JP2007259207A - Ofdm demodulator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the malfunction of an OFDM demodulator caused by using erroneous TMCC information for parameter updating. <P>SOLUTION: A demodulation unit (11) detects a TMCC signal contained in an input signal by implementing predetermined demodulation processing on the input signal modulated by an orthogonal frequency division multiplexing system. An error correction unit (12) performs error correction on TMCC information in the TMCC signal detected by the demodulation unit and judges whether the error correction is made successful. A first check unit (13) checks whether the TMCC information obtained by error correction operation of the error correction unit complies with the predetermined broadcast transmission standard or a broadcast operation standard. If the check through the first check unit is not passed, a notification unit (14) notifies that the TMCC information error-corrected by the error correction unit is erroneous. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an OFDM demodulator that demodulates a signal modulated in accordance with an Orthogonal Frequency Division Multiplex (OFDM) system.

In digital terrestrial broadcasting that transmits and receives broadcast signals modulated by OFDM, TMCC (Transmission and Multiplexing Configuration Control) signals superimposed on broadcast signals are used for system identification, partial reception, carrier modulation, convolutional coding rate, and interleaving. TMCC information (encoded part) indicating the length, the number of segments, and the like is included.
In the OFDM demodulator provided on the receiving side, first, DBPSK (Double Binary Phase Shift Keying) system demodulation processing is performed on a signal obtained by fast Fourier transform (FFT) of the received broadcast signal. The TMCC signal is detected. Then, error correction processing using the shortened code (184, 102) of the difference set cyclic code (273, 191) is performed on the TMCC information in the TMCC signal, and the success or failure of the error correction is determined. The TMCC information obtained by the error correction process is used for parameter update only when it is determined that error correction is successful. Techniques relating to such an OFDM demodulator are disclosed in Patent Documents 1 and 2, for example.
Japanese Patent Laid-Open No. 11-252189 JP 2002-218339 A

  In the OFDM demodulator, the TMCC information obtained by the error correction processing is determined even though it is determined that the error correction is successful due to an increase in the number of errors in the TMCC information in the TMCC signal accompanying the deterioration of the reception state. It may actually be wrong. In such a case, parameter updating is performed using incorrect TMCC information, and the OFDM demodulator may malfunction. If the OFDM demodulator malfunctions because incorrect TMCC information is used for parameter update, it is necessary to reset the OFDM demodulator. After the next parameter update, the main signal is demodulated for various interleave times. There is a problem that processing is not performed correctly.

  The present invention has been made in view of such a problem, and is to prevent erroneous operation of an OFDM demodulator due to erroneous TMCC information used for parameter updating.

  In the first embodiment of the present invention, the OFDM demodulator includes a demodulation unit, an error correction unit, a first check unit, and a notification unit. The demodulation unit detects a TMCC signal included in the input signal by performing a predetermined demodulation process on the input signal modulated by the orthogonal frequency division multiplexing method. The error correction unit performs error correction on the TMCC information in the TMCC signal detected by the demodulation unit, and determines whether the error correction is successful. The first inspection unit inspects whether the TMCC information obtained by the error correction operation of the error correction unit conforms to at least one of a predetermined broadcast transmission standard and broadcast operation standard. When the inspection by the first inspection unit fails, the notification unit notifies that the TMCC information that has been error-corrected by the error correction unit is incorrect.

  In terrestrial digital broadcasting, what kind of TMCC information is transmitted is determined in accordance with broadcast transmission standards and broadcast operation standards. Therefore, even if the error correction unit determines that the error correction is successful, if the TMCC information obtained by the error correction operation of the error correction unit does not comply with either the broadcast transmission standard or the broadcast operation standard, the TMCC at that time It can be assumed that the information is incorrect. Focusing on this, in the above-described OFDM demodulator, even if the error correction unit determines that the error correction is successful, if the check by the first check unit does not pass, the TMCC information at that time is erroneously displayed by the notification unit. Be notified. Therefore, it is possible to prevent erroneous operation of the OFDM demodulator due to incorrect TMCC information used for parameter update.

