JP4110342B2 - Broadcast signal receiver - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The invention described in the claims of the present application receives a broadcast signal (digital audio broadcast signal) under digital audio broadcast (DAB), and program data and control information data from the received digital audio broadcast signal. And a broadcast signal receiving device for obtaining a reproduced audio signal based on the reproduced program data.
[0002]
[Prior art]
Audio broadcasting, which is often called “radio broadcasting”, is an AM audio broadcasting that transmits an audio information signal as an amplitude modulation (AM) audio signal for many years, and an audio information signal is transmitted as a frequency modulation (FM) audio signal. In recent years, digital audio has been used to transmit audio information signals as digital audio signals in order to improve the quality of audio information transmitted and received under the audio broadcasting. It has been proposed to be broadcast. Particularly in the European region, digital audio broadcasting has already been put into practical use as a broadcasting system called DAB (Digital Audio Broad-casting).
[0003]
The digital audio broadcasting signal transmits not only the audio information data forming the digital audio signal but also service information data including, for example, weather forecasts, traffic information, etc., and further receives audio information on the receiving side. Data and service information data are reproduced, and control voice data necessary for obtaining a digital voice signal based on voice information data or service data based on service information data is transmitted. The audio information data is usually obtained as including a plurality of audio program data each representing a plurality of programs, and the plurality of audio program data includes announcement data representing a predetermined announcement. Also, the service information data is usually obtained as including a plurality of service program data each representing a plurality of programs.
[0004]
Audio information data and service information data transmitted by digital audio broadcasting signals are subjected to time interleaving processing in order to minimize adverse effects caused by missing data bits, data bit changes, etc. that occur during transmission. The The voice information data and the service information data are transmitted in such a manner that unit sections called logical frames having a time length of 24 ms (24 milliseconds) are successively connected. For example, 16 consecutive logical frames are used as an interleave completion classification, and the voice information data and service information data for 16 consecutive logical frames subjected to time interleaving processing are again continuous. 16 logical frames are formed.
[0005]
A digital audio broadcast signal transmitted in such digital audio broadcast is received using a digital audio broadcast signal receiving apparatus. In the digital audio broadcast signal receiving apparatus, a digital audio broadcast signal transmitted by each broadcasting station that performs digital audio broadcast is selectively received by a channel selection operation, and a demodulation process is performed on the received digital audio broadcast signal. Thus, voice information data, service information data, and control information data subjected to time interleaving are obtained. Then, the time interleaving process performed on the voice information data and service information data subjected to the time interleaving process is canceled to obtain the original voice information data and service information data. Deinterleaving is performed.
[0006]
Subsequently, the voice program data and the service program data based on the voice information data and the service information data subjected to the time deinterleaving process are individually obtained with the control information data involved. The digital audio signal is reproduced by performing the decoding process of, and the reproduced audio signal is obtained based on the digital audio signal, and the reproduction service data is obtained by performing the decoding process on the service program data.
[0007]
[Problems to be solved by the invention]
The digital audio broadcast signal that is selectively received by the digital audio broadcast signal receiving apparatus as described above includes the audio data obtained based thereon including announcement data representing a plurality of repetitions of the same announcement, The control information data corresponding to the voice information data is a variety of information about the announcement represented by the announcement data, for example, the announcement type, the announcement start time, the announcement end time, the announcement new It tells the distinction between things and things. Then, in the digital audio broadcast signal receiving apparatus, announcement data representing a plurality of repetitions for the same announcement is selected, and the announcement data is stored in the memory unit, and thereafter at an arbitrary timing from the memory unit. There may be a situation where the announcement data representing the announcement is read out and the audio announcement is reproduced based on the announcement data.
[0008]
In such a case, the announcement data included in the digital audio broadcast signal selectively received by the digital audio broadcast signal receiving device may be partially errored data, like other audio program data. . For example, in the announcement data, each one period of the announcement is formed by a series of a plurality of voice frames, and a plurality of voice frames corresponding to one period of the announcement are included in them. There is a possibility that a part of the error will be accompanied by an error.
[0009]
If the announcement data is partially errored data, the announcement data is partially stored in the memory unit when the announcement data is stored in the memory unit. Will end up. Therefore, when the announcement data stored in the memory unit is subsequently read out from the memory unit and used for the reproduction of the voice announcement, the error occurs in the announcement data read out from the memory unit. , Audio announcements will not be played back properly.
[0010]
In view of the above, the invention described in the claims of the present application selectively receives a digital audio broadcast signal, program data including audio information data and service information data from the received digital audio broadcast signal, and control data. When reproducing information data and obtaining a reproduced audio signal based on the reproduced program data, the program data includes audio program data that is announcement data representing a plurality of repetitions of the same announcement. When the announcement data is stored in the memory section, the control information data corresponding to the program data conveys various information about the announcement represented by the announcement data. Sentiment data partially The disadvantage caused due to be that an error has occurred, to provide a broadcast signal receiving apparatus capable of effectively avoided.
