 14496-10 video as the sub-viewpoint (for the right eye) video stream. A video stream can be transmitted at a high compression rate.

That is, according to the combination example 2, it is possible to achieve both the commercial merit of the broadcasting station and the technical merit of high-efficiency transmission.

In combination example 3, an H.262 (MPEG2) base-view bit stream (main viewpoint) (stream format type 0x02) in the case of transmitting multiple viewpoints of 3D video as separate streams as the main viewpoint (left-eye) video stream When transmitting multiple viewpoints of 3D video as separate streams as sub-viewpoint (for the right eye) video stream, a bitstream of another viewpoint of the H.262 (MPEG2) system (
Stream format type 0x21) is transmitted.

Also in this case, as in the combination example 2, if the receiving apparatus has a function of displaying (outputting) an existing ITU-T recommendation H.262 | ISO / IEC 13818-2 video stream, a 3D display (output) function It is possible to display (output) as a 2D program even in a receiving apparatus that does not have the.

In addition to the commercial merits of the broadcast station, which further prevents a decrease in audience rating due to restrictions on the functions of the receiving device, the encoding method of the main viewpoint (left eye) video stream and the sub viewpoint (right eye) video stream is H. By unifying the 262 (MPEG2) system, the hardware configuration of the video decoding function in the receiving apparatus can be simplified.

Note that, as in Combination Example 4, multi-view video encoding is performed as the main-view (left-eye) video stream.
(Example: H.264 / MVC) Stream base-view sub-bitstream (primary viewpoint) (stream format type 0x1B) is transmitted, and multiple viewpoints of 3D video are transmitted as separate streams as sub-viewpoint (right-eye) video streams It is also possible to transmit a bit stream (stream format type 0x21) of another viewpoint in the H.262 (MPEG2) system in this case.

47, instead of the base-view sub-bitstream (main viewpoint) (stream format type 0x1B) of the multi-view video coding (eg, H.264 / MVC) stream, the ITU-T recommendation H.264 | AVC video stream defined by ISO / IEC 14496-10 video (stream format type 0x
Similar effects can be obtained with 1B).

In addition, in the combination of FIG. 47, H in the case of transmitting multiple viewpoints of 3D video in different streams.
Instead of the base-view bitstream (main view) of the .262 (MPEG2) system, ITU-T Recommendation H.262 |
A similar effect can be obtained as an ISO / IEC 13818-2 video stream (stream format type 0x02).

FIG. 4 shows an example of the structure of a component descriptor (Component Descriptor) which is one piece of program information. The component descriptor is a component (element constituting a program. For example,
Video, audio, character, various data) and the like, and is also used to represent an elementary stream in a character format. This descriptor is placed in the PMT and / or EIT.

The meaning of the component descriptor is as follows. In other words, descriptor_tag is an 8-bit field and describes a value that can identify this descriptor as a component descriptor. descri
ptor_length is an 8-bit field and describes the size of this descriptor. stream_co
The ntent (component content) is a 4-bit field and represents a stream type (video, audio, data), and is encoded according to FIG. The component_type (component type) defines the type of component such as an 8-bit field, video, audio, and data, and is encoded according to FIG. component_tag (component tag) is an 8-bit field. The component stream of the service can refer to the description content (FIG. 5) indicated by the component descriptor by this 8-bit field.

In the program map section, the component tag value given to each stream should be different. The component tag is a label for identifying the component stream, and has the same value as the component tag in the stream identification descriptor (provided that the stream identification descriptor exists in the PMT). The 24-bit field of ISO_639_language_code (language code) identifies the language of the component (speech or data) and the language of the character description contained in this descriptor.

The language code is represented by a three-letter code defined in ISO 639-2 (22). Each character is encoded in 8 bits according to ISO8859-1 (24) and inserted in the 24-bit field in that order. For example, Japanese is “jpn”, which is a three-letter code of the alphabet, and is encoded as follows. “0110 1010 0111 0000 0110 1110”. text_char (component description) is an 8-bit field. A series of component description fields define the character description of the component stream.

FIGS. 5A to 5E show examples of stream_content (component content) and component_type (component type) that are components of the component descriptor. The component content 0x01 shown in FIG. 5A represents various video formats of a video stream compressed in the MPEG2 format.

Component content 0x05 shown in FIG. 5B represents various video formats of a video stream compressed in the H.264 AVC format. Component content 0x06 shown in FIG. 5C represents various video formats of a 3D video stream compressed by multi-view video coding (for example, H.264 MVC format).

Component content 0x07 shown in FIG. 5D is MPEG2 or H.264 A.
Various video formats of a side-by-side stream of 3D video compressed in the VC format will be described. In this example, the same component content value is used in MPEG2 and H.264 AVC format, but different values may be set in MPEG2 and H.264 AVC.

Component content 0x08 shown in FIG. 5 (e) is MPEG2 or H.264 A.
Various video formats of a Top-and-Bottom stream of 3D video compressed in VC format will be described. In this example, the same component content value is used in MPEG2 and H.264 AVC format, but different values may be set in MPEG2 and H.264 AVC.

As shown in FIG. 5D and FIG. 5E, stream_conte, which is a component of the component descriptor.
Depending on the combination of nt (component content) and component_type (component type)
Whether it is 3D video or not, it is configured to show the combination of 3D video format, resolution, and aspect ratio, so that even for 3D and 2D mixed broadcasting, 2D program / 3D program identification can be performed with a small transmission amount. It is possible to transmit various types of video format information.

In particular, MPEG2 and H, which are not originally defined as multi-view video coding methods.
.264 AVC (excluding MVC) and other encoding methods, Side-by-Side format and Top-an
When transmitting a 3D video program including multiple viewpoint images in one image such as d-Bottom format, multiple viewpoints in one image for the 3D video program can be obtained only with the above-described stream_type (stream format type). It is difficult to identify whether the image is transmitted including a single image or a normal image from one viewpoint. Therefore, in this case, stream_content (component content) and componen
What is necessary is just to identify the various video systems including the 2D program / 3D program identification by the combination of t_type (component type). In addition, by receiving a component descriptor related to a program that is currently being broadcast or will be broadcast in the future by EIT, the receiving device 4
EPG (program guide) is created by acquiring EIT in EPG, and 3 as EPG information
It is possible to create whether or not it is a D video, whether or not it is a 3D video system, resolution, aspect ratio, and 3D video. The receiving apparatus has an advantage that such information can be displayed (output) on the EPG.

As described above, the receiver 4 monitors stream_content and component_type, so that it is possible to recognize that the currently received program or a future received program is a 3D program.

FIG. 6 shows a component group descriptor (Component Group Desc) that is one piece of program information.
An example of the structure of (riptor) is shown. The component group descriptor defines and identifies the combination of components in the event. That is, grouping information of a plurality of components is described. This descriptor is placed in the EIT.

The meaning of the component group descriptor is as follows. That is, descriptor_tag is 8
A bit field describes a value that allows this descriptor to be distinguished from a component group descriptor. descriptor_length is an 8-bit field and describes the size of this descriptor. component_group_type (component group type) is a 3-bit field and represents the group type of the component in accordance with FIG.
Here, 001 represents a 3DTV service and is distinguished from 000 multi-view TV services. Here, the multi-view TV service is a TV service capable of switching and displaying a 2D video of a plurality of viewpoints for each viewpoint. For example, in a multi-view video encoded video stream or a stream of an encoding method that is not originally an encoding method defined as a multi-view video encoding method, a stream in which images of a plurality of viewpoints are transmitted in one screen 3D
It may be used not only for video programs but also for multi-view TV programs. In this case,
Even when a multi-view video is included in a stream, it may not be possible to identify whether it is a 3D video program or a multi-view TV program only by the above-described stream_type (stream format type). In such a case, identification by component_group_type (component group type) is effective. total_bit_rate_flag is a 1-bit flag.
Indicates the description state of the total bit rate in the component group during the event. When this bit is “0”, it indicates that the total bit rate field in the component group does not exist in the descriptor. When this bit is “1”, it indicates that the total bit rate field in the component group exists in the descriptor. num_of_group (number of groups) is a 4-bit field and indicates the number of component groups in the event.

component_group_id (component group identification) is a 4-bit field.
According to this, the component group identification is described. num_of_CA_unit (billing unit number) is a 4-bit field and indicates the number of billing / non-billing units in the component group. CA_u
nit_id (billing unit identification) is a 4-bit field and describes the charging unit identification to which the component belongs according to FIG.

num_of_component (number of components) is a 4-bit field and indicates the number of components belonging to the component group and belonging to the billing / non-billing unit indicated by the immediately preceding CA_unit_id. component_tag (component tag) is an 8-bit field indicating the value of the component tag belonging to the component group.

total_bit_rate (total bit rate) is an 8-bit field, and describes the total bit rate of the components in the component group by rounding up the transport stream packet transmission rate every 1/4 Mbps. text_length (component group description length) is an 8-bit field and represents the byte length of the subsequent component group description. text_char (component group description) is an 8-bit field. A series of character information fields describes a description about the component group.

As described above, the monitoring of the component_group_type by the receiving device 4 has an effect of recognizing that a program that is currently received or that will be received in the future is a 3D program.

Next, an example in which a new descriptor indicating information related to a 3D program is used will be described. FIG. 10 (a)
Shows an example of the structure of a 3D program detail descriptor, which is one piece of program information. The 3D program detailed descriptor indicates detailed information when the program is a 3D program, and is used for determining a 3D program in the receiver. This descriptor is placed in the PMT and / or EIT. The 3D program detail descriptor may coexist with stream_content (component content and component_type (component type) for the 3D video program shown in FIGS. 5 (c) to 5 (e) already described. By transmitting the child, the stream_content (component content or component_type (component type)) for the 3D video program may not be transmitted. The meaning of the 3D program detail descriptor is as follows. In this field, a value (for example, 0xE1) that can distinguish this descriptor from the 3D program detail descriptor is described.
r_length is an 8-bit field and describes the size of this descriptor.

3d_2d_type (3D / 2D type) is an 8-bit field, and is 3 in accordance with FIG.
Indicates the type of 3D video / 2D video in the D program. This field is information for identifying whether a 3D video or a 2D video in a 3D program in which the main part of the program is a 3D video and a commercial inserted in the middle of the program is composed of 2D video, for example. Yes, it is arranged for the purpose of preventing malfunction in the receiving apparatus (display (output) problem that occurs because the broadcast program is 2D video even though the receiving apparatus performs 3D processing). 0x01 is 3D video, 0x02
Represents a 2D image.
3d_method_type (3D method type) is an 8-bit field and represents a 3D method type according to FIG. 0x01 is the “3D2 viewpoint-specific ES transmission method”, and 0x02 is Side-by-Side
System, 0x03 represents Top-and-Bottom system. stream_type (stream format type) is 8
The bit field indicates the ES format of the program according to FIG. 3 described above.
The 3D program detail descriptor may be transmitted in the case of a 3D video program and not transmitted in a 2D video program. The presence or absence of transmission of the 3D program detail descriptor for the received program
It is possible to identify whether the program is a 2D video program or a 3D video program.