In a preferred example of the first aspect of the present invention, the first inspection unit inspects the TMCC information obtained by the error correction operation of the error correction unit in parallel for a plurality of inspection items. Thereby, the test | inspection with respect to TMCC information by a 1st test | inspection part can be implemented in a short time.
In a preferred example of the first aspect of the present invention, the first inspection unit sequentially inspects TMCC information obtained by the error correction operation of the error correction unit for a plurality of inspection items. The first inspection unit omits subsequent inspections when the inspection for any of the plurality of inspection items fails. Therefore, the power consumption peak of the OFDM demodulator can be reduced as compared with the case where TMCC information is inspected in parallel for a plurality of inspection items.

  In a preferred example of the first aspect of the present invention, the OFDM demodulator further comprises a second inspection unit. The second checking unit sequentially stores a predetermined number of TMCC information corrected by the error correcting unit, and checks whether the stored TMCC information matches. The notification unit notifies that the TMCC information that has been error-corrected by the error correction unit is incorrect even when the inspection by the second inspection unit fails.

  Even when the error correction unit determines that the error correction is successful, if the TMCC information at that time does not match the previous TMCC information, it can be estimated that the TMCC information at that time is incorrect. By paying attention to this, in the above-described OFDM demodulator, a notification is given if the error correction unit determines that the error correction has been successful and the test by the second test unit does not pass even if the test by the first test unit passes. Is notified that the TMCC information at that time is incorrect. For this reason, it can prevent more reliably that incorrect TMCC information is used for parameter update, and an OFDM demodulator malfunctions.

  In the second embodiment of the present invention, the OFDM demodulator includes a demodulator, an error corrector, an inspection unit, and a notification unit. The demodulation unit detects a TMCC signal included in the input signal by performing a predetermined demodulation process on the input signal modulated by the orthogonal frequency division multiplexing method. The error correction unit performs error correction on the TMCC information in the TMCC signal detected by the demodulation unit, and determines whether the error correction is successful. The inspection unit sequentially accumulates a predetermined number of TMCC information errors corrected by the error correction unit, and inspects whether the accumulated TMCC information matches. If the inspection by the inspection unit fails, the notification unit notifies that the TMCC information that has been error-corrected by the error correction unit is incorrect.

  Even when the error correction unit determines that the error correction is successful, if the TMCC information at that time does not match the previous TMCC information, it can be estimated that the TMCC information at that time is incorrect. Paying attention to this, in the above-described OFDM demodulator, even if the error correction unit determines that the error correction is successful, if the check by the check unit does not pass, the TMCC information at that time is incorrect by the notification unit Will be notified. Therefore, it is possible to prevent erroneous operation of the OFDM demodulator due to incorrect TMCC information used for parameter update.

  According to the present invention, it is possible to prevent erroneous operation of the OFDM demodulator due to incorrect TMCC information used for parameter updating.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a first embodiment of the present invention. FIG. 2 shows the bit structure of the TMCC signal. FIG. 3 shows inspection items for TMCC information. The OFDM demodulator 10 of the first embodiment includes a DBPSK demodulator 11, a TMCC decoder 12, a TMCC information checker 13, and an error flag output unit 14. In FIG. 1, only the part related to the processing of the TMCC signal in the OFDM demodulator 10 is illustrated.

  The DBPSK demodulator 11 detects and outputs a TMCC signal included in the input signal IN by performing a DBPSK demodulation process on the input signal IN. For example, the input signal IN is a signal obtained by performing a fast Fourier transform on a terrestrial digital broadcast signal (received signal). As shown in FIG. 2, the TMCC signal is a 204-bit signal that conforms to the ISDB-T (Integrated Services Digital Broadcasting-Terrestrial) standard, which is a Japanese terrestrial digital broadcasting standard.