[0011]
[Means for Solving the Problems]
The broadcast signal receiving apparatus according to any one of claims 1 to 5 in the claims of the present application includes a receiving unit that selectively receives a digital audio broadcast signal, and a digital signal received by the receiving unit. A data reproduction unit that reproduces program data and control information data based on the audio broadcast signal, an audio signal output unit that obtains a reproduction audio signal based on the program data reproduced by the data reproduction unit, and a data reproduction unit Control information data is supplied, and based on the portion of the control information data corresponding to the announcement data included in the program data, the announcement cycle represented by the announcement data is detected, and the detected cycle is indicated. Control unit for sending announcement cycle detection output and data reproduction unit An announcement data controller comprising a memory unit for writing and reading program data reproduced and an announcement data control unit, and the announcement data control unit reproducing the program data reproduced by the data reproduction unit and the control unit When the program cycle detection output is supplied and the program data is announcement data representing an announcement that is repeated a plurality of times with a predetermined cycle, the announcement that represents one cycle of the announcement in the memory unit as being accompanied by no error It is configured to set the state in which the data portion will be written.
[0012]
In particular, the broadcast signal receiving apparatus according to the invention described in claim 3 in the scope of claims of the present application is the broadcast signal receiving apparatus according to any one of claims 1 to 5 described above. Based on the premise of the configuration, the announcement data control unit checks the frame audio data included in each of a plurality of audio frames corresponding to one period of the announcement forming the announcement data, and gives an error. In addition to setting a state in which only frame audio data that is not accompanied is written in the memory unit, an error included in a plurality of audio frames corresponding to one period of the subsequent announcements is included instead of the frame audio data including an error. No frame audio data corresponding to the frame audio data with the above error is written to the memory unit. It is intended to set the state.
[0013]
In the broadcast signal receiving device according to any one of claims 1 to 5 in the claims of the present application configured as described above, the data reproduction unit converts the digital audio broadcast signal into a digital audio broadcast signal. Announcement period detection output formed by detecting the period of the announcement represented by the announcement data included in the program data based on the control information data, by reproducing the program data and control information data based on the control data The announcement data control unit to which the program data from the data reproduction unit and the announcement cycle detection output from the control unit are supplied, announces that the program data is repeated a plurality of times with a predetermined cycle. Announcement data Can, in the memory unit, the state becomes the portion of the announcement data representing one period of the announcement as without error is written is set.
[0014]
At that time, the announcement data control unit forms the announcement data for one cycle of the announcement as in the broadcast signal receiving apparatus according to the invention described in claim 3 of the claims of the present application, for example. The frame audio data included in each of a plurality of audio frames corresponding to the above is inspected, and a state is set in which only frame audio data without error is written in the memory unit. Sets the state in which frame audio data without errors included in a plurality of audio frames corresponding to one period of subsequent announcements, and corresponding to the frame audio data with errors described above is written in the memory unit It is supposed to be.
[0015]
As a result, even in the case where the announcement data representing the announcement that is repeated a plurality of times with a predetermined cycle is partially errored, the memory unit contains an error for one cycle of the announcement. The state in which the announcement data that represents the error is stored is obtained, and the inconvenience caused by the fact that the announcement data is partially errored is effectively avoided.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows an example of a broadcast signal receiving apparatus according to the invention described in any one of claims 1 to 5 in the claims of the present application. In this example, the digital audio broadcast signal transmitted from the broadcast station and captured by the reception antenna 21 is selectively received by the channel selection reception operation in the channel selection reception unit 22.
[0017]
The digital audio broadcast signal that is selectively received by the channel selection receiving unit 22 is, for example, a modulated wave signal obtained by modulating digital data by an orthogonal frequency division multiplexing (OFDM) system. Data is composed of a series of frame units called transmission frames.
[0018]
Each transmission frame has a time length of 96 ms, for example, as shown in FIG. 2A, and includes a synchronization channel portion, a fast information channel (FIC) portion, and a main frame. It is formed including a service channel (MSC) portion. The MSC portion is constituted by a series of a plurality of common interleaved frames (CIF) as shown in FIG. 2B. Each CIF consists of 55,296 bits as a whole, and a total of 864 capacity units (CU) from 0 to 863 are connected as shown in C of FIG. Each capacity unit is 64 bits of unit data. Program information data, which is audio information data, is transmitted by such MSC.
[0019]
The program information data transmitted by the MSC includes a plurality of audio program data and a plurality of service program data. The voice program data includes announcement data for a predetermined announcement regarding road traffic information, regional weather information, entertainment information, and the like.
[0020]
Further, as shown in FIG. 2B, the FIC portion is constituted by a series of a plurality of fast information blocks (FIBs). Each FIB is composed of 256 bits as shown in FIG. 2C, and includes an FIB data field and an error detection word CRC (Cyclic Redundancy Check). Further, each FIB data field is constituted by a series of a plurality of fast information groups (FIGs) as shown in FIG. 2D, and each FIG is represented by E in FIG. It includes a FIG header and a FIG data field. Such FIC transmits control information data representing multiplex configuration information (MCI) and other information.
