JP2006074466A - Digital data receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a digital data receiver seamlessly making a switch between a strong hierarchy and a weak hierarchy without giving displeasure to a viewer. <P>SOLUTION: This digital data receiver (10) has: a first video data generating part (20) for generating first video data from weak hierarchy received data; a second video data generating part (21) for generating second video data from strong hierarchy received data; a video switching part (24) for switching the first video data and the second video data; a composing part (26) for preparing a composed frame image of a frame image included in the first video data and a frame image included in the second video data; and a control part (34) for controlling the video switching part so as to make a switch from the frame image included in the first video data to the frame image included in the second video image through the composed frame image. <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, hierarchical transmission with variable modulation method within the same channel is possible, so switching between high-resolution video with high image quality but low error tolerance and low-layer video with high error tolerance according to the reception status It is known to perform hysteresis processing using a received bit error rate (for example, Patent Document 1).

  In digital broadcasting, it is known to perform layer switching control according to a decoding error error rate related to video data and an audio decoding error error rate related to audio data (for example, Patent Document 2).

JP 2001-78180 A (pages 5 and 6) JP 2001-309273 A (page 3, FIG. 1)

  In digital broadcasting, TS packets of each layer are transmitted even when a broadcast program having the same content in a strong layer (high layer) and a weak layer (low layer) is transmitted hierarchically in the same broadcast channel from a broadcasting station. The video data and audio data included in the signal are not completely the same. Therefore, when video and audio are switched between the strong hierarchy (high hierarchy) and the weak hierarchy (low hierarchy), the video and audio may not be seamlessly transferred, which may cause discomfort to the viewer.

  Also, in digital broadcasting, depending on the selected channel, broadcast programs with the same content in the strong hierarchy (high hierarchy) and weak hierarchy (low hierarchy) may be transmitted hierarchically in the same broadcast channel from the broadcast station. It may not be. Therefore, if it is set so that a specific hierarchy is selected regardless of the channel, the video cannot be displayed, and the viewer may feel uncomfortable.

  Furthermore, in digital broadcasting, depending on the selected channel, only the broadcast program in the weak hierarchy (low hierarchy) was initially broadcast from the broadcast station, but after that the time zone etc. changed and the weak hierarchy (low hierarchy) ) And a strong hierarchy (high hierarchy) of the same content broadcast program may be changed to be transmitted hierarchically (change of hierarchical transmission configuration). Therefore, if it is set so that a specific hierarchy is always selected, the video cannot be displayed, and the viewer may feel uncomfortable.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a digital data receiver capable of seamlessly switching between a strong hierarchy and a weak hierarchy without causing discomfort to the viewer.

  In addition, the present invention provides a digital data receiver capable of outputting an optimal video of a strong hierarchy or a weak hierarchy without causing discomfort to the viewer regardless of changes in the channel or hierarchical transmission configuration. With the goal.

  In order to solve the above problems, a digital data receiver according to the present invention generates a first video data generation unit that generates first video data from weak hierarchical reception data, and generates second video data from strong hierarchical reception data. A second video data generation unit; a signal generation unit that generates a video data reception state detection signal indicating a reception state of the first video data; first video data and second video data based on the video data reception state detection signal; A video switching unit that performs switching, a synthesis unit for creating a composite frame image of a frame image included in the first video data and a frame image included in the second video data, and the first video data A control unit that controls the video switching unit to switch the video data from the included frame image to the frame image included in the second video data via the composite frame image; Characterized in that it. The digital data receiver can be switched seamlessly.

  Moreover, it is preferable to further have an audio data generation unit for generating audio data corresponding to the second video data, and a delay unit for delaying the audio data in accordance with switching of the video data. The audio data can be output according to the switched video data.

  In order to solve the above-described problem, a digital data receiver according to the present invention includes a first video data generation unit that generates first video data from weak hierarchy reception data, and first audio data from weak hierarchy reception data. A first audio data generation unit that generates, a second video data generation unit that generates second video data from strong hierarchical reception data, a second audio data generation unit that generates second audio data from strong hierarchical reception data, A signal generator for generating a video data reception state detection signal indicating a reception state of the first video data and an audio data reception state detection signal indicating a reception state of the first audio data, and a first video data and a second video data The video switching unit for switching, the audio switching unit for switching between the first audio data and the second audio data, and the reception status of the first video data are poor based on the video data reception status detection signal If it is determined that the reception state of the first audio data is good based on the audio data reception state detection signal, the video switching unit is controlled to output the second video data and the first audio data is output. And a control unit that controls the voice switching unit. When only the video data becomes defective, only the video data can be switched without switching the audio data.

