JP2006074456A - Digital data receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a digital data receiver for smoothly changing over a broadcast service without giving a viewer unpleasant feeling. <P>SOLUTION: The receiver comprises a first video data generating part (20) for generating first video data from first reception data; a second video data generating part (22) for generating second video data which is smaller in video size than the first video data from second reception data; a signal generating part (16) for generating a reception state detecting signal which indicates the reception state of the first reception data; a video changeover part (24) for changing over the first video data and the second video data in response to the reception state detecting signal; and a size changing part (27) for changing the video size of the second video data when the video changeover part performs changeover from the first video data into the second video data. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a digital data receiver such as a digital broadcast receiver capable of switching and using a plurality of types of video data.

  In digital broadcasting, if the electric field strength of a received radio wave is small, error correction cannot be performed and thus video or the like cannot be output. In view of this, it is known that when the electric field strength of the received radio wave is small, the video is switched from digital broadcasting to analog broadcasting and the video output is continued (for example, Patent Document 1).

  In digital broadcasting, the video size may differ for each broadcast program. Therefore, it is known that when image data having a number of pixels larger than the number of pixels that can be displayed on the display is received, the size of the received video data is changed in accordance with the display (for example, Patent Document 2).

  Further, in digital broadcasting, a first modulation scheme having a large C / N value (carrier power to noise power ratio) necessary for demodulation and a second modulation scheme having a low C / N value necessary for demodulation are simultaneously transmitted. Hierarchical transmission is possible. Therefore, it is known to count the C / N value and switch between the first modulation method and the second modulation method (for example, Patent Document 3).

JP 2000-332632 A (2 pages, FIG. 1) JP 2003-348478 A (page 3, FIG. 1) JP 2002-158726 A (page 5, FIG. 1)

  For example, in a car-mounted television or the like, there is a case where a digital television broadcast by hierarchical transmission that simultaneously transmits a general broadcast for home use (MPEG2 system) and a mobile broadcast for mobile reception (MPEG4 system or H.264 system) may be received. Mobile broadcasting for mobile reception has a larger reception limit than general broadcasting for home use, so if the reception status of general broadcasting for home use deteriorates, switching from general broadcasting for home use to mobile broadcasting for mobile reception will continue broadcasting. Since the video sizes are different, there is a problem that the viewer is uncomfortable.

  Therefore, an object of the present invention is to provide a digital data receiver that can provide the viewer with the best video according to the reception state.

  Another object of the present invention is to provide a digital data receiver capable of smoothly switching between broadcast services without causing discomfort to the viewer.

  In order to solve the above problems, a digital data receiver according to the present invention includes a first video data generation unit that generates first video data from first received data, and a video size that is larger than first video data from second received data. A second video data generation unit that generates second video data having a small size, a signal generation unit that generates a reception state detection signal indicating a reception state of the first reception data, and the first video data according to the reception state detection signal A video switching unit that switches between the second video data and a size changing unit that changes a video size of the second video data when the video switching unit switches from the first video data to the second video data; It is characterized by having.

  The digital data receiver according to the present invention further includes a display unit for displaying the first video data, and the size changing unit changes the video size of the second video data in accordance with the size of the display unit. It is preferable. By expanding mobile broadcast data having different video sizes in accordance with the display unit, the broadcast data can be switched without giving the viewer a sense of incongruity.

  Furthermore, in the digital data receiver according to the present invention, it is preferable that the size changing unit varies the change rate of the video size of the second video data in accordance with the reception state by the reception state detection signal. Since the noise included in the received video varies depending on the state of the received electric field, the image quality is prevented from being lowered due to enlargement when there is a lot of noise.

  Furthermore, in the digital data receiver according to the present invention, it is preferable that the size changing unit selects a data interpolation method for changing the video size of the second video data in accordance with the reception state by the reception state detection signal. . Since the noise included in the received video fluctuates according to the state of the received electric field, the video data is expanded by a data interpolation method most suitable for the noise state.

  Furthermore, the digital data receiver according to the present invention has a broadcast content acquisition unit for acquiring the broadcast content based on the second video data, and the size changing unit determines the video size of the second video data according to the broadcast content. It is preferable to select a data interpolation method for performing the change. Video data is expanded by an optimal data interpolation method according to the broadcast content (graphical images, natural images, etc.).