  The TMCC decoding unit 12 performs error correction processing on the TMCC information (bits 20 to 121) in the TMCC signal output from the DBPSK demodulation unit 11 using a shortened code of the difference set cyclic code, and performs error correction processing. Is output as TMCC information PAR. Also, the TMCC decoding unit 12 determines whether or not error correction is successful, deactivates the determination result signal JR0 when it is determined that error correction is successful, and activates the determination result signal JR0 when it is determined that error correction has failed. .

  The TMCC information inspection unit 13 includes inspection circuits CA1 to CA9 and a determination circuit JA1. The inspection circuit CA1 (CA2 to CA9) acquires the TMCC information PAR and determines whether the inspection item 1 (2 to 9) shown in FIG. 3 is satisfied when the TMCC decoding unit 12 determines that the error correction is successful. . The inspection circuit CA1 (CA2 to CA9) deactivates the inspection result signal CR1 (CR2 to CR9) when the inspection passes and activates the inspection result signal CR1 (CR2 to CR9) when the inspection fails. Let Here, the inspection items 1 to 8 correspond to items for inspecting whether the TMCC information PAR conforms to the broadcast transmission standard. The inspection item 9 corresponds to an item for inspecting whether the TMCC information PAR conforms to the broadcast operation standard in the broadcast transmission standard. In the present embodiment, the number of inspection items (inspection circuits) is nine, but it goes without saying that the number of inspection items (inspection circuits) may be smaller or larger than nine. . The determination circuit JA1 determines that the TMCC information PAR is correct when all the inspection result signals CR1 to CR9 are inactivated, and deactivates the determination result signal JR1. The determination circuit JA1 determines that the TMCC information PAR is incorrect when at least one of the inspection result signals CR1 to CR9 is activated, and activates the determination result signal JR1.

  The error flag output unit 14 deactivates the error flag signal EF in order to notify that the TMCC information PAR is correct when both the determination result signals JR0 and JR1 are deactivated. The error flag output unit 14 activates the error flag signal EF to notify that the TMCC information PAR is incorrect when at least one of the determination result signals JR0 and JR1 is activated. In the OFDM demodulator 10, the parameter update is performed using the TMCC information PAR only when the error flag signal EF is deactivated. That is, in the OFDM demodulator 10, when the error flag signal EF is activated, parameter updating is not performed using the TMCC information PAR.

  FIG. 4 shows the operation of the OFDM demodulator of FIG. In the OFDM demodulator 10 configured as described above, first, the DBPSK demodulator 11 performs DBPSK demodulation processing on the input signal IN, and detects the TMCC signal included in the input signal IN (step S11). Next, the TMCC decoding unit 12 performs error correction processing on the TMCC information in the TMCC signal (step S12). Then, success or failure of error correction is determined by the TMCC decoding unit 12 (step S13).

  When the TMCC decoding unit 12 determines that the error correction is successful, the TMCC information inspection unit 13 (inspection circuits CA1 to CA9 and determination circuit JA1) checks whether the TMCC information PAR satisfies all the inspection items 1 to 9. (Step S14). When the inspection by the TMCC information inspection unit 13 passes, the error flag output unit 14 deactivates the error flag signal EF (step S15). And parameter update is implemented using the TMCC information PAR at this time. (Step S16). On the other hand, when it is determined that the error correction has failed by the TMCC decoding unit 12, or when the inspection by the TMCC information inspection unit 13 fails, the error flag output unit 14 activates the error flag signal EF (step S17). . Accordingly, parameter updating is not performed using the TMCC information PAR at this time.

  In the first embodiment as described above, even when the TMCC decoding unit 12 determines that the error correction is successful, the TMCC information inspection unit 13 checks (TMCC information PAR conforms to at least one of the broadcast transmission standard and the broadcast operation standard). If the error flag signal EF is not passed, the error flag output unit 14 activates the error flag signal EF. Therefore, it is possible to prevent the OFDM demodulator 10 from malfunctioning due to erroneous TMCC information PAR being used for parameter update.