The component_tag (component tag) is an 8-bit field. The component stream of the service can refer to the description content (FIG. 5) indicated by the component descriptor by this 8-bit field. In the program map section, the component tag value given to each stream should be different. The component tag is a label for identifying the component stream, and has the same value as the component tag in the stream identification descriptor (provided that the stream identification descriptor exists in the PMT).

As described above, if the receiving device 4 monitors the 3D program detail descriptor and this descriptor exists,
There is an effect that it is possible to recognize that the program currently received or received in the future is a 3D program. In addition, if the program is a 3D program, identifying the type of 3D transmission method,
When D video and 2D video are mixed, the identification can be performed.

Next, an example in which 3D video or 2D video is identified on a service (organization channel) basis will be described. FIG. 12 shows an example of the structure of a service descriptor (Service Descriptor) which is one piece of program information. The service descriptor represents the organization channel name and the business operator name together with the service format type by a character code. This descriptor is placed in the SDT.

The meaning of the service descriptor is as follows. That is, service_type (service type)
Is an 8-bit field and represents the type of service according to FIG. 0x01 represents a 3D video service. The 8-bit field of service_provider_name_length (operator name length) represents the byte length of the subsequent operator name. char (character code) is an 8-bit field. A series of character information fields represents a business name or a service name. service_name_l
The 8-bit field of ength (service name length) represents the byte length of the subsequent service name.

As described above, the reception device 4 monitors service_type, so that the service (organization channel) is 3
There is an effect of recognizing that it is a channel of D program. In this way, if it is possible to identify whether a service (organization channel) is a 3D video service or a 2D video service, it is possible to display, for example, that the service is a 3D video program broadcast service by EPG display or the like. . However, even a service that broadcasts mainly 3D video programs may need to broadcast 2D video, such as when the source of advertisement video is only 2D video. Therefore, the 3D video service is identified by the service_type (service type type) of the service descriptor. The 3D video program is identified by the combination of stream_content (component content) and component_type (component type), and component_group_type (component group type). 3D video program identification by 3) or 3D video program identification by 3D program detail descriptor is desirable. 3 to identify multiple information in combination
Although it is a D video broadcasting service, it is possible to identify that only some programs are 2D video. If such identification can be made, the receiving device, for example, EPG can clearly indicate that the service is a “3D video broadcasting service”, and the service includes a mixture of 2D video programs in addition to 3D video programs. Even when the program is received, the display control or the like can be switched as necessary between the 3D video program and the 2D video program.

FIG. 14 shows a service list descriptor (Service List Descriptor) which is one piece of program information.
An example of the structure is shown. The service list descriptor provides a list of services according to service identification and service type. That is, a list of organization channels and their types is described. This descriptor is placed in the NIT.

The meaning of the service list descriptor is as follows. That is, service_id (service identification)
Is a 16-bit field that uniquely identifies the information service in the transport stream. The service identification is equal to the broadcast program number identification (program_number) in the corresponding program map section. The service_type (service type type) is an 8-bit field and represents the type of service according to FIG. 12 described above.

Since it is possible to identify whether or not it is “3D video broadcasting service” by these service_type (service type type), for example, by using the list of organized channels and their types indicated in the service list descriptor, EPG In the display, it is possible to perform a display in which only “3D video broadcasting service” is grouped.

As described above, there is an effect that the receiving device 4 can recognize that the organization channel is a channel of a 3D program by monitoring service_type.

The examples of descriptors described above describe only representative members. Having other members, combining multiple members into one, and converting one member into multiple members with detailed information. Dividing is also conceivable.

<Examples of program information transmission operation rules>
Program information component descriptor, component group descriptor, 3 described above
The D program detail descriptor, service descriptor, and service list descriptor are, for example, management information adding unit 1
6 is generated and added to the PSI of MPEG-TS (PMT as an example), or SI (
For example, the information is stored in EIT, SDT, NIT, etc.) and transmitted from the transmission apparatus 1.

An example of program information transmission operation rules in the transmission apparatus 1 will be described below.
FIG. 15 shows an example of a transmission operation rule in the component descriptor transmission apparatus 1. "
In “descriptor_tag”, describe “0x50” which means the component descriptor. "Descript
“or_length” describes the descriptor length of the component descriptor. The maximum descriptor length is not specified. In “stream_content”, “0x01” (video) is described.

In “component_type”, the video component type of the component is described.
The component type is set from FIG. “Component_tag” describes a component tag value that is unique within the program. "ISO_639_language_code" is "jpn (
Write "0x6A706E") ".

“Text_char” is described with a video type name of 16 bytes (8 full-width characters) or less when there are multiple video components. Do not use a line feed code. This field can be omitted if the component description is the default string. The default character string is “video”.

It should be noted that at least one video component having a component_tag value of 0x00 to 0x0F included in the event (program) is always transmitted.

As described above, when the transmission apparatus 1 performs the transmission operation, the reception apparatus 4 makes the stream_content and comp
By monitoring the onent_type, there is an effect that it is possible to recognize that the currently received program or a program to be received in the future is a 3D program.

FIG. 16 shows an example of a transmission operation rule in the component group descriptor transmission apparatus 1.

In “descriptor_tag”, “0xD9” indicating a component group descriptor is described. In “descriptor_length”, the descriptor length of the component group descriptor is described.
The maximum descriptor length is not specified. “Component_group_type” indicates the type of component group. “000” indicates a multi-view TV, and “001” indicates a 3D TV.

In “total_bit_rate_flag”, if all the total bit rates in the group in the event are at the specified default value, set to “0”, and one of the total bit rates in the group in the event exceeds the specified default value. If it is present, it indicates '1'.

“Num_of_group” describes the number of component groups in the event. The maximum is 3 for multi-view television (MVTV) and 2 for 3D television (3DTV).

“Component_group_id” describes component group identification. In the case of the main group, “0x0” is assigned, and in the case of each subgroup, the broadcaster assigns it uniquely within the event.

“Num_of_CA_unit” describes the number of charge / non-charge units in the component group. The maximum value is 2. Set to "0x1" if no component to be charged is included in the component group.

“CA_unit_id” describes the charging unit identification. The broadcaster assigns it uniquely within the event. “Num_of_component” belongs to the component group, and “CA_unit_
Describes the number of components belonging to the charging / non-charging unit indicated by “id”. Maximum value is 15
And

“Component_tag” describes a component tag value belonging to the component group. “Total_bit_rate” describes the total bit rate in the component group. However, “0x00” is described for the default value.

“Text_length” describes the byte length of the subsequent component group description. The maximum value is 16 (8 full-width characters). “Text_char” always describes the description about the component group. No default string is specified. Also, no line feed code is used.

When performing multi-view TV service, “component_group_type” is' 000
Always send as'. In addition, when performing 3D TV service, “component_group_ty
“pe” must be sent as '001'.

As described above, when the transmission apparatus 1 performs the transmission operation, the reception apparatus 4 makes the component_group_type
By monitoring this, it is possible to recognize that the program that is currently being received or will be received in the future is a 3D program.

FIG. 17 shows an example of a transmission operation rule in the transmission device 1 for the 3D program detail descriptor. "De
In “scriptor_tag” is described “0xE1” which means a 3D program detail descriptor. "Descriptor_l
“ength” describes the descriptor length of the 3D program detail descriptor. "3d_2d_type" is 3D / 2D
Describe identification. It sets from FIG.10 (b). “3d_method_type” describes 3D method identification. The setting is made from FIG. “Stream_type” describes the ES format of the program.
The setting is made from FIG. “Component_tag” describes a component tag value that is unique within the program.

By performing transmission operation in the transmission apparatus 1 in this way, the reception apparatus 4 monitors the 3D program detail descriptor, and if this descriptor exists, a program that is currently received or will be received in the future is a 3D program. There is an effect that can be recognized.

FIG. 18 shows an example of a transmission operation rule in the service descriptor transmission apparatus 1. "Descri
In “ptor_tag”, “0x48” indicating a service descriptor is described. "Descriptor_length"
Describes the descriptor length of the service descriptor. “Service_type” describes the service type.

The service format type is set from FIG. "Service_provider_name_le
“ngth” describes the name of the operator in BS / CS digital television broadcasting. Maximum value is 20
And Since terrestrial digital television broadcasting does not operate service_provider_name,
Write “0x00”.

“Char” describes an operator name in BS / CS digital television broadcasting. Maximum full width 10
character. Nothing is described for digital terrestrial television broadcasting. “Service_name_length” describes the organization channel name length. The maximum value is 20. “Char” describes the organization channel name. It is within 20 bytes and within 10 full-width characters. Note that only one is always arranged for the target knitting channel.

By performing transmission operation in the transmission apparatus 1 in this manner, there is an effect that the reception apparatus 4 can recognize that the organization channel is a 3D program channel by monitoring service_type.

FIG. 19 shows an example of a transmission operation rule in the service list descriptor transmitting apparatus 1. "
In “descriptor_tag”, describe “0x41” which means the service list descriptor. "Descript
“or_length” describes the descriptor length of the service list descriptor. “Loop” describes a loop of the number of services included in the target transport stream.

“Service_id” describes service_id included in the transport stream.
“Service_type” describes the service type of the target service. The setting is made from FIG. Note that this is always arranged for the TS loop in the NIT.

By performing transmission operation in the transmission apparatus 1 in this manner, there is an effect that the reception apparatus 4 can recognize that the organization channel is a 3D program channel by monitoring service_type.

As described above, the transmission example of the program information in the transmission apparatus 1 has been described. When the program is switched from the 2D program to the 3D program, on the first screen where the 3D program starts, for example, using a telop, the “3D program is started. “When viewing with 3D display, wearing 3D viewing glasses”, “Recommending viewing with 2D display when eyes are tired or unwell”, “3D program length For a user who views a 3D program on the receiving device 4 by inserting and sending it to the video of the 3D program created by the transmitting device 1 such as “viewing time may cause eyestrain or poor physical condition”. There is a merit that warning / warning for 3D program viewing can be performed.

