JP2013214850A - Broadcasting receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a broadcasting receiver which prevents an un-reproduced announcement from being failed to hear and announcements of an identical content from being reproduced twice.SOLUTION: A digital broadcasting receiver comprises: an RF unit 10, an FE unit 20 and a BE unit 30 which receive broadcast signals and extract services and announcements; an output processing unit 32, an amplifier 34, and a speaker 36 which output a voice signal corresponding to each of the extracted services and announcements; a comparison unit 42 which compares the content of an announcement extracted this time with that of an announcement extracted last time to determine whether the contents are identical; and a switch unit 44 which, if the comparison unit 42 determines that the contents are not identical, issues a switch instruction to output the voice signal of the announcement.

Description

  The present invention relates to a broadcast receiver that receives program data and the like according to DAB (Digital Audio Broadcasting) / T-DMB (Terrestrial-digital media broadcasting) broadcasting standards.

  Conventionally, a DAB receiver that receives a digitally modulated broadcast signal is known (see, for example, Patent Document 1). In this DAB receiver, when a temporary announcement added to the normal service is received, the output of the voice corresponding to the normal service is interrupted and switched to the voice corresponding to the announcement. . This announcement is repeatedly sent multiple times with the same content, and by checking the content of the new flag, it is determined whether the announcement is new or the second or later. I can know. In the DAB receiver described above, only announcements with a new flag of “1” are to be played, so that even when announcements with the same content are repeatedly sent, they are listened to only once. It is possible to repeatedly reproduce the announcements that have been listened to, and to prevent frequent interruption of normal service audio output.

JP 2000-295126 A

  Incidentally, the DAB receiver disclosed in Patent Document 1 described above has the following problems when mounted on a vehicle.

  If the DAB receiver is turned off while the vehicle is stopped, or if you are traveling in a tunnel or other location where radio waves are difficult to reach, an announcement with the new flag set to “1” will be sent during that time. I cannot receive this announcement. Therefore, even if an announcement with the same content is received thereafter, the new flag is set to “0”, so it is excluded from the playback target, and even if an unplayed announcement is received, it will be missed. . On the other hand, for announcements received immediately after turning on the power or immediately after leaving the tunnel, it is possible to avoid such missed listening by setting it as the playback target regardless of the setting contents of the new flag. When the travel time is short, the announcement with the new flag “1” is not always transmitted during this short time, and the announcement having the same content is reproduced twice.

  The present invention was created in view of the above points, and its purpose is to provide a broadcast receiver that can prevent unplayed announcements from being heard and duplicated announcements having the same content. It is to provide.

  In order to solve the above-described problem, the broadcast receiver of the present invention outputs audio corresponding to a service included in a broadcast signal and switches to audio corresponding to an announcement temporarily inserted in the broadcast signal. In the broadcast receiver for outputting, receiving means for receiving broadcast signals and extracting services and announcements, audio output means for outputting audio signals corresponding to the services and announcements extracted by the receiving means, and receiving The announcement extracted by the means is compared with the announcement extracted last time, and the announcement comparison means for determining whether or not the contents are the same is determined by the announcement comparison means. Output the audio signal of the announcement from the audio output means And an announcement switching means for performing a switching instruction that.

  When an announcement contained in a broadcast signal is received, it is determined whether the content of this announcement is the same as the content of the announcement that has already been received, so only new announcements should be output. It is possible to prevent unannounced announcements from being missed and duplicate reproduction of announcements having the same content.

  Moreover, it is desirable that the above-mentioned announcement comparison means compare the contents of the announcement based on the compressed audio data corresponding to the announcement. By using compressed audio data for announcement comparison, comparison can be performed with a small amount of data, and the processing burden can be reduced.

  The compressed voice data described above includes first data indicating a voice waveform, second data indicating the presence or absence of a signal corresponding to each of a plurality of frequency bands for the voice waveform, and a plurality of frequency bands for the voice waveform. It is desirable that the announcement comparison means compare the contents of the announcement based on at least one of the second and third data. By performing the comparison using the second and third data indicating the characteristics instead of the speech waveform data itself, the comparison can be performed with a smaller amount of data, and the processing load can be reduced. .