  FIG. 5 shows a comparative example of the present invention. In describing the comparative example, the same elements as those described in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. The OFDM demodulator 90 of the comparative example is configured by removing the TMCC information inspection unit 13 and the error flag output unit 14 from the OFDM demodulator 10 of the first embodiment, and replacing the TMCC decode unit 12 with a TMCC decode unit 92. Has been. The TMCC decoding unit 92 performs error correction processing using the shortened code of the difference set cyclic code on the TMCC information in the TMCC signal output from the DBPSK demodulation unit 11, and the data after the error correction processing is completed Output as information PAR. Further, the TMCC decoding unit 92 determines whether or not the error correction is successful, deactivates the error flag signal EF when it is determined that the error correction is successful, and activates the error flag signal EF when it is determined that the error correction has failed. .

  FIG. 6 shows the operation of the OFDM demodulator of FIG. In the OFDM demodulator 90 configured as described above, first, the DBPSK demodulator 11 performs DBPSK demodulation processing on the input signal IN, and detects the TMCC signal included in the input signal IN (step S91). Next, the TMCC decoding unit 92 performs error correction processing on the TMCC information in the TMCC signal (step S92). Then, the success or failure of error correction is determined by the TMCC decoding unit 92 (step S93).

  When the TMCC decoding unit 92 determines that the error correction is successful, the TMCC decoding unit 92 deactivates the error flag signal EF (step S94). And parameter update is implemented using the TMCC information PAR at this time. (Step S95). On the other hand, if the TMCC decoding unit 92 determines that the error correction has failed, the TMCC decoding unit 92 activates the error flag signal EF (step S96). Accordingly, parameter updating is not performed using the TMCC information PAR at this time.

In the comparative example as described above, if the TMCC information PAR is actually erroneous even though the error flag signal EF is deactivated even though the error correction signal is determined to be successful by the TMCC decoding unit 92, an error occurs. There is a possibility that the OFDM demodulator 90 malfunctions because the TMCC information PAR is used for parameter update.
FIG. 7 shows a second embodiment of the present invention. In describing the second embodiment, the same elements as those described in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. The OFDM demodulator 20 according to the second embodiment is configured by replacing the TMCC information inspection unit 13 with a TMCC information inspection unit 23 with respect to the OFDM demodulator 10 according to the first embodiment.

  The TMCC information inspection unit 23 includes inspection circuits CB1 to CB9 and a determination circuit JB1. The inspection circuit CB1 acquires TMCC information PAR and inspects whether or not the inspection item 1 is satisfied when the TMCC decoding unit 12 determines that the error correction is successful. When the inspection passes, the inspection circuit CB1 deactivates the inspection result signal CR1 and outputs the inspected TMCC information. The inspection circuit CB1 activates the inspection result signal CR1 when the inspection fails.

  The inspection circuit CB2 (CB3 to CB8) acquires TMCC information output from the inspection circuit CB1 (CB2 to CB7) along with the inspection path by the inspection circuit CB1 (CB2 to CB7), and performs inspection item 2 (3 to 3). 8) Inspect whether it is satisfied. When the inspection passes, the inspection circuit CB2 (CB3 to CB8) deactivates the inspection result signal CR2 (CR3 to CR8) and outputs the inspected TMCC information. The inspection circuit CB2 (CB3 to CB8) activates the inspection result signal CR2 (CR3 to CR8) when the inspection fails. The inspection circuit CB9 obtains TMCC information output from the inspection circuit 8 along with the inspection path by the inspection circuit CB8, and inspects whether the inspection item 9 is satisfied. The inspection circuit CB9 deactivates the inspection result signal CR9 when the inspection passes and activates the inspection result signal CR9 when the inspection fails. The determination circuit JB1 determines that the TMCC information PAR is correct when all of the inspection result signals CR1 to CR9 are inactivated, and deactivates the determination result signal JR1. The determination circuit JB1 determines that the TMCC information PAR is incorrect when at least one of the inspection result signals CR1 to CR9 is activated, and activates the determination result signal JR1.

