JP2008148230A - Broadcasting receiver and method for receiving broadcasting - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable to distinguish an activation flag for emergency warning broadcasting in a standby operation with less standby power requirement and a simple configuration. <P>SOLUTION: A received signal processing part 20 of a digital terrestrial broadcasting receiver is provided with a first signal processing part 20a for obtaining transmission multiplex control data by performing demodulation processing of a received signal and decoding processing of demodulated data obtained by the demodulation processing, a second signal processing part 20b for obtaining a transport stream by processing the demodulated data obtained in the first signal processing part 20a, and a processing control part 30. The processing control part 30 stops operation of the second signal processor 20b by stopping supply of a clock signal CLK to the second signal processing part 20b by a clock supply control part 28, so as to obtain only transmission multiplex control data when distinguishing the activation flag for emergency warning broadcasting during standby operation. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a broadcast receiving apparatus and a broadcast receiving method. Specifically, in reception of digital terrestrial broadcasting, when the emergency warning broadcast activation flag is determined during standby operation, a reception signal processing unit that performs reception signal processing of a desired transmission channel to obtain a transport stream, performs transmission multiplexing control. By performing processing for obtaining only data, standby power is reduced.

  In digital broadcasting, in addition to satellite broadcasting using BS (Broadcasting Satellite) / CS (Communication Satellite), terrestrial digital broadcasting has also been started.

  In this terrestrial digital broadcast, broadcast content data is multiplexed and transmitted as a terrestrial digital broadcast signal of a predetermined communication method. As this communication method, an Orthogonal Frequency Division Multiplexing (OFDM) method is adopted. The OFDM scheme is a multi-carrier transmission scheme that uses a plurality of carriers simultaneously. Each carrier is orthogonal to each other, and is modulated using DQPSK (Differential Quadrature Phase Shift Keying), QPSK (Quadrature Phase Shift Keying), 16QAM (Quadrature Amplitude Modulation), and 64QAM. As described above, since a plurality of schemes can be used for carrier modulation, and transmission parameters such as coding rate can be changed, transmission multiplexing control data (TMCC) indicating a modulation scheme, transmission parameters, and the like can be used. : Transmission and Multiplexing Configuration Control) and other various control data are also transmitted.

  In such terrestrial digital broadcasting, emergency warning broadcasting that has been performed in conventional analog broadcasting is also performed, and an emergency warning broadcasting activation flag indicating whether or not emergency warning broadcasting is performed is included in the transmission multiplexing control data. Is provided. Therefore, by determining the state of the emergency warning broadcast activation flag, it is possible to automatically receive this broadcast when the emergency warning broadcast is performed.

  FIG. 1 shows a configuration of a broadcast receiving apparatus that receives a terrestrial digital broadcast signal. A signal SRF obtained by receiving the terrestrial digital broadcast signal with the antenna 11 is supplied to the tuner unit 15. The tuner unit 15 performs a channel selection operation and frequency conversion processing based on a control signal RT from the control unit 51 described later, and supplies the reception signal SIF that is an OFDM baseband signal of a desired transmission channel to the reception signal processing unit 20. .

  The received signal processing unit 20 performs OFDM demodulation processing of the received signal SIF, decoding processing for extracting transmission multiplexing control data (hereinafter referred to as “TMCC data”) including an emergency warning broadcast activation flag, and OFDM demodulation processing. An equalization process for compensating the distortion of the obtained demodulated data, an error correction process for the demodulated data after the equalization process, a deinterleaving process for rearranging the data in the original order, etc. Supply to the multiplexer 41. Also, TMCC data DTM is supplied to the control unit 51.

  The demultiplexer 41 extracts the video data packet Dpv of the viewing channel to be viewed from the transport stream and supplies the packet Dpv to the video decoder 42. The audio data packet Dpa is extracted and supplied to the audio decoder 43.

  The video decoder 42 decodes the video data and outputs the decoded video data. By using this video data, it is possible to display a video of a desired program. The audio decoder 43 decodes the audio data and outputs the decoded audio data. By using this audio data, audio of a desired program can be output.

  The tuner unit 15, the received signal processing unit 20, the demultiplexer 41, the video decoder 42, and the audio decoder 43 are connected to the control unit 51 via the bus 50. An input unit 52 and a memory unit 53 are connected to the bus 50.