<Hardware configuration of receiving device>
FIG. 25 is a hardware configuration diagram illustrating a configuration example of the receiving device 4 in the system of FIG. 21 is a CPU (Central Processing Unit) for controlling the entire receiver, 22 is a CPU 2
1 is a general-purpose bus for transmitting control and information between each part in the receiving apparatus and 23 is a radio (satellite,
The broadcast signal transmitted from the transmission device 1 is received via a broadcast transmission network such as a cable, a cable, etc., a specific frequency is selected, demodulation, error correction processing, etc. are performed, and an MPEG2-Transport Stream (hereinafter, “ (Also referred to as “TS”), a tuner that outputs multiplexed packets such as 24), a descrambler 24 that decodes scrambled data by the scrambler 13, and 25 that transmits and receives information to and from the network. A network interface (I / F) 26 for transmitting and receiving a HDD (Har, for example) built in the receiving device 4
d Disk Drive), a flash memory, or a recording medium such as a removable HDD, a disk-type recording medium, or a flash memory, 27 controls the recording medium 26, records signals to the recording medium 26, and signals from the recording medium 26 A recording / playback unit 29 for controlling playback of MPEG2-
Signals multiplexed in a format such as TS are converted into video ES (Elementary Stream), audio ES
A demultiplexing unit that separates signals such as program information. An ES is each of compressed and encoded image / sound data. 30 is a video decoding unit that decodes the video ES into a video signal, 31 is an audio decoding unit that decodes the audio ES into an audio signal and outputs it to the speaker 48 or output from the audio output 42, and 32 is the video decoding unit 30. The decoded video signal is superposed on the video signal by processing to convert the 3D or 2D video signal into a predetermined format by a conversion process to be described later according to the instruction of the CPU, and the display such as OSD (On Screen Display) created by the CPU 21. The processed video signal is displayed on the display 47 or the video signal output unit 4.
1, a video conversion processing unit that outputs a synchronization signal and a control signal (used for device control) corresponding to the format of the processed video signal from the video signal output unit 41 and the control signal output unit 43,
33 receives an operation input from the user operation input unit 45 (for example, a key code from a remote controller that transmits an IR (Infrared Radiation) signal), and controls the device to the external device generated by the CPU 21 or the video conversion processing unit 32. A control signal transmission / reception unit that transmits a signal (for example, IR) from the device control signal transmission unit 44, 34 has a counter therein, a timer that holds the current time, and 46 is reconfigured by the demultiplexing unit High-speed digital I / F such as a serial interface or IP interface that performs necessary processing such as encryption on the TS and outputs the TS to the outside or decrypts the TS received from the outside and inputs it to the demultiplexing unit 29
, 47 is a display that displays 3D video and 2D video decoded by the video decoding unit 30 and converted by the video conversion processing unit 32, and 48 is a speaker that outputs sound based on the audio signal decoded by the audio decoding unit. The receiving device 4 is mainly composed of these devices. In the case of 3D display on the display, if necessary, the synchronization signal and the control signal are output from the control signal output unit 43 and the device control signal transmission terminal 44.

Examples of the system configuration including the receiving device, the viewing device, and the 3D viewing assistance device (for example, 3D glasses) are shown in FIG. 35 and FIG. FIG. 35 shows a system configuration in which the receiving device and the viewing device are integrated, and FIG. 36 shows an example in which the receiving device and the viewing device are configured separately.

In FIG. 35, 3501 is a display device including the configuration of the receiving device 4 and capable of 3D video display and audio output, 3503 is a 3D viewing assist device control signal (for example, IR signal) output from the display device 3501, and 3502 is 3D shows a 3D viewing assistance device. In the example of FIG. 35, the video signal is displayed from a video display included in the display device 3501, and the audio signal is output from a speaker included in the display device 3501. Similarly, the display device 3501 includes an output terminal that outputs a 3D viewing assist device control signal output from the device control signal 44 or the output portion of the control signal 43.

The above description has been made on the assumption that the display device 3501 and the 3D viewing assistance device 3502 shown in FIG. 35 perform display by an active shutter method to be described later, but the display device 3501 and the 3D viewing assistance device shown in FIG. In the case of a method of performing a 3D video display device by polarization separation, which will be described later, the 3D viewing assistance device 3502 only needs to perform polarization separation so that different images are incident on the left eye and the right eye, and the display device 3501. From device control signal 4
4 or the output part of the control signal 43 may not output the 3D viewing assistance device control signal 3503 output to the 3D viewing assistance device 3502.

In FIG. 36, 3601 is a video / audio output device including the configuration of the receiving device 4, and
02 is a transmission path (for example, HDMI cable) for transmitting video / audio / control signals, 3603
Represents a display for displaying and outputting an externally input video signal and audio signal.

In this case, the video signal output from the video output 41 of the video / audio output device 3601 (reception device 4), the audio signal output from the audio output 42, and the control signal output from the control signal output unit 43 are transmitted through the transmission path 3602. Is converted into a transmission signal in a format suitable for the format specified in (for example, a format specified by the HDMI standard), and input to the display 3603 via the transmission path 3602. The display 3603 receives the transmission signal, decodes it to the original video signal, audio signal, and control signal, outputs video and audio, and outputs a 3D viewing assist device control signal 3503 to the 3D viewing assist device 3502. To do.

The above description has been made on the assumption that the display device 3603 and the 3D viewing assistance device 3502 shown in FIG. 36 display by an active shutter method described later, but the display device 3603 and the 3D viewing assistance device shown in FIG. In the case of a method of performing a 3D video display device by polarization separation, which will be described later, the 3D viewing assistance device 3502 only needs to perform polarization separation so that different images are incident on the left eye and the right eye, and the display device 3603. 3D viewing assist device control signal 3603 does not have to be output from 3D to 3D viewing assist device 3502.

A part of each of the constituent elements 21 to 46 shown in FIG. 25 may be composed of one or a plurality of LSIs. Moreover, it is good also as a structure which implement | achieves a part of function of each structural requirement of 21-46 shown in FIG. 25 with software.

<Functional block diagram of receiver>
FIG. 26 is an example of a functional block configuration of processing inside the CPU 21. Here, each functional block exists, for example, as a software module executed by the CPU 21, and some means (for example, message passing, function call, event transmission) is performed between each module to exchange and control information and data. Give instructions.

Each module also transmits / receives information to / from hardware in the receiving device 4 via the general-purpose bus 22. Moreover, although the relationship line (arrow) described in the figure mainly describes the part related to this explanation, there is a communication means and a process that requires communication between other modules. For example, the channel selection control unit 59 obtains program information necessary for channel selection from the program information analysis unit 54.
From time to time.

Next, the function of each functional block will be described. The system control unit 51 manages the state of each module, the user instruction state, and the like, and issues a control instruction to each module. The user instruction receiving unit 52 receives and interprets a user operation input signal received by the control signal transmitting / receiving unit 33 and transmits the user instruction to the system control unit 51. The device control signal transmission unit 53 instructs the control signal transmission / reception unit 33 to transmit a device control signal in accordance with instructions from the system control unit 51 and other modules.

The program information analysis unit 54 acquires program information from the demultiplexing unit 29, analyzes the contents, and provides necessary information to each module. The time management unit 55 acquires time correction information (TOT: Time offset table) included in the TS from the program information analysis unit 54 and manages the current time, and uses the counter of the timer 34 to An alarm (notification of the arrival of a specified time) and a one-shot timer (notification of the elapse of a certain time) are performed as requested.

The network control unit 56 controls the network I / F 25 to specify a specific URL (Unique R
esource Locater) and various information from specific IP (Internet Protocol) addresses and TS
Get the. The decoding control unit 57 controls the video decoding unit 30 and the audio decoding unit 31 to start and stop decoding and acquire information included in the stream.

The recording / playback control unit 58 controls the recording / playback unit 27, and from the recording medium 26, from a specific position of a specific content, and in any reading format (normal playback, fast forward, rewind, pause)
Read the signal with. Further, control is performed to record the signal input to the recording / reproducing unit 27 on the recording medium 26.

The channel selection control unit 59 controls the tuner 23, the descrambler 24, the demultiplexing unit 29, and the decoding control unit 57 to receive broadcasts and record broadcast signals. Alternatively, control is performed until reproduction from the recording medium and output of the video signal and the audio signal. Detailed broadcast reception operation, broadcast signal recording operation, and reproduction operation from the recording medium will be described later.

The OSD creation unit 60 creates OSD data including a specific message, and instructs the video conversion control unit 61 to superimpose the created OSD data on the video signal and output it. Here, the OSD creation unit 60 creates parallax OSD data for left eye and right eye, and requests the video conversion control unit 61 to perform 3D display based on the left-eye and right-eye OSD data. As a result, message display in 3D is performed.

The video conversion control unit 61 controls the video conversion processing unit 32 to convert the video signal input from the video decoding unit 30 to the video conversion processing unit 32 into 3D or 2D video according to an instruction from the system control unit 51. Then, the converted video and the OSD input from the OSD creation unit 60 are superimposed,
Further, if necessary, the video is processed (scaling, PinP, 3D display, etc.) and displayed on the display 47 or output to the outside. Details of a method for converting 3D video and 2D video into a predetermined format in the video conversion processing unit 32 will be described later. Each functional block provides these functions.

<Broadcast reception>
Here, a control procedure and a signal flow when performing broadcast reception will be described. First, the user's instruction (for example, pressing the CH button on the remote control) indicating broadcast reception of a specific channel (CH)
The system control unit 51 received from the user instruction receiving unit 52 receives the CH (
The channel selection control unit 59 is instructed to select a channel using the designated CH).

Upon receiving the instruction, the channel selection control unit 59 instructs the tuner 23 to perform reception control of the designated CH (tuning to the designated frequency band, broadcast signal demodulation processing, error correction processing), and sends the TS to the descrambler 24. Output.

Next, the channel selection control unit 59 instructs the descrambler 24 to descramble the TS and output it to the demultiplexing unit 29. The demultiplexing unit 29 receives the demultiplexing of the input TS, In addition, an instruction to output the demultiplexed video ES to the video decoding unit 30 and to output the audio ES to the audio decoding unit 31 is given.

Further, the channel selection control unit 59 instructs the decoding control unit 57 to decode the video ES and the audio ES input to the video decoding unit 30 and the audio decoding unit 31. Upon receiving the decoding instruction, the decoding control unit 31 controls the video decoding unit 30 to output the decoded video signal to the video conversion processing unit 32, and the audio decoding unit 31 receives the decoded audio signal from the speaker. 48 or audio output 4
Control to output to 2. In this way, control is performed to output the video and audio of the CH designated by the user.

Further, in order to display a CH banner (OSD for displaying a CH number, program name, program information, etc.) at the time of channel selection, the system control unit 51 instructs the OSD creation unit 60 to create and output a CH banner. . The OSD creation unit 60 that has received the instruction transmits the created CH banner data to the video conversion control unit 61, and the video conversion control unit 61 that has received the data outputs the CH banner superimposed on the video signal. To control. In this way, a message is displayed at the time of channel selection.

<Recording of broadcast signal>
Next, broadcast signal recording control and signal flow will be described. When recording a specific CH, the system control unit 51 selects a specific CH and records / plays back to the channel selection control unit 59.
7 is instructed to output a signal.

The channel selection control unit 59 that has received the instruction instructs the tuner 23 to receive the designated channel as in the broadcast reception process, and the MPEG2-TS received from the tuner 23 to the descrambler 24. The descrambler 24 with respect to the descrambler / demultiplexer 29
To input to the recording / reproducing unit 27.

In addition, the system control unit 51 instructs the recording / playback control unit 58 to record the input TS to the recording / playback unit 27. Receiving the instruction, the recording / playback control unit 58 performs necessary processing such as encryption on the signal (TS) input to the recording / playback unit 27, and also adds additional information (recording CH of the recording CH) required for recording / playback. Program information, content information such as bit rate)
Processing for recording the MPEG2-TS, additional information, and management data on the recording medium 26 after recording the management data (recorded content ID, recording position on the recording medium 26, recording format, encryption information, etc.) I do. In this way, the broadcast signal is recorded.

