JP4789206B2 - Terrestrial digital broadcast receiver - Google Patents

Description

  The present invention relates to a receiving apparatus applied to terrestrial digital television broadcasting (hereinafter referred to as terrestrial digital broadcasting).

  As a digital data modulation method, a modulation method called an orthogonal frequency division multiplexing method (hereinafter referred to as an OFDM method, OFDM: Orthogonal Frequency Division Multiplexing) is known. In the OFDM modulation scheme, a number of orthogonal subcarriers (subcarriers) are provided in a transmission band, and data is assigned to the amplitude and phase of each subcarrier by PSK (Phase Shift Keying) or QAM (Quadrature Amplitude Modulation), This is a digital modulation method.

  The OFDM system is often applied to terrestrial digital broadcasting that is strongly affected by multipath interference. ISDB-T (Integrated Services Digital Broadcasting-Terrestrial) standard is applied to terrestrial digital broadcasting adopting the OFDM system. The ISDB-T standard is described in ARIB STD-B30 {Published by the Japan Radio Industry Association, published "Transmission Method for Terrestrial Digital Broadcasting (STD-B30)" July 29, 2003 (1.1th Edition)}. Is defined. In this ISDB-T standard, a transmission method called hierarchical transmission is adopted.

  Hierarchical transmission uses a segment division method that divides one channel (transmission band) into multiple regions (called segments) and enables broadcast signals to be transmitted using different modulation methods for each segment. In the transmission system, a plurality of different broadcast signals are broadcast simultaneously on the same channel. Each segment transmits signals in a state where orthogonality is maintained, and on the receiving side, it is possible to collectively demodulate broadcast signals transmitted to a plurality of segments in one channel. Yes.

  Therefore, in the ISDB-T standard, one channel (6 MHz) is divided into 13 segments, one broadcast signal is modulated into one central segment, and 12 segments excluding the central segment are formed. A hierarchical transmission system is used in which one broadcast signal is modulated. Hereinafter, the hierarchy of the broadcast signal of one central segment is referred to as a strong hierarchy (A hierarchy), and the broadcast signal hierarchy of the segment excluding the strong hierarchy is referred to as a weak hierarchy (B hierarchy).

  In the ISDB-T standard, a broadcast signal in the strong layer has a low transmission capacity (low image quality and low sound quality) and a high error tolerance, and a broadcast signal in the weak layer has a high transmission capacity (high image quality and high sound quality) and an error. By using signals with low tolerance, the strong layer and weak layer are applied to broadcasting for mobile terminals and broadcasting for fixed reception, respectively.

  By the way, in terrestrial digital broadcasting, there is a high possibility that the reception status will change every moment by receiving while moving, and the reception status may gradually deteriorate even though the reception status was good at first. . When the reception situation deteriorates (defective), the video and audio are disturbed on the way. When the video is disturbed on the way, the video becomes very difficult for the viewer to see, and even when the audio is disturbed on the way, the audio becomes hard to hear for the viewer.

  Therefore, a general terrestrial digital broadcast receiver does not output the decoded video signal as a moving image as it is, but displays a still image that holds the image decoded immediately before. Thereby, it is possible to eliminate the difficulty in viewing the video when the reception state deteriorates.

  On the other hand, the audio signal cannot be processed as hold. For this reason, general terrestrial digital broadcast receivers have no choice but to mute the audio signal to perform the same processing as the video signal when the reception state deteriorates. However, when the audio signal is muted in the middle, the sound is interrupted in the middle and becomes difficult to hear.

  In order to solve this problem, Japanese Patent Application Laid-Open No. 2005-2005 discloses a technique of outputting weak hierarchical video / audio data when the reception state is good and switching from weak hierarchical video / audio data to strong hierarchical video / audio data when the reception state is bad. -223348 (refer to Patent Document 1). However, in the ISDB-T standard, there is no guarantee that the broadcast signal modulated into one segment at the center of the channel and the broadcast signal modulated into 12 segments other than the center are the same source. For this reason, when switching from weak hierarchical video / audio data to strong hierarchical video / audio data and outputting, there is a possibility that audio data that is completely unrelated to the audio data up to that time may be output. Therefore, in Patent Document 1, when the reception state is bad, it is checked whether or not the same program is hierarchically transmitted. That is, it is confirmed whether the weak hierarchical audio data and the strong hierarchical audio data are the same audio data, and when they are the same, the weak hierarchical video audio data is switched to the strong hierarchical video audio data.

  Also, as a technology related to digital broadcasting, Japanese Patent Application Laid-Open No. 2006-74466 discloses switching from weak hierarchical video data and weak hierarchical audio data to strong hierarchical video data and strong hierarchical audio data when the reception state is poor. A technique is described (see Patent Document 2). In this patent document 2, when switching from weak hierarchical video data to strong hierarchical video data, a composite frame image of a frame image included in the weak hierarchical video data and a frame image included in the strong hierarchical video data is generated. The frame image included in the hierarchical video data is switched from the frame image included in the hierarchical video data to the frame image included in the strong hierarchical video data via the strong hierarchical video data.