  The input unit 52 includes a remote control signal receiving unit that receives a signal transmitted from an operation key or a remote control device (not shown). The input unit 52 supplies an operation signal corresponding to a key operation of an operation key provided in the input unit 52 to the control unit 51. Alternatively, a signal transmitted from the remote control device is received, and an operation signal corresponding to a key operation of an operation key provided in the remote control device is supplied to the control unit 51.

  The memory unit 53 is for storing a program for operating the receiving apparatus, various information necessary for operating the receiving apparatus, and the like.

  The control unit 51 executes the program read from the memory unit 53, and operates the operation signal PS supplied from the input unit 52, various information read from the memory unit 53, and the TMCC data DTM supplied from the received signal processing unit 20. The broadcast receiver is operated by generating a control signal RT based on the above and supplying it to each unit.

  In the broadcast receiving apparatus configured as described above, when determining the state of the emergency warning broadcast activation flag during the standby operation, it is necessary to keep the tuner unit 15 and the reception signal processing unit 20 in the energized state, which increases standby power. End up. For this reason, in the invention of Patent Document 1, a transmission control signal receiving device that extracts TMCC data including an emergency warning broadcast activation flag is newly provided, and power supply to the received signal processing unit 20 and the like is stopped during standby operation. As a result, standby power is being reduced.

JP 2005-333512 A

  By the way, if a transmission control signal receiving apparatus is newly provided, the circuit scale increases and the cost increases. Furthermore, since a space for providing a transmission control signal receiving device is also required, it is not easy to newly provide a transmission control signal receiving device. Further, standby power in the broadcast receiving apparatus can be reduced, but power consumption occurs in the transmission control signal receiving apparatus.

  In view of the above, according to the present invention, it is possible to determine an emergency warning broadcast activation flag during standby operation with a small standby power and an easy configuration.

  The concept of the present invention is that, in standby operation, when determining an emergency warning broadcast activation flag provided in transmission multiplex control data transmitted by terrestrial digital broadcasting, demodulation processing of a received signal of a selected transmission channel And first signal processing for obtaining transmission multiplex control data by performing decoding processing of the demodulated data obtained by this demodulation processing, and second processing for obtaining the transport stream by processing the demodulated data obtained by this demodulation processing The signal processing operation is controlled so that only transmission multiplexing control data can be obtained.

  In the present invention, when the emergency warning broadcast activation flag provided in the transmission multiplex control data is determined during the standby operation, for example, the supply of the clock signal necessary for performing the second signal processing is stopped. Only transmission multiplex control data can be obtained by performing only the first signal processing. Further, it is assumed that only the transmission multiplexing control data is obtained by stopping the supply of the clock signal necessary for performing the second signal processing and performing only the first signal processing. In the first signal processing, only the transmission multiplex control data is obtained by performing partial reception by switching the number of segments to be processed when demodulating the received signal.

  According to the present invention, when the emergency warning broadcast activation flag provided in the transmission multiplex control data transmitted by the terrestrial digital broadcast is determined during the standby operation, the received signal of the selected transmission channel is demodulated. And first signal processing for obtaining transmission multiplex control data by performing decoding processing of the demodulated data obtained by this demodulation processing, and second processing for obtaining the transport stream by processing the demodulated data obtained by this demodulation processing For the signal processing operation, the signal processing operation is controlled so that only transmission multiplexing control data can be obtained. For this reason, the power consumption caused by the signal processing operation is reduced, and the emergency warning broadcast activation flag can be determined in the standby operation with a small standby power and an easy configuration.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In Japanese terrestrial digital broadcasting signals, as shown in FIG. 2, 6 MHz, which is a transmission path bandwidth, is divided into 14 blocks called segments, and 13 segments are used for transmission. In each segment, not only video and audio data but also various control data are transmitted simultaneously. This control data includes TMCC data, SP (Scattered Pilot) data, CP (Continual Pilot) data, and AC (Auxiary Channel) data.

  The terrestrial digital broadcasting broadcasting system defines three types of modes: mode 1 suitable for mobile reception, mode 3 suitable for SFN (Single Frequency Network), and mode 2 in an intermediate position between the two. Has been.