  Furthermore, the digital data receiver according to the present invention has a data interpolation method setting unit, and the size changing unit changes the video size of the second video data using the data interpolation method set by the setting means. It is preferable. The video data is enlarged by a data interpolation method according to the user's preference.

  Furthermore, in the digital data receiver according to the present invention, it is preferable that the selected data interpolation method is any one of the nearest neighbor method, the bicubic method, and the bilinear method.

  Further, the digital data receiver according to the present invention has a correlation unit for correlating the frame image included in the first video data and the frame image included in the second video data, and the video switching unit is It is preferable to switch the video from the frame image included in the first video data to the frame image included in the second video data having the most correlation with the frame image. By controlling the video to be switched between frame images having high correlation, a sense of incongruity due to the video switching is eliminated, and the video is switched seamlessly.

  Furthermore, in the digital data receiver according to the present invention, an audio data generation unit for generating audio data corresponding to the second video data, and a video switching unit from a frame image included in the first video data to a frame image It is preferable to have a control unit that delays the audio data in accordance with the video switching to the second video data when switching the video to the frame image included in the second video data having the most correlation. The output timing of the audio data is adjusted in accordance with the video switching.

  Further, in the digital data receiver according to the present invention, the reception state detection signal is a transport error signal of a packet signal related to the first received data, a Reed-Solomon error signal related to the first received data, or an AGC signal related to the first received data. It is preferable that

  According to the present invention, for example, on a display installed on a moving body such as an in-vehicle television, a viewer can always view an optimal video corresponding to a reception state.

  Further, according to the present invention, even when switching between broadcasting services having different images or video sizes depending on the reception state, the viewer continues broadcasting without being aware of the change in the video size due to the switching. Can be viewed.

  Furthermore, according to the present invention, even when switching between broadcasting services having different video sizes according to the reception state, the viewer can broadcast without being aware of changes in the video size and broadcasting content due to the switching. It becomes possible to watch continuously.

  A digital data (broadcast) receiver according to the present invention will be described below with reference to the drawings.

  FIG. 1 is a block diagram showing an outline of a digital data receiver 10 according to the present invention. In FIG. 1, a digital data receiver 10 includes an RF baseband processing unit 12, an OFDM demodulation processing unit 14, a TS decoding unit 16, an audio decoder 18, a first video decoder 20, a second video decoder 22, and a video switching processing unit 24. , A presentation processing unit 26, a delay circuit 30, a D / A converter 31, a storage unit 32, a control unit 34, an I / O 36, a system bus 38, and the like. The digital data receiver 10 is connected to the antenna 40, the vehicle-mounted display 50, and the speaker 60, and is operated by the remote controller 70 or the like.

  The RF baseband processing unit 12 receives a received broadcast wave from the antenna 40, extracts an OFDM (Orthogonal Frequency Division Multiplexing) signal existing in a desired band, and performs level adjustment by a built-in AGC (Auto Gain Control) circuit To the OFDM demodulation processing unit 14. The OFDM signal is controlled to a desired level by the AGC signal.

  The OFDM demodulation processing unit 14 demodulates the digitally modulated OFDM signal, performs error correction processing, and the like, and sends a TS (transport stream) packet signal to the TS decoding unit 16. At the same time, the OFDM demodulation processing unit 14 sends an error signal (transport error signal in the header portion of the packet) to the control unit 34 via the system bus 38 in order to determine the reception electric field state.

  The TS decoding unit 16 separates the TS packet signal into audio data, first video data, and second video data, and sends them to the audio decoder 18, the first video decoder 20, and the second video decoder 22, respectively. Here, the first video data is encoded data (hereinafter referred to as “digital broadcast data”) that is encoded by the MPEG2 method and corresponds to home-use broadcast for general use. The second video data corresponds to mobile broadcast for mobile reception, and is MPEG4 or H.264. This is encoded data (hereinafter referred to as “mobile broadcast data”) encoded by the H.264 system (one of the video compression systems also known as MPEG-4 Part 10).

  The TS decoding unit 16 simultaneously obtains EPG (electronic program guide) data from the TS packet signal. The EPG data is sent to the storage unit 32 via the system bus 38 and stored therein.

  In the OFDM system, since three types of signal carriers can be carried simultaneously, a maximum of three types of video data can be separated from the TS decoding unit 16, but in this embodiment, the MPEG2 system and the MPEG4 system or H . Two types of encoded data encoded with the H.264 system are handled. However, the present invention is not limited to this, and a third video decoder can be provided.