JP 2005-223548 A JP 2006-74466 A

  However, Patent Document 1 is a method of switching from weak hierarchical audio data to strong hierarchical audio data after determining that the reception state is poor. For this reason, when switching from weak hierarchical voice data to strong hierarchical voice data, there are problems that the voice is interrupted and output in a discontinuous state, still eliminating the difficulty of hearing the voice Can not do it.

  Japanese Patent Application Laid-Open No. 2004-228561 is a method of switching from weak hierarchical video data and weak hierarchical audio data to strong hierarchical video data and strong hierarchical audio data after determining that the reception state is poor. For this reason, with regard to video data, the difficulty of viewing the video at the time of deterioration of the reception state is eliminated, but with regard to audio data, when switching from weak hierarchical audio data to strong hierarchical audio data, audio is interrupted and output, There is a problem that the voice is output in a discontinuous state, and it is still impossible to eliminate the difficulty of hearing the voice.

  Hereinafter, means for solving the problem will be described using the numbers and symbols used in [Best Mode for Carrying Out the Invention]. These numbers and symbols are added to clarify the correspondence between the description of [Claims] and the description of [Best Mode for Carrying Out the Invention]. It should not be used to interpret the technical scope of the invention described in “

The terrestrial digital broadcast receiving apparatus (2) of the present invention includes a receiving unit (21; 11, 12) and a demodulation processing unit (22; 13-15, 17, 19) (22; 33, 14, 15, 17, 19). ), A reception state determination unit (16), and speech synthesis units (20) and (40).
The receiving unit (21; 11, 12) receives broadcast data obtained by performing OFDM (Orthogonal Frequency Division Multiplexing) modulation on strong hierarchical voice data and weak hierarchical voice data.
The demodulation processing unit (22; 13-15, 17, 19) (22; 33, 14, 15, 17, 19) performs OFDM demodulation on the broadcast data, and the strong layer audio data and the weak layer Audio data is output.
The reception state determination unit (16) generates a reception state determination result indicating whether or not the reception state when the reception unit (21; 11, 12) receives the broadcast data is good.
The speech synthesizer (20) (40)
If the reception status determination result indicates that the reception state is good (S1-YES), synthesized voice data obtained by synthesizing the strong hierarchy voice data and the weak hierarchy voice data is output to the output device (3) ( S6),
If the reception status determination result indicates a failure in the reception state (S1-NO), the strong hierarchical voice data is output to the output device (3) (S4).

  As described above, in the terrestrial digital broadcast receiving apparatus (2) of the present invention, the synthesized speech obtained by synthesizing the weak hierarchical voice data and the strong hierarchical voice data when the reception state is good by the voice synthesizing units (20) and (40). Data is output, and when the reception state becomes defective, the strong hierarchical voice data is continuously output and the output of the weak hierarchical voice data is stopped. As a result, in the terrestrial digital broadcast receiving apparatus (2) of the present invention, strong hierarchical audio data with high error tolerance is always output, so that when the reception state deteriorates, the audio is interrupted and output or the audio is discontinuous. It is possible to solve the problem of output in the state of.

  Hereinafter, a digital terrestrial broadcast receiver according to the present invention will be described in detail with reference to the accompanying drawings. The present invention can be used for various mobile terminal devices including, for example, a car navigation system having a terrestrial digital broadcast receiving function and a portable terminal.

(First embodiment)
FIG. 1 is a block diagram showing a configuration of a mobile terminal device 1 to which a terrestrial digital broadcast receiving device 2 according to a first embodiment of the present invention is applied. The mobile terminal device 1 includes a terrestrial digital broadcast receiving device 2 and an output device 3 according to the first embodiment.

  The terrestrial digital broadcast receiving apparatus 2 includes a reception unit 21, a demodulation processing unit 22, a reception status determination unit 16, a content comparison unit 18, a voice synthesis unit 20, a video output terminal T1, and an audio output terminal T2. It has. The receiving unit 21 includes an antenna 11 and a tuner 12. The demodulation processing unit 22 includes an OFDM demodulation unit 13, an MPEG-2TS separation unit 14, a weak layer video decoding unit 15, a strong layer audio decoding unit 17, and a weak layer audio decoding unit 19.

  The antenna 11 is connected to the tuner 12. The tuner 12 is connected to the OFDM demodulator 13. The OFDM demodulator 13 is connected to the MPEG-2TS separator 14 and the reception status determiner 16. The MPEG-2TS separation unit 14 is connected to the weak layer video decoding unit 15, the strong layer audio decoding unit 17, and the weak layer audio decoding unit 19. The weak layer video decoding unit 15 is connected to the video output terminal T1. The strong hierarchy speech decoding unit 17 and the weak hierarchy speech decoding unit 19 are connected to the content comparison unit 18 and the speech synthesis unit 20. The content comparison unit 18 is connected to the voice synthesis unit 20. The reception status determination unit 16 is connected to the weak layer video decoding unit 15 and the voice synthesis unit 20. The voice synthesizer 20 is connected to the audio output terminal T2. The video output terminal T1 and the audio output terminal T2 are connected to the output device 3.