  FIG. 3 shows a frame structure of a segment when, for example, in mode 1, FIG. 3A shows a case where the symbol modulation method is the DQPSK method, and FIG. 3B shows a case where the symbol modulation method is QPSK. This is the case of the 16QAM and 64QAM systems, and not only the data symbol “s” based on data such as video and audio but also control data is provided.

  SP data is a signal for enabling estimation of transmission path characteristics when QPSK, 16QAM, or 64QAM is used as a symbol modulation method. Data is corrected by correcting a data symbol according to an estimation result. The symbol is a synchronized signal. The CP data is for synchronization. AC data is a symbol for transmitting additional information. Also, the TMCC data transmitted in each segment is the same.

  FIG. 4 shows a frame structure of TMCC data. The frame of TMCC data is provided with “frame synchronization”, “segment format identification”, “system identification”, “emergency warning broadcast activation flag”, “transmission parameter etc.”, “parity”, and the like. “Frame synchronization” is a synchronization signal of TMCC data. “Segment type identification” is information indicating differential modulation or synchronous modulation. “System identification” is information that makes it possible to identify whether a digital television broadcast or a digital audio broadcast. The “emergency warning broadcast activation flag” is information indicating whether or not emergency warning broadcasting is being performed. “Transmission parameter etc.” is information indicating the carrier modulation mapping method, the convolutional coding rate, the length of time interleaving, the number of segments, and the like.

  Next, the configuration of the received signal processing unit 20 of the broadcast receiving apparatus will be described with reference to FIG. The reception signal SIF supplied from the tuner unit 15 shown in FIG. 1 is supplied to the first signal processing unit 20a. The first signal processing unit 20a is for obtaining TMCC data including an emergency warning broadcast activation flag by performing demodulation processing of the received signal SIF and decoding processing of the demodulated data obtained by the demodulation processing. , An A / D converter 21, an OFDM demodulator 22, and a TMCC data decoder 23. The second signal processing unit 20b processes the demodulated data obtained by the first signal processing unit 20a to obtain a transport stream, and includes a time-frequency deinterleaving unit 24, a demapping unit 25, and an error correction process. A portion 26 is provided.

  In the reception signal processing unit 20 configured as described above, the reception signal SIF supplied from the tuner unit 15 is converted into a digital reception signal DIF by the A / D conversion unit 21 and supplied to the OFDM demodulation unit 22.

  FIG. 6 shows the configuration of the OFDM demodulator 22. The orthogonal demodulation unit 221 performs orthogonal demodulation of the received signal DIF using a carrier signal having a predetermined frequency (carrier frequency), and outputs an OFDM baseband signal DIQ. This OFDM baseband signal DIQ is a complex signal composed of a real axis component (I channel signal) and an imaginary axis component (Q channel signal) as a result of orthogonal demodulation. The OFDM baseband signal DIQ output from the orthogonal demodulation unit 221 is supplied to the FFT operation unit 223 and the synchronization processing unit 225.

  The FFT operation unit 223 performs an FFT (Fast Fourier Transform) operation on the OFDM baseband signal DIQ, and extracts and outputs a signal that is orthogonally modulated on each subcarrier. The FFT operation unit 223 extracts an effective symbol length signal obtained by removing a signal corresponding to the guard interval length from one OFDM symbol, and performs an FFT operation on the extracted signal.

  The signal DSC modulated on each subcarrier extracted by the FFT operation unit 223 is a complex signal composed of a real axis component (I channel signal) and an imaginary axis component (Q channel signal). The signal DSC extracted by the FFT operation unit 223 is supplied to the frame extraction unit 224, the synchronization processing unit 225, the equalization processing unit 226, and the TMCC data decoding unit 23 shown in FIG.

  The frame extraction unit 224 supplies the boundary of the ISDB-T transmission frame to the synchronization processing unit 225 and the like using the signal DSCt based on the TMCC data in the signal DSC. Further, the frame extraction unit 224 supplies the signal DSCt based on the TMCC data to the TMCC data decoding unit 23 shown in FIG.