<Reproduction from recording media>
Next, playback processing from a recording medium will be described. When reproducing a specific program, the system control unit 51 instructs the recording / reproduction control unit 58 to reproduce the specific program. As an instruction at this time, the content ID and the reproduction start position (for example, the top of the program, 10
Minute position, last continuation, 100Mbyte position from the beginning, etc.). The recording / playback control unit 58 that has received the instruction controls the recording / playback unit 27 to read out a signal (TS) from the recording medium 26 using additional information and management data, and perform necessary processing such as decryption of encryption. After that, processing is performed to output TS to the demultiplexing unit 29.

In addition, the system control unit 51 instructs the channel selection control unit 59 to output the video and audio of the reproduction signal. The channel selection control unit 59 that has received the instruction receives the input from the recording / reproducing unit 27 as the demultiplexing unit 2.
9, the demultiplexing unit 29 demultiplexes the input TS, outputs the demultiplexed video ES to the video decoding unit 30, and demultiplexed audio ES audio. The output to the decoding unit 31 is instructed.

Further, the channel selection control unit 59 instructs the decoding control unit 57 to decode the video ES and the audio ES input to the video decoding unit 30 and the audio decoding unit 31. Upon receiving the decoding instruction, the decoding control unit 31 controls the video decoding unit 30 to output the decoded video signal to the video conversion processing unit 32, and the audio decoding unit 31 receives the decoded audio signal from the speaker. 48 or audio output 4
Control to output to 2. In this way, signal reproduction processing from the recording medium is performed.

<3D video display method>
As a 3D video display method that can be used in the present invention, left and right eye images that make the left and right eyes feel parallax are created, and a human being recognizes that a three-dimensional object exists. There is a method.

As one method, the glasses worn by the user are shielded from light by the left and right glasses alternately using a liquid crystal shutter, etc., and the left and right eye images are displayed in synchronization with the glasses. There is an active shutter system that generates parallax in an image displayed on the screen.

In this case, the receiving device 4 outputs a synchronization signal and a control signal from the control signal output unit 43 and the device control signal transmission terminal 44 to the active shutter glasses worn by the user. Further, the video signal is output from the video signal output unit 41 to an external 3D video display device, and the left-eye video and the right-eye video are alternately displayed. Alternatively, the same 3D display is performed on the display 47 of the receiving device 4. In this way, a user wearing active shutter glasses can view 3D video on the display 47 of the 3D video display device or the receiving device 4.

As another method, for the glasses worn by the user, a film orthogonal to the linearly polarized light is applied to the left and right glasses, or a linearly polarized coating is applied, or a circularly polarized film with the rotation direction of the polarization axis reversed. Or apply a circularly polarized coat, and simultaneously output the image for the left eye and the image for the right eye with different polarizations corresponding to the polarization of the glasses for the left eye and the right eye respectively. There is a polarization method that generates parallax between the left eye and the right eye by separating them according to the polarization state.

In this case, the receiving device 4 outputs the video signal from the video signal output unit 41 to an external 3D video display device, and the 3D video display device converts the left-eye video and the right-eye video in different polarization states. Display. Alternatively, the same display is performed on the display 47 of the receiving device 4.
In this way, a user wearing polarized glasses can view 3D video on the display 47 of the 3D video display device or the receiving device 4. In the polarization method, the polarization method glasses 3 do not transmit a synchronization signal or a control signal from the receiving device 4.
Since D video viewing is possible, there is no need to output a synchronization signal or a control signal from the control signal output unit 43 or the device control signal transmission terminal 44.

In addition, a color separation method that separates the left and right eye images by color may be used. Alternatively, a parallax barrier method that creates a 3D image using a parallax barrier that can be viewed with the naked eye may be used.

  The 3D display method according to the present invention is not limited to a specific method.

<Example of specific determination method of 3D program using program information>
As an example of a 3D program determination method, information for determining whether or not a 3D program is newly included is obtained from various tables and descriptors included in the program information of the broadcast signal and the reproduction signal described above. It is possible to determine whether or not.

Check the information to determine whether the 3D program is newly included in the component descriptor or component group descriptor described in the table such as PMT and EIT [schedule basic / schedule extended / present / following]. Or 3D program details descriptor, which is a new descriptor for 3D program determination, is newly included in the service descriptor, service list descriptor, etc. described in tables such as NIT and SDT It is determined whether or not it is a 3D program by checking information for determining whether or not it is a 3D program. These pieces of information are added to the broadcast signal in the transmission device described above and transmitted. In the transmission device, for example, the management information adding unit 16 adds these pieces of information to the broadcast signal.

The use of each table is characterized in that, for example, only information on the current program is described for PMT, so information on future programs cannot be confirmed, but the reliability is high. On the other hand, for EIT [schedule basic / schedule extended], information on future programs as well as current programs can be acquired, but it takes a long time to complete reception, requires a large storage area, and is a future event. There are disadvantages such as low reliability. As for EIT [following], it is possible to obtain information on a program at the next broadcast time, and therefore it is suitable for application to the present embodiment. Further, EIT [present] can be used to obtain current program information, and information different from PMT can be obtained.

Next, a detailed example of processing of the receiving device 4 related to the program information described in FIGS. 4, 6, 10, 12, and 14 sent from the transmitting device 1 will be described.

FIG. 20 shows an example of processing for each field of the component descriptor in the receiving device 4.

If “descriptor_tag” is “0x50”, it is determined that the descriptor is a component descriptor. Based on “descriptor_length”, it is determined to be the descriptor length of the component descriptor. If “stream_content” is “0x01”, it is determined that the descriptor is valid (video). “
If it is other than “0x01”, it is determined that the descriptor is invalid. If “stream_content” is “0x01”, the subsequent processing is performed.

“Component_type” is determined as the video component type of the component. For this component type, one of the values in FIG. 5 is designated. From this content, it can be determined whether or not the component is a component for a 3D video program.

“Component_tag” is a component tag value that is unique within the program, and can be used in association with the component tag value of the PMT stream identifier.

“ISO_639_language_code” treats a character code arranged later as “jpn”, except for “jpn (“ 0x6A706E ”)”.

“Text_char” is determined to be a component description within 16 bytes (8 full-width characters). If this field is omitted, it is determined as the default component description. The default character string is “video”.

As described above, the component descriptor can determine the type of video component constituting the event (program), and the component description can be used when selecting the video component in the receiver.

Note that only video components whose component_tag value is set to a value between 0x00 and 0x0F are to be selected independently. Video components set with component_tag values other than the above are
It should not be a single selection target, nor a component selection function.

In addition, the component description may not match the actual component due to a mode change during an event (program). (The component_type of the component descriptor describes the representative component type of the component, and this value is not changed in real time in response to a mode change during the program.)
The component_type described by the component descriptor is the default when the digital copy control descriptor, which is a description of the information for controlling the copy generation in the digital recording device and the maximum transmission rate, is omitted for the event (program). Maximum_bit_ra
Referenced when determining te.

In this way, by performing processing for each field of this descriptor in the receiving device 4, the receiving device 4 monitors the stream_content and component_type, so that the program currently received or received in the future is a 3D program. There is an effect that can be recognized.

FIG. 21 shows an example of processing for each field of the component group descriptor in the receiving device 4.

If “descriptor_tag” is “0xD9”, it is determined that the descriptor is a component group descriptor. Based on “descriptor_length”, it is determined to be the descriptor length of the component group descriptor.

If "component_group_type" is '000', it is judged as a multi-view TV service,
If it is 001 ', it is judged as a 3D TV service.

If “total_bit_rate_flag” is “0”, it is determined that the total bit rate in the group in the event (program) is not described in the descriptor. If '1', it is determined that the total bit rate in the group in the event (program) is described in the descriptor.

“Num_of_group” is determined as the number of component groups in the event (program). If the maximum value exists and exceeds this value, it may be processed as the maximum value.
If “component_group_id” is “0x0”, it is determined as the main group. If it is not “0x0”, it is determined as a subgroup.

“Num_of_CA_unit” is determined as the number of billing / non-billing units in the component group. If the maximum value is exceeded, it may be processed as 2.

If “CA_unit_id” is “0x0”, it is determined as a non-billing unit group. If it is “0x1”, it is determined as a charging unit including the default ES group. If it is other than “0x0” and “0x1”, it is determined that the charging unit is not identified above.

“Num_of_component” belongs to the component group and the previous CA_unit_id
The number of components belonging to the charging / non-charging unit indicated by If it exceeds the maximum value, it may be processed as 15.

“Component_tag” is determined to be a component tag value belonging to the component group, and can be used in correspondence with the component tag value of the PMT stream identifier.
“Total_bit_rate” is determined as the total bit rate in the component group. However, when it is “0x00”, it is determined as the default.

If “text_length” is 16 (8 full-width characters) or less, it is determined as the component group description length. If it is greater than 16 (8 full-width characters), the description for the component group description length exceeding 16 (8 full-width characters) is You can ignore it.

“Text_char” indicates an explanatory text related to the component group. In addition, component_g
By arranging the component group descriptor of roup_type = '000', it is determined that the multi-view TV service is performed in the event (program), and can be used for processing for each component group.

Further, the arrangement of the component group descriptor of component_group_type = '001' makes it possible to determine that a 3D television service is to be performed in the event (program) and use it for processing for each component group.

Furthermore, the default ES group of each group is always described in the component loop arranged at the head of the CA_unit loop.

In the main group (component_group_id = 0x0)
・ If the group's default ES is non-chargeable, set free_CA_mode = 0 and CA_unit_id =
Do not set a component loop of 0x1.
・ If the group's default ES group is chargeable, set free_CA_mode = 1 and CA_unit_id = ”
Be sure to set and describe the component loop of “0x1”.
In the subgroup (component_group_id> 0x0)
-Only the same billing unit as the main group or a non-billing unit can be set for the sub group.
-If the default ES group of the group is a non-billing target, set and describe a component loop with CA_unit_id = 0x0.
・ If the group's default ES group is a chargeable target, set and describe a component loop with CA_unit_id = 0x1.

In this way, by performing processing for each field of this descriptor in the receiving device 4, the receiving device 4 monitors the component_group_type, so that a program that is currently received or that will be received in the future is a 3D program. There is a recognizable effect.

FIG. 22 shows an example of processing for each field of the 3D program detail descriptor in the receiving device 4.

If “descriptor_tag” is “0xE1”, it is determined that the descriptor is a 3D program detail descriptor. Based on “descriptor_length”, the descriptor length of the 3D program detail descriptor is determined.
“3d_2d_type” is determined to be 3D / 2D identification in the 3D program. Figure 10 (b
) Is specified. “3d_method_type” is determined to be 3D method identification in the 3D program. It is specified from FIG.

“Stream_type” is determined to be the ES format of the 3D program. It is specified from FIG. “Component_tag” is determined to be a component tag value that is unique within the 3D program. It can be used in correspondence with the component tag value of the PMT stream identifier.

Note that it may be configured to determine whether or not the program is a 3D video program based on the presence or absence of the 3D program detail descriptor itself. That is, in this case, if there is no 3D program detail descriptor, 2
If it is determined as a D video program and there is a 3D program detail descriptor, it is determined as a 3D video program.