[0021]
Such control information data transmitted by the FIC includes information related to announcement data included in the program information data transmitted by the MSC, for example, the start time and end time of the announcement data, and the contents of the announcement data. A plurality of flag data indicating whether the data is new or repeated is included. For example, program information data transmitted by the MSC by what is called “type 0, Ex-tension 19” (Extension 19 of FIG type 0 (FIG 0/19)) among the plurality of FIGs constituting the FIC. Announcement switch flag data (AS flag data) which takes “1” in the transmission period of announcement data included in the, and “0” in other periods, and is included in the program information data transmitted by the MSC New flag data that takes “1” when the content of the announcement data to be transmitted is new and takes “0” when the content of the announcement data included in the program information data transmitted by the MSC is repetitive. Are transmitted. Further, other flag data related to the announcement data included in the program information data transmitted by the MSC is transmitted by another one of the plurality of FIGs constituting the FIC.
[0022]
The time when the AS flag data or new flag data changes from “0” to “1” corresponds to the start time of the announcement represented by the announcement data included in the program information data transmitted by the MSC. The time when the AS flag data or new flag data changes from “1” to “0” corresponds to the end time of the announcement represented by the announcement data included in the program information data transmitted by the MSC.
[0023]
The channel selection operation in the channel selection reception unit 22 includes channel selection control corresponding to the channel selection control signal CCH supplied from the control unit 50 forming the operation control unit, and further, a synchronization control signal connected to the data reproduction unit 23. This is performed under frequency synchronization control according to the synchronization control signal SSY supplied from the forming unit 24. Then, the channel selection receiving unit 22 performs amplification processing, frequency conversion processing, and the like on the selectively received digital audio broadcast signal to form an intermediate frequency (IF) signal SID for the selectively received digital audio broadcast signal. Then, the IF signal SID is supplied to the data reproducing unit 23.
[0024]
In the data reproduction unit 23, the IF signal SID from the channel selection reception unit 22 is supplied to the analog / digital (A / D) conversion unit 25, and the digital IF signal DID corresponding to the IF signal SID is output from the A / D conversion unit 23. Is obtained and supplied to the quadrature demodulator 26. In the quadrature demodulator 26, a quadrature demodulation process is performed on the digital IF signal DID, thereby obtaining a quadrature demodulated output signal DQX.
[0025]
The quadrature demodulated output signal DQX obtained from the quadrature demodulator 24 is supplied to a fast Fourier transform (FFT) differential demodulator 27. In the FFT differential demodulator 27, the orthogonal demodulated output signal DQX is converted from a time domain signal to a frequency domain signal. From the FFT differential demodulator 27, the orthogonal demodulated output signal DQX is synchronized in each transmission frame. Synchronization information data DRS representing synchronization information transmitted by the channel is obtained, and control information data and MSC (main information) transmitted by FIC (Fast Information Channel) in each transmission frame of the orthogonal demodulation output signal DQX are obtained. The composite data DCX formed by the program information data transmitted by the service channel) is obtained.
[0026]
The synchronization information data DRS obtained from the FFT differential demodulation unit 27 is supplied to the synchronization control signal forming unit 24 and used for forming the synchronization control signal SSY in the synchronization control signal forming unit 24. Also, the composite data DCX obtained from the FFT differential demodulator 27 is subjected to frequency deinterleave processing for canceling the frequency interleave state in the frequency deinterleaver 28 to become composite data DCX ′, and then program selection is performed. Supplied to the unit 29.
[0027]
The program selection unit 29 is also supplied with a program selection control signal CPR from the control unit 50. In the program selection unit 29, the program information data transmitted by the MSC forming the composite data DCX ′ and the control information data transmitted by the FIC are separated, and separated according to the program selection control signal CPR. The selected voice program data or service program data is selected by selecting one of a plurality of audio program data included in the program information data or one of a plurality of service program data. The program data DPD is obtained, and the separated control information data is obtained as the control information data DCD.
[0028]
In this way, the program data DPD obtained by the program selection unit 29 is subjected to time interleaving processing. Such program data DPD corresponds to a common interleaved frame (CIF), and is composed of, for example, sequential sequential logical frames having a time length of 24 ms. Interleaving processing is performed, for example, with 16 consecutive logical frames as the interleaving completion classification. Each logical frame is composed of 864 capacity units (CUs) that form unit data.
[0029]
The program data DPD obtained from the program selection unit 29 is supplied to the time deinterleaving unit 30. The time deinterleaving unit 30 performs time deinterleaving processing on the program data DPD that has been subjected to time interleaving processing. In this case, for example, first, among the sequential logical frames formed by the program data DPD, in each of the 16 logical frames for each of the 16 consecutive groups forming each interleave completion section. A plurality of capacity units are sequentially written and stored in a memory built in the time deinterleave unit 30.
[0030]
Subsequently, after all of the plurality of capacity units in each of the 16 logical frames are stored in the memory, the plurality of capacity units stored in the memory have a predetermined reading mode set in advance. It is read out from the memory and taken out in order to form program data DPD ′ in 16 consecutive logical frames. As a result, the time deinterleave unit 30 obtains the program data DPD ′ subjected to the time deinterleave process for canceling the time interleave process, and supplies the program data DPD ′ to the Viterbi decoding unit 31.