  The synchronization processing unit 225 generates the synchronization control signal CY using the OFDM baseband signal DIQ and the signal DSC modulated on each subcarrier demodulated by the FFT operation unit 223. In addition, the synchronization processing unit 225 supplies the generated synchronization control signal CY to the FFT calculation unit 223, thereby performing various synchronization processes such as the calculation range and timing of the FFT calculation in the FFT calculation unit 223.

  The equalization processing unit 226 performs equalization processing on the signal DSC supplied from the FFT operation unit 223. Here, the TMCC data DTM is supplied from the TMCC data decoding unit 23 to the equalization processing unit 226, and the TMCC data DTM indicates that it is a differential modulation signal (DQPSK system signal). In some cases, equalization processing corresponding to the differential modulation signal is performed. When the TMCC data DTM indicates that the signal is a synchronous modulation signal (QPSK, 16QAM, or 64QAM), equalization processing corresponding to the synchronous modulation signal is performed. The demodulated signal DDM equalized by the equalization processing unit 226 is supplied to the time-frequency deinterleaving unit 24 shown in FIG.

  The TMCC data decoding unit 23 shown in FIG. 5 performs a decoding process on the signal DSCt based on the TMCC data to generate TMCC data DTM. Also, the TMCC data decoding unit 23 converts the generated TMCC data DTM into an equalization processing unit 226 of the OFDM demodulation unit 22, a time-frequency deinterleaving unit 24, a demapping unit 25, an error correction processing unit 26, and a control unit 51 shown in FIG. Etc. In the decoding process of the signal DSCt based on the TMCC data, since the TMCC data DTM is modulated by the DBPSK (Differential Binary Phase Shift Keying) method to be subcarriers, the demodulation process by the DBPSK method is performed. The TMCC data decoding unit 23 also performs error correction processing in order to obtain correct TMCC data DTM.

  The time-frequency deinterleaving unit 24 performs deinterleaving processing in the time-frequency direction on the demodulated signal DDM and supplies it to the demapping unit 25.

  The demapping unit 25 performs a data reassignment process (demapping process) on the signal after the time-frequency deinterleaving process, restores the transmission data sequence, and supplies it to the error correction processing unit 26. For example, when demodulating an OFDM signal conforming to ISDB-T (Integrated Services Digital Broadcasting-Terrestrial) standard, the demapping unit 25 performs demapping processing corresponding to QPSK, 16QAM, or 64QAM.

  The error correction processing unit 26 performs a Viterbi decoding process or a Reed-Solomon decoding process using the signal supplied from the demapping unit 25 to generate a transport stream TS that is an error-corrected stream, and performs the decoding in FIG. Supply to the multiplexer 41. The error correction processing unit 26 also performs deinterleaving processing corresponding to bit interleaving for error dispersion of multilevel symbols, deinterleaving processing in byte units, energy despreading processing corresponding to energy spreading processing, and the like.

  The clock generation unit 27 is for generating a clock signal CLK for operating each part of the reception signal processing unit 20. A clock supply control unit 28 is connected to the clock generation unit 27.

  The clock supply control unit 28 controls the supply of the clock signal CLK to the second signal processing unit 20b based on the control signal RTck from the processing control unit 30.

  The processing control unit 30 communicates with the control unit 51 and controls the operation of each unit of the reception signal processing unit 20 based on the control signal RT supplied from the control unit 51. Further, based on the TMCC data DTM obtained by the TMCC data decoding unit 23, the operation of the reception signal processing unit 20 is also controlled.

  Next, the operation of the broadcast receiving apparatus will be described. At the time of normal operation for outputting video data and audio data of a desired knitting channel, the control unit 51 controls the tuner unit 15 to select a transmission channel including the knitting channel selected by the user. The reception signal SIF obtained by the tuner unit 15 is supplied to the reception signal processing unit 20 to perform OFDM demodulation, time-frequency deinterleaving processing, demapping processing, error correction processing, and the like. The transport stream TS obtained by performing these processes is supplied to the demultiplexer 41. The demultiplexer 41 extracts the video data packet Dpv of the desired organization channel and supplies it to the video decoder 42. Further, the audio data packet Dpa of the desired organization channel is extracted and supplied to the audio decoder 43. Therefore, a desired program can be viewed by performing video display and audio output using the video data output from the video decoder 42 and the audio data output from the audio decoder 43.