  Furthermore, in order to solve the above-described problem, a digital data receiver according to the present invention includes a first video data generation unit that generates first video data from weak hierarchy reception data, and first audio data from weak hierarchy reception data. A first audio data generation unit that generates, a second video data generation unit that generates second video data from strong hierarchical reception data, a second audio data generation unit that generates second audio data from strong hierarchical reception data, A signal generator for generating a video data reception state detection signal indicating a reception state of the first video data and an audio data reception state detection signal indicating a reception state of the first audio data, and a first video data and a second video data A video switching unit for switching, a voice switching unit for switching between the first audio data and the second audio data, and a good reception state of the first video data based on the video data reception state detection signal And the video switching unit is controlled to output the first video data and the second audio data is output to the first audio data when it is determined that the reception status of the first audio data is poor based on the audio data reception status detection signal. And a control unit that controls the voice switching unit to output. In the case where only the audio data becomes defective, only the audio data can be switched without switching the video data.

  Furthermore, in order to solve the above-described problem, a digital data receiver according to the present invention includes a first video data generation unit that generates first video data from weak hierarchical reception data, and second video data from strong hierarchical reception data. A second video data generation unit for generating, a video switching unit for switching between the first video data and the second video data, a broadcast channel selection unit, a hierarchical transmission configuration detection unit for detecting a hierarchical transmission configuration, When the hierarchical transmission configuration detection unit detects that the broadcast program of the selected channel is transmitted hierarchically with the same content broadcast program in the weak hierarchy and the strong hierarchy, the video is output so as to output the second video data. And a control unit that controls the switching unit. In the case of so-called simulcasting, it is configured to automatically output high-level video data that is likely to be received well.

  Furthermore, in order to solve the above-described problem, a digital data receiver according to the present invention includes a first video data generation unit that generates first video data from weak hierarchical reception data, and second video data from strong hierarchical reception data. A second video data generation unit to be generated, a video switching unit for switching between the first video data and the second video data, a hierarchical transmission configuration detection unit for detecting a hierarchical transmission configuration, and a hierarchical transmission configuration detection unit And a control unit that controls the video switching unit so as to output the second video data when it is detected that broadcasting on the strong hierarchy is started. At first, only the broadcast on the weak hierarchy was performed, but when the broadcast on the strong hierarchy was started after that, the video data on the strong hierarchy was automatically output.

  Furthermore, in order to solve the above-described problem, a vehicle-mounted digital data receiver according to the present invention includes a first video data generation unit that generates first video data from weak hierarchical reception data, and a second video from strong hierarchical reception data. A second video data generating unit for generating data, a moving state detecting unit for generating a detection signal for detecting the moving state of the vehicle, and a video switching unit for switching between the first video data and the second video data The second video data is output when it is determined that the vehicle is moving based on the detection signal, and the first video data is output when it is determined that the vehicle is stopped based on the detection signal. And a control unit for controlling the video switching unit. When the vehicle is moving, it is configured to output video data with a strong hierarchy that is likely to be received well, and when the vehicle is stopped, it can output high-quality video data with a weak hierarchy. .

  According to the present invention, even if switching between the strong layer and the weak layer is performed according to the reception state, the viewer continuously views the broadcast without being aware of the switching of video and audio due to the switching. It became possible.

  Further, according to the present invention, for example, on a display installed on a moving body such as an in-vehicle television, the viewer can seamlessly view the optimum broadcast according to the reception state.

  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, a first audio decoder 18, a second audio decoder 19, a first video decoder 20, and a second video. It comprises a decoder 21, an audio switching processing unit 22, 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. ing. The digital data receiver 10 is connected to an antenna 40, a vehicle-mounted display 50 and a speaker 60, a remote controller 70, and a navigation device 80.