  FIG. 8 shows the operation of the OFDM demodulator of FIG. In the OFDM demodulator 20 configured as described above, first, the DBPSK demodulator 11 performs DBPSK demodulation processing on the input signal IN, and detects a TMCC signal included in the input signal IN (step S21). Next, the TMCC decoding unit 12 performs error correction processing on the TMCC information in the TMCC signal (step S22). Then, the success or failure of error correction is determined by the TMCC decoding unit 12 (step S23).

  When the TMCC decoding unit 12 determines that the error correction is successful, the TMCC information inspection unit 23 (inspection circuit CB1 and determination circuit JB1) checks whether the TMCC information PAR satisfies the inspection item 1 (step S241). When the inspection for inspection item 1 by the TMCC information inspection unit 23 passes, the TMCC information inspection unit 23 (inspection circuit CB2 and determination circuit JB1) inspects whether the TMCC information PAR satisfies the inspection item 2 (step S242). ). Thereafter, similarly, the TMCC information inspection unit 23 (inspection circuits CB3 to CB9 and determination circuit JB1) sequentially inspects whether the TMCC information PAR satisfies the inspection items 3 to 9 (steps S243 to S249).

  When the inspection of the inspection item 9 by the TMCC information inspection unit 23 passes, the error flag output unit 14 deactivates the error flag signal EF (step S25). And parameter update is implemented using the TMCC information PAR at this time. (Step S26). On the other hand, when it is determined that the error correction has failed by the TMCC decoding unit 12 or when any of the inspection items 1 to 9 by the TMCC information inspection unit 23 has not passed, the error flag signal is output by the error flag output unit 14. EF is activated (step S27). Accordingly, parameter updating is not performed using the TMCC information PAR at this time.

Even in the second embodiment as described above, the same effect as in the first embodiment can be obtained. In the second embodiment, whether the TMCC information PAR satisfies the inspection items 1 to 9 is sequentially checked, so that the power consumption peak of the OFDM demodulator can be reduced as compared with the first embodiment.
FIG. 9 shows a third embodiment of the present invention. In describing the third embodiment, the same elements as those described in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. The OFDM demodulator 30 according to the third embodiment replaces the OFDM demodulator 10 according to the first embodiment by replacing the TMCC information check unit 13 and the error flag output unit 14 with a TMCC information check unit 33 and an error flag output unit 34, respectively. Configured.

  The TMCC information inspection unit 33 includes buffers BA1 to BAn and a determination circuit JA2. The buffer BA1 acquires the TMCC information PAR when the TMCC decoding unit 12 determines that the error correction is successful. The buffer BA2 (BA3 to BAn) acquires the data held in the buffer BA1 (BA2 to BAn-1) when the TMCC decoding unit 12 determines that the error correction is successful.

  The determination circuit JA2 compares the data held in the buffer BA1 (current TMCC information PAR) with the data held in the buffers BA2 to BAn (past TMCC information PAR). However, the determination circuit JA2 does not compare parameters that change during an emergency or parameter update (such as a countdown signal or an emergency signal). The determination circuit JA2 determines that the TMCC information PAR is correct when the data held in the buffer BA1 matches the data held in the buffers BA2 to BAn, and deactivates the determination result signal JR2. When the data held in the buffer BA1 does not match the data held in the buffers BA2 to BAn, the determination circuit JA2 determines that the TMCC information PAR is incorrect and activates the determination result signal JR2.

  The error flag output unit 34 deactivates the error flag signal EF to notify that the TMCC information PAR is correct when both the determination result signals JR0 and JR2 are deactivated. The error flag output unit 34 activates the error flag signal EF to notify that the TMCC information PAR is incorrect when at least one of the determination result signals JR0 and JR2 is activated.

  FIG. 10 shows the operation of the OFDM demodulator of FIG. In the OFDM demodulator 30 configured as described above, first, the DBPSK demodulator 11 performs DBPSK demodulation processing on the input signal IN, and detects the TMCC signal included in the input signal IN (step S31). Next, the TMCC decoding unit 12 performs error correction processing on the TMCC information in the TMCC signal (step S32). Then, the success or failure of error correction is determined by the TMCC decoding unit 12 (step S33).