  When the broadcast receiving device is set to determine the emergency warning broadcast activation flag during the standby operation, the control unit 51 controls the tuner unit 15 so that TMCC data can be received. The tuner unit 15 performs a channel selection operation based on the control signal RT from the control unit 51 and supplies the reception signal SIF to the reception signal processing unit 20.

  When the control signal RT from the control unit 51 indicates that the reception signal processing unit 20 indicates that the broadcast reception device is in a standby operation and is set to determine the emergency warning broadcast activation flag, the reception signal processing unit 20 The operations of the first signal processing unit 20a and the second signal processing unit 20b are controlled so that only the TMCC data DTM including the warning broadcast activation flag is obtained. For example, the supply of the clock signal CLK from the clock generation unit 27 is stopped to other than the minimum functional blocks necessary for obtaining the TMCC data DTM. Specifically, the clock signal is supplied to the first signal processing unit 20a of the reception signal processing unit 20 and the clock signal is supplied to the second signal processing unit 20b by the clock supply control unit 28. Stop. As a result, the operations of the time-frequency deinterleaving unit 24, the demapping unit 25, and the error correction processing unit 26 of the second signal processing unit 20b are stopped, so that the power consumption of the reception signal processing unit 20 is reduced and broadcast reception is performed. Standby power in the apparatus can be reduced.

  When it is necessary to output video data or audio data, the processing control unit 30 activates the clock supply control unit 28 by the control signal RTck so that the clock signal CLK is supplied to the second signal processing unit 20b. By controlling, the transport stream TS may be supplied to the demultiplexer 41.

  Further, in the above-described embodiment, since the operations of the first signal processing unit 20a and the second signal processing unit 20b are controlled so that only the TMCC data DTM is obtained, the minimum necessary for obtaining the TMCC data DTM is required. Although the supply of the clock signal CLK is stopped with respect to other than the limited functional blocks, the power consumption of the reception signal processing unit 20 can be more reliably reduced by stopping the power supply.

  FIG. 7 shows another configuration of the received signal processing unit in which power supply is controlled to reduce power consumption. In FIG. 7, portions corresponding to those in FIG. 5 are given the same reference numerals, and detailed description thereof is omitted. The reception signal processing unit 20 ′ is provided with a power supply control unit 29 for enabling the power supply to the second signal processing unit 20 b to be stopped. The power supply control unit 29 controls power supply to the second signal processing unit 20b based on the control signal RTpw from the processing control unit 30.

  When the reception signal processing unit 20 ′ indicates by the control signal RT from the control unit 51 that the broadcast reception device is in a standby operation and set to determine the emergency warning broadcast activation flag, In order to obtain only the TMCC data DTM including the emergency warning broadcast activation flag, the power supply is stopped for other than the minimum functional blocks necessary for obtaining the TMCC data DTM. Specifically, power is supplied to the first signal processing unit 20a and the clock generation unit 27 of the reception signal processing unit 20 ′, and the control from the processing control unit 30 is performed to the second signal processing unit 20b. Based on the signal RTpw, the power supply control unit 29 stops the supply of the power PW. As a result, the operations of the time-frequency deinterleaving unit 24, the demapping unit 25, and the error correction processing unit 26 of the second signal processing unit 20b are stopped, so that the power consumption of the reception signal processing unit 20 is reduced and broadcast reception is performed. Standby power in the apparatus can be more reliably reduced.

  By the way, the TMCC data DTM transmitted in each segment described above is assumed to be equal. Therefore, TMCC data DTM can be obtained without performing demodulation processing for all 13 segments. For this reason, the first signal processing unit 20a enables partial reception by switching the number of segments to be processed when demodulating received signals, and performs partial reception when determining the emergency warning broadcast activation flag during standby operation. As a result, the amount of signal processing in the first signal processing unit 20a is reduced, and the power consumption of the first signal processing unit 20a can be reduced.

  FIG. 8 shows another configuration of the OFDM demodulator where partial reception is possible by switching the number of segments to be processed when performing demodulation processing. In FIG. 8, portions corresponding to those in FIG. 6 are denoted by the same reference numerals, and detailed description thereof is omitted.