[0031]
On the other hand, the control information data DCD obtained from the program selection unit 29 is directly supplied to the Viterbi decoding unit 31. In the Viterbi decoding unit 31, error correction processing is performed on the control information data DCD from the program selection unit 29 and the program data DPD ′ from the time deinterleaving unit 30 by the maximum likelihood decoding method. As a result, the program data DPD ′ subjected to the error correction process and the control information data DCD subjected to the error correction process are obtained from the Viterbi decoding unit 31.
[0032]
In this way, the data reproducing unit 23 including the A / D conversion unit 25 to the Viterbi decoding unit 31 is based on the digital audio broadcast signal received by the channel selection receiving unit 22 and the program data DPD ′. An operation of reproducing the control information data DCD is performed. The program data DPD ′ obtained from the Viterbi decoding unit 31 in the data reproduction unit 23 is supplied to the data selection unit 32, and the control information data DCD obtained from the Viterbi decoding unit 31 in the data reproduction unit 23 is controlled. It is supplied to the unit 50.
[0033]
When the program data DPD ′ subjected to the error correction process from the Viterbi decoding unit 31 is the audio program data, the audio program data DAD is derived from the data selection unit 32, and the error correction process from the Viterbi decoding unit 31 is performed. When the program data DPD ′ made is service program data, service program data DSD is derived.
[0034]
The audio program data DAD derived from the data selection unit 32 is supplied to each of the selection contact 33a, the memory unit 34, and the announcement data control unit 35 of the switch 33 forming the data switching unit. The service program data DSD derived from the data selection unit 32 is supplied to the decryption unit 39. In the decryption unit 39, decryption processing is performed on the service program data DSD, and reproduction service data DS based on the service program data DSD is obtained. Then, the reproduction service data DS obtained from the decoding unit 39 is derived to the output terminal 40.
[0035]
On the other hand, the control unit 50 supplied with the control information data DCD obtained from the Viterbi decoding unit 31 in the data reproducing unit 23 receives the control information data DCD from the Viterbi decoding unit 31 and a high-efficiency decoding unit 36 described later. According to the program-related data DPA, and further, the control command CR corresponding to the remote control signal SR from the receiving unit 52 that receives the remote control signal SR from the remote operation control unit 51 or the operation in the input operation unit 53 In response to the control command CX or the like, the channel selection control signal CCH, the program selection control signal CPR, and further the control data DVD are formed, and the channel selection control signal CCH is sent to the channel selection receiving unit 22 and the program selection control signal CPR is sent. The control data DVD is supplied to the program selection unit 29 and further to the Viterbi decoding unit 31, respectively, and the channel selection reception unit 2 is supplied. , It controls the operation for program selection unit 29 and the Viterbi decoding unit 31.
[0036]
The control information data DCD supplied from the Viterbi decoding unit 31 to the control unit 50 is data transmitted by the FIC, and is “type 0, Extension 19” (FIG 0 / 19) AS flag data and new flag data transmitted by the above, and other flag data. The AS flag data is “1” in the transmission period of the announcement data included in the program data DPD ′, and is “0” in the other periods. The new flag data is the program data DPD. This is flag data that takes “1” when the content of the announcement data contained in 'is new, and takes “0” when the content of the announcement data contained in the program data DPD' is repeated. .
[0037]
In the control unit 50, the control information data DCD from the Viterbi decoding unit 31 is supplied to the built-in announcement cycle detection unit. The announcement cycle detection unit detects AS flag data and new flag data included in the control information data DCD, and announce data included in the program data DPD ′ based on the detected AS flag data and new flag data. The start time and end time of the new announcement that is represented are detected and stored in the built-in memory, and the period of the new announcement represented by the announcement data included in the program data DPD ′ is detected and detected. Store announcement cycle in internal memory.
[0038]
The announcement cycle detection unit transmits the announcement data included in the program data DPD ′ together with the start and end points of the detected announcement and the storage of the detected announcement cycle in the built-in memory. Announcement determination data DAN indicating that the voice program data DAD obtained from the data selection unit 32 based on the program data DPD ′ is the announcement data is the announcement data control unit 35. And an operation to send the announcement cycle detection output representing the detected announcement cycle to the announcement data control unit 35 as the announcement cycle data DAP.
[0039]
In this case, the announcement cycle detection unit detects the start time and end time of the above-described new announcement, and further detects the cycle of the new announcement. First, the AS flag data is “1”. It is detected whether the announcement data included in the program data DPD ′ is in the transmission period or whether the AS flag data is “0” and the announcement data included in the program data DPD ′ is not in the transmission period. To do. When the AS flag data is “0”, an announcement start time detection waiting state for detecting the start time of the announcement is taken, and a state in which the AS flag data becomes “1” is waited.
[0040]
On the other hand, when the AS flag data is “1” or when the AS flag data is changed from “0” to “1”, the time when the new flag data changes from “0” to “1” is captured. The start point of the new announcement represented by the announcement data included in the program data DPD ′ is detected and stored in the built-in memory as the detected announcement start point, and then the end point of the announcement is detected. Announcement end time detection waiting state for detection is taken, and the time when the new flag data changes from “1” to “0” is waited for. Then, the time point at which the new flag data changes from “1” to “0” is detected, and the end point of the new announcement represented by the announcement data included in the program data DPD ′ is detected and detected. It is stored in the built-in memory as the announcement end point. Then, based on the detected announcement start time and announcement end time, the period of the new announcement is detected and stored in the built-in memory as the detected announcement period. At the same time, announcement determination data DAN and announcement cycle data DAP are formed and sent to announcement data control unit 35.