  The digital data receiver 10 is controlled by operation inputs from various input devices (buttons, touch panel, etc.) provided on the remote controller 70 and / or the display 50. Further, the digital data receiver 10 is configured to receive at least position information from a GPS information receiving unit 82 provided in the navigation device 80 and vehicle speed pulse information from a vehicle speed pulse receiving unit 84. The digital data receiver 10 may be configured to include any one or more of the antenna 40, the in-vehicle display 50 and the speaker 60, the remote controller 70, and the navigation device 80 described above.

  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 first video data and first audio data, second video data and second audio data, and the first audio decoder 18 and the first video decoder 20 respectively. The data is sent to the 2 audio decoder 19 and the second video decoder 21. Here, the first video data and the first audio data are encoded data (hereinafter, referred to as “weak hierarchical data”) encoded by the MPEG2 method, corresponding to home broadcasts for general use. The second video data and the second audio data correspond to mobile broadcast for mobile reception, and are MPEG4 format or H.264. This is encoded data (hereinafter referred to as “strong hierarchical 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 control unit 34 via the system bus 38 and stored in the storage unit 32.

  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 audio and video decoder can be provided.

  One of the audio data of the coders 18 and 19 in the first and second audio is selected by the audio switching processing unit 22 under the control of the control unit 34, and predetermined delay processing is performed by the delay circuit 30, and the video data After being synchronized, the analog signal is converted by the D / A converter 31 and output from the speaker 60.

  Further, after the video data from the first and second video decoders 20 and 21 is selected by the video switching processing unit 24 under the control of the control unit 34, the presentation processing unit 26 performs arithmetic processing to be described later. Is displayed on the display 50.

  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 layer from the OFDM demodulation processing unit 14 and determines the state of the received electric field for each layer based on the error signal. 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 audio switching processing unit 22 and the video switching processing unit 24 in accordance with the state of the received electric field to switch between video data and audio data.

  The video data and audio data in the weak layer are encoded data encoded by the MPEG2 system, and are high quality, but have a high bit rate, so that the noise resistance is weak and the distance from the broadcasting station is long. Then, good reception may be difficult. On the other hand, the video data and audio data of the strong hierarchy are MPEG4 format or H.264. Because it is based on encoded data encoded by the H.264 system and has a lower bit rate than the MPEG2 system, it has high noise resistance and can be received well even when the distance from the broadcasting station is longer. It becomes.

  The presentation processing unit 26 is a processing unit for displaying the selected video data of the weak hierarchy or the strong hierarchy in conformity with the display 50 (800 × 480 pixels), and is a VRAM for temporarily storing the video data A temporary storage unit 27, and a calculation processing unit 28 for performing calculation processing of video data, which will be described later.

  Hereinafter, the switching process flow between the weak hierarchy and the strong hierarchy will be described with reference to FIG. The flow of FIG. 2 is executed by the control unit 34 of the digital data receiver 10 mainly according to a program installed in advance.

  First, from a broadcasting station, weak hierarchical data based on encoded data encoded by the MPEG2 system, MPEG4 system or H.264 is used. A broadcast program having the same content as strong hierarchical data encoded by H.264 encoded data is hierarchically transmitted in the same broadcast channel, and the digital data receiver 10 is turned on to transmit the broadcast data. It is assumed that reception is possible (S201).

  Next, the control unit 34 determines whether or not the reception electric field of the video data of the weak hierarchy is good based on the error signal regarding the video data of the weak hierarchy (S202).

  If it is determined in S202 that the reception field of the weak layer video data is good, the control unit 34 then determines that the reception field of the weak layer audio data is based on the error signal related to the weak layer audio data. It is determined whether or not it is good (S203).

  When it is determined in S203 that the reception electric field of the audio data of the weak hierarchy is good, the control unit 34 next controls the video switching processing unit 24 to display the video data decoded by the first video decoder 20. The audio data is selected and displayed on the display 50, and the audio switching processor 22 is controlled to select audio data decoded by the first audio decoder 18 and output from the speaker 60 (S204). That is, high-quality weak hierarchical data is selected for both video and audio data.