  The compressed voice data described above includes first data indicating a voice waveform, second data indicating the presence or absence of a signal corresponding to each of a plurality of frequency bands for the voice waveform, and a plurality of frequency bands for the voice waveform. The third data indicating the signal level corresponding to each of the first data and the fourth data used for detecting that the third data includes an error, and the announcement comparing means includes: It is desirable to compare the contents of the announcement based on the fourth data. In general, the fourth data for error detection has a smaller amount of data than the third data to be error-detected, so that the processing load can be further reduced by performing comparison using the fourth data. it can.

  The compressed voice data described above includes first data indicating a voice waveform, second data indicating the presence or absence of a signal corresponding to each of a plurality of frequency bands for the voice waveform, and a plurality of frequency bands for the voice waveform. It is desirable that the announcement comparison means compare the contents of the announcement based on the first data. It is possible to confirm that the contents of the two announcements are the same by performing comparison using the first data indicating the speech waveform.

  Moreover, it is desirable that the above-mentioned announcement comparison means compare the contents of the announcement based on the data indicating the voice waveform. By using the data indicating the voice waveform, the announcements can be reliably compared regardless of the data compression format or the voice signal modulation method (digital / analog).

  Moreover, it is desirable that the above-described announcement comparison means adjusts the time lag between two announcements to be compared before comparing the contents of the announcements. As a result, for example, it is possible to eliminate the time lag between the start of transmission of the announcement and the actual reception and accumulation of the announcement at the receiver and the analysis of the content. Thus, it is possible to prevent erroneous determination that the announcements are not the same.

  In addition, the above-described announcement is associated with identification information indicating whether or not the announcement is retransmitted for the same content, and the announcement extracted by the receiving unit is not retransmitted. When it is detected based on the identification information that it has new contents, the announcement switching means issues a switching instruction to output the announcement audio signal from the audio output means, and the announcement comparison means is the announcement comparison means. It is desirable not to perform the content comparison operation. Thereby, since it is possible to omit the content comparison operation of the announcement when it is known that the announcement is new based on the identification information, it is possible to reduce the processing load accordingly.

  Further, it further comprises an announcement storage means for storing the announcement data extracted by the reception means described above, and the announcement switching means stores the announcement when it is determined that the announcement comparison means is not the same. It is desirable to read out the announcement data stored in the means and issue a switching instruction for outputting the announcement audio signal from the audio output means. Thereby, when the received announcement has not been reproduced, it is possible to reliably prevent the announcement from being missed.

  Further, an announcement storage means for storing a part of the data necessary for comparing the contents of the announcement from the announcement data extracted by the receiving means described above is provided, and the announcement switching means is an announcement comparison. When it is determined by the means that they are not the same, it is desirable to issue a switching instruction to output the announcement audio signal extracted next by the receiving means from the audio output means. Since the announcement storage means only needs to have a minimum capacity necessary for comparing the contents of announcements, the capacity of the announcement storage means can be reduced, and the cost of parts can be reduced.

It is a figure which shows the structure of the digital broadcast receiver of one Embodiment. It is a figure which shows the flame | frame structure of the broadcast signal according to DAB / T-DMB broadcast standard. It is a figure which shows the frame structure of MP2 data. It is a flowchart which shows the operation | movement procedure switched to the audio | voice of the received announcement. It is explanatory drawing of position alignment of MP2 data. It is explanatory drawing of the comparison operation | movement of the audio | voice waveform using MP2 data. It is a flowchart which shows the modification of the operation | movement procedure switched to the audio | voice of the received announcement. It is a flowchart which shows the other modification of the operation | movement procedure switched to the audio | voice of the received announcement. It is a flowchart which shows the other modification of the operation | movement procedure switched to the audio | voice of the received announcement.

  Hereinafter, a digital broadcast receiver according to an embodiment to which the present invention is applied will be described with reference to the drawings. FIG. 1 is a diagram illustrating a configuration of a digital broadcast receiver according to an embodiment. This digital broadcast receiver is for receiving a digital broadcast signal according to the DAB / T-DMB broadcast standard mainly used in Europe. For example, this digital broadcast receiver is mounted on a vehicle.