  When the TMCC decoding unit 12 determines that the error correction is successful, the TMCC information checking unit 33 (buffers BA1 to BAn and the determination circuit JA2) checks whether the current TMCC information PAR matches the past TMCC information PAR. (Step S34). When the inspection by the TMCC information inspection unit 33 passes, the error flag output unit 34 deactivates the error flag signal EF (step S35). And parameter update is implemented using the TMCC information PAR at this time. (Step S36). On the other hand, if it is determined by the TMCC decoding unit 12 that the error correction has failed, or if the inspection by the TMCC information inspection unit 33 fails, the error flag output unit 34 activates the error flag signal EF (step S37). . Accordingly, parameter updating is not performed using the TMCC information PAR at this time.

  In the third embodiment as described above, even if it is determined that the error correction is successful by the TMCC decoding unit 12, the test by the TMCC information test unit 33 (checks whether the current TMCC information PAR matches the past TMCC information PAR). ) Does not pass, the error flag output unit 34 activates the error flag signal EF. Therefore, it is possible to prevent the OFDM demodulator 30 from malfunctioning due to erroneous TMCC information PAR being used for parameter update.

  FIG. 11 shows a fourth embodiment of the present invention. In describing the fourth embodiment, the same elements as those described in the first and third embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. The OFDM demodulator 20 of the fourth embodiment is configured by adding a TMCC information inspection unit 43 to the OFDM demodulator 10 of the first embodiment and replacing the error flag output unit 14 with an error flag output unit 44. Yes.

  The TMCC information inspection unit 43 includes buffers BB1 to BBn and a determination circuit JB2. The buffer BB1 acquires the TMCC information PAR when determining that the TMCC information PAR by the determination circuit JA1 of the TMCC information inspection unit 13 is correct. The buffer BB2 (BB3 to BBn) acquires data held in the buffer BB1 (BB2 to BBn-1) when the TMCC information PAR by the determination circuit JA1 of the TMCC information inspection unit 13 is determined to be correct.

  The determination circuit JB2 compares the data held in the buffer BB1 (current TMCC information PAR) with the data held in the buffers BB2 to BBn (past TMCC information PAR). However, the determination circuit JB2 does not compare parameters that change during an emergency or parameter update (such as a countdown signal or an emergency signal). When the data held in the buffer BB1 matches the data held in the buffers BB2 to BBn, the determination circuit JB2 determines that the TMCC information PAT is correct and deactivates the determination result signal JR2. When the data held in the buffer BB1 does not match the data held in the buffers BB2 to BBn, the determination circuit JB2 determines that the TMCC information PAR is incorrect and activates the determination result signal JR2.

  When all of the determination result signals JR0 to JR2 are inactivated, the error flag output unit 44 deactivates the error flag signal EF to notify that the TMCC information PAR is correct. When at least one of the determination result signals JR0 to JR2 is activated, the error flag output unit 44 activates the error flag signal EF to notify that the TMCC information PAR is incorrect.

  FIG. 12 shows the operation of the OFDM demodulator of FIG. In the OFDM demodulator 40 configured as described above, first, the DBPSK demodulator 11 performs DBPSK demodulation processing on the input signal IN, and detects the TMCC signal included in the input signal IN (step S41). Next, the error correction process is performed on the TMCC information in the TMCC signal by the TMCC decoding unit 12 (step S42). Then, the success / failure of error correction is determined by the TMCC decoding unit 12 (step S43).

  When the TMCC decoding unit 12 determines that the error correction is successful, the TMCC information inspection unit 13 (inspection circuits CA1 to CA9 and determination circuit JA1) checks whether the TMCC information PAR satisfies all the inspection items 1 to 9. (Step S44). When the inspection by the TMCC information inspection unit 13 passes, the TMCC information inspection unit 43 (buffers BB1 to BBn and the determination circuit JB2) checks whether the current TMCC information PAR matches the past TMCC information PAR (step) S45). When the inspection by the TMCC information inspection unit 43 passes, the error flag output unit 44 deactivates the error flag signal EF (step S46). And parameter update is implemented using the TMCC information PAR at this time. (Step S47).