In this way, by performing processing for each field of this descriptor in the receiving device 4, the receiving device 4 monitors the 3D program detail descriptor, and if this descriptor exists,
There is an effect that it is possible to recognize that the program currently received or received in the future is a 3D program.

FIG. 23 shows an example of processing for each field of the service descriptor in the receiving device 4. If “descriptor_tag” is “0x48”, it is determined that the descriptor is a service descriptor. Based on “descriptor_length”, it is determined to be the descriptor length of the service descriptor. "Ser
If “vice_type” is other than the service_type shown in FIG. 13, it is determined that the descriptor is invalid.

When “service_provider_name_length” is 20 or less in the case of reception of BS / CS digital television broadcasts, it is determined that the name of the operator is greater than 20, and if it is greater than 20, the operator name is determined to be invalid. On the other hand, in the case of reception of digital terrestrial television broadcasting, it is determined that anything other than “0x00” is invalid.

In the case of receiving BS / CS digital television broadcasting, “char” is determined to be a business name. On the other hand, in the case of receiving terrestrial digital television broadcasting, the description is ignored. "
If “service_name_length” is 20 or less, it is determined that the composition channel name length is greater than 20, and if it is greater than 20, the composition channel name is determined to be invalid.

“Char” is determined as the organization channel name. If the SDT in which the descriptor is arranged cannot be received according to the example of the transmission operation rule described with reference to FIG. 18, it is determined that the basic information of the target service is invalid.

Thus, by performing processing for each field of this descriptor in the receiving device 4, there is an effect that the receiving device 4 can recognize that the organization channel is a 3D program channel by monitoring service_type.

FIG. 24 shows an example of processing for each field of the service list descriptor in the receiving device 4. If “descriptor_tag” is “0x41”, it is determined that the descriptor is a service list descriptor. Based on “descriptor_length”, it is determined that it is the descriptor length of the service list descriptor.

“Loop” describes a loop of the number of services included in the target transport stream. “Service_id” is determined to be service_id for the transport stream.
“Service_type” indicates the service type of the target service. It is determined that the service types other than those specified in FIG. 13 are invalid.

As described above, the service list descriptor can be determined as information on the transport stream included in the target network.

Thus, by performing processing for each field of this descriptor in the receiving device 4, there is an effect that the receiving device 4 can recognize that the organization channel is a 3D program channel by monitoring service_type.

Next, specific descriptors in each table will be described. First, PMT 2nd loop (E
The ES format can be determined as described with reference to FIG. 3 according to the data type in the stream_type described in the loop for each S). Among these, the currently broadcast stream is a 3D video. If there is a description indicating that the program is present, the program is determined to be a 3D program (for example, a multi-view video encoding (eg, H.264 / MVC) stream sub-bit stream (other viewpoint) is set to stream_type). If there is 0x1F shown, the program is determined to be a 3D program.

In addition to stream_type, the area currently reserved in the PMT
It is also possible to newly assign a 2D / 3D identification bit for identifying a 3D program or a 2D program, and to make a determination based on the area.

Similarly, EIT can be determined by newly assigning a 2D / 3D identification bit to the reserved area.

When a 3D program is determined by a component descriptor arranged in the PMT and / or EIT, as described in FIGS. 4 and 5, the component_type of the component descriptor
A type indicating 3D video is assigned (for example, FIGS. 5C to 5E), and component_type is 3D.
Can be determined as a 3D program. (For example,
5C to 5E are assigned, and it is confirmed that the value exists in the program information of the target program. )
As a determination method based on the component group descriptor arranged in the EIT, FIG.
As described in (7) and (7), if a description representing a 3D service is assigned to the value of component_group_type and the value of component_group_type represents a 3D service, it can be distinguished from a 3D program (for example, 001 in the bit field is 3DTV). Allocate a service, etc., and confirm that the value exists in the program information of the target program.)
As a determination method using the 3D program detail descriptor arranged in the PMT and / or EIT, as described in FIGS. 10 and 11, when determining whether the target program is a 3D program, the 3D program detail descriptor It can be determined by the content of 3d_2d_type (3D / 2D type). If no 3D program detail descriptor is transmitted for the received program, it is determined to be a 2D program. In addition, if the receiving apparatus is compatible with the 3D method type (3d_method_type) included in the descriptor, a method of determining the next program as a 3D program is also conceivable. In this case, although the descriptor analysis process is complicated, it is possible to stop the operation for performing the message display process and the recording process for the 3D program that cannot be handled by the receiving apparatus.

As described with reference to FIGS. 12, 13, and 14, the service_type information included in the service descriptor arranged in the SDT and the service list descriptor arranged in the NIT includes 0x01.
When the 3D video service is assigned to the program information and the program information having the descriptor is acquired, it can be determined as a 3D program. In this case, the determination is not made on a program basis but on a service (CH, organization channel) basis, and the 3D of the next program in the same organization channel is determined.
Although the program cannot be determined, there is an advantage that information is not easily acquired because it is not a program unit.

There is also a method of acquiring program information through a dedicated communication channel (broadcast signal or the Internet). Even in this case, the program start time and CH (broadcast organization channel, UR
L or IP address), if there is an identifier indicating whether the program is a 3D program, 3D
Program determination is possible.

In the above description, various information (information included in tables and descriptors) for determining whether or not a 3D video is a service (CH) or a program unit has been described. There is no need. What is necessary is just to transmit required information according to a broadcast form. Of these pieces of information, each piece of information may be checked to determine whether it is a 3D video for each service (CH) or program, or a combination of multiple pieces of information for 3D for each service (CH) or program. You may determine whether it is an image | video. When determining by combining a plurality of pieces of information, it is a 3D video broadcasting service, but it is also possible to determine that only some programs are 2D video. If such a determination can be made, the receiving device, for example, EPG can clearly indicate that the service is a “3D video broadcasting service”, and the service includes a mixture of 2D video programs in addition to 3D video programs. Even when the program is received, the display control or the like can be switched between the 3D video program and the 2D video program.

In addition, when it is determined as a 3D program by the 3D program determination method described above,
For example, the 3D component specified in FIGS. 5C to 5E is appropriately processed by the receiving device 4 (
If it can be displayed (output), it can be processed (reproduced, displayed, output) in 3D, and cannot be properly processed (reproduced, displayed, output) in the receiving device 4 (for example, specified 3D)
2D processing (playback, display, etc.) when there is no 3D video playback function corresponding to the transmission method.
Output). At this time, along with the display and output of the 2D video, it may be displayed that the 3D video program cannot be appropriately 3D displayed or 3D output by the receiving apparatus. In this way, the user needs to know whether the program is broadcast as a 2D video program or is a program broadcast as a 3D video program, but the 2D video is displayed because it cannot be properly processed by the receiving device. Can do.

<3D playback / output / display processing of 3D content by 3D2 viewpoint-based ES transmission method>
Next, processing during playback of 3D content (digital content including 3D video) will be described. Here, first, as shown in FIG. 47, a main viewpoint video ES and a sub viewpoint video E are included in one TS.
A reproduction process in the case of the 3D2 viewpoint-specific ES transmission method in which S is present will be described. First, when the user gives an instruction to switch to 3D output / display (for example, pressing the “3D” key on the remote controller), the user instruction receiving unit 52 that has received the key code converts the 3D video to the system control unit 51. (Note that the following processing is performed for 3D2 viewpoint-specific ES transmission system content under conditions other than a user switching instruction to 3D display / output of 3D content.
The same processing is performed when switching to output / display). Next, the system control unit 51 determines whether or not the current program is a 3D program by the above method.

If the current program is a 3D program, the system control unit 51 first instructs the channel selection control unit 59 to output 3D video. Upon receiving the instruction, the tuning control unit 59 first receives a PID (packet ID) from the program information analysis unit 54 for each of the main viewpoint video ES and the sub-viewpoint video ES.
) And an encoding method (for example, H.264 / MVC, MPEG2, H.264 / AVC, etc.), and then demultiplexes the main viewpoint video ES and the sub viewpoint video ES to the demultiplexing unit 29. And control to output to the video decoding unit 30.

Here, for example, the demultiplexing unit 29 is controlled so that the main viewpoint video ES is input to the first input of the video decoding unit and the sub-viewpoint video ES is input to the second input of the video decoding unit. Thereafter, the channel selection control unit 59 transmits to the decoding control unit 57 the information that the first input of the video decoding unit 30 is the main viewpoint video ES and the second input is the sub-view video ES and the respective encoding methods. And instruct to decrypt these ESs.

In order to decode 3D programs having different encoding methods between the main-view video ES and the sub-view video ES, like the combination example 2 and the combination example 4 of the 3D2 viewpoint-specific ES transmission method shown in FIG. 47, the video decoding unit 3
0 may be configured to have a plurality of types of decoding functions corresponding to each encoding method.

In order to decode a 3D program having the same encoding method for the main-view video ES and the sub-view video ES, as in combination example 1 and combination example 3 of the 3D2 viewpoint-specific ES transmission method shown in FIG. 47, the video decoding unit 30
May be configured to have only a decoding function corresponding to a single encoding method. In this case, the video decoding unit 30 can be configured at low cost.

Upon receiving the instruction, the decoding control unit 57 performs decoding corresponding to the encoding methods of the main viewpoint video ES and the sub viewpoint video ES, and outputs the left-eye and right-eye video signals to the video conversion processing unit 32. Here, the system control unit 51 instructs the video conversion control unit 61 to perform 3D output processing. The video conversion control unit 61 that has received the instruction from the system control unit 51,
The video conversion processing unit 32 is controlled to output from the video output 41 or to display the 3D video on the display 47 provided in the receiving device 4.

  The 3D playback / output / display method will be described with reference to FIG.

FIG. 37 (a) is an explanatory diagram of a frame sequential method output for alternately displaying and outputting videos of the left and right viewpoints of 3D content in the 3D2 viewpoint-specific ES transmission method, and a playback / output / display method corresponding to the display. . The upper left frame row (M1, M2, M3,...) Is 3
A plurality of frames included in the main viewpoint (for left eye) video ES of the D2 viewpoint-specific ES transmission method content, and a frame sequence (S1, S2, S3,... A plurality of frames included in the content sub-viewpoint (right eye) video ES are shown. In the video conversion processing unit 32, each frame of the input main viewpoint (for left eye) / sub-viewpoint (for right eye) video signal is converted into a right frame sequence (M1, S1, M2, S2, M3, S3). ...
As shown by ..), the frame is alternately output / displayed as a video signal. According to such an output / display method, the maximum resolution that can be displayed on the display for each viewpoint can be used, and high-resolution 3D display is possible.

In the system configuration of FIG. 36, when the method of FIG. 37 (a) is used, the video signals are output and synchronized so that each video signal can be discriminated for the main viewpoint (left eye) and for the sub viewpoint (right eye). A signal is output from the control signal 43. The external video output device that has received the video signal and the synchronization signal outputs the video of the main viewpoint (for the left eye) and the sub-viewpoint (for the right eye) according to the synchronization signal, and supports 3D viewing. By sending a synchronization signal to the device, 3D display can be performed. Note that the synchronization signal output from the external video output device may be generated by the external video output device.