  The output device 3 is exemplified by a monitor and a recording device, and includes a speaker 5, a display unit 6, a recording unit 7, and a control unit 4 for controlling them (see FIG. 5).

  The tuner 12 performs channel search in digital terrestrial broadcasting by operating a viewer input device (not shown). In other words, the tuner 12 controls the antenna 11 so as to receive broadcast data with a frequency designated by the viewer from a plurality of frequencies in the terrestrial digital broadcast.

  Broadcast data broadcast from a broadcasting station corresponds to the ISDB-T standard and includes two services by hierarchical transmission. That is, when one channel is divided into 13 segments, the broadcast data includes strong layer (A layer) content data (video data and audio data) transmitted to the central segment and the central one. Content data (video data and audio data) of a weak hierarchy (B hierarchy) transmitted to a segment other than one segment. Further, the broadcast signal of the strong hierarchy is applied to the broadcast for mobile reception having a low transmission capacity (low image quality and low sound quality) and high error tolerance. On the other hand, the broadcast signal in the weak hierarchy is applied to broadcasting for fixed reception having a high transmission capacity (high image quality and high sound quality) and low error resistance.

  The broadcast data is subjected to OFDM modulation on a transport stream (hereinafter referred to as TS) defined in ISO / IEC13818-1. The OFDM modulation includes Reed-Solomon coding, convolutional coding, transmission path coding for time and frequency interleaving, IFFT (Inverse Fast Fourier Transform) calculation, guard interval addition processing, and the like. The TS includes a plurality of transport stream packets (hereinafter referred to as TS packets) from the first to the last.

  The TS packet is a 188 [byte] packet including a 4 [byte] header (header) portion and a payload (payload) portion in which a code of 184 [byte] is set. The header part includes a transport error indicator (transport error signal) and a PID (packet ID).

  The PID is an identifier for identifying a code set in the payload portion. The PID includes an ID representing either the strong hierarchy or the weak hierarchy. The ID representing the strong hierarchy is a fixed value. The PID representing the strong hierarchy and the weak hierarchy further includes an ID representing either a video (Video) code representing video or an audio (Audio) code representing audio. Further, the PID representing the strong hierarchy and the weak hierarchy further includes a service ID representing a broadcasted program (content). The service ID is uniquely determined for each program.

  The transport error signal is a 1-bit flag. When the flag is set to “1”, it indicates that at least one bit error (bit error that cannot be corrected) exists in the TS packet. On the other hand, when the flag is set to “0”, it indicates that there is no uncorrectable bit error in the TS packet.

  The tuner 12 outputs broadcast data received by the antenna 11 to the OFDM demodulator 13. The OFDM demodulator 13 performs OFDM demodulation on the broadcast data, and outputs the TS to the MPEG-2TS separator 14 and the reception status determiner 16.

  The MPEG-2TS separation unit 14 outputs a weak layer video TS packet including a PID representing a weak layer and a video code among the plurality of TS packets of the TS to the weak layer video decoding unit 15. At this time, if the reception status determination result from the reception status determination unit 16 indicates that the reception status is good, the weak layer video decoding unit 15 decodes the video code included in the weak layer video TS packet, and the weak layer video Data is output to the output device 3 via the video output terminal T1. The weak hierarchy video data includes the service ID. When the reception status determination result from the reception status determination unit 16 indicates that the reception status is defective, the weak layer video decoding unit 15 uses the video data immediately before the weak layer video data as still image data, and connects the video output terminal T1. To the output device 3.

  In addition, the MPEG-2TS separation unit 14 outputs a strong layer audio TS packet including a PID representing a strong layer and an audio code among the plurality of TS packets to the strong layer audio decoding unit 17. At this time, the strong layer voice decoding unit 17 decodes the audio code included in the strong layer voice TS packet, and outputs the decoded audio code to the content comparison unit 18 and the voice synthesis unit 20 as strong layer voice data. The strong hierarchical voice data includes the service ID described above.

  Also, the MPEG-2 TS separation unit 14 outputs a weak layer audio TS packet including a PID representing a weak layer and an audio code among the plurality of TS packets to the weak layer audio decoding unit 19. At this time, the weak layer audio decoding unit 19 decodes the audio code included in the weak layer audio TS packet, and outputs the decoded audio code to the content comparison unit 18 and the voice synthesis unit 20 as weak layer audio data. The weak hierarchy audio data includes the service ID.

  The reception status determination unit 16 checks (monitors) whether or not there is a TS packet representing a bit error from among a plurality of TS packets of the TS, and the reception unit (antenna 11 and tuner 12) transmits the broadcast data (or A reception status determination result indicating whether or not the reception state when receiving (TS) is good is generated and output to the weak layer video decoding unit 15 and the voice synthesis unit 20. When there is no TS packet that represents a bit error, the reception status determination result indicates that the reception status is good. When there is a TS packet that indicates a bit error, the reception status determination result indicates that the reception status is poor. Represents that.