  The audio data from the coder 18 in the audio is subjected to predetermined delay processing in the delay circuit 30 under the control of the control unit 34, and after being synchronized with the video data, is converted into an analog signal by the D / A converter 31. And output from the speaker 60.

  The video data from the first and second video decoders 20 and 22 is selected by the video switching processing unit 24 under the control of the control unit 34 and displayed on the display 50 via the presentation processing unit 26. .

  The control unit 34 includes a CPU, a RAM, a ROM, and the like, operates according to a program installed in advance, and controls each element connected to the system bus 38. Further, the control unit 34 receives an error signal for each “digital broadcast data” and “mobile broadcast data” from the OFDM demodulation processing unit 14, and for each “digital broadcast data” and “mobile broadcast data” based on the error signal. Next, the state of the received electric field is determined. In the present embodiment, the control unit 34 determines that the received electric field is defective when a predetermined number or more (for example, 6 or more) error signals are received for a predetermined number (for example, 1000) of TS packet signals. Further, the control unit 34 controls the video switching processing unit 24 and the like based on the state of the received electric field, and switches video data and audio data between “digital broadcast data” and “mobile broadcast data”.

“Digital broadcast data” is encoded data encoded according to the MPEG2 system, and corresponds to a large video size (eg, 720 × 480 pixels) for home TVs, but with a bit rate. Therefore, noise resistance is weak, and when the distance from the broadcasting station is long, it may be difficult to receive well. On the other hand, “mobile broadcast data” is MPEG4 or H.264. This is based on the encoded data encoded by the H.264 system, and corresponds to, for example, a small video size (240 × 320 pixels) for mobile phones. However, since the bit rate is lower than the MPEG2 system, noise resistance is strong. Even if the distance from the broadcasting station becomes longer, it is possible to receive well.
The presentation processing unit 26 is a processing unit for displaying the received video data such as “digital broadcast data” or “mobile broadcast data” in conformity with the display 50 (800 × 480 pixels). A resizing unit 27 for changing the size, a temporary storage unit 28 such as a VRAM for temporarily storing video data, a correlation processing unit 29 for obtaining correlation between video data when the video data is switched, and the like. ing.
Hereinafter, the video data switching process will be described with reference to FIGS. FIG. 2 shows an example of a switching process flow for switching video data to be displayed on the display 50 according to the reception state, and FIG. 3 shows an example of the video data switching process. In FIG. 3, “digital broadcast data” has a good reception electric field in periods T1 and T3, whereas “digital broadcast data” has a bad reception electric field in period T2, but “mobile broadcast data” has a period of T1 to T3. In either case, the reception electric field is good.

  First, “digital broadcast data” (video size 720 × 480 pixels) based on encoded data encoded by the MPEG2 system, and MPEG4 system or H.264 from the broadcast station. A broadcast program having the same content as “mobile broadcast data” (video size 240 × 320 pixels) using encoded data encoded in the H.264 format is hierarchically transmitted in the same broadcast channel, and the digital data receiver 10 It is assumed that the power is turned on and the broadcast data can be received (S201).

  Next, the control unit 34 determines whether or not the reception electric field of the “digital broadcast data” is good based on the error signal count of the “digital broadcast data” described above (S202).

  When it is determined that the reception electric field of “digital broadcast data” is good, the control unit 34 controls the video switching processing unit 24 to select “digital broadcast data” decoded by the first video decoder 20 ( In step S203, the audio decoder 18 is controlled to output audio data corresponding to “digital broadcast data” (S204). The presentation processing unit 26 displays the decoded “digital broadcast data” on the display 50 as it is without changing the video size. This state corresponds to, for example, a state in which the video data 301 based on “digital broadcast data” is displayed on the display 50 in the period T1 of FIG.

  If it is determined in S202 that the received electric field of “digital broadcast data” is defective, the control unit 34 then determines “mobile broadcast data” based on the error signal count of “mobile broadcast data” described above. It is determined whether or not the received electric field is good (S205).