In the system configuration of FIG. 35, when the video signal is displayed on the display 47 included in the receiving device 4 using the method of FIG. 37A, the synchronization signal is transmitted to the device control signal transmission unit 53 and the control signal. 3D display is performed by outputting from the device control signal transmission terminal 44 via the transmission / reception unit 33 and controlling the external 3D viewing assistance device (for example, shading switching of the active shutter).

FIG. 37 (b) is an explanatory diagram of the output / reproduction / display method corresponding to the output and display of the method of displaying the video of the left and right viewpoints of 3D content in the 3D2 viewpoint-specific ES transmission method in different areas of the display. In this process, the 3D2 viewpoint-specific ES transmission system stream is decoded by the video decoding unit 30 and the video conversion processing unit 32 performs the video conversion process. Here, displaying in different areas means, for example, that the odd and even lines of the display are respectively the main viewpoint (left eye)
Display as a display area for the sub-viewpoint (right eye). Alternatively, the display area does not have to be in line units, and in the case of a display having different pixels for each viewpoint, the main viewpoint (
The display area may be a combination of a plurality of pixels for the left eye) and a combination of a plurality of pixels for the sub-viewpoint (right eye). For example, in the above-described polarization type display device, for example, images of different polarization states corresponding to the respective polarization states of the left eye and right eye of the 3D viewing assistance device may be output from the different regions. According to such an output / display method, the resolution that can be displayed on the display for each viewpoint is smaller than that in the method of FIG. 37 (a), but the video for the main viewpoint (left eye) and the sub viewpoint (right eye). Video can be output / displayed simultaneously, and there is no need to display them alternately. Thereby, 3D display with less flicker than the method of FIG.

In any of the system configurations shown in FIGS. 35 and 36, when the method shown in FIG. 37 (b) is used, the 3D viewing assistance device may be polarization-separated glasses and does not need to perform electronic control. . In this case, the 3D viewing assistance device can be provided at a lower cost.

<3D2 2D output / display processing of 3D content by viewpoint-based ES transmission method>
The operation in the case of performing 2D output / display of 3D content in the 3D2 viewpoint-specific ES transmission method will be described below. When the user gives an instruction to switch to 2D video (for example, pressing the “2D” key on the remote control), the user instruction receiving unit 52 that has received the key code instructs the system control unit 51 to switch the signal to 2D video. (Note that the following processing is based on 3D2 viewpoint E
The same processing is performed even when switching to 2D output / display under conditions other than the user switching instruction to 2D output / display of 3D content of the S transmission method). Next, the system control unit 51 first instructs the channel selection control unit 59 to output 2D video.

Upon receiving the instruction, the tuning control unit 59 first receives an ES for 2D video from the program information analysis unit 54.
The PID of the main viewpoint ES or the ES having a default tag is acquired, and the demultiplexing unit 2
9 is controlled to output the ES to the video decoding unit 30. Thereafter, the tuning control unit 59
Instructs the decoding control unit 57 to decode the ES. That is, in the 3D2 viewpoint-specific ES transmission method, since the substream or ES is different between the main viewpoint and the subview, it is only necessary to decode the substream or ES of the main viewpoint.

Upon receiving the instruction, the decoding control unit 57 controls the video decoding unit 30 to decode the ES and outputs a video signal to the video conversion processing unit 32. Here, the system control unit 51 controls the video conversion control unit 61 to perform 2D video output. The video conversion control unit 61 that has received the instruction from the system control unit 51 performs control to output a 2D video signal from the video output terminal 41 to the video conversion processing unit 32 or display a 2D video on the display 47.

The 2D output / display method will be described with reference to FIG. The structure of the encoded video is shown in FIG.
7, but as described above, the video decoding unit 30 uses the second ES (sub-viewpoint video ES).
Is not decoded, the video conversion processor 32 converts one of the decoded video signals on the ES side into a 2D video signal represented by the right frame sequence (M1, M2, M3,...). And output. In this way, 2D output / display is performed.

Here, the method of not decoding the right-eye ES as a 2D output / display method has been described, but both the left-eye ES and the right-eye ES are decoded and the video conversion processing unit 32 performs the same as in 3D display. You may perform 2D display by implementing the process which thins out the video signal for right eyes. In that case, the switching process between the decoding process and the demultiplexing process is eliminated, and effects such as a reduction in switching time and simplification of software processing can be expected.

<3D output / display processing of 3D content in Side-by-Side format / Top-and-Bottom format>
Next, when there is a left-eye video and a right-eye video in one video ES (for example, a left-eye video and a right-eye video in one 2D screen as in the Side-by-Side method and the Top-and-Bottom method) 3D content playback processing will be described. When the user instructs to switch to 3D video in the same manner as described above, the user instruction receiving unit 52 that has received the key code instructs the system control unit 51 to switch to 3D video (note that The same processing is performed even when switching to 2D output / display under conditions other than the user switching instruction to 2D output / display of 3D content of the Side-by-Side system or Top-and-Bottom system). Next, the system control unit 51 similarly determines whether or not the current program is a 3D program by the above method.

If the current program is a 3D program, the system control unit 51 first instructs the channel selection control unit 59 to output 3D video. Upon receiving the instruction, the channel selection control unit 59 first obtains the PID (packet ID) of 3D video ES including 3D video and the encoding method (for example, MPEG2, H.264 / AVC, etc.) from the program information analysis unit 54. Next, the 3D video ES is sent to the demultiplexing unit 29.
Are demultiplexed and output to the video decoding unit 30, and the video decoding unit 30 is subjected to decoding processing according to the encoding method, and the decoded video signal is output to the video conversion processing unit 32. I do.

Here, the system control unit 51 instructs the video conversion control unit 61 to perform 3D output processing. Upon receiving the instruction from the system control unit 51, the video conversion control unit 61 converts the input video signal into a left-eye video and a right-eye video and performs processing such as scaling (details will be described later). An instruction is given to the processing unit 32. The video conversion processing unit 32 outputs the converted video signal from the video output 41 or a display 47 provided in the receiving device 4.
Display video on.

  The 3D video playback / output / display method will be described with reference to FIG.

FIG. 39 (a) shows a frame sequential output that alternately displays and outputs video from the left and right viewpoints of 3D content in the Side-by-Side format or the Top-and-Bottom format, and the playback / output / It is explanatory drawing of a display method. Encode video as Side-by-Side, Top-and-
Although the description of the Bottom method is also shown in the figure, the only difference between the two is the difference in the arrangement of the left-eye video and the right-eye video in the video, so the following description uses the Side-by-Side method. The description of the Top-and-Bottom method is omitted. The left frame sequence (L1 / R1, L2 / R
2, L3 / R3... Represents a side-by-side video signal in which left-eye and right-eye videos are arranged on the left / right side of one frame. The video decoding unit 30 decodes the side-by-side video signal arranged on the left / right side of the left-eye and right-eye video frames, and the video conversion processing unit 32 decodes the decoded Side- Each frame of the by-Side video signal is separated into left and right images so that it becomes a left-eye image and a right-eye image, and is further scaled (expanded / interpolated or compressed / decimated to match the horizontal size of the output image) )do. Further, as represented by the right frame sequence (L1, R1, L2, R2, L3, R3,...), Frames are alternately output as video signals.

In FIG. 39 (a), the processing after the conversion to the output / display video for alternately outputting / displaying the frame, the output of the synchronization signal and the control signal to the 3D viewing assistance device, etc. have already been described. 3D playback / 3D content of the 3D2 viewpoint-specific ES transmission method described in (a) /
Since this is the same as the output / display process, description thereof is omitted.

FIG. 39B shows the output / display corresponding to the output and display of the method of displaying the left and right viewpoint videos of the 3D content of the Side-by-Side method or the Top-and-Bottom method in different areas of the display.
It is explanatory drawing of an output / display method. As in FIG. 39 (a), Side-by-Side is used as the encoded video.
The description of the method and the Top-and-Bottom method is shown together, but the difference between the two is only the difference in the arrangement of the video for the left eye and the video for the right eye. Explanation will be made using the by-Side method, and description of the Top-and-Bottom method will be omitted. The frame sequence on the left side of the figure (L1 /
R1, L2 / R2, L3 / R3,...), The left-eye video and the right-eye video are
A side-by-side video signal arranged on the right side is shown. The video decoding unit 30 decodes the side-by-side video signal arranged on the left / right side of the left-eye and right-eye video frames, and the video conversion processing unit 32 decodes the decoded Side- Each frame of the by-Side video signal is separated into left and right images so that it becomes a left-eye image and a right-eye image, and is further scaled (expanded / interpolated or compressed / decimated to match the horizontal size of the output image) )do. Further, the scaled left-eye video and right-eye video are output and displayed in different areas. FIG.
Similar to the description in (b), here, displaying in different areas means, for example, that the odd lines and even lines of the display are displayed as the display areas for the main viewpoint (left eye) and the sub viewpoint (right eye), respectively. There are methods. In addition, the display processing in different areas, the display method in the polarization type display device, and the like are the same as the 3D playback / output / display processing of 3D content of the 3D2 viewpoint-specific ES transmission method described in FIG. Therefore, the description is omitted.

In the method of FIG. 39 (b), when the vertical resolution of the display and the vertical resolution of the input video are the same, the left-eye video and the right-eye video are output and displayed on the odd-numbered line and the even-numbered line of the display, respectively. May need to reduce the vertical resolution of each,
In such a case as well, thinning corresponding to the resolution of the display area of the left-eye video and the right-eye video may be performed in the scaling process.

<2D output / display processing of 3D content in Side-by-Side format / Top-and-Bottom format>
The operation of each unit when performing 2D display of 3D content in Side-by-Side format or Top-and-Bottom format will be described below. When the user gives an instruction to switch to 2D video (for example, pressing the “2D” key on the remote control), the user instruction receiving unit 52 that has received the key code.
Instructs the system control unit 51 to switch the signal to 2D video (note that the following processing is performed by the user for 2D output / display of 3D content in the Side-by-Side format or Top-and-Bottom format) The same processing is performed even when switching to 2D output / display under conditions other than the switching instruction).
The system control unit 51 that has received the instruction instructs the video conversion control unit 61 to output 2D video. The video conversion control unit 61 that has received the instruction from the system control unit 51 performs control so that 2D video output is performed on the video signal input to the video conversion processing unit 32.

A video 2D output / display method will be described with reference to FIG. Figure 40 (a) shows Side-by-S.
The ide method, FIG. 40 (b) illustrates the description of the Top-and-Bottom method, both of which differ only in the arrangement of the left-eye video and the right-eye video in the video, so the description is shown in FIG. 40 (a). This will be described using the side-by-side method. Frame sequence on the left side of the figure (L1 / R1, L2 / R2, L3 / R3 ...)
However, the left-eye and right-eye video signals represent side-by-side video signals arranged on the left / right side of one frame. The video conversion processing unit 32 separates each frame of the input side-by-side video signal into left and right left-eye video and right-eye video frames, and then only the main viewpoint video (left-eye video) portion. , And the right frame sequence (L1, L2, L
3..., Only the main viewpoint video (left-eye video) is output as a video signal.