  The content comparison unit 18 checks whether or not hierarchical transmission is performed in the same program. That is, the content comparison unit 18 compares the service ID included in the strong hierarchical audio data from the strong hierarchical audio decoding unit 17 with the service ID included in the weak hierarchical audio data from the weak hierarchical audio decoding unit 19, and A comparison result indicating whether the hierarchical audio data and the weak hierarchical audio data have the same content is generated. The content comparison unit 18 outputs the comparison result to the speech synthesis unit 20.

  When the reception status determination result from the reception status determination unit 16 indicates that the reception status is good and the comparison result from the content comparison unit 18 indicates the same content, the speech synthesis unit 20 Synthetic voice data synthesized with the voice data is generated and output to the output device 3 via the audio output terminal T2. On the other hand, when the comparison results do not represent the same content, the speech synthesizer 20 outputs weak hierarchical speech data to the output device 3 via the audio output terminal T2.

  When the reception status determination result from the reception status determination unit 16 indicates a poor reception status and the comparison result from the content comparison unit 18 indicates the same content, the speech synthesis unit 20 converts the strong hierarchical audio data into audio It outputs to the output device 3 via the output terminal T2. On the other hand, when the comparison results do not represent the same content, the speech synthesizer 20 does not output audio data.

  When the output device 3 is a monitor, the control unit 4 of the output device 3 outputs the audio data from the terrestrial digital broadcast receiving device 2 to the speaker 5 and the video data from the terrestrial digital broadcast receiving device 2 to the display unit 6. indicate. When the output device 3 is a recording device, audio data and video data from the terrestrial digital broadcast receiving device 2 are recorded in the recording unit 7.

  As described above, in the terrestrial digital broadcast receiving apparatus 2 according to the first embodiment of the present invention, the synthesized voice data obtained by synthesizing the weak hierarchy voice data and the strong hierarchy voice data is received by the voice synthesizer 20 when the reception state is good. If the reception state becomes poor, the strong hierarchical audio data is continuously output, and the output of the weak hierarchical audio data is stopped. As a result, in the terrestrial digital broadcast receiving apparatus 2 according to the first embodiment of the present invention, strong hierarchical audio data with high error tolerance is always output. Therefore, when the reception state deteriorates, audio is interrupted and output. Can be solved in a discontinuous state.

  In addition, when the voice synthesis unit 20 uses the comparison result of the content comparison unit 18 to output by switching from weak hierarchical voice data to strong hierarchical voice data, or by switching from strong hierarchical voice data to weak hierarchical voice data. In this case, it is possible to prohibit the output of audio data that has nothing to do with the audio data so far.

  FIG. 2 is a flowchart showing the operation of the digital terrestrial broadcast receiving apparatus 2 according to the first embodiment of the present invention.

  The tuner 12 outputs broadcast data received by the antenna 11 to the OFDM demodulator 13. The OFDM demodulator 13 performs OFDM demodulation on the broadcast data, and outputs the TS to the MPEG-2TS separator 14 and the reception status determiner 16. The MPEG-2 TS separation unit 14 outputs the above weak layer video TS packet to the weak layer video decoding unit 15 from among a plurality of TS packets of the TS, and the strong layer audio decoding unit 17 outputs the above strong layer audio TS packet. And the above weak hierarchical voice TS packet is output to the weak hierarchical voice decoding unit 19. At this time, the weak layer video decoding unit 15 decodes the video code included in the weak layer video TS packet to generate the above weak layer video data. The strong layer audio decoding unit 17 decodes the audio code included in the above strong layer audio TS packet to generate the above strong layer audio data, and outputs it to the content comparison unit 18 and the audio synthesis unit 20. The weak layer audio decoding unit 19 decodes the audio code included in the weak layer audio TS packet to generate the weak layer audio data, and outputs the weak layer audio data to the content comparison unit 18 and the audio synthesis unit 20. The reception status determination unit 16 monitors whether or not there is a TS packet representing a bit error from among a plurality of TS packets of the TS, generates a reception status determination result, and performs voice synthesis with the weak hierarchical video decoding unit 15 To the unit 20 (step S1).

  It is assumed that the reception status determination result from the reception status determination unit 16 indicates “good” (assuming that the reception status is good) (step S1-YES). The content comparison unit 18 compares the service ID included in the strong hierarchical audio data from the strong hierarchical audio decoding unit 17 with the service ID included in the weak hierarchical audio data from the weak hierarchical audio decoding unit 19, and compares the comparison result. Generate and output to the speech synthesizer 20 (step S3).