  When it is determined that the reception electric field of “mobile broadcast data” is good, the control unit 34 controls the video switching processing unit 24 to select “mobile broadcast data” decoded by the second video decoder 22 ( S206), by controlling the resizing unit 27 of the presentation processing unit 26, the mobile broadcast video size (240 × 320 pixels) is enlarged to the video size (720 × 480 pixels) that matches the size of the display 50, and the display 50 (S207). Further, the control unit 34 controls the audio decoder 18 to output audio data corresponding to “digital broadcast data” (S208). This state corresponds to, for example, a state in which the video data 311 based on the original “mobile broadcast data” is enlarged and the enlarged video data 312 is displayed on the display 50 in the period T2 of FIG.

  In the present embodiment, the video data is enlarged by a simple data replication method. The simple data duplication method is an interpolation method in which video data is enlarged to simply duplicate a non-existing pixel from an original pixel. For example, when an image of 3 × 3 pixels is enlarged four times (6 × 6 pixels), 36−9 = 27 pixels to be newly interpolated are interpolated by any one of 3 × 3 pixels.

  If it is determined in S205 that the received electric field of “mobile broadcast data” is also defective, the control unit 34 then controls the video switching processing unit 24 to select any broadcast data and determine it in advance. The presentation processing unit 26 is controlled so that the displayed still image is displayed on the display 50 (S209). Further, the control unit 34 controls the audio decoder 18 to output audio data corresponding to “mobile broadcast data” from the speaker 60 (S210). Since any broadcast data is determined to have a poor received electric field, a predetermined still image is displayed and only audio data is output. This state corresponds to a state in which the still image 313 is displayed on the display 50 in the period T2 in FIG.

  The control unit 34 repeats the flow shown in FIG. 2 at predetermined intervals (for example, every 1000 counts of the TS packet signal), and performs video switching control so that an optimal video corresponding to the error signal is displayed on the display 50. repeat. In the period T3 in FIG. 3, since the reception electric field of “digital broadcast data” becomes good again, the control unit 34 controls the video switching processing unit 24 to decode “digital broadcast data”. Is selected and the video data 321 is displayed on the display 50 (see S203 in FIG. 2).

  Next, switching of video data between “digital broadcast data” and “mobile broadcast data” will be described in more detail with reference to FIG. 4A shows each frame image “n + 1” 401, “n + 2” 402, “n + 3” 403, etc. included in “digital broadcast data”, and FIG. 4B shows “mobile broadcast data”. FIG. 4C shows an example of a frame image displayed on the display 50. FIG. 4C shows each frame image “m + 2” 411, “m + 3” 412, “m + 4” 413, and the like. In FIG. 4, it is assumed that at “400”, the reception electric field of “digital broadcast data” becomes defective, and the control unit 34 performs switching control of video data from “digital broadcast data” to “mobile broadcast data”.

  As described above, broadcast programs having the same contents based on “digital broadcast data” and “mobile broadcast data” are hierarchically transmitted on the same broadcast channel from the broadcast station, but the video data included in the TS packet is not transmitted. Each frame image is not completely the same. Therefore, when the “digital broadcast data” cannot be received 400 and the frame image 401 of “digital broadcast data” is switched to the frame image 412 of “mobile broadcast data”, the video does not move seamlessly. , Which can be uncomfortable for the viewer.

  Therefore, the frame image 401 of “digital broadcast data” immediately before the point 400 when “digital broadcast data” becomes unreceivable is temporarily stored in the temporary storage unit 28, and “mobile” having the highest correlation with the frame image 401 is stored. A frame image of “broadcast data” is selected by the correlation processing unit 29, and the presentation processing unit 26 performs processing so as to switch to the frame image.

Specifically, the correlation processing unit 29 compares the frame image 401 of “digital broadcast data” with the three adjacent frame images 411 to 413 of “mobile broadcast data”, and is most correlated with the frame image 401. Select a higher frame image. In FIG. 4, the frame image 412 is selected and switched to “mobile broadcast data” (see the frame image 424 in FIG. 4C). In the case of taking a correlation, the difference method between frames (the method of taking the difference of the same pixel data and making the correlation if the number of pixels having a certain level or less is below a certain number), the frequency characteristic detection method (intra-frame) Performs FFT analysis, and if the frequency-level is less than a certain level difference, a correlation is established), or detection by the least square method (square the difference of the same pixel data, and if less than a certain level) Or the like).
Since the correlation processing in the correlation processing unit 29 requires time, until the frame image is selected, the “digital broadcast data” frame image immediately before the point 400 when the reception electric field becomes defective is displayed. 401 is continuously displayed on the display 50 (see frame images 422 and 423 in FIG. 4C).