The video conversion processing unit 32 outputs the processed video signal as a 2D video from the video output 41 and outputs a control signal from the control signal 43. In this way, 2D output / display is performed.

FIGS. 40C and 40D also show an example of performing 2D output / display of 3D content of the Side-by-Side system or Top-and-Bottom system as it is, with 2 viewpoints stored in one image. For example, as shown in FIG. 36, when the receiving device and the viewing device have different configurations, the receiving device decodes the decoded Side-by-
Side-type or Top-and-Bottom-type video may be output as video with two viewpoints stored in one image, and conversion for 3D display may be performed by the viewing device.

<Example of 2D / 3D video display processing flow based on whether or not the current program is 3D content>
Next, content output / display processing when the current program is 3D content or when the current program becomes 3D content will be described. When viewing the 3D content when the current program is a 3D content program or when it becomes a 3D content program, if the display of the 3D content is unconditionally started, the user cannot view the content. There is a possibility that the convenience of the user is impaired. On the other hand, user convenience can be improved by performing the following processing.

FIG. 41 is an example of a processing flow of the system control unit 51 that is executed when the current program or program information is changed at the time of program switching. In the example of FIG. 41, even a 2D program is 3
Even in the case of a D program, first, the flow is to perform 2D display of video from one viewpoint (for example, the main viewpoint).

The system control unit 51 acquires the program information of the current program from the program information analysis unit 54, determines whether or not the current program is a 3D program by the above-described 3D program determination method, and further determines the current program 3
Similarly, the D system type (for example, determination from the 3D system type described in the 3D program detailed descriptor, such as the 2-view ES transmission system / Side-by-Side system) is acquired from the program information analysis unit 54 (S4).
01). The acquisition of the program information of the current program is not limited to when the program is switched, and may be acquired periodically.

As a result of the determination, if the current program is not a 3D program (No in S402), control is performed so that 2D video is displayed in 2D (S403).

When the current program is a 3D program (Yes in S402), the system control unit 51 uses the method described in FIGS. 38 and 40 (a) and 40 (b) to generate a 3D video signal in a format corresponding to each 3D system type. Control is performed so that one of the viewpoints (for example, the main viewpoint) is displayed in 2D (S404). At this time,
A display indicating that the program is a 3D program may be displayed superimposed on the 2D display video of the program. In this way, when the current program is a 3D program, the video from one viewpoint (for example, the main viewpoint) is displayed in 2D.

Even when the channel selection operation is performed and the current program is changed, the above-described flow is performed in the system control unit 51.

As described above, when the current program is a 3D program, the video of one viewpoint (for example, the main viewpoint) is displayed in 2D for the time being. As a result, even if the user is not ready for 3D viewing, such as when the user is not wearing a 3D viewing assistance device, the user can view almost the same as the 2D program for the time being. In particular, in the case of 3D content in the Side-by-Side format or Top-and-Bottom format, as shown in FIGS. As shown in FIGS. 40 (a) and 40 (b), an instruction for 2D display of one viewpoint from a video stored in two viewpoints in one image by using 2D output / display of one viewpoint, a remote control or the like Even if the user does not perform it manually, it is possible for the user to view the program in the same way as a normal 2D program.

Next, FIG. 42 shows an example of a message that is displayed in 2D in step S404 and the system control unit 51 displays on the OSD creation unit 60, for example. A message notifying the user that the 3D program has started is displayed, and an object (hereinafter referred to as user response receiving object: for example, a button on the OSD) 1602 to which the user responds is displayed.
The subsequent operation is selected.

When the message 1601 is displayed, for example, when the user presses the “OK” button on the remote controller, the user instruction receiving unit 52 notifies the system control unit 51 that “OK” has been pressed.

As an example of a user selection determination method in the screen display of FIG. 42, when the user operates the remote control and presses the <3D> button on the remote control, or moves the cursor to “OK / 3D” on the screen and <OK> on the remote control When the button is pressed, the user selection is determined as “3D switching”.

Or, when the user presses the <Cancel> button or <Return> button on the remote control, or when the cursor is placed on "Cancel" on the screen and <OK> is pressed on the remote control, the user selection is determined to be "other than 3D switching" To do. Other than this, for example, the user's 3D
When an operation is performed in which the state (3D viewing preparation state) indicating whether or not the viewing preparation is completed is performed (for example, wearing 3D glasses), the user selection is “3D switching”.

FIG. 43 shows a processing flow of the system control unit 51 executed after the user makes a selection. The system control unit 51 acquires the user selection result from the user instruction receiving unit 52 (S501). When the user selection is not “3D switching” (No in S502),
The video ends in 2D display and no processing is performed.

When the user's selection is “3D switching” (yes in S502), the video is displayed in 3D by the above 3D display method (S504).

With the above flow, when the 3D program starts, the video of one viewpoint is output / displayed in 2D, and the user wants to perform 3D viewing, such as after the user prepares for operation or 3D viewing, etc. Can be output / displayed to view the video in 3D, and a viewing method suited to the convenience of the user can be provided.

In the display example of FIG. 42, an object for the user to respond is displayed.
It is also possible to simply display a character, a logo, a mark or the like simply indicating that the program is a program corresponding to “3D viewing” such as “3D program”. In this case, the user who has recognized that the program is compatible with “3D viewing” depresses the “3D” key of the remote controller and receives the signal from the remote controller from the user instruction receiver 52 to the system controller 51. 2 triggered by notification
Switching from D display to 3D display may be performed.

Furthermore, as another example of the message display displayed in step S404, a method of clearly indicating whether the program display method is 2D video or 3D video as well as simply OK as shown in FIG. . FIG. 44 shows an example of the message and the user response reception object in that case.

This makes it easier for the user to determine the operation after the button is pressed as compared to the “OK” display as shown in FIG. 42, and allows the user to explicitly indicate a 2D display (see “2D described in 1202”). When “view with” is pressed, the user 3D viewing preparation state is determined to be NG), and convenience is improved.

Next, an example in which specific video / audio is output or video / audio is muted (black screen display / display stop, audio output is stopped) when 3D program viewing is started will be described. This is when the user starts viewing a 3D program. If the display of the 3D content is started unconditionally, the user cannot view the content, and there is a possibility that the convenience of the user is impaired. On the other hand, user convenience can be improved by performing the following processing. FIG. 45 shows a processing flow executed by the system control unit 51 at the start of the 3D program in this case. A difference from the processing flow of FIG. 41 is that a step (S405) of outputting specific video and audio is added instead of the processing of S404.

The specific video / audio here includes, for example, a 3D preparation message, a black screen, a still image of a program, etc. for video, and the audio includes silence or a fixed pattern of music (
Environmental music).

For display of fixed pattern video (message, environment video, 3D video, etc.), data is read from the video decoding unit 30 or from a ROM or recording medium 26 not shown in the figure, and the video decoding unit 30 decodes and outputs the data. This can be achieved. The output of the black screen can be realized, for example, by the video decoding unit 30 outputting only the video signal indicating black, or the video conversion processing unit 32 muting the output signal or outputting the black video.

Similarly, in the case of fixed pattern sound (silence, environmental music), it can be realized by reading out data from the inside of the sound decoding unit 31 or from the ROM or the recording medium 26, decoding output, muting output signals, and the like.

The output of the still image of the program video can be realized by instructing the recording / playback control unit 58 from the system control unit 51 to play back the program and pause the video. The processing of the system control unit 51 after the user selection is executed as shown in FIG.

This makes it possible to prevent the program video and audio from being output until the user completes preparation for 3D viewing.

Similar to the above example, the message display displayed in step S405 is as shown in FIG. The difference from FIG. 42 is that only the displayed video and audio are different, and the displayed message, the configuration of the user response receiving object, and the operation of the user response receiving object are the same.

As for the message display, not only simply OK as shown in FIG. 46, but also a method of clearly specifying whether the display method of the program is 2D video or 3D video. In this case, the message and an example of the user response receiving object can be displayed in the same manner as in FIG. 44. In this way, the user can judge the operation after pressing the button more than the display of “OK” as described above. In addition to facilitating the convenience, it is possible to explicitly instruct display in 2D, and the convenience is improved as in the above example.

<Example of 2D / 3D video display processing flow based on whether the next program is 3D content>
Next, content output / display processing when the next program is 3D content will be described. Regarding the viewing of the 3D content program that is the next program when the next program is 3D content, if the user is not in a state of viewing the 3D content and the display of the 3D content starts, the user is best. In such a state, the content cannot be viewed, which may impair user convenience. On the other hand, user convenience can be improved by performing the following processing.

In FIG. 27, when the time until the start of the next program changes due to channel selection processing or the like, or by the start time of the next program or the end time information of the current program included in the EIT of the program information transmitted from the broadcast station, When it is determined that the start time of the next program has changed, the system control unit 5
2 is an example of a flow executed in 1. First, the system control unit 51 acquires program information of the next program from the program information analysis unit 54 (S101), and the next program is determined by the 3D program determination method.
It is determined whether or not it is a D program.

If the next program is not a 3D program (No in S102), the process ends without performing any particular process. When the next program is a 3D program (yes in S102), the time until the start of the next program is calculated. Specifically, the start time of the next program or the end time of the current program is acquired from the EIT of the acquired program information, the current time is acquired from the time management unit 55, and the difference is calculated.

If it is not less than X minutes until the next program start (No in S103), the process waits until X minutes before the next program start without any particular processing. When it is X minutes or less until the next program start (yes in S103), a message is displayed to the user that the 3D program will start soon (S104).

FIG. 28 shows an example of message display at that time. 701 is an entire screen displayed by the apparatus,
2 shows a message displayed by the apparatus. In this way, it is possible to alert the user to prepare the 3D viewing assistance device before the 3D program is started.

As for the determination time X before the start of the program, if X is reduced, the user may not be ready for 3D viewing before the start of the program. Further, if X is increased, there is a demerit that message display is hindered for a long period of time, and there is a gap after preparation is completed, so it is necessary to adjust to an appropriate time.

Further, when displaying a message to the user, the start time of the next program may be specifically displayed. FIG. 29 shows a screen display example in that case. A message 802 displays the time until the start of the 3D program. Here, description is made in units of minutes, but description may be made in units of seconds. In that case, the user can know the start time of the next program in more detail, but there is a demerit that the processing load increases.

In addition, although the example which displays the time until a 3D program is started was shown in FIG. 29, you may make it display the time when a 3D program starts. When the 3D program starts at 9:00 pm, for example, a message “3D program starts from 9:00 pm. Please wear 3D glasses” may be displayed.
By displaying such a message, the user can know the specific start time of the next program and prepare for 3D viewing at an appropriate pace.

In addition, as shown in FIG. 30, it is also conceivable to add a mark (3D check mark) that looks stereoscopic when using the 3D viewing assistance device. 902 is a message for notifying the start of a 3D program, and 903 is a mark that looks three-dimensional when the 3D viewing assistance device is used. Thereby, the user can confirm the normal operation of the 3D viewing assistance device before the start of the 3D program. Eg 3D
When a trouble (for example, battery exhaustion, failure, etc.) occurs in the viewing assistance device, it is possible to take measures such as repair or replacement before the program starts.