  Here, it is assumed that the comparison result from the content comparison unit 18 indicates “match” (represents the same content) (YES in step S3). In this case, the weak layer video decoding unit 15 outputs the weak layer video data to the output device 3 via the video output terminal T1 based on the reception status determination result “good”. At the same time, the speech synthesizer 20 generates synthesized speech data obtained by synthesizing the strong hierarchical speech data and the weak hierarchical speech data based on the reception status determination result “good” and the comparison result “match”, and the audio output terminal T2 To the output device 3 (step S6). Here, when the output device 3 is a monitor, the control unit 4 of the output device 3 outputs the synthesized voice data to the speaker 5 and displays the weak hierarchical video data on the display unit 6. When the output device 3 is a recording device, the synthesized audio data and the weak hierarchical video data are recorded in the recording unit 7.

  On the other hand, it is assumed that the comparison result indicates “mismatch” (not the same content) (step S3-NO). In this case, the weak layer video decoding unit 15 outputs the weak layer video data to the output device 3 via the video output terminal T1 based on the reception status determination result “good”. At the same time, the speech synthesizer 20 outputs weak hierarchical speech data to the output device 3 via the audio output terminal T2 based on the reception status determination result “good” and the comparison result “mismatch” (step S7). Here, when the output device 3 is a monitor, the control unit 4 of the output device 3 outputs weak hierarchical audio data to the speaker 5 and displays weak hierarchical video data on the display unit 6. When the output device 3 is a recording device, the weak hierarchical audio data and the weak hierarchical video data are recorded in the recording unit 7.

  It is assumed that the reception status determination result from the reception status determination unit 16 represents “defective” (represents a reception status failure) (step S1-NO). The content comparison unit 18 compares the service ID included in the strong hierarchical audio data from the strong hierarchical audio decoding unit 17 with the service ID included in the weak hierarchical audio data from the weak hierarchical audio decoding unit 19, and compares the comparison result. Generate and output to the speech synthesizer 20 (step S2).

  Here, it is assumed that the comparison result from the content comparison unit 18 represents “match” (step S2-YES). In this case, the weak layer video decoding unit 15 outputs the video data immediately before the weak layer video data as still image data to the output device 3 via the video output terminal T1 based on the reception status determination result “bad”. . At the same time, the speech synthesizer 20 outputs the strong hierarchical speech data to the output device 3 via the audio output terminal T2 based on the reception status determination result “bad” and the comparison result “match” (step S4). Here, when the output device 3 is a monitor, the control unit 4 of the output device 3 outputs the strong hierarchical audio data to the speaker 5 and displays the still image data on the display unit 6. When the output device 3 is a recording device, strong hierarchical audio data and still image data are recorded in the recording unit 7.

  On the other hand, it is assumed that the comparison result indicates “mismatch” (step S2-NO). In this case, the weak layer video decoding unit 15 outputs the video data immediately before the weak layer video data as still image data to the output device 3 via the video output terminal T1 based on the reception status determination result “bad”. . At the same time, the speech synthesizer 20 does not output speech data based on the reception status determination result “bad” and the comparison result “mismatch” (step S5). When the output device 3 is a monitor, the control unit 4 of the output device 3 displays still image data on the display unit 6. When the output device 3 is a recording device, still image data is recorded in the recording unit 7.

  In the terrestrial digital broadcast receiving apparatus 2 of the present invention, the MPEG-2TS separation unit 14 corresponds to the multiplexing method of the MPEG-2 system, but the present invention is not limited to the MPEG-2 system. Absent.

  Further, in the terrestrial digital broadcast receiving apparatus 2 of the present invention, the weak hierarchical video decoding unit 15 may have a function of generating strong hierarchical video data in addition to the function of generating weak hierarchical video data as described above. . That is, the MPEG-2TS separation unit 14 outputs a strong layer video TS packet including a PID representing a strong layer and a video code among the plurality of TS packets to the weak layer video decoding unit 15. The weak layer video decoding unit 15 decodes the video code included in the strong layer video TS packet, generates strong layer video data including the service ID, and the reception status determination result from the reception status determination unit 16 is the reception state. In this case, the weak hierarchical video data is switched to the strong hierarchical video data. This eliminates the difficulty in viewing the video when the reception state deteriorates.

  Here, in the terrestrial digital broadcast receiving apparatus 2 of the present invention, the technique described in Japanese Patent Laid-Open No. 2006-74466 (Patent Document 2) may be applied to the weak hierarchical video decoding unit 15. That is, when switching from weak hierarchical video data to strong hierarchical video data, a composite frame image of a frame image included in the weak hierarchical video data and a frame image included in the strong hierarchical video data is generated. Is switched from the frame image included in the frame image to the frame image included in the strong layer video data via the strong layer video data. This further eliminates the difficulty in viewing the video when the reception state deteriorates.