[0041]
Further, the control unit 50 responds to a control command CR corresponding to the remote control signal SR from the receiving unit 52 that receives the remote control signal SR from the remote operation control unit 51 or an operation in the control unit CR from the input operation unit 53. In response to the control command CX, a memory read command signal CMR is formed and supplied to the announcement data control unit 35.
[0042]
The announcement data control unit 35 is supplied with the audio program data DAD from the data selection unit 32, the announcement determination data DAN and the announcement cycle data DAP from the announcement cycle detection unit built in the control unit 50. When the voice program data DAD is announcement data representing an announcement that is repeated a plurality of times with a predetermined period, the announcement data supplied to the memory unit 34 as the voice program data DAD from the data selection unit 32 Is set to a state where a portion representing one cycle of the announcement is written with no error. Accordingly, when the voice program data DAD is announcement data representing an announcement that is repeated a plurality of times with a predetermined cycle, the memory unit 34 indicates one cycle of the announcement as being accompanied by no error. Data is written. In such a case, writing of one-period announcement data to the memory unit 34 is performed according to a write control signal QW supplied from the announcement data control unit 35 to the memory unit 34.
[0043]
Also, the announcement data control unit 35 receives the one-cycle announcement data stored in the memory unit 34 in response to the memory read command signal CMR from the control unit 50 with the one-cycle announcement data stored in the memory unit 34. Data is read out, and a state is set in which the read one-period announcement data is supplied to the selection contact 33b of the switch 33 as the audio program data DAD ′. In such a case, reading of one-period announcement data from the memory unit 34 is performed only once or a plurality of times according to the read control signal QR supplied from the announcement data control unit 35 to the memory unit 34. Is called.
[0044]
Further, the announcement data control unit 35 forms a switching control signal CS for controlling the state of the switch 33 and supplies it to the switch 33. The switching control signal CS is read from, for example, one-cycle announcement data stored in the memory unit 34, and the read one-cycle announcement data is used as audio program data DAD 'to select the selection contact 33b of the switch 33. In the period during which the movable contact 33c is connected to the selection contact 33b, the switch 33 is connected to the selection contact 33b. In other periods, the switch 33 is connected to the selection contact 33a. It is supposed to be in a state to take. Thereby, when one cycle announcement data from the memory unit 34 is supplied to the selection contact 33b of the switch 33 as the audio program data DAD ', the audio program data DAD' is derived to the movable contact 33c of the switch 33, and the others At this time, the audio program data DAD from the data selection unit 32 is derived to the movable contact 33 c of the switch 33.
[0045]
The audio program data DAD or DAD ′ derived to the movable contact 33 c of the switch 33 is supplied to the high efficiency decoding unit 36. The high-efficiency decoding unit 36 performs high-efficiency decoding processing on the audio program data DAD or DAD ′, decompresses the data compressed by the high-efficiency encoding processing, and obtains decoded audio data DA. It is done. Further, from the high-efficiency decoding unit 36, program-related data DPA included in the audio program data DAD or DAD ′ is obtained and supplied to the control unit 50.
[0046]
The program-related data DPA included in the audio program data DAD or DAD ′ is, for example, as shown in FIG. 3, a data unit having a time length of 24 ms forming the audio program data DAD or DAD ′. It is assumed that indefinite length program related data X-PAD and fixed length program related data F-PAD arranged in a portion following the audio data in the audio frame as the section. The program related data DPA represents various types of information related to the contents of the audio data in the audio frame to which the program related data DPA belongs.
[0047]
The decoded audio data DA obtained from the high-efficiency decoding unit 36 is supplied to a digital / analog (D / A) conversion unit 37 to be converted into an analog signal, and the D / A conversion unit 37 corresponds to the audio data DA. A reproduced audio signal SA is formed. Then, the reproduced audio signal SA obtained in the D / A converter 37 is derived to the output terminal 38. Under such circumstances, the high-efficiency decoding unit 36 and the D / A conversion unit 37 are the audio program data DAD selected by the data selection unit 32 or the one-cycle announcement data read from the memory unit 34. An audio signal output unit for obtaining a reproduction audio signal based on the audio program data DAD ′ is configured.
[0048]
The reproduced audio signal SA derived to the output terminal 38 is supplied to, for example, an audio reproducing unit including a speaker or the like, and is used for reproducing audio based on audio information represented by the audio program data DAD or DAD ′. The
[0049]
When the reproduction audio signal SA is obtained based on the audio program data DAD ′, an announcement represented by the announcement data is issued from the audio reproduction unit. Such an announcement is based on the audio program data DAD ′, which is the one-cycle announcement data read from the memory unit 34, that is, one-cycle announcement data that represents one announcement cycle as having no error. For example, the announcement data representing the announcement repeated a plurality of times with a predetermined period obtained as the audio program data DAD from the data selection unit 32 is partly an error. Even high quality is not affected by the error. Therefore, the inconvenience caused by the fact that the announcement data obtained from the data selection unit 32 is partially errored is effectively avoided.