  As shown in FIG. 1, the digital broadcast receiver of this embodiment includes an RF unit 10, an FE (front end) unit 20, a BE (back end) unit 30, an output processing unit 32, an amplifier 34, a speaker 36, and main control. Unit 40, display device 50, operation unit 52, and memory 60.

  The digital broadcast receiver according to the present embodiment receives a digital broadcast signal broadcast by a multicarrier method using OFDM (Orthogonal Frequency Division Multiplexing) as a modulation method, performs demodulation processing and decoding processing, and reproduces audio data. To do. The RF unit 10 is a high-frequency circuit, and converts a broadcast signal received via the antenna 12 into an intermediate frequency signal. The FE unit 20 performs a demodulation process and a decoding process on the intermediate frequency signal output from the RF unit 10 to generate compressed audio data for each service and compressed audio data of various announcements inserted separately from the service. Output. For example, compressed audio data in MP2 (MPEG1 Audio Layer 2 and MPEG2 Audio Layer 2) format is output as compressed audio data.

  FIG. 2 is a diagram showing a frame structure of a broadcast signal according to the DAB / T-DMB broadcast standard. As shown in FIG. 2, the frame is composed of a synchronization channel, a first information channel FIC, and a main service channel MSC.

  The synchronization channel is composed of a NULL symbol and a phase reference symbol PRS (Phase Reference Symbol), and is used for frame synchronization by detecting the head portion of the frame. The first information channel FIC is an area for explaining the contents of the main service channel MSC, and includes time / date data, service (program) arrangement data, service label (name), service identification code SID (Service Identification). Code). A plurality of FIGs (first information groups) are energy-spread to form one FIB (first information block) which is a predetermined information unit. Each FIB is convolutionally encoded, and the three FIBs subjected to the convolutional coding constitute one FIC. The main service channel MSC mainly includes music data corresponding to each of a plurality of services. The main service channel MSC includes a plurality of sub-channels (SubCh) that are energy spread, convolutionally encoded, and time interleaved.

  This embodiment is characterized by a method of switching from voice output of various services to voice output of announcements. FIG (0/18) is used to specify announcement support for the broadcast signal (ensemble) being received. This FIG (0/18) includes an announcement support flag, the number of clusters, and a cluster ID. The announcement support flag is a flag indicating an announcement type supported by the service specified by the first service identification code SID. Announcement types include emergency broadcasts, road traffic information broadcasts, news broadcasts, and weather forecast broadcasts. The number of clusters indicates the number of subsequent cluster IDs, and is 23 at the maximum. The cluster ID is an identifier for identifying an announcement group (announcement cluster) supported by the service indicated by the service identification code SID.

  Also, FIG (0/19) is used to switch to the announcement for the broadcast signal being received. The FIG (0/19) includes a cluster ID, an announcement switching flag, a new flag, a region flag, and a subchannel identification. The announcement switching flag indicates the broadcast status of the announcement cluster indicated by each cluster ID. When an announcement belonging to the cluster ID is broadcast, a bit corresponding to the announcement type being broadcast is set to “1” in this flag, and the announcement is not broadcast. All the bits of the announcement switching flag corresponding to the cluster ID are reset to “0”. The new flag indicates whether the announcement of interest has been broadcast for the first time (flag is “1”) or has been previously retransmitted (flag is “0”) It is.

  FIG. 3 is a diagram illustrating a frame structure of MP2 data. As shown in FIG. 3, the MP2 data includes bit allocation data (Bit Alloc.), Scale factor (ScF), audio data, and error detection word (ScF-CRC (Cyclic Redundancy Check)). include. The bit allocation data is frequency information indicating whether or not audio components are present in each subband by dividing the audio band (20 Hz to 20 KHz) indicated by the audio waveform data included in the audio data into 32 subbands. is there. For example, for left and right voices, 1 bit is assigned to each subband, and a total of 64 bits is assigned to bit allocation data. The scale factor is amplitude information of each frequency indicating the sound level for each subband. For example, with a D range of 96 dB from -96 dB to 0 dB and a step of 0.25 dB, 4 × 96 = 384 (9 bits as 512) is required for each subband, and 32 × 2 × 9 = for the left and right subbands. 576 bits (72 bytes) are required. The error detection word is for detecting the presence or absence of an error included in the scale factor, and the CRC value calculated based on these data does not match the CRC value stored in the error detection word In addition, it is determined that these data are corrupted. For example, 2 bytes are allocated as an error detection word. The audio data described above corresponds to the first data, the bit allocation data corresponds to the second data, the scale factor corresponds to the third data, and the error detection word corresponds to the fourth data.