  In the terrestrial digital broadcast receiving apparatus 2 of the present invention, the same technology as that of the content comparison unit 18 may be applied to the weak hierarchical video decoding unit 15. That is, when the reception status determination result from the reception status determination unit 16 indicates that the reception status is good, the weak layer video decoding unit 15 (video decoding unit 15) transmits the weak layer video data via the video output terminal T1. To the output device 3. In addition, the reception status determination result from the reception status determination unit 16 indicates that the reception status is poor, and the service ID included in the weak hierarchical video data matches the service ID included in the strong hierarchical video data (represents the same content). The video decoding unit 15 switches from the weak hierarchical video data to the strong hierarchical video data, and outputs it to the output device 3 via the audio output terminal T2. On the other hand, when the same content is not represented, the video decoding unit 15 outputs the video data immediately before the weak hierarchical video data as still image data to the output device 3 via the video output terminal T1. As a result, when switching from weak layer video data to strong layer video data for output, or when switching from strong layer video data to weak layer video data for output, video data that has nothing to do with the previous video data Can be prohibited from being output.

  As described above, in the terrestrial digital broadcast receiving apparatus 2 according to the first embodiment of the present invention, the synthesized speech data obtained by synthesizing the weak hierarchical voice data and the strong hierarchical voice data is output by the voice synthesizing unit 20 when the reception state is good. In addition, when the reception state becomes defective, the strong hierarchical voice data is continuously output, and the output of the weak hierarchical voice data is stopped. As a result, in the terrestrial digital broadcast receiving apparatus 2 according to the first embodiment of the present invention, strong hierarchical audio data with high error tolerance is always output. Therefore, when the reception state deteriorates, audio is interrupted and output. Can be solved in a discontinuous state.

  In addition, when the voice synthesis unit 20 uses the comparison result of the content comparison unit 18 to output by switching from weak hierarchical voice data to strong hierarchical voice data, or by switching from strong hierarchical voice data to weak hierarchical voice data. In this case, it is possible to prohibit the output of audio data that has nothing to do with the audio data so far.

(Second Embodiment)
In the terrestrial digital broadcast receiving apparatus 2 according to the second embodiment of the present invention, the description overlapping with that of the first embodiment is omitted.

  FIG. 3 is a block diagram showing a configuration of the mobile terminal device 1 to which the terrestrial digital broadcast receiving device 2 according to the second embodiment of the present invention is applied. The terrestrial digital broadcast receiver 2 according to the second embodiment replaces the OFDM demodulator 13, the content comparator 18, and the voice synthesizer 20 in the first embodiment with an OFDM demodulator 33, a simulcast determination unit 38, and a voice synthesizer. 40.

  The OFDM demodulator 33 is connected to the MPEG-2TS separator 14, the reception status determination unit 16, and the simulcast determination unit 38. The strong hierarchical speech decoding unit 17 and the weak hierarchical speech decoding unit 19 are connected to the speech synthesis unit 40. The reception status determination unit 16 is connected to the weak layer video decoding unit 15 and the voice synthesis unit 40. The simulcast determination unit 38 is connected to the voice synthesis unit 40. The speech synthesizer 40 is connected to the audio output terminal T2.

  Broadcast data is subjected to OFDM modulation on a transport stream (hereinafter referred to as TS) defined in ISO / IEC13818-1 and a TMCC (Transmission Multiplex Configuration and Control) transmission signal. The TMCC signal includes a partial reception flag indicating whether or not partial reception, so-called one-segment broadcasting (video, audio, data broadcasting, etc. transmitted in a strong layer) exists.

  The tuner 12 outputs broadcast data received by the antenna 11 to the OFDM demodulator 33. The OFDM demodulator 33 performs OFDM demodulation on the broadcast data, outputs the TS to the MPEG-2TS separator 14 and the reception status determiner 16, and outputs the TMCC signal to the simulcast determiner 38.

  The simulcast determination unit 38 checks whether or not hierarchical transmission is performed in the same program. That is, the simulcast determination unit 38 refers to the partial reception flag included in the TMCC signal from the OFDM demodulator 33 and generates a simulcast determination result indicating whether or not the broadcast data is simulcast. The simulcast determination unit 38 outputs the simulcast determination result to the speech synthesis unit 40.

  When the reception status determination result from the reception status determination unit 16 indicates that the reception state is good and the simulcast determination result from the simulcast determination unit 38 indicates simulcast, the voice synthesis unit 40 determines that the strong hierarchical audio data and Synthetic speech data synthesized with the weak hierarchical speech data is generated and output to the output device 3 via the audio output terminal T2. On the other hand, when the simulcast determination result does not represent simulcast, the speech synthesizer 40 outputs weak hierarchical audio data to the output device 3 via the audio output terminal T2.

  If the reception status determination result from the reception status determination unit 16 indicates a poor reception status and the simulcast determination result from the simulcast determination unit 38 indicates simulcast, the voice synthesis unit 40 stores the strong hierarchical audio data. And output to the output device 3 via the audio output terminal T2. On the other hand, when the simulcast determination result does not represent simulcast, the speech synthesizer 40 does not output audio data.

  FIG. 4 is a flowchart showing the operation of the digital terrestrial broadcast receiving apparatus 2 according to the second embodiment of the present invention.