[0050]
FIG. 4 shows a specific configuration example of the announcement data control unit 35. In the example shown in FIG. 4, the audio program data DAD from the data selection unit 32 is supplied to the audio frame counter unit 61 and the error frame detection unit 62. The audio program data DAD is formed of a series of audio frames as shown in FIG. 3, and when the audio program data DAD is announcement data representing an announcement that is repeated a plurality of times with a predetermined period, the audio program data DAD is continuous. A predetermined number of, for example, five audio frames corresponds to one period of the announcement. That is, the announcement data representing one period of the announcement is formed by a predetermined number, for example, five audio frames.
[0051]
The audio frame counter unit 61 generates count value data DT representing a count value that sequentially counts and gradually changes for each audio frame included in a sequence of audio frames forming the audio program data DAD. Send it out. The count value data DT sent from the audio frame counter unit 61 is supplied to the error frame count value memory unit 63 and the memory control unit 64, respectively.
[0052]
The error frame detection unit 62 detects an audio frame including frame audio data with an error (hereinafter referred to as an error frame) included in a series of audio frames forming the audio program data DAD. When detected, an error frame detection output signal SER is formed and supplied to the error frame count value memory unit 63 and the memory control unit 64, respectively. The error frame count value memory unit 63 has its writable state and readable state controlled by a control signal CRS sent from the memory control unit 64.
[0053]
The memory control unit 64 is also supplied with announcement determination data DAN, announcement cycle data DAP, and memory read command signal CMR from the control unit 50. Then, when the control signal CRS is not supplied to the error frame count value memory unit 63, the memory control unit 64 maintains the error frame count value memory unit 63 in a writable state.
[0054]
Further, the memory control unit 64 sends the count / reset signal CRE to the audio frame counter unit 61 at each start of the announcement period represented by the announcement period data DAP according to the announcement determination data DAN and the announcement period data DAP. And the audio frame counter 61 performs counting / resetting. As a result, the audio frame counter unit 61 is an announcement data representing an announcement in which the audio program data DAD is repeated a plurality of times with a predetermined period, and for each period of the announcement forming the announcement data. The operation of obtaining count value data DT representing a count value that gradually changes by sequentially counting each of a predetermined number, for example, five audio frames, is repeated.
[0055]
Under such circumstances, when the audio program data DAD is announcement data representing an announcement that is repeated a plurality of times with a predetermined period, first, the audio frame counter unit 61 uses the audio program data DAD as shown in A of FIG. Counting is sequentially performed for five audio frames: audio frame 0 to audio frame 4 corresponding to the announcement of the first period in the announcement data, and the count value data DT obtained thereby is an error frame count value memory unit. 63 and the memory control unit 64. The memory control unit 64 sends out a write control signal QW that changes sequentially according to the count value data DT from the audio frame counter unit 61 and supplies it to the memory unit 34. As a result, five audio frames corresponding to the announcement in the first period in the announcement data counted by the audio frame counter unit 61: audio frame 0 to audio frame 4 are sequentially written in the memory unit 34. The state is taken.
[0056]
At this time, the error frame detection unit 62 includes five audio frames corresponding to the announcement in the first period in the announcement data counted by the audio frame counter unit 61: audio frame 0 to audio frame 4. For example, if there is an error frame such as audio frame 3 in FIG. 5A, the error frame is detected, and the error frame detection output signal SER is sent to the error frame count value memory unit 63 and the memory control unit 64, respectively. Supply.
[0057]
In the error frame count value memory unit 63, in response to the error frame detection output signal SER from the error frame detection unit 62, the count value represented by the count value data DT from the audio frame counter unit 61 at that time, that is, Five audio frames corresponding to the announcement in the first period in the announcement data: a count value corresponding to the audio frame 3 which is an error frame among the audio frames 0 to 4 is written and stored.
[0058]
Further, the memory control unit 64 responds to the error frame detection output signal SER from the error frame detection unit 62, and the count value represented by the count value data DT from the audio frame counter unit 61 at that time, that is, the announcement data Five audio frames corresponding to the announcement of the first cycle: to the memory unit 34 of the write control signal QW corresponding to the count value corresponding to the audio frame 3 which is an error frame of the audio frames 0 to 4 Stops sending. As a result, in the memory unit 34, five error frames corresponding to the announcement in the first period in the announcement data counted by the audio frame counter unit 61: an error frame among the audio frames 0 to 4. A certain voice frame 3 is not written.
[0059]
Therefore, as shown in FIG. 5A, for the five audio frames: audio frame 0 to audio frame 4 corresponding to the announcement in the first period in the announcement data, frame audio without error among them. The audio frame 0, the audio frame 1, the audio frame 2, and the audio frame 4 that are audio frames including data are written in the memory unit 34, and the audio frame 3 that is an error frame is not written in the memory unit 34.