  The signal DIQ obtained by the orthogonal demodulation unit 221 is supplied to the filter unit 222. The filter unit 222 is configured so that the filter characteristics can be switched. For example, based on a control signal RTsg from the processing control unit 30, it is possible to switch between a filter characteristic that passes a signal for 13 segments and a filter characteristic that passes only a signal for one segment. The signal DIQ band-limited by the filter unit 222 is supplied to the FFT operation unit 223a.

  The FFT operation unit 223a is configured so that the number of FFT operation points can be switched. Here, when the broadcasting system is, for example, mode 1, based on the control signal RTsg from the processing control unit 30, the number of FFT calculation points “2048” for performing the 13-segment FFT calculation and the 1-segment FFT calculation are performed. For this reason, the number of FFT calculation points “256” can be switched. In the case of mode 3, based on a control signal from the processing control unit, the number of FFT calculation points “8192” for performing 13-segment FFT calculation and the number of FFT calculation points “1192” for performing one-segment FFT calculation “ “1024” can be switched.

  The synchronization processing unit 225a is configured to be able to switch the reproduction operation of the carrier frequency and the timing frequency. For example, based on the control signal RTsg from the processing control unit 30, switching between carrier frequency and timing frequency reproduction using CP data, SP data, TMCC data, and AC data for 13 segments or 1 segment is performed. It is configured to be possible.

  The equalization processing unit 226a is configured to be able to switch the number of segments to be demodulated. For example, based on the control signal RTsg from the processing control unit 30, it is possible to switch between processing for 13 segments and processing for 1 segment.

  Next, the operation when using the OFDM demodulator 22a will be described. When the control signal RT from the control unit 51 indicates that the processing control unit 30 is in a normal operation, the processing control unit 30 uses the control signal RTsg to pass the filter characteristic of the filter unit 222 through the signal for 13 segments. Switch to characteristics. In addition, the FFT computation unit 223a sets the FFT computation point number “8192” so as to perform 13-segment FFT computation. Further, the carrier frequency and timing frequency are reproduced by the synchronization processing unit 225a using 13 segments of CP data, SP data, TMCC data, and AC data, and the equalization processing unit 226a demodulates the 13 segments. Set to perform the targeted processing. By setting the OFDM demodulator 22a in this way, it is possible to generate video data and audio data based on 13 segment signals.

  Next, a case where the control signal RT from the control unit 51 indicates that the emergency warning broadcast activation flag is determined during the standby operation will be described. In this case, the processing control unit 30 switches the filter characteristic of the filter unit 222 to a filter characteristic that allows only one segment signal to pass based on the control signal RTsg. Further, the FFT calculation unit 223a sets the number of FFT calculation points to “1024” so as to perform, for example, one segment FFT calculation. Further, the carrier frequency and timing frequency are reproduced in the synchronization processing unit 225a by using each segment of CP data, SP data, TMCC data, and AC data, and the equalization processing unit 226a demodulates one segment. Set to perform the targeted processing.

  If the OFDM demodulator 22a is set in this way, the number of segments to be demodulated is less than that during normal operation when the emergency warning broadcast activation flag is set to be determined during standby operation. Since the power consumption of the first signal processing unit 20a is reduced, the standby power of the broadcast receiving apparatus can be reduced.

  Further, in the broadcast receiving apparatus, if the partial reception of the OFDM demodulator and the control of clock supply and power supply are performed together, the standby power of the broadcast receiving apparatus can be further reduced compared to the case where only one of them is performed.

  Here, in the case where the partial reception of the OFDM demodulator and the control of clock supply and power supply are performed in combination, the processing becomes easier if the partial reception and control of the supply of clock and power are performed in conjunction. That is, it is shown that the emergency warning broadcast activation flag is determined during the standby operation, and when the partial reception is performed by the control signal RTsg, the clock supply control unit 28 or the power supply control unit 29 uses the control signal RTsg. By controlling the operation, the supply of the clock signal CLK and the power PW to the second signal processing unit 20b is stopped. In this way, the processing control unit 30 does not need to individually control the operations of the OFDM demodulation unit 22a, the clock supply control unit 28, and the power supply control unit 29, and the control operation is simplified.