  On the other hand, if it is determined that the error correction has failed by the TMCC decoding unit 12, if the inspection by the TMCC information inspection unit 13 fails, or if the inspection by the TMCC information inspection unit 43 fails, the error flag output unit 44 The error flag signal EF is activated (step S48). Accordingly, parameter updating is not performed using the TMCC information PAR at this time.

  Also in the fourth embodiment as described above, the same effect as in the first embodiment can be obtained. Further, in the fourth embodiment, even if it is determined that the error correction is successful by the TMCC decoding unit 12 and the inspection by the TMCC information inspection unit 13 passes, if the inspection by the TMCC information inspection unit 43 does not pass, the error flag output unit 44 activates the error flag signal EF. Therefore, it is possible to more reliably prevent erroneous operation of the OFDM demodulator 40 due to erroneous TMCC information PAR being used for parameter update.

  FIG. 13 shows a fifth embodiment of the present invention. In describing the fifth embodiment, the same elements as those described in the first to fourth embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. The OFDM demodulator 50 according to the fifth embodiment is configured by replacing the OFDM demodulator 40 according to the fourth embodiment by replacing the TMCC information inspection unit 13 with the TMCC information inspection unit 23 according to the second embodiment. In the TMCC information inspecting unit 43, the buffer BB1 acquires the TMCC information PAR when it is determined that the TMCC information PAR is correct by the judging circuit JB1 of the TMCC information inspecting unit 23. The buffer BB2 (BB3 to BBn) acquires the data held in the buffer BB1 (BB2 to BBn-1) when determining that the TMCC information PAR is correct by the determination circuit JB1 of the TMCC information inspection unit 23.

  FIG. 14 shows the operation of the OFDM demodulator of FIG. In the OFDM demodulator 50 configured as described above, first, the DBPSK demodulator 11 performs DBPSK demodulation processing on the input signal IN, and detects the TMCC signal included in the input signal IN (step S51). Next, the TMCC decoding unit 12 performs error correction processing on the TMCC information in the TMCC signal. (Step S52). Then, the success / failure of error correction is determined by the TMCC decoding unit 12 (step S53).

  When the TMCC decoding unit 12 determines that the error correction is successful, the TMCC information inspection unit 23 (inspection circuit CB1 and determination circuit JB1) checks whether the TMCC information PAR satisfies the inspection item 1 (step S541). When the inspection for inspection item 1 by the TMCC information inspection unit 23 passes, the TMCC information inspection unit 23 (inspection circuit CB2 and determination circuit JB1) inspects whether the TMCC information PAR satisfies the inspection item 2 (step S542). ). Thereafter, similarly, the TMCC information inspection unit 23 (inspection circuits CB3 to CB9 and determination circuit JB1) sequentially inspects whether the TMCC information PAR satisfies the inspection items 3 to 9 (steps S543 to S549).

  When the inspection about the inspection item 9 by the TMCC information inspection unit 23 passes, the TMCC information inspection unit 43 (buffers BB1 to BBn and the determination circuit JB2) determines whether the current TMCC information PAR matches the past TMCC information PAR. Inspected (step S55). When the inspection by the TMCC information inspection unit 43 passes, the error flag output unit 44 deactivates the error flag signal EF (step S56). And parameter update is implemented using the TMCC information PAR at this time. (Step S57).

  On the other hand, when it is determined that the error correction has failed by the TMCC decoding unit 12, when any of the inspection items 1 to 9 by the TMCC information inspection unit 23 fails or the inspection by the TMCC information inspection unit 43 fails. If this happens, the error flag signal EF is activated by the error flag output unit 44 (step S58). Accordingly, parameter updating is not performed using the TMCC information PAR at this time. In the fifth embodiment as described above, the same effects as those of the first, second, and fourth embodiments can be obtained.