  The tuner 12 outputs broadcast data received by the antenna 11 to the OFDM demodulator 33. The OFDM demodulator 33 performs OFDM demodulation on the broadcast data, outputs the TS to the MPEG-2TS separator 14 and the reception status determiner 16, and outputs the TMCC signal to the simulcast determiner 38. The MPEG-2 TS separation unit 14 outputs the above weak layer video TS packet to the weak layer video decoding unit 15 from among a plurality of TS packets of the TS, and the strong layer audio decoding unit 17 outputs the above strong layer audio TS packet. And the above weak hierarchical voice TS packet is output to the weak hierarchical voice decoding unit 19. At this time, the weak layer video decoding unit 15 decodes the video code included in the weak layer video TS packet to generate the above weak layer video data. The strong layer speech decoding unit 17 decodes the audio code included in the above strong layer speech TS packet, generates the above strong layer speech data, and outputs it to the speech synthesis unit 40. The weak layer speech decoding unit 19 decodes the audio code included in the weak layer speech TS packet to generate the above weak layer speech data, and outputs it to the speech synthesis unit 40. The reception status determination unit 16 monitors whether or not there is a TS packet representing a bit error from among a plurality of TS packets of the TS, generates a reception status determination result, and performs voice synthesis with the weak hierarchical video decoding unit 15 To the unit 40 (step S1).

  It is assumed that the reception status determination result from the reception status determination unit 16 indicates “good” (assuming that the reception status is good) (step S1-YES). The simulcast determination unit 38 refers to the partial reception flag included in the TMCC signal from the OFDM demodulator 33, generates a simulcast determination result, and outputs it to the speech synthesizer 40 (step S12).

  Here, it is assumed that the simulcast determination result from simulcast determination unit 38 represents “simultaneous broadcast present” (simultaneous broadcast is represented) (YES in step S12). In this case, the weak layer video decoding unit 15 outputs the weak layer video data to the output device 3 via the video output terminal T1 based on the reception status determination result “good”. At the same time, the voice synthesis unit 40 generates synthesized voice data obtained by synthesizing the strong hierarchy voice data and the weak hierarchy voice data based on the reception status judgment result “good” and the simultaneous broadcast judgment result “simultaneous broadcasting exists”. Output to the output device 3 via the audio output terminal T2 (step S6).

  On the other hand, it is assumed that the simulcast determination result indicates “no simulcast” (not simulcast) (step S12—NO). In this case, the weak layer video decoding unit 15 outputs the weak layer video data to the output device 3 via the video output terminal T1 based on the reception status determination result “good”. At the same time, the speech synthesizer 40 outputs the weak hierarchical audio data to the output device 3 via the audio output terminal T2 based on the reception status determination result “good” and the simulcast determination result “no simulcast”. Step S7).

  In addition, it is assumed that the reception status determination result from the reception status determination unit 16 represents “defective” (represents a reception status failure) (step S1-NO). The simulcast determination unit 38 refers to the partial reception flag included in the TMCC signal from the OFDM demodulator 33, generates a simulcast determination result, and outputs it to the speech synthesizer 40 (step S11).

  Here, it is assumed that the simulcast determination result from simulcast determination unit 38 indicates “simultaneous broadcast exists” (simultaneous broadcast is assumed) (step S11—YES). In this case, the weak layer video decoding unit 15 outputs the video data immediately before the weak layer video data as still image data to the output device 3 via the video output terminal T1 based on the reception status determination result “bad”. . At the same time, the voice synthesizer 40 outputs the strong hierarchical voice data to the output device 3 via the audio output terminal T2 based on the reception status judgment result “bad” and the simulcast judgment result “simultaneous broadcast exists” ( Step S4).

  On the other hand, it is assumed that the simulcast determination result indicates “no simulcast” (not simulcast) (step S2-NO). In this case, the weak layer video decoding unit 15 outputs the video data immediately before the weak layer video data as still image data to the output device 3 via the video output terminal T1 based on the reception status determination result “bad”. . At the same time, the voice synthesizer 40 does not output voice data based on the reception status judgment result “bad” and the simulcast judgment result “no simulcast” (step S5).

  As described above, the terrestrial digital broadcast receiving device 2 according to the second embodiment of the present invention includes the simulcast determination unit 38 and the voice synthesis unit 40 instead of the content comparison unit 18 and the voice synthesis unit 20 in the first embodiment. Even in the case, the same effect as the first embodiment can be realized.

FIG. 1 is a block diagram showing a configuration of a mobile terminal device 1 to which a terrestrial digital broadcast receiving device 2 according to a first embodiment of the present invention is applied. FIG. 2 is a flowchart showing the operation of the digital terrestrial broadcast receiving apparatus 2 according to the first embodiment of the present invention. FIG. 3 is a block diagram showing a configuration of the mobile terminal device 1 to which the terrestrial digital broadcast receiving device 2 according to the second embodiment of the present invention is applied. FIG. 4 is a flowchart showing the operation of the digital terrestrial broadcast receiving apparatus 2 according to the second embodiment of the present invention. FIG. 5 is a block diagram showing a configuration of the output device 3 applied to the mobile terminal device 1.