Next, after notifying the user that the next program is 3D, it is determined whether or not the user is ready for 3D viewing (3D viewing preparation state), and the video of the 3D program is displayed in 2D or 3D.
A method for switching to D display will be described.

The method for notifying the user that the next program is 3D is as described above. However, the message displayed to the user in step S104 is different in that an object to which the user responds (hereinafter, a user response receiving object: for example, a button on the OSD) is displayed. An example of this message is shown in FIG.

Reference numeral 1001 denotes an entire message, and reference numeral 1002 denotes a button for a user to respond. When the message 1001 in FIG. 31 is displayed, for example, when the user presses the “OK” button on the remote controller, the user instruction receiving unit 52 indicates that “OK” has been pressed.
1 is notified.

The system control unit 51 that has received the notification stores the state that the user's 3D viewing preparation state is OK as a state. Next, a processing flow of the system control unit 51 when time has elapsed and the current program becomes a 3D program will be described with reference to FIG.

The system control unit 51 acquires program information of the current program from the program information analysis unit 54 (S20).
1) Whether the current program is a 3D program is determined by the 3D program determination method described above. When the current program is not a 3D program (No in S202), control is performed so that the video is displayed in 2D by the above method (S203).

If the current program is a 3D program (yes in S202), then the user's 3D viewing preparation status is confirmed (S204). The 3D viewing preparation state stored by the system control unit 51 is O
If it is not K (No in S205), similarly, control is performed so that the video is displayed in 2D (S203).
).

When the 3D viewing preparation state is OK (Yes in S205), control is performed so that the video is displayed in 3D by the above method (S206). In this way, when it is confirmed that the current program is a 3D program and the user's 3D viewing preparation is completed, the video is displayed in 3D.

As the message display displayed in step S104, not only simply OK as shown in FIG. 31, but also a method of clearly indicating whether the display method of the next program is 2D video or 3D video is conceivable. Examples of the message and the user response receiving object in that case are shown in FIGS.
4 shows.

In this way, compared to the “OK” display as described above, the user can more easily determine the operation after the button is pressed, and the user can explicitly instruct the display in 2D (see “2D in 1202”). When “view” is pressed, the user 3D viewing preparation state is determined to be NG, and convenience is enhanced.

The determination of the 3D viewing preparation state of the user is performed by operating the user menu on the remote controller here, but the 3D viewing preparation state is also determined by, for example, a user wearing completion signal transmitted by the 3D viewing assistance device, for example. A method or an imaging device may be used to photograph a user's viewing state, and image recognition or user's face recognition may be performed based on the photographing result to determine that a 3D viewing assistance device is worn.

By making such a determination, it is possible to save the user from having to perform any operation on the receiving device, and to avoid erroneously setting 2D video viewing and 3D video viewing due to an erroneous operation. Is possible.

As another method, when the user presses the <3D> button on the remote control, 3
There is also a method of determining that the D viewing preparation state is OK, and determining that the 3D viewing preparation state is NG when the user presses the <2D> button, the <Return> button, or the <Cancel> button on the remote control. In this case, the user can clearly and easily notify the device of his / her state, but there are also disadvantages such as erroneous operation and state transmission due to misunderstanding.

In the above example, it is also conceivable to perform processing by determining only the program information of the next program acquired in advance without acquiring information of the current program. In this case, step S20 in FIG.
In 1, a method of using program information acquired in advance (for example, step S <b> 101 in FIG. 27) without determining whether the current program is a 3D program is also conceivable. In this case, there is a merit that the processing structure becomes simple. However, there is a possibility that the 3D video switching process may be executed even when the program configuration is suddenly changed and the next program is not a 3D program. There are disadvantages.

The message display for each user described in this embodiment is preferably deleted after a user operation. In this case, there is an advantage that the video can be easily viewed after the user performs the operation. Similarly, after a certain period of time has elapsed, it is assumed that the user has already recognized the message information, and deleting the message to make it easy to view the video improves the user's convenience.

According to the embodiment described above, the user is required to 3D in advance for the start of the 3D program.
Users can complete the viewing preparation, or if the time is not enough to start the 3D program, the user can use the recording / playback function to display the video again after the user is ready to view the 3D program. Can watch 3D programs. In addition, it is possible to improve user convenience, such as automatically switching the video display to a display method that is desirable for the user (3D video display when viewing 3D video, or vice versa).
The same effect can be expected when switching to a 3D program by channel selection or when starting playback of a recorded 3D program.

DESCRIPTION OF SYMBOLS 1 Transmission apparatus 2 Relay apparatus 3 Network 4 Reception apparatus 10 Recording / reproducing part 11 Source generation part 12 Encoding part 13 Scramble part 14 Modulation part 15 Transmission antenna part 16 Management information 17 Encryption part 18 Channel encoding part 19 Network I / F Part 21 CPU
22 General-purpose bus 23 Tuner 24 Descrambler 25 Network I / F
26 Recording medium 27 Recording / reproducing unit 29 Demultiplexing unit 30 Video decoding unit 31 Audio decoding unit 32 Video conversion processing unit 33 Control signal transmission / reception unit 34 Timer 41 Video output unit 42 Audio output unit 43 Control signal output unit 44 Device control signal transmission 45 User operation input 46 High-speed digital interface 47 Display 48 Speaker 51 System control unit 52 User instruction reception unit 53 Device control signal transmission unit 54 Program information analysis unit 55 Time management unit 56 Network control unit 57 Decoding control unit 58 Recording / playback control unit 59 Station control unit 60 OSD creation unit 61 Video conversion control unit

Claims (8)

A receiving device that receives a digital broadcast signal that is broadcast in a mixture of 3D video program content and 2D video program content,
A receiver for receiving a digital broadcast signal including encoded program content and identification information for identifying whether the program content is a 3D video program or a 2D video program content;
A control unit that determines whether the received program content is 3D video program content or 2D video program content based on identification information about the program content received by the receiving unit;
A decoding / conversion unit that decodes the video of the program content in accordance with a determination result of the control unit, converts the video into a predetermined display video format or an output video format, and outputs the video;
The control unit determines whether the program content received by the receiving unit is 3D video program content or 2D video program content based on the identification information,
The control unit determines that the program content received by the receiving unit is 3D video program content, and the decoding / conversion unit converts the video of the 3D video program content into a 2D display video format or a 2D output video format. A receiving apparatus, wherein when a video is converted and output, a display indicating that the program is a 3D video program is superimposed on the video and output. The receiving device according to claim 1,
With an operation input unit for inputting an operation signal from the user,
The control unit determines that the program content received by the receiving unit is 3D video program content, and the decoding / conversion unit converts the video of the 3D video program content into a 2D display video format or a 2D output video format. When an instruction signal indicating that switching from 2D video viewing to 3D video viewing is input from the operation input unit after converting and outputting a display indicating that the program is a 3D video program on the video The decoding / conversion unit outputs a display video format or an output video format of the video of the 3D video program content to be output.
A receiving apparatus that changes to a 3D display video format or a 3D output video format. The receiving device according to claim 1,
The identification information includes information for identifying a transmission method of 3D video program content,
Based on the identification information, the control unit divides one screen of the video content into two regions based on the identification information, and the left-eye viewpoint video and the right-eye viewpoint video And the decoding / conversion unit converts the video of the 3D video program content into video of 2D display video format or 2D output video format. The decoding / conversion unit decodes the 3D video program content and outputs either one of the left-eye viewpoint video and the right-eye viewpoint video stored in the one screen. The video is subjected to scaling processing, and the video of one viewpoint subjected to the scaling processing is converted into a 2D display video format or a 2D output video format and output. Apparatus. The receiving device according to claim 1,
The identification information includes information for identifying a transmission method of 3D video program content,
3D video in which the control unit stores and transmits the left-eye viewpoint video and the right-eye viewpoint video in different elementary streams based on the identification information, based on the identification information. It is determined that the content is a program content, and the decoding / conversion unit performs the 3D
When the video of the video program content is converted into the video of the 2D display video format or the video of the 2D output video format and output, the decoding / conversion unit stores the video of the viewpoint for the left eye of the 3D video program content. Among the elementary streams that store the viewpoint stream for the right-eye view, the video is decoded from one of the elementary streams,
A receiving apparatus that outputs the decoded video of the one viewpoint in a 2D display video format or a 2D output video format. A receiving method in a receiving apparatus for receiving a digital broadcast signal that is broadcast in a mixture of 3D video program content and 2D video program content,
Receiving a digital broadcast signal including encoded program content and identification information for identifying whether the program content is a 3D video program or a 2D video program;
A determination step of determining whether the received program content is 3D video program content or 2D video program content according to identification information about the received program content;
A decoding / conversion step that decodes the video of the program content according to a determination result of the determination step, converts the video into a predetermined display video format or an output video format, and outputs the decoded video.
In the determination step, the program content received in the reception step is determined based on the identification information as to whether it is 3D video program content or 2D video program content,
In the determining step, it is determined that the program content received in the receiving step is 3D video program content, and in the decoding / converting step, the video of the 3D video program content is converted into a 2D display video format or a 2D output video format. A receiving method characterized by superimposing a display indicating that the program is a 3D video program on the video. The reception method according to claim 5, comprising:
In the determining step, it is determined that the program content received in the receiving step is 3D video program content, and in the decoding / converting step, the video of the 3D video program content is converted into a 2D display video format or a 2D output video format. When the instruction signal indicating that switching from 2D video viewing to 3D video viewing is input to the receiving apparatus after the display indicating that the program is a 3D video program is superimposed on the video and output, output is performed. A receiving method comprising: changing a display video format or an output video format of video of the 3D video program content to a 3D display video format or a 3D output video format. The reception method according to claim 6, comprising:
The identification information includes information for identifying a transmission method of 3D video program content,
In the determining step, according to the identification information, the program content received in the receiving step divides one screen in the video into two regions, and the left-eye viewpoint video and the right-eye viewpoint video are It is determined that the content is 3D video program content stored and transmitted in two areas,
When the video of the 3D video program content is converted into the video of the 2D display video format or the 2D output video format in the decoding / conversion step, the 3D video program content is decoded and stored in the one screen. One of the left-eye viewpoint video and the right-eye viewpoint video is subjected to scaling processing, and the one-sided video subjected to the scaling processing is converted into a 2D display video format or a 2D output video format. A receiving method characterized by converting and outputting. The reception method according to claim 6, comprising:
The identification information includes information for identifying a transmission method of 3D video program content,
In the determination step, 3D video program content in which the program content received in the reception step stores and transmits the left-eye viewpoint video and the right-eye viewpoint video in different elementary streams based on the identification information in the determination step. When the video of the 3D video program content is converted into the video of the 2D display video format or the 2D output video format and output in the decoding / conversion step, the video for the left eye of the 3D video program content is output. Of the elementary stream storing the viewpoint video and the elementary stream storing the right-eye viewpoint video, the video is decoded from one of the elementary streams, and the decoded video of the one viewpoint is displayed in the 2D display video format or Output in 2D output video format Shin method.

Images