  Further, the control unit 34 controls the audio decoder 18 and the D / A converter 30 so that the audio data of “mobile broadcast data” is delayed and output from the speaker 60 in accordance with the frame image 412 in which the video is switched. To do. This makes it possible to switch between video and audio in complete synchronization. It should be noted that the audio output is turned OFF while “digital broadcast data” is switched from the time point 400 when the reception electric field becomes defective to the frame image 412.

  In this way, when switching from “digital broadcast data” to “mobile broadcast data”, the frame image having the most correlation is selected and switched, so that switching control can be performed without causing discomfort to the viewer. It became possible to carry out.

  In the above embodiment, if the received electric field of “mobile broadcast data” is good, the video data is uniformly expanded (see S207 in FIG. 2), but the received electric field of “mobile broadcast data” is good, The state where viewing is possible is divided into three stages: 1: good reception electric field, 2: weak reception electric field, 3: weak reception electric field, and 3: low reception electric field, and magnification of video data expansion according to three stages. Can be varied. For example, when the reception electric field is good, the video size of 240 × 320 pixels is enlarged to the video size of 720 × 480 pixels (see 312 in FIG. 3). 2: When the reception electric field is weak, 240 × 240 The video size of × 320 pixels can be increased to a video size of 520 × 360 pixels, and when the reception electric field is weak, control can be performed without increasing the video size. Since noise increases in accordance with the state of the received electric field, the image quality is maintained by suppressing the magnification.

  FIG. 5 shows an example of switching video while changing the magnification of “mobile broadcast data” according to the state of the received electric field. In FIG. 5, since the received electric field is weak in period T4, the “mobile broadcast data” is not enlarged and is displayed on the display 50 in the same size (240 × 320 pixels). Further, since the reception electric field is weak in the period T5, the video size of 240 × 320 pixels is enlarged to the video size of 520 × 360 pixels and displayed on the display 50. Further, in the period T6, because the reception electric field is good, the video size of 240 × 320 pixels is enlarged to the video size of 720 × 480 pixels (see 312 in FIG. 3) and displayed on the display 50. In the above example, the control is performed in three stages. However, this is an example, and various modifications can be made according to the size of the display.

  In the above embodiment, the resize unit 27 of the presentation processing unit 26 increases the mobile broadcast video size (240 × 320 pixels) to the video size (720 × 480 pixels) that matches the size of the display 50. Although the simple data replication method is used, resizing can also be performed based on the nearest neighbor method, the bilinear method, and the bicubic method.

The nearest neighbor method is a method of interpolating a pixel that does not exist due to enlargement by duplicating a pixel closest to the pixel, and can be used particularly preferably in the case of a graphic image with a high processing speed. This is because, in the case of a graphic image such as an animation, a gray color is formed when the white and black images are averaged, and thus there is little discomfort even when the closest method is used for enlargement. Note that, when the reception electric field of “mobile broadcast data” is good, there is almost no noise, so it is particularly preferable to use the nearest neighbor method with priority on the processing speed.
The bicubic method is a method of interpolating pixels that do not exist due to enlargement using a linear or three-dimensional function on the basis of nine surrounding pixels, and can be particularly preferably used in the case of a natural image with a high spatial frequency. Note that when the reception electric field of “mobile broadcast data” is weak, it is particularly preferable to use the bicubic method because even if the noise is large, the noise can be averaged and made inconspicuous in a 9-pixel space. .
The bilinear method is a method of interpolating pixels that do not exist due to enlargement using a linear or three-dimensional function on the basis of four surrounding pixels, and can be particularly preferably used for a natural image with a low spatial frequency. In the case where the received electric field of “mobile broadcast data” is weak, it is particularly preferable to use the bilinear method in order to reduce noise and average noise in a 4-pixel space to make it inconspicuous.
Furthermore, in the above embodiment, if the reception electric field of “mobile broadcast data” is good, the video data is uniformly expanded by the simple data replication method (see S207 in FIG. 2). The reception electric field is good, that is, the state in which viewing is possible is divided into three stages: 1: reception electric field good, 2: reception electric field weakness, 3: reception electric field weakness, according to the error signal. It is also possible to change the interpolation method. For example, when the reception electric field is good, the video data is enlarged by the nearest neighbor method. 2: When the reception electric field is weak, the video data is enlarged by the bicubic method. 3: The reception electric field is weak. In this case, the video data can be controlled to be enlarged by the bilinear method. Since the state of noise changes according to the state of the received electric field, the video data enlargement method is to be changed accordingly.