  In addition, since the standby power of the broadcast receiving apparatus is reduced by stopping the supply of clocks and power and performing partial reception, the circuit scale is large as in the case where a transmission control signal receiving apparatus is newly provided. There is no need to provide a space for the transmission control signal receiving device without increasing the cost or cost, and therefore it becomes possible to easily determine the emergency warning broadcast activation flag during standby operation. Of course, the reception signal processing units 20 and 20a may be configured by hardware, and each process may be performed by software.

It is a figure which shows the structure of a broadcast receiver. It is a figure which shows the segment structure of a transmission signal. It is a figure which shows the frame structure of a segment. It is a figure which shows the frame structure of TMCC data. It is a figure which shows the structure of a received signal processing part. It is a figure which shows the structure of an OFDM demodulation part. It is a figure which shows the other structure of a received signal processing part. It is a figure which shows the other structure of an OFDM demodulation part.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... Antenna, 15 ... Tuner part 20, 20 '... Received signal processing part, 20a ... 1st signal processing part, 20b ... 2nd signal processing part, 21 ... A / D conversion unit, 22, 22a ... OFDM demodulation unit, 23 ... TMCC data decoding unit, 24 ... time-frequency deinterleaving unit, 25 ... demapping unit, 26 ... error correction processing unit , 27 ... Clock generation unit, 28 ... Clock supply control unit, 29 ... Power supply control unit, 30 ... Processing control unit, 41 ... Demultiplexer, 42 ... Video decoder, 43 ... Audio decoder, 50 ... Bus, 51 ... Control part, 52 ... Input part, 53 ... Memory part, 221 ... Quadrature demodulator, 222 ... Filter part, 223 223a... FFT calculation unit, 224, 2 4a · · · frame extraction unit, 225,225a ··· synchronization processing unit, 226,226a ··· equalization processing unit

Claims (5)

A tuner unit that receives a terrestrial digital broadcast signal including broadcast content data and transmission multiplex control data provided with an emergency warning broadcast activation flag, and outputs a received signal of a desired transmission channel, and performs signal processing of the received signal In a broadcast receiving apparatus having a reception signal processing unit that outputs a transport stream,
In the received signal processing unit,
A first signal processing unit that obtains transmission multiplexing control data by performing demodulation processing of the received signal and decoding processing of demodulated data obtained by the demodulation processing;
A second signal processing unit that processes the demodulated data obtained by the first signal processing unit to obtain a transport stream;
A processing control unit for controlling operations of the first signal processing unit and the second signal processing unit;
The processing control unit controls operations of the first signal processing unit and the second signal processing unit so as to obtain only the transmission multiplexing control data when determining the emergency warning broadcast activation flag during standby operation. A broadcast receiver characterized by that. The reception signal processing unit is provided with a clock signal supply control unit that controls supply of a clock signal to at least the second signal processing unit,
The processing control unit controls the clock signal control unit to stop supplying the clock signal to the second signal processing unit when determining the emergency warning broadcast activation flag during standby operation. The broadcast receiving apparatus according to claim 1. The reception signal processing unit is provided with a power supply control unit that controls power supply to the second signal processing unit,
The processing control unit controls the power supply control unit to stop the power supply to the second signal processing unit when determining the emergency warning broadcast activation flag during standby operation. The broadcast receiving apparatus according to claim 1. The first signal processing unit enables partial reception by switching the number of segments to be processed when performing demodulation processing of the received signal;
The processing control unit controls the first signal processing unit to perform the partial reception and obtain the transmission multiplex control data when determining the emergency warning broadcast activation flag during standby operation. Item 2. The broadcast receiving device according to Item 1. A channel selection step of receiving a digital terrestrial broadcast signal including broadcast content data and transmission multiplex control data provided with an emergency warning broadcast activation flag and obtaining a reception signal of a desired transmission channel;
A first signal processing step of obtaining transmission multiplexing control data by performing demodulation processing of the received signal and decoding processing of demodulated data obtained by the demodulation processing;
A second signal processing step of processing demodulated data obtained by the demodulation processing and outputting a transport stream;
A processing control step for controlling the operations of the first signal processing step and the second signal processing step so as to obtain only the transmission multiplex control data when determining the emergency warning broadcast activation flag during standby operation; A broadcast receiving method characterized by the above.

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