The BE unit 30 receives the compressed audio data (MP2 data) output from the FE unit 20, and expands the compressed audio data corresponding to the service or announcement to be output, the switched service, or the like. Perform processing. By the expansion processing, for example, audio data in the I ² S (The Inter-IC Sound Bus) format is output. The output processing unit 32 receives the audio data output from the BE unit 30 and converts it into an analog audio signal, and performs variable control of the volume, overlay processing of other sounds (for example, operation sounds), and the like. . The amplifier 34 amplifies the audio signal output from the output processing unit 32 and outputs the amplified audio from the speaker 36.

  The main control unit 40 controls the reception operation of the entire digital broadcast receiver, and performs control to switch to the audio output of the announcement when an announcement having new contents is received. In order to perform this switching control, the main control unit 40 includes a comparison unit 42 and a switching unit 44. Configuration related to normal reception operation control other than announcement switching control in the present invention (operation for selecting a service to be received, operation for displaying received contents of a service being received, announcement type desired to be received) The configuration required for the operation of designating the item is not shown.

  The comparison unit 42 compares the content of the announcement extracted from the received broadcast signal with the previously extracted announcement, and determines whether the content is the same. When the comparison unit 42 determines that the contents of the two announcements to be compared are not the same, the switching unit 44 issues a switching instruction to output a sound for the announcement extracted this time.

  The display device 50 displays an operation screen indicating an operation state of the digital broadcast receiver, an operation screen for performing various operations, and the like. The operation unit 52 is for a user to give an operation instruction, and includes various operation keys and operation knobs. An instruction to change the volume by the user, an instruction to change the service to be received or an announcement type, and the like are performed using the operation unit 52.

  The memory 60 stores data of two announcements to be compared. As for the data to be stored, when only the data necessary for the comparison of two announcement data is to be stored, or in addition to the data necessary for this comparison, the contents of the announcement acquired later are reproduced (voice output). For this reason, it may be possible to include data necessary for storage. The processing procedure differs depending on which storage object is adopted, and details thereof will be described later. The memory 60 retains the stored contents even when the digital broadcast receiver is powered off. For example, a non-volatile memory or a RAM with power backup is used as the memory 60.

  The RF unit 10, the FE unit 20, and the BE unit 30 described above are reception means, the output processing unit 32, the amplifier 34, and the speaker 36 are audio output units, the comparison unit 42 is an announcement comparison unit, and the switching unit 44 is an announcement. The memory 60 corresponds to the switching unit and the announcement storage unit.

  The digital broadcast receiver according to the present embodiment has such a configuration. Next, an operation of receiving an announcement during the audio output of the service being received and switching to the audio output of the announcement will be described.

  FIG. 4 is a flowchart showing an operation procedure for switching to the voice of the received announcement. The operation procedure shown in FIG. 4 is based on the premise that data necessary for audio output is stored in the memory 60 together with data necessary for comparison with respect to two announcement data to be compared. After performing the comparison process using the announcement data, the stored announcement data is read and the corresponding audio output is performed.

  When the digital broadcast receiver is activated and starts receiving services (step 100), the main control unit 40 instructs the output processing unit 32 to output audio corresponding to the service to be received, and outputs audio from the speaker 36. (Step 102).

  In parallel with such service reception operation, the comparison unit 42 determines whether or not an announcement has been received (step 104). The announcement to be determined is an announcement that matches the announcement type specified in advance, and may include all announcement types. If the announcement has not been received or if it has been received but is different from the designated announcement type, a negative determination is made in the determination of step 104, and the process returns to step 100 to continue the service reception operation.

  When an announcement of the designated announcement type is received, an affirmative determination is made in the determination at step 104. Next, the comparison unit 42 stores the entire MP2 data included in the received announcement in the memory 60 (step 108).