  If it is determined in S203 that the received electric field of the weak hierarchical audio data is defective, the control unit 34 then determines that the received electric field of the strong hierarchical audio data is based on the error signal related to the strong hierarchical video data. It is determined whether or not it is satisfactory (S205).

  If it is determined in S205 that the reception electric field of the audio data of the weak hierarchy is good, the control unit 34 then controls the video switching processing unit 24 to display the video data decoded by the first video decoder 20. The audio data is selected and displayed on the display 50, and the audio switching processor 22 is controlled to select audio data decoded by the second audio decoder 19 and output it from the speaker 60 (S206). That is, high-quality weak hierarchical data is selected for video data, and strong hierarchical data is selected for audio data.

  If it is determined in S205 that the received electric field of the audio data of the higher hierarchy is defective, the control unit 34 next controls the video switching processing unit 24 to display the video data decoded by the first video decoder 20. The selected data is displayed on the display 50, but no audio data is output (S207). That is, high-quality weak hierarchical data is selected as video data, but no audio data is selected.

  If it is determined in S202 that the received electric field of the weak hierarchical video data is defective, the control unit 34 then determines that the received electric field of the strong hierarchical video data is based on the error signal related to the strong hierarchical video data. It is determined whether or not it is good (S208).

  If it is determined in S208 that the reception field of the strong layer video data is good, the control unit 34 then determines that the reception field of the weak layer audio data is based on the error signal related to the weak layer audio data. It is determined whether or not it is satisfactory (S209).

  When it is determined in S209 that the reception electric field of the audio data of the weak hierarchy is good, the control unit 34 next controls the video switching processing unit 24 to display the video data decoded by the second video decoder 21. The selected audio data is displayed on the display 50, and the audio switching processor 22 is controlled to select audio data decoded by the first audio decoder 18 and output it from the speaker 60 (S210). That is, strong hierarchical data is selected as video data, and high quality weak hierarchical data is selected as audio data.

  If it is determined in S209 that the received electric field of the weak hierarchical audio data is defective, the control unit 34 then determines that the received electric field of the strong hierarchical audio data is based on the error signal related to the strong hierarchical audio data. It is determined whether or not it is satisfactory (S211).

  If it is determined in S211 that the reception electric field of the audio data of the higher hierarchy is good, the control unit 34 next controls the video switching processing unit 24 to display the video data decoded by the second video decoder 21. The audio data is selected and displayed on the display 50, and the audio switching processor 22 is controlled to select audio data decoded by the second audio decoder 19 and output it from the speaker 60 (S212). That is, strong hierarchical data is selected for both video and audio data.

  If it is determined in S211 that the received electric field of the audio data of the higher hierarchy is defective, the control unit 34 then controls the video switching processing unit 24 to display the video data decoded by the second video decoder 20. The selected data is displayed on the display 50, but no audio data is output (S213). That is, as the video data, strong hierarchical data is selected, but no audio data is selected.

  If it is determined in S208 that the reception field of the strong layer video data is defective, the control unit 34 then determines that the reception field of the weak layer audio data is based on the error signal related to the weak layer audio data. It is determined whether or not it is satisfactory (S214).

  When it is determined in S214 that the reception electric field of the audio data of the weak hierarchy is good, the control unit 34 then controls the presentation processing unit 26 to display a desired still image stored in advance on the display 50. Then, the audio switching processing unit 22 is controlled to select the audio data decoded by the first audio decoder 18 and output it from the speaker 60 (S215). In other words, high-quality weak hierarchical data is selected as audio data, but no video data is selected, and a still image is displayed instead.

  If it is determined in S214 that the received electric field of the weak hierarchy audio data is defective, the control unit 34 then determines that the received electric field of the strong hierarchy audio data is based on the error signal related to the strong hierarchy audio data. It is determined whether or not it is good (S216).

  If it is determined in S216 that the received electric field of the strong hierarchical audio data is good, the control unit 34 then controls the presentation processing unit 26 to display a desired still image stored in advance on the display 50. Then, the audio switching processor 22 is controlled to select the audio data decoded by the second audio decoder 19 and output from the speaker 60 (S217). That is, high-quality strong hierarchical data is selected as the audio data, but no video data is selected, and a still image is displayed instead.