  Furthermore, in the above embodiment, if the reception electric field of “mobile broadcast data” is good, the video data is uniformly expanded by the simple data replication method (see S207 in FIG. 2). It is also possible to change the interpolation method according to the broadcast content. For example, if the broadcast content is a graphic image such as an animation, the video data is enlarged by the nearest neighbor method, and if the natural image has a high spatial frequency component, the video data is enlarged by the bicubic method. In the case of a natural image having a low frequency component, control can be performed so that video data is enlarged by the bilinear method. An attempt is made to select an optimal interpolation method according to the broadcast content. The broadcast content can be separately acquired from broadcast content acquisition means that is also used by the control unit 34 such as an EPG (electronic program guide).

  Further, the data interpolation method can be selected by the remote controller 70 or by other input means attached to the digital data receiver 10 so that the data interpolation method for expanding the video data can be selected according to the user's preference. It may be configured.

  Furthermore, in the above embodiment, the state of the reception electric field of “digital broadcast data” and “mobile broadcast data” is determined based on the transport error signal in the header portion of the packet, but Reed-Solomon (RS) You may control so that it may judge based on an error signal.

  The RF signal output from the RF baseband processing unit 12 is level-controlled by an AGC circuit and used for subsequent processing. The AGC signal for performing this level control also corresponds to the state of the received electric field. Therefore, the AGC signal can be used to determine the state of the received electric field.

It is a block diagram which shows the outline | summary of the digital data receiver which concerns on this invention. It is a figure which shows an example of the switching process flow of video data. It is a figure which shows an example of the switching process of video data. It is a figure which shows an example of the frame image switching process of video data. It is a figure which shows the other example of the switching process of video data.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Digital data receiver 14 OFDM demodulation process part 16 TS decode process part 20 1st video decoder 22 2nd video decoder 24 Video switching process part 26 Presentation process part 27 Resizing part 34 Control part 50 Display 60 Speaker

Claims (10)

A digital data receiver,
A first video data generator for generating first video data from the first received data;
A second video data generator for generating second video data having a video size smaller than the first video data from second received data;
A signal generator for generating a reception state detection signal indicating a reception state of the first reception data;
A video switching unit that switches between the first video data and the second video data in response to the reception state detection signal;
A size changing unit for changing a video size of the second video data when the video switching unit switches from the first video data to the second video data;
A digital data receiver comprising: And a display unit for displaying the first video data.
The digital data receiver according to claim 1, wherein the size changing unit changes a video size of the second video data according to a size of the display unit.   The digital data receiver according to claim 1, wherein the size changing unit varies a change rate of a video size of the second video data according to a reception state by the reception state detection signal.   2. The digital data receiver according to claim 1, wherein the size changing unit selects a data interpolation method for changing a video size of the second video data according to a reception state based on the reception state detection signal. Furthermore, it has a broadcast content acquisition unit for acquiring the broadcast content by the second video data,
The digital data receiver according to claim 1, wherein the size changing unit selects a data interpolation method for changing a video size of the second video data according to the broadcast content. Furthermore, it has a data interpolation method setting unit,
The digital data receiver according to claim 1, wherein the size changing unit changes a video size of the second video data using a data interpolation method set by the setting unit.   The digital data receiver according to any one of claims 4 to 6, wherein the selected data interpolation method is any one of a nearest neighbor method, a bicubic method, and a bilinear method. And a correlation unit for correlating the frame image included in the first video data and the frame image included in the second video data,
The video switching unit performs video switching from a frame image included in the first video data to a frame image included in the second video data most correlated with the frame image. 8. The digital data receiver according to any one of items 7. Furthermore, an audio data generation unit for generating audio data corresponding to the second video data;
When the video switching unit switches the video from the frame image included in the first video data to the frame image included in the second video data most correlated with the frame image, the first video data A control unit that delays the audio data in response to video switching to two video data;
The digital data receiver according to claim 8, further comprising:   The reception state detection signal is a transport error signal of a packet signal related to first received data, a Reed-Solomon error signal related to first received data, or an AGC signal related to the first received data. A digital data receiver according to claim 1.

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