Explanation of symbols

1 mobile terminal device 2 terrestrial digital broadcast receiver,
3 output device,
4 control unit,
5 Speaker,
6 Display section,
7 Recording section,
11 Antenna,
12 Tuner,
13 OFDM demodulator,
14 MPEG-2TS separator,
15 Weak hierarchical video decoding unit,
16 Reception status judgment unit,
17 Strong hierarchical speech decoding unit,
18 Content comparison part,
19 Weak hierarchical speech decoding unit,
20 Speech synthesis unit,
21 receiver,
22 demodulation processing unit,
33 OFDM demodulator,
38 Simul Broadcasting Judgment Department,
40 speech synthesizer,
T1 video output terminal,
T2 audio output terminal,

Claims (10)

A receiving unit that receives broadcast data obtained by performing OFDM (Orthogonal Frequency Division Multiplexing) modulation on the strong layer voice data and the weak layer voice data;
A demodulation processing unit that performs OFDM demodulation on the broadcast data and outputs the strong layer audio data and the weak layer audio data;
A reception state determination unit that generates a reception state determination result indicating whether or not the reception state when the reception unit receives the broadcast data is good;
When the reception status determination result indicates that the reception state is good, synthesized voice data obtained by synthesizing the strong hierarchy audio data and the weak hierarchy audio data is output to an output device, and the reception status determination result is the reception status A terrestrial digital broadcast receiver comprising: a voice synthesizer that outputs the strong hierarchical voice data to the output device when a state failure is indicated. In the terrestrial digital broadcast receiver according to claim 1,
The broadcast data is further subjected to the OFDM modulation on the video data,
The demodulation processing unit performs the OFDM demodulation on the broadcast data, outputs the video data to the output device, and outputs the strong hierarchy audio data and the weak hierarchy audio data to the audio synthesis unit Digital broadcast receiver. In the terrestrial digital broadcast receiver according to claim 2,
The demodulation processing unit includes:
When the reception status determination result indicates that the reception state is good, the video data is output to the output device,
A terrestrial digital broadcast receiving device that outputs video data immediately before the video data to the output device as still image data when the reception status determination result indicates a failure in the reception state. In the terrestrial digital broadcast receiver according to any one of claims 1 to 3,
A content comparison unit that generates a comparison result indicating whether or not the strong hierarchy audio data and the weak hierarchy audio data are the same content;
The speech synthesizer
If the reception status determination result indicates that the reception state is good and the comparison result indicates the same content, the synthesized audio data is output to the output device,
When the reception status determination result indicates that the reception state is good and the comparison result does not represent the same content, the weak hierarchical audio data is output to the output device,
A terrestrial digital broadcast receiver that outputs the strong hierarchical audio data to the output device when the reception status determination result indicates a failure in the reception state and the comparison result indicates the same content. In the terrestrial digital broadcast receiver according to claim 4,
The strong hierarchy audio data and the weak hierarchy audio data include a service ID representing the content to be broadcast,
The content comparison unit compares a service ID included in the strong hierarchy audio data with a service ID included in the weak hierarchy audio data, and the strong hierarchy audio data and the weak hierarchy audio data are the same content. A terrestrial digital broadcast receiving apparatus that generates the comparison result indicating whether or not there is. In the terrestrial digital broadcast receiver according to any one of claims 1 to 3,
The broadcast data is further subjected to the OFDM modulation on a TMCC (Transmission Multiplex Configuration and Control) transmission signal,
The TMCC signal includes a partial reception flag indicating whether partial reception is present,
The demodulation processing unit performs the OFDM demodulation on the broadcast data and outputs the TMCC signal,
A simulcast determination unit that generates a simulcast determination result indicating whether the broadcast data is simulcast with reference to the partial reception flag included in the TMCC signal;
The speech synthesizer
If the reception status determination result indicates good reception status and the simulcast determination result indicates simulcast, the synthesized audio data is output to the output device,
If the reception status determination result indicates that the reception state is good and the simulcast determination result does not indicate simulcast, the weak hierarchical audio data is output to the output device,
A terrestrial digital broadcast receiver that outputs the strong hierarchical audio data to the output device when the reception status determination result indicates a failure in the reception state and the simultaneous broadcast determination result indicates simultaneous broadcast. A terrestrial digital broadcast receiver according to claim 1;
Speakers,
A mobile terminal device comprising: a control unit that outputs audio data from the terrestrial digital broadcast receiving device to the speaker. A terrestrial digital broadcast receiver according to claim 2;
Speakers,
A display unit;
A mobile terminal device comprising: a control unit that outputs audio data from the terrestrial digital broadcast receiving device to the speaker and displays video data from the terrestrial digital broadcast receiving device on the display unit. A terrestrial digital broadcast receiver according to claim 1;
A recording section;
A mobile terminal device comprising: a control unit that records audio data from the terrestrial digital broadcast receiving device in the recording unit. A terrestrial digital broadcast receiver according to claim 2;
A recording section;
A mobile terminal device comprising: a control unit that records audio data and video data from the terrestrial digital broadcast receiving device in the recording unit.

Images