  If it is determined in S216 that the reception electric field of the audio data in the strong hierarchy is bad, the control unit 34 next controls the presentation processing unit 26 without selecting any video data and audio data. A desired still image stored in advance is displayed on the display 50 (S218).

  The control unit 34 performs the switching process of the weak hierarchy and the strong hierarchy at the digital data receiver 10 while performing the processing flow shown in FIG. 2 at every predetermined timing (for example, every predetermined count number of the TS packet signal). Continue as long as reception is in progress.

  As described above, in the present embodiment, the state of the reception electric field of the video data and audio data of each layer is judged, and the optimal video and audio data are output while giving priority to the video data and audio data of the weak layer. To control.

  Next, the switching of the video data of the weak hierarchy and the video data of the strong hierarchy will be described in more detail with reference to FIG.

  FIG. 3A shows the frame images “n + 1” 301, “n + 2” 302, “n + 3” 303, etc. included in the weak layer video data, and FIG. 3B shows the strong layer video data. FIG. 3C shows an example of a frame image displayed on the display 50. Each frame image “m + 2” 311, “m + 3” 312, “m + 4” 313 and the like included in FIG. Reference numeral 300 in FIG. 3 indicates a point in time when the weak reception electric field becomes defective and the control unit 34 switches from weak hierarchical video data to strong hierarchical video data.

  As described above, the broadcast program having the same content using the weak layer video data and the strong layer video data is 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 control unit 34 switches from the frame image 301 of the weak layer video data to the frame image 312 of the strong layer video data at the time point 300 when switching from the weak layer video data to the strong layer video data, The video does not move seamlessly, which may cause discomfort to the viewer.

Therefore, in the present embodiment, the frame image 301 of the weak layer video data immediately before the time point 300 at which the weak layer video data is switched, and the frame image 311 of the strong layer video data just before the time point 300 at which the weak layer video data is switched. Are combined in the calculation processing unit 28 of the presentation processing unit 26 to create a composite frame image 324, and control is performed to switch from weak layer video data to strong layer video data via the composite frame image 324 ( (See frame images 325 and 326 in FIG. 3C). For example, the composite frame image is an R.D. G. It can be created by RGB additive color mixing processing that forms an image with an average value of B values.
Since it takes time to create the composite frame image 324 in the arithmetic processing unit 28, the frame image of the weak layer video data immediately before the time point 300 when the weak layer video data is switched until the composite frame image is generated. 301 is continuously displayed on the display 50 (see frame images 322 and 323 in FIG. 3C).

  Further, the control unit 34 controls the delay circuit 30 to delay the audio data and output it from the speaker 60 in accordance with the frame image 325 switched to the video data of the higher hierarchy. As a result, the video data and audio data can be switched between the layers almost synchronously. Note that the control unit 34 switches the audio output from the speaker 60, the delay circuit 30 or D so that the audio output from the speaker 60 is turned off during the switching from the time point 300 when the video data of the weak hierarchy is switched to the composite frame image 324. The / A converter 31 was controlled. The same applies to switching from video data of a strong hierarchy to video data of a weak hierarchy.

  In this way, when switching from weak layer video data to strong layer video data, switching of the video data is performed via a composite frame image of the frame image of the weak layer video data and the frame image of the strong layer video data. Since the control was performed, the switching shock of the video data was reduced, and the switching control could be performed without causing discomfort to the viewer.

  In the above embodiment, the frame image 301 in FIG. 3A and the frame image 311 in FIG. 3B are combined to create a combined frame image, but the most correlated with the frame image 301 in FIG. It is also possible to select a frame image having a high value in advance and create a composite frame image with the selected frame image. Specifically, the frame image 301 of FIG. 3A is temporarily stored in the storage unit 27, and the correlation between the frame image 301 and the frame images 311 to 313 of the strong hierarchical video data having the highest correlation is examined. The most correlative frame image is selected (for example, frame image 312), and processing is performed so that the arithmetic processing unit 28 creates a composite frame image of the frame image 301 and the frame image 312.