[0060]
Subsequently, the supply of the five audio frames corresponding to the announcement in the first period in the announcement data: audio frame 0 to audio frame 4 to the audio frame counter unit 61 is completed, and subsequently, B in FIG. When the supply of five audio frames: audio frames 0 to 4 to the audio frame counter unit 61 corresponding to the announcement in the second period in the announcement data as shown in FIG. 64 supplies a memory reset signal CRE to the audio frame counter unit 61 according to the announcement determination data DAN and the announcement cycle data DAP from the control unit 50, and also sends the control signal CRS to the error frame count value memory unit 63. To supply.
[0061]
Thereby, the audio frame counter unit 61 performs count / reset by the count / reset signal CRE from the memory control unit 64, and five audio frames corresponding to the announcement in the second period in the announcement data: audio frames 0 to the audio frame 4 are sequentially counted, and the count value data DT obtained as a result is supplied to the error frame count value memory unit 63 and the memory control unit 64. Also, from the error frame count value memory unit 63, five audio frames corresponding to the announcement in the first period in the announcement data stored therein: an audio frame that is an error frame among the audio frames 0 to 4 The count value corresponding to 3 is read and supplied to the memory control unit 64 as the error frame count value DTE.
[0062]
When the error frame count value DTE read from the error frame count value memory unit 63 is supplied, the memory control unit 64 holds the error frame count value DTE and count value data DT from the audio frame counter unit 61. Is compared with the error frame count value DTE, that is, the count value corresponding to the audio frame 3, and the count value represented by the count value data DT from the audio frame counter unit 61 is the error frame count value DTE, That is, the count value data DT from the audio frame counter unit 61 is provided on condition that the error frame detection output signal SER from the error frame detection unit 62 is not supplied when the count value corresponding to the audio frame 3 is matched. The count value represented by The write control signal QW corresponding to the count value corresponding to the frame 3 and sends to the memory section 34. As a result, as shown in FIG. 5B, in the memory unit 34, five audio frames corresponding to the announcement in the second period in the announcement data counted by the audio frame counter unit 61: audio frame 0 ~ Writing of the audio frame 3 of the audio frames 4 is performed. Such an audio frame 3 is an audio frame including frame audio data without an error because the error frame detection output signal SER is not transmitted from the error frame detection unit 62.
[0063]
As a result, in addition to the writing for the voice frame 0, the voice frame 1, the voice frame 2 and the voice frame 4 previously made, the memory unit 34 is written for the voice frame 3, and for one period of the announcement. That is, the announcement data portion representing the voice frames 0 to 4 as being not accompanied by an error is written. In this way, when a portion of announcement data representing one cycle of the announcement without error is written in the memory unit 34, the memory control unit 64 stores the memory of the further write control signal QW. No transmission to the unit 34 is performed, and therefore writing of an audio frame forming announcement data in the memory unit 34 is not performed.
[0064]
Further, when the count value represented by the count value data DT from the audio frame counter unit 61 matches the error frame count value DTE, that is, the count value corresponding to the audio frame 3, the memory control unit 64 When the error frame detection output signal SER from 62 is supplied, five audio frames corresponding to the announcement in the second period in the announcement data: audio frame 3 in audio frame 0 to audio frame 4 are also in error. Since it is a frame, the write control signal QW is sent to the memory unit 34 in accordance with the count value represented by the count value data DT from the audio frame counter unit 61, that is, the count value corresponding to the audio frame 3. Absent. Then, for five voice frames corresponding to the announcement in the third period in the announcement data: voice frames 0 to 4, five voice frames corresponding to the announcement in the second period in the announcement data described above. : The same processing as in the case of the audio frame 0 to the audio frame 4 is performed, and the audio frame 3 is obtained as an audio frame including frame audio data without an error, and is written in the memory unit 34. Repeat until.
[0065]
Thereafter, when the memory read command signal CMR from the control unit 50 is supplied, the memory control unit 64 sends a read control signal QR to the memory unit 34 in response to the memory read command signal CMR, and the switch 33. Then, a switching control signal CS for sending the movable contact 33c to the selection contact 33b is sent to the switch 33. As a result, the portion of the announcement data representing one cycle of the announcement, that is, the voice frame 0 to the voice frame 4 as being not accompanied by an error, is read from the memory unit 34 once or a predetermined number of times. Then, the audio program data DAD ′ is supplied to the selection contact 33b of the switch 33, and is supplied to the high-efficiency decoding unit 36 through the selection contact 33b and the movable contact 33c of the switch 33.
[0066]
【The invention's effect】
As is apparent from the above description, in the broadcast signal receiving apparatus according to any one of claims 1 to 5 in the claims of the present application, the data reproduction unit converts the digital audio broadcast signal into a digital audio broadcast signal. Announcement period detection output formed by detecting the period of the announcement represented by the announcement data included in the program data based on the control information data from the control unit, and reproducing the program data and control information data based on The announcement data control unit to which the program data from the data reproduction unit and the announcement cycle detection output from the control unit are supplied, announces that the program data is repeated a plurality of times with a predetermined cycle. Announcement data One time in the memory unit, the state becomes the portion of the announcement data representing one period of the announcement as without error is written is set.
