JP3885690B2 - Digital broadcast receiver - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a digital broadcast receiving apparatus that receives BS (Broadcasting Satellite) digital broadcast and CS (Communication Satellite) digital broadcast.
[0002]
[Prior art]
Recently, the progress of communication technology using communication networks and satellites has been remarkable. Currently, a digital broadcasting service for distributing video and audio data via a communication satellite using MPEG2 (Moving Picture Experts Group phase 2) has been started.
[0003]
According to the MPEG2 standard, the MPEG2-TS (Transport Stream) format, which is a multiplexing / separation method compatible with multiple programs (multiple programs), and one program are multiplexed into basic packets for time division transmission. There are two types of MPEG2-PS (Program Stream) format, and the former is mainly applied to digital broadcasting services.
[0004]
Digital broadcast services to which the MPEG2-TS format is applied include real-time services and storage services. In the real-time type service, a transmission method using an independent PES (Packetized Elementary Stream) is used, and video and audio data are transmitted to the receiving device. The receiving device receives the data received from the transmitting device in real time. Process and output video and audio. On the other hand, in the storage type service, a carousel transmission system of MPEG-2 DSM-CC (Digital Storage Media-Command and Control: server-terminal control protocol) is used.
[0005]
The data transmitted from the transmission device in the storage type service includes, for example, data obtained by dividing and multiplexing a control program for the CPU of the reception device to control the reception device. When the receiving device receives the divided and multiplexed control program data, the receiving device converts the received signal into data of a unit called a section by the demultiplexer. The section data includes a plurality of block data obtained by dividing the control program, and combined data for generating a control program by combining the plurality of block data. The CPU of the receiving device detects block data and synthesized data from the section data, causes the decoder to synthesize the block data based on the synthesized data, generates a control program, and this control program generates an existing control in the receiving device. Update the program. As a result, the control program for the receiving apparatus is always automatically updated to a new one, and the operability and functionality of the receiving apparatus are enhanced.
[0006]
However, when the received signal is converted into section data by the demultiplexer, if the CPU is busy, synthesized data and block data cannot be detected from the section data, and a control program cannot be generated. The received broadcast signal may be wasted. In carousel transmission in digital broadcasting, a broadcast signal is repeatedly transmitted from a transmission device, but since the same data is transmitted at intervals of several weeks, if the reception device fails to use the broadcast signal once, the control program is updated. It will be late. In addition, the number of transmissions in the control program download service is limited, and if the timing of receiving the broadcast signal in the receiving device and the state of the CPU do not match, the receiving device cannot process the broadcast signal and update the control program. There was no problem. .
[0007]
By the way, conventionally, various ideas for improving data communication efficiency have been made. For example, according to the “game data communication device using satellite communication” described in Japanese Patent Application Laid-Open No. 06-044269, the receiving device receives game data transmitted cyclically from the transmitting device by radio wave broadcasting, and has a large capacity. The game data stored in the storage device is executed. Thereby, in communication that does not necessarily require two-way communication, the reception device can receive a large amount of game data at a high speed regardless of the traffic state.
[0008]
[Problems to be solved by the invention]
However, the device described in Japanese Patent Laid-Open No. 06-044269, which is the above-mentioned prior art, can receive data at high speed, but does not achieve improved detection accuracy when detecting desired data from a broadcast signal. In addition, the above-described problem that the broadcast signal cannot be processed and the control program cannot be updated when the CPU is busy cannot be solved.
[0009]
Therefore, an object of the present invention is to provide a digital broadcast receiving apparatus that can reliably generate a control program from section data and update an existing control program without delay.
[0010]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the invention according to claim 1 is a reception for receiving a broadcast signal of a digital broadcast and scheduled data indicating a broadcast scheduled time of the digital broadcast, for example, as shown in FIGS. In a digital broadcast receiving apparatus (for example, the television receiver 1) that includes means (for example, the television antenna 11) and can process the data of the real-time service and the data of the storage service ,
First storage means (for example, memory 16) for storing a first program for controlling the digital broadcast receiver;
A second storage means (for example, HDD 19);
Control means for storing the storage service data received by the receiving means at the scheduled broadcast time indicated by the schedule data in the second storage means;
A plurality of pieces of divided data (for example, block data) obtained by dividing a second program for controlling the digital broadcast receiving device from the storage service data stored in the second storage means, and the plurality of pieces of divided data Detection means for detecting synthesized data for synthesis (for example, synthesized data);
Combining means for generating the second program by combining the plurality of divided data based on the combined data detected by the detecting means;
Updating means for updating the first program stored in the first storage means by the second program generated by the combining means;
CPU (for example, CPU 23) having
With
The second storage means is an HDD (Hard Disk Drive),
The CPU reads out the data of the accumulation type service stored in the second storage means when the data of the real time type service is not being processed, and performs detection, synthesis, and update processing. Features.
[0011]
According to the first aspect of the present invention, the control program receives the divided and multiplexed broadcast signal based on the scheduled broadcast time indicated by the scheduled data, stores the broadcast signal in the storage means, and the divided data and the combined data from the stored broadcast signal. And a control program can be generated. For this reason, even when each part of the digital broadcast receiving apparatus is busy when receiving a broadcast signal, the control means can read and process the broadcast signal stored in the storage means when it can be processed, and generate a control program. Therefore, the control program can be reliably updated. Further, the operability and functionality of the digital receiver can be improved by updating the control program. Furthermore, it is not always necessary to monitor the broadcast signal received by the receiving means, and only the broadcast signal received at the time determined by the scheduled data needs to be stored in the storage means. And the processing speed of the control means can be maintained.
[0012]
According to the second aspect of the present invention, for example, as shown in FIGS. 2 and 3, a digital broadcast receiving apparatus (for example, the television receiving apparatus 1) provided with receiving means (for example, the television antenna 11) for receiving a broadcast signal of digital broadcasting. )
First storage means (for example, memory 16) for storing a first program for controlling the digital broadcast receiver;
A second storage means (for example, HDD 19);
Control means (for example, CPU 23) for storing the broadcast signal received by the receiving means in the second storage means;
To synthesize a plurality of divided data (for example, block data) obtained by dividing a second program for controlling the digital broadcast receiving device and the plurality of divided data from the broadcast signal stored in the second storage means. Detecting means (for example, CPU 23) for detecting the synthesized data (for example, synthesized data);
Combining means (for example, CPU 23) for generating the second program by combining the plurality of divided data based on the combined data detected by the detecting means;
Updating means (for example, CPU 23) for updating the first program stored in the first storage means by the second program generated by the combining means;
Equipped with a,
The second storage means is an HDD ( Hard Disk Drive ) .
[0013]
According to the second aspect of the present invention, the digital broadcast signal is received and stored in the storage means, and the divided data and the synthesized data are detected from the stored broadcast signal to generate the control program. For this reason, even if each part constituting the digital broadcast receiving apparatus is busy when receiving the broadcast signal, the control means can read and process the stored broadcast signal when it can be processed and generate a control program. The control program can be updated. Further, the operability and functionality of the digital receiver can be improved by updating the control program.
[0014]
The invention described in claim 3 is the digital broadcast receiver according to claim 2,
The receiving means receives schedule data indicating a scheduled broadcast time of the digital broadcast;
The control means stores the broadcast signal received by the receiving means at the scheduled broadcast time indicated by the schedule data in the second storage means.
[0015]
According to the third aspect of the present invention, the schedule data indicating the scheduled broadcast time of the digital broadcast is used to receive the broadcast signal divided and multiplexed by the control program and store it in the storage means. Therefore, it is possible to reliably store the broadcast