  In the above embodiment, weak hierarchical data based on encoded data encoded by the MPEG2 system, MPEG4 system or H.264 is transmitted from the broadcasting station. A switching process flow between hierarchies was executed on the assumption that a broadcast program having the same contents as the strong hierarchical data by the encoded data encoded by the H.264 system was hierarchically transmitted in the same broadcast channel. However, it is convenient to determine the initially selected layer in advance rather than immediately detecting the reception state and determining which layer to select after determining the channel desired by the user. Therefore, when the user selects a channel that the user desires to receive with the remote controller 70 or the like, a broadcast program having the same content by the weak hierarchical data and the strong hierarchical data is hierarchically transmitted on the same broadcast channel (simultaneous broadcasting). It is preferable that the video data and audio data of a strong hierarchy, which are highly likely to be viewed, are initially set to be selected.

  Whether or not the channel is simulcast can be determined by a TMCC (Transmission and Multiplex Configuration and Control) signal output from the OFDM demodulation processing unit 14. Therefore, when the channel is selected, the control unit 34 determines whether the selected channel is a simulcast based on the TMCC signal. If the channel is a simulcast, the control unit 34 and the audio switching processor 22 and The video switching processing unit 24 may be controlled so as to output the strong hierarchical video data and the strong hierarchical audio data from the display 50 and the speaker 60.

  Further, in the above-described embodiment, weak hierarchical data based on encoded data encoded by the MPEG2 system, MPEG4 system or H.264 is transmitted from the broadcasting station. The switching process flow between hierarchies has been described on the assumption that a broadcast program having the same content as the strong hierarchical data by the encoded data encoded by the H.264 system is hierarchically transmitted on the same broadcast channel. However, at the time when the digital data receiver 10 starts reception, only the broadcast with the weak hierarchical data exists, but the so-called countdown (the hierarchical transmission configuration) that the broadcast with the strong hierarchical data starts after the start of reception. Change) may be made. When the countdown occurs, the digital data receiver 10 can be controlled to output newly started strong hierarchical data in order to grasp the broadcast contents more reliably.

  The countdown can be determined by a TMCC (Transmission and Multiplex Configuration and Control) signal output from the OFDM demodulation processing unit 14. Therefore, when the control unit 34 detects the broadcast start of the strong hierarchical data due to the countdown based on the TMCC signal, the control unit 34 controls the audio switching processing unit 22 and the video switching processing unit 24 to control the strong hierarchical video data and the strong hierarchical data. Control may be performed so that audio data is output from the display 50 and the speaker 60.

  Further, in the above embodiment, the switching control between layers is performed using only the reception electric field state of the video data and audio data of each layer, but the vehicle speed pulse from the vehicle speed pulse receiving unit 84 is used. It is possible to perform switching control between hierarchies. That is, the control unit 34 uses the vehicle speed pulse to determine whether the vehicle on which the digital data receiver 10 is mounted is moving or stopped, and outputs the video data and audio data of the higher hierarchy during the movement. Control is performed so that video data and audio data of a weak hierarchy are output during stoppage. Since the state of the received electric field tends to be poor while the vehicle is moving, control is performed to output video data and audio data of a strong hierarchy. Even in this case, it is preferable to switch the video data via the composite frame image described with reference to FIG.

  Furthermore, in the above embodiment, the reception field states of the weak and strong layers are determined based on the transport error signal in the header portion of the TS packet signal, but the Reed-Solomon output from the TS decode processing unit 16 is used. It may be controlled to make a determination based on (RS) error signal.

  The OFDM signal output from the RF baseband processing unit 12 is level-controlled by the AGC circuit and input to the OFDM demodulation processing unit 14 at the subsequent stage. The AGC signal for controlling the level of the AGC circuit is also received by the received electric field. It corresponds to the state of. Therefore, the state of the reception electric field of each hierarchical data may be determined using the AGC signal.