  Further, the comparison unit 42 determines whether or not the MP2 data of the announcement received last time is stored in the memory 60 (step 110). This determination is made for each announcement type. That is, when only one announcement type is designated, it is determined whether or not MP2 data of the announcement received last time is stored. When a plurality of announcement types are designated, it is determined whether or not the MP2 data of the announcement received last time is stored by paying attention to the announcement type of the announcement received this time. If it is stored, an affirmative determination is made, and then the comparison unit 42 determines whether or not the contents of the MP2 data are the same (step 112). A specific example for determining whether or not the contents of the two MP2 data (the contents of the announcement) are the same will be described later. If they are the same, an affirmative determination is made, and the process returns to step 104 to repeat the determination of presence / absence of announcement reception.

If the contents of the two MP2 data are not the same, a negative determination is made in step 112. Next, or when the MP2 data of the announcement received last time is not stored in the memory 60 and a negative determination is made in the determination in step 110, the switching unit 44 then displays the contents of the announcement received this time. (MP2 data) is read from the memory 60 and input to the BE unit 30, and a switching instruction for changing to an audio output corresponding to the input MP2 data is sent to the BE unit 30. Thereafter, the BE unit 30 outputs I ² S format audio data corresponding to the MP2 data input by the switching unit 44, and the speaker 36 outputs audio corresponding to the audio data (step 114). .

Thereafter, the switching unit 44 determines whether or not the audio output corresponding to the announcement has ended (step 116). If not, a negative determination is made, and the process returns to step 114 to continue the announcement audio output. When the audio output corresponding to the announcement is completed, an affirmative determination is made in the determination of step 116. Next, the switching unit 44 sends to the BE unit 30 a switching instruction to change to service voice output. Thereafter, the BE unit 30 outputs I ² S format audio data corresponding to the MP2 data of the service before switching to the announcement, and the speaker 36 outputs audio corresponding to the audio data (step 118). ). After that, the process returns to step 104 and the determination after the announcement reception is repeated.

  Next, the operation of step 112 in FIG. 4 for determining whether or not two announcements are the same will be described. Specifically, processing is performed in the order of (1) establishment of temporal synchronization and (2) comparison of speech waveforms. In addition, when performing these processes, it is assumed that there is no error in the data of the two announcements to be compared. Therefore, for example, when an error is detected based on the error detection word (ScF-CRC) in the MP2 data having the frame structure shown in FIG. 3, the CRC value calculated using the scale factor and the CRC value of the error detection word Is not matched), it is desirable to exclude the MP2 data from the determination target and perform the determination using only the error-free MP2 data.

(1) Establishing temporal synchronization When there is a time lag between the start of transmission of each announcement and the reception and accumulation of the announcements in the digital broadcast receiver of the present embodiment for content analysis. In this case, even if two announcements have the same contents, it is possible that the leading position of the MP2 data is shifted by several frames at the maximum. Therefore, it is necessary to adjust the deviation and align the MP2 data before comparing the audio waveforms.

  FIG. 5 is an explanatory diagram of MP2 data alignment. In the example shown in FIG. 5, MP2 data A, B, C, D,... Are stored in the memory 60 corresponding to the previous announcement, and the MP2 data a, b corresponding to the current announcement. , C, d,... Are stored in the memory 60.

  The comparison unit 42 selects one of the MP2 data of the current announcement, and checks for a match / mismatch between each of the plurality of MP2 data at the same position and the front and rear positions of the previous announcement. In the example shown in FIG. 5, the MP2 data a is selected from the MP2 data of the current announcement, and comparison is made with each of the four MP2 data A, B, C, and D of the previous announcement. . As a result of this comparison, for example, if MP2 data a and MP2 data B match, temporal synchronization is established by matching the positions of the frames of the matched MP2 data a and MP2 data B.

  By the way, the above-mentioned comparison of MP2 data can be considered when bit allocation data shown in FIG. 3 is used, when a scale factor is used, when an error detection word is used, when voice data is used, or when these are combined. The voice data is data indicating a voice waveform, and using this means that alignment is performed so that the shapes of the voice waveforms match. The bit allocation data and the scale factor indicate the frequency information and amplitude information of each frequency that are the characteristics of the voice waveform. If the shape of the voice waveform is the same, the frequency information and the amplitude information of each frequency are also displayed. Since they should be the same, it is possible to perform alignment so that the shapes of the speech waveforms are the same as when speech data is used. Furthermore, since the error detection word (CRC value) has the same value as long as the scale factor is the same, alignment can be performed so that the shapes of the speech waveforms match as in the case where the scale factor is used. .

  It should be noted that the amount of data is the smallest when an error detection word is used, the bit allocation data and the scale factor are the second smallest, and the voice data is the largest. Therefore, in order to reduce the processing load, it is desirable to use an error detection word with a small amount of data. In the above-described example, the method of aligning two announcements having the same content has been described. However, there may be no matching MP2 data for two announcements having different content (contents differ). However, since there is a case where a common sound effect or the like is inserted at the head portion, the MP2 data does not necessarily become inconsistent because the contents are different). In this case, two announcements to be compared Are not the same, a negative determination is made in step 112 of FIG.

(2) Comparison of Speech Waveforms The comparison unit 42 performs the above-described alignment for the two announcements to be compared, and then checks for a match / mismatch between the speech waveforms. FIG. 6 is an explanatory diagram of a voice waveform comparison operation using MP2 data. In the example shown in FIG. 6, a combination of MP2 data to be compared is shown for the case where alignment is performed using MP2 data a and MP2 data B. In this way, the MP2 data is compared for each combination, and it is determined whether or not the speech waveforms of the two announcements are the same. Note that the entire announcement (for example, MP2 data corresponding to 30 seconds when the playback time of the announcement is 30 seconds) may be compared, but a part of the MP2 data may be used. . Further, when the speech waveforms are compared in this way, the speech data shown in FIG. 3 may be used. However, any of bit allocation data, scale factor, or error detection word representing the features of the speech waveform may be used. May be used. This is the same as the case of “(1) Establishing temporal synchronization” described above, and it is desirable to use an error detection word with a small amount of data in order to reduce the processing load.

By the way, the determination of whether or not the contents of the two announcements to be compared are the same (step 112 in FIG. 4) is performed using the MP2 data that is the compressed data. Audio data in a certain I ² S format may be used. In this case, "(1) temporal synchronization establishment" and may be used for audio data of I ² S format in both "(2) Comparison of the speech waveform", either for one I ² S format audio data may be used, and MP2 data may be used for the other.

In FIG. 1, the input / output path of audio data when using I ² S format audio data is indicated by a dotted line. In FIG. 4, in step 108, the comparison unit 42 stores the I ² S format audio data corresponding to the received announcement in the memory 60. In step 114, the switching unit 44 receives the announcement received this time. inputs the voice data of the corresponding I ² S format reads the output processing unit 32 from the memory 60 to send a switch instruction to change audio output corresponding to the music data the input into the input processing unit 32. Thereafter, the I ² S format audio data input by the switching unit 44 is output from the output processing unit 32, and audio corresponding to the audio data is output from the speaker 36.

  FIG. 7 is a flowchart showing a modified example of the operation procedure for switching to the voice of the received announcement. In the operation procedure shown in FIG. 4, when a new announcement is received, a comparison operation (step 112) with the previous announcement is performed except when the previous announcement data is not stored. When the new flag is set to ON (value is “1”) corresponding to the newly received announcement, the announcement is excluded from the comparison operation target and the corresponding audio output is performed. It may be. In the operation procedure shown in FIG. 7, the operation of Step 109 is added between Step 108 and Step 110 with respect to the operation procedure shown in FIG. Note that the above-described new flag corresponds to identification information indicating whether or not the announcement is retransmitted for the same content.

  In step 109, the comparison unit 42 determines whether the new flag corresponding to the received announcement is set to ON (value is set to “1”). If the new flag is set on, a positive determination is made. In this case, the process proceeds to step 114 without performing the operations of steps 110 and 112, and the sound output corresponding to the announcement is performed. On the other hand, if the new flag is not set to ON, a negative determination is made in the determination of step 109. In this case, the determination operation in steps 110 and 112 is performed in the same manner as the operation procedure shown in FIG.

  FIG. 8 is a flowchart showing another modified example of the operation procedure for switching to the voice of the received announcement. In the operation procedure shown in FIG. 4, for two pieces of announcement data to be compared, data necessary for audio output together with data necessary for comparison is stored in the memory 60, and the announcement data stored in the memory 60 is stored. After performing the comparison process using the stored announcement data, the stored announcement data is read out and the corresponding sound is output. That is, it is assumed that the announcement data stored in the memory 60 is read out and the sound is output. However, when only the data necessary for comparing the two announcement data is stored in the memory 60, this Announcement audio cannot be output even if data is read. FIG. 8 shows an operation procedure when only data necessary for comparison of two announcement data is stored in the memory 60. In the operation procedure shown in FIG. 8, steps 108 and 114 are replaced with steps 108A and 114A and steps 120 and 122 are added to the operation procedure shown in FIG. Hereinafter, the description will be given focusing on these steps.

When an affirmative determination is made in the determination of step 104 (announcement reception determination), the comparison unit 42 selects a part of data (bit allocation) necessary for the comparison of the announcement from the MP2 data included in the received announcement. Data, scale factor, error detection word or part of voice data) are stored in the memory 60 (step 108A). Next, the comparison unit 42 determines whether or not the announcement received this time is designated as a reproduction target (the designated operation is performed in step 122 described later) (step 120). If it is not designated as a reproduction target, a negative determination is made, and the determination operations in steps 110 and 112 are performed in the same manner as the operation procedure shown in FIG. If the reproduction target is designated, an affirmative determination is made in the determination of step 120. Next, the switching unit 44 sends to the FE unit 20 a switching instruction to output MP2 data corresponding to the announcement designated as the reproduction target. Thereafter, the FE unit 20 outputs MP2 data included in the broadcast signal, the BE unit 30 outputs I ² S format audio data corresponding to the MP2 data, and the speaker 36 supports the audio data. Is output (step 114A).

  Further, when the contents of the two MP2 data are not the same and the negative determination is made in the determination of step 112, or the MP2 data of the announcement received last time is not stored in the memory 60, the processing of step 110 After a negative determination is made in the determination, the switching unit 44 designates the next announcement having the same announcement type as the announcement received this time as a reproduction target (step 122). That is, in the modification shown in FIG. 8, when an announcement or the like whose content is different from the previously received announcement is received, the next time the same announcement type announcement is received, the audio output is performed without comparing the content. Is done.

  FIG. 9 is a flowchart showing another modified example of the operation procedure for switching to the voice of the received announcement. In the operation procedure shown in FIG. 9, the operation of Step 109 is added between Step 108A and Step 120 with respect to the operation procedure shown in FIG. This step 109 is the same as the step 109 added in FIG. 7, and the comparison unit 42 determines whether the new flag corresponding to the received announcement is set to ON. If the new flag is set to ON, an affirmative determination is made, and the process proceeds to step 114A without performing the operation of step 120, and the sound output corresponding to the announcement is performed.

  As described above, in the digital broadcast receiver according to the present embodiment, when the announcement included in the broadcast signal is received, it is determined whether or not the content of the announcement is the same as the content of the announcement already received. Therefore, only new announcements can be output, and unannounced announcements can be prevented from being listened to and duplicate announcements having the same content can be prevented from being reproduced.

Also, by comparing the contents of announcements using MP2 data that is compressed audio data, it is possible to perform comparison with a small amount of data, and the processing burden can be reduced. Alternatively, by comparing the contents of announcements using I ² S format voice data indicating a voice waveform, the announcements can be reliably compared regardless of the data compression format.

  In addition, by adjusting the time lag between two announcements to be compared (establishing synchronization) before comparing the contents of the announcements, for example, after the announcement transmission is started, the receiver actually , It is possible to eliminate the time lag from receiving and accumulating the announcements to analyzing the contents, and to prevent erroneous determination that the announcements are not the same due to the time lag.

  Further, when the announcement content comparison operation is omitted when it is known that the announcement is new based on the new flag, the processing burden can be reduced accordingly.

  Further, by storing the data necessary for reproducing the contents of the announcement (sound output) together with the data necessary for comparing the two announcement data in the memory 60, when the received announcement has not been reproduced, By reading the announcement data from the memory 60 and playing it back, it is possible to reliably prevent hearing loss. Alternatively, by storing only data necessary for comparing the two announcement data in the memory 60, the capacity of the memory 60 can be reduced, and the component cost can be reduced.

  In addition, this invention is not limited to the said embodiment, A various deformation | transformation implementation is possible within the range of the summary of this invention. For example, in the above-described embodiment, a digital broadcast receiver that receives a broadcast signal according to the DAB / T-DMB broadcast standard has been described. However, an announcement distributed in parallel with a service (program) being received is received. The present invention can also be applied to other broadcast receivers.

  As described above, according to the present invention, when the announcement included in the broadcast signal is received, it is determined whether or not the content of the announcement is the same as the content of the announcement already received. Only new announcements can be output, and unannounced announcements can be prevented from being missed and duplicate announcements with the same content can be prevented.

DESCRIPTION OF SYMBOLS 10 RF part 20 FE (front end) part 30 BE (back end) part 32 Output processing part 34 Amplifier 36 Speaker 40 Main control part 42 Comparison part 44 Switching part 50 Display apparatus 52 Operation part 60 Memory

Claims (10)

In the broadcast receiver that outputs the sound corresponding to the service included in the broadcast signal and outputs the sound corresponding to the announcement temporarily inserted in the broadcast signal,
Receiving means for receiving the broadcast signal and extracting the service and the announcement;
Audio output means for outputting an audio signal corresponding to each of the service and the announcement extracted by the receiving means;
About the announcement extracted by the receiving means, an announcement comparison means for comparing contents with the announcement extracted last time and determining whether the contents are the same,
An announcement switching means for giving a switching instruction to output an audio signal of the announcement from the audio output means when it is determined by the announcement comparison means that they are not the same;
A broadcast receiver comprising: In claim 1,
The announcement comparison means compares announcement contents based on compressed audio data corresponding to the announcement. In claim 2,
The compressed voice data includes first data indicating a voice waveform, second data indicating the presence or absence of a signal corresponding to each of a plurality of frequency bands for the voice waveform, and a plurality of frequency bands for the voice waveform. And third data indicating the signal level corresponding to each,
The broadcast receiver characterized in that the announcement comparison means compares the contents of the announcement based on at least one of the second and third data. In claim 2,
The compressed voice data includes first data indicating a voice waveform, second data indicating the presence or absence of a signal corresponding to each of a plurality of frequency bands for the voice waveform, and a plurality of frequency bands for the voice waveform. Third data indicating a signal level corresponding to each of the third data and fourth data used for detecting that the third data includes an error;
The broadcast receiver characterized in that the announcement comparison means compares the contents of the announcement based on the fourth data. In claim 2,
The compressed voice data includes first data indicating a voice waveform, second data indicating the presence or absence of a signal corresponding to each of a plurality of frequency bands for the voice waveform, and a plurality of frequency bands for the voice waveform. And third data indicating the signal level corresponding to each,
The broadcast receiver characterized in that the announcement comparison means compares the contents of the announcement based on the first data. In claim 1,
The broadcast receiver according to claim 1, wherein the announcement comparison means compares the contents of the announcement based on data indicating a voice waveform. In any one of Claims 2-6,
The announcement comparison means adjusts a time lag between two announcements to be compared before comparing the contents of announcements. In any one of Claims 1-7,
The announcement is associated with identification information indicating whether the announcement is retransmitted for the same content,
When it is detected based on the identification information that the announcement extracted by the receiving means has a new content that has not been retransmitted, the announcement switching means receives the audio signal of the announcement. A broadcast receiver characterized in that a switching instruction to be output from the audio output means is issued, and the announcement comparison means does not perform an announcement content comparison operation. In any one of Claims 1-8,
Announcement storage means for storing announcement data extracted by the receiving means,
The announcement switching means reads the announcement data stored in the announcement storage means and outputs the audio signal of the announcement when the announcement comparison means determines that they are not the same. A broadcast receiver characterized by issuing a switching instruction output from the means. In any one of Claims 1-8,
Announcement storage means for storing a part of the data necessary for the comparison of the announcement contents from the announcement data extracted by the receiving means,
The announcement switching means issues a switching instruction to output the audio signal of the announcement extracted next by the receiving means from the audio output means when the announcement comparing means determines that they are not the same. A broadcast receiver characterized by that.

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