  In the first and fourth embodiments (second and fifth embodiments), TMCC information to be inspected by the TMCC information inspecting unit 13 (TMCC information inspecting unit 23) is subjected to error correction processing in the TMCC decoding unit 12. Although an example of data after completion has been described, the present invention is not limited to such an embodiment. For example, the TMCC information to be inspected by the TMCC information inspecting unit 13 (TMCC information inspecting unit 23) may be data during error correction processing in the TMCC decoding unit 12.

  As mentioned above, although this invention was demonstrated in detail, the above-mentioned embodiment and its modification are only examples of this invention, and this invention is not limited to these. Obviously, modifications can be made without departing from the scope of the present invention.

1 is a block diagram showing a first embodiment of the present invention. It is explanatory drawing which shows the bit structure of a TMCC signal. It is explanatory drawing which shows the test | inspection item with respect to TMCC information. It is a flowchart which shows operation | movement of the OFDM demodulation apparatus of FIG. It is a block diagram which shows the comparative example of this invention. FIG. 6 is a flowchart showing the operation of the OFDM demodulator in FIG. 5. It is a block diagram which shows 2nd Embodiment of this invention. It is a flowchart which shows operation | movement of the OFDM demodulation apparatus of FIG. It is a block diagram which shows 3rd Embodiment of this invention. FIG. 10 is a flowchart showing the operation of the OFDM demodulator of FIG. 9. It is a block diagram which shows 4th Embodiment of this invention. FIG. 12 is a flowchart showing the operation of the OFDM demodulator in FIG. 11. It is a block diagram which shows 5th Embodiment of this invention. It is a flowchart which shows operation | movement of the OFDM demodulation apparatus of FIG.

Explanation of symbols

10, 20, 30, 40, 50 OFDM demodulator; 11 DBPSK demodulator; 12 TMCC decoder; 13, 23, 33, 43 TMCC information checker; 14, 34, 44 error flag output unit; BA1 to BAn, BB1 to BBn... Buffer; CA1 to CA9, CB1 to CB9... Inspection circuit; JA1, JA2, JB1, JB2.

Claims (5)

A demodulation unit that detects a TMCC signal included in the input signal by performing predetermined demodulation processing on the input signal modulated by the orthogonal frequency division multiplexing method;
An error correction unit that corrects error of TMCC information in the TMCC signal and determines success or failure of the error correction;
A first inspection unit that inspects whether TMCC information obtained by the error correction operation of the error correction unit conforms to at least one of a predetermined broadcast transmission standard and a broadcast operation standard;
An OFDM demodulator comprising: a notification unit that notifies that the TMCC information that has been error-corrected by the error correction unit is in error when the inspection by the first inspection unit fails. The OFDM demodulator according to claim 1, wherein
The OFDM demodulator characterized in that the first check unit checks TMCC information obtained by the error correction operation of the error correction unit in parallel for a plurality of check items. The OFDM demodulator according to claim 1, wherein
The first inspection unit inspects the TMCC information obtained by the error correction operation of the error correction unit in order for a plurality of inspection items, and if the inspection for any of the plurality of inspection items fails, then An OFDM demodulator characterized by omitting the inspection. The OFDM demodulator according to claim 1, wherein
A second inspection unit that sequentially accumulates a predetermined number of TMCC information that has been error-corrected by the error correction unit and inspects whether the accumulated TMCC information matches,
The OFDM demodulator characterized in that the notification unit notifies that the TMCC information error-corrected by the error correction unit is incorrect even when the inspection by the second inspection unit fails. A demodulation unit that detects a TMCC signal included in the input signal by performing predetermined demodulation processing on the input signal modulated by the orthogonal frequency division multiplexing method;
An error correction unit that corrects error of TMCC information in the TMCC signal and determines success or failure of the error correction;
A test unit that sequentially accumulates a predetermined number of TMCC information that has been error-corrected by the error correction unit, and checks whether the stored TMCC information matches,
An OFDM demodulator comprising: a notification unit that notifies that the TMCC information that has been error-corrected by the error correction unit is incorrect when the inspection by the inspection unit fails.

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