[0067]
At that time, the announcement data control unit forms the announcement data for one cycle of the announcement as in the broadcast signal receiving apparatus according to the invention described in claim 3 of the claims of the present application, for example. The frame audio data included in each of a plurality of audio frames corresponding to the above is inspected, and a state is set in which only frame audio data without error is written in the memory unit. Sets the state in which frame audio data without errors included in a plurality of audio frames corresponding to one period of subsequent announcements, and corresponding to the frame audio data with errors described above is written in the memory unit It is supposed to be.
[0068]
Therefore, according to the broadcast signal receiving apparatus according to any one of claims 1 to 5 in the claims of the present application, announcement data representing an announcement that is repeated a plurality of times with a predetermined period. Even if it is assumed that an error has occurred in part, announcement data that represents one period of the announcement without an error can be stored in the memory unit. Therefore, it is possible to effectively avoid the inconvenience caused by the error.
[Brief description of the drawings]
FIG. 1 is a block configuration diagram showing an example of a broadcast signal receiving apparatus according to the invention described in any one of claims 1 to 5 in the claims of the present application.
FIG. 2 is a signal format used to explain a digital audio broadcast signal received by the example shown in FIG.
FIG. 3 is a data format used for explaining audio program data obtained in the example shown in FIG. 1;
4 is a block configuration diagram showing a specific configuration example of an announcement data control unit in the example shown in FIG. 1;
FIG. 5 is a conceptual diagram for explaining the operation of a specific configuration example of the announcement data control unit shown in FIG. 4;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 21 ... Reception antenna, 22 ... Channel selection receiving part, 23 ... Data reproduction part, 24 ... Synchronization control signal formation part, 25 ... A / D conversion part, 26 ... Orthogonal demodulation , 27... FFT differential demodulator, 28... Frequency deinterleaver, 29... Program selection unit, 30 ... time deinterleave unit, 31 .. Viterbi decoding unit, 32. Data selection unit, 33 ... switch, 34 ... memory unit, 35 ... announcement data control unit, 36 ... high-efficiency decoding unit, 37 ... D / A conversion unit, 39. ..Decoding unit 50 ... Control unit 51 ... Remote operation control unit 52 ... Reception unit 53 ... Input operation unit 61 ... Audio frame counter unit 62 ... Error Frame detector, 63 ... error Mukaunto value memory section, 64 ... memory control unit

Claims (5)

A receiver for selectively receiving a digital audio broadcast signal;
A data reproduction unit for reproducing the program data and the control information data based on the digital audio broadcast signal received by the reception unit;
An audio signal output unit for obtaining a reproduced audio signal based on the program data reproduced by the data reproduction unit;
Control information data reproduced by the data reproduction unit is supplied, and based on a portion corresponding to the announcement data included in the program data in the control information data, an announcement cycle represented by the announcement data is determined. A control unit for detecting and sending an announcement period detection output representing the detected period;
A memory unit for writing and reading program data reproduced by the data reproducing unit;
When the program data reproduced by the data reproduction unit and the announcement period detection output sent from the control unit are supplied, and the program data is announcement data representing an announcement repeated a plurality of times with a predetermined period, An announcement data control unit for setting a state in which a portion of announcement data representing one cycle of the announcement without error is written in the memory unit;
A broadcast signal receiving apparatus comprising: 2. The broadcast according to claim 1, further comprising a data switching unit that selectively supplies program data reproduced by the data reproduction unit and announcement data read from the memory unit to the audio signal output unit. Signal receiving device. An announcement data control unit inspects frame audio data included in each of a plurality of audio frames corresponding to one period of announcement forming the announcement data, and an audio frame including frame audio data without error Only in the state where only the data is written in the memory unit, and instead of the audio frame including the frame audio data with an error, a frame without an error among a plurality of audio frames corresponding to one period of the next announcement or later The broadcast signal reception according to claim 1 or 2, wherein audio data is included, and an audio frame corresponding to an audio frame including the frame audio data accompanied by the error is written in the memory unit. apparatus. Announcement data control unit, which forms announcement data, sequentially counts each of a plurality of audio frames corresponding to each period of the announcement, and obtains a count value that gradually changes, and An error frame detection unit that detects frame audio data that includes an error among audio frames, and a frame that includes the error when the error frame detection unit detects an audio frame that includes frame audio data that includes an error. An error frame count value memory unit in which a count value obtained by the counter unit is written for audio frames including audio data, and a count value for each of a plurality of audio frames corresponding to a predetermined period obtained from the counter unit The above error frame count value memory Is a count value for a plurality of audio frames corresponding to a period other than the count value written in the above and one cycle after the predetermined one cycle, and is written in the error frame count value memory unit A memory control unit configured to set a state in which a voice frame corresponding to each count value corresponding to the count value and a count value of the voice frame including the frame voice data without error is written to the memory unit. The broadcast signal receiving apparatus according to claim 3. Announcement cycle detection output sent from the control unit is supplied to the memory control unit, and in response to the announcement cycle detection output, the counter unit is reset and the count value is read from the error frame count value memory unit. The broadcast signal receiving apparatus according to claim 4, wherein the broadcast signal receiving apparatus is performed.

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