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.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Digital data receiver 14 OFDM demodulation process part 16 TS decode process part 18 Coder in 1st audio 19 Coder in 2nd audio 20 1st video decoder 21 2nd video decoder 22 Audio | voice switch process part 24 Video | video switch process part 26 Presentation process Unit 27 storage unit 28 arithmetic processing unit 30 delay circuit 34 control unit 50 display 60 speaker 70 remote control 84 vehicle speed pulse receiving unit

Claims (8)

A digital data receiver,
A first video data generation unit that generates first video data from weak hierarchical reception data;
A second video data generation unit for generating second video data from the strong hierarchical reception data;
A signal generator for generating a video data reception state detection signal indicating a reception state of the first video data;
A video switching unit that switches between the first video data and the second video data based on the video data reception state detection signal;
A combining unit for creating a combined frame image of a frame image included in the first video data and a frame image included in the second video data;
Control for controlling the video switching unit to switch the video data from the frame image included in the first video data to the frame image included in the second video data via the composite frame image And
A digital data receiver comprising: Furthermore, an audio data generation unit for generating audio data corresponding to the second video data;
A delay unit that delays the audio data in accordance with the switching of the video data;
The digital data receiver according to claim 1. A digital data receiver,
A first video data generation unit that generates first video data from weak hierarchical reception data;
A first audio data generation unit that generates first audio data from the weak layer reception data;
A second video data generation unit for generating second video data from the strong hierarchical reception data;
A second audio data generation unit that generates second audio data from the strong layer reception data;
A signal generator for generating a video data reception state detection signal indicating a reception state of the first video data and an audio data reception state detection signal indicating a reception state of the first audio data;
A video switching unit for switching between the first video data and the second video data;
A voice switching unit for switching between the first voice data and the second voice data;
When it is determined that the reception state of the first video data is poor based on the video data reception state detection signal and the reception state of the first audio data is good based on the audio data reception state detection signal A control unit that controls the video switching unit to output the second video data and controls the audio switching unit to output the first audio data;
A digital data receiver comprising: A digital data receiver,
A first video data generation unit that generates first video data from weak hierarchical reception data;
A first audio data generation unit that generates first audio data from the weak layer reception data;
A second video data generation unit for generating second video data from the strong hierarchical reception data;
A second audio data generation unit that generates second audio data from the strong layer reception data;
A signal generator for generating a video data reception state detection signal indicating a reception state of the first video data and an audio data reception state detection signal indicating a reception state of the first audio data;
A video switching unit for switching between the first video data and the second video data;
A voice switching unit for switching between the first voice data and the second voice data;
When it is determined that the reception state of the first video data is good based on the video data reception state detection signal and the reception state of the first audio data is bad based on the audio data reception state detection signal A control unit that controls the video switching unit to output the first video data and controls the audio switching unit to output the second audio data;
A digital data receiver comprising:   The video data reception state detection signal and the audio data reception state detection signal are related to a transport error signal of a packet signal related to the weak layer reception data, a Reed-Solomon error signal related to the weak layer reception data, or the weak layer reception data. The digital data receiver according to claim 1, wherein the digital data receiver is an AGC signal. A digital data receiver,
A first video data generation unit that generates first video data from weak hierarchical reception data;
A second video data generation unit for generating second video data from the strong hierarchical reception data;
A video switching unit for switching between the first video data and the second video data;
A broadcast channel selector,
A hierarchical transmission configuration detector for detecting a hierarchical transmission configuration;
When the broadcast transmission of the selected channel is detected by the hierarchical transmission configuration detection unit to transmit a broadcast program having the same content in a weak hierarchy and a strong hierarchy, the second video data is output. A control unit for controlling the video switching unit;
A digital data receiver comprising: A digital data receiver,
A first video data generation unit that generates first video data from weak hierarchical reception data;
A second video data generation unit for generating second video data from the strong hierarchical reception data;
A video switching unit for switching between the first video data and the second video data;
A hierarchical transmission configuration detector for detecting a hierarchical transmission configuration;
A control unit that controls the video switching unit to output the second video data when it is detected by the hierarchical transmission configuration detection unit that broadcasting by a strong hierarchy is started;
A digital data receiver comprising: An in-vehicle digital data receiver,
A first video data generation unit that generates first video data from weak hierarchical reception data;
A second video data generation unit for generating second video data from the strong hierarchical reception data;
A moving state detector for generating a detection signal for detecting the moving state of the vehicle;
A video switching unit for switching between the first video data and the second video data;
The second video data is output when it is determined that the vehicle is moving based on the detection signal, and the first video is output when it is determined that the vehicle is stopped based on the detection signal. A control unit for controlling the video switching unit to output data;
An in-vehicle digital data receiver characterized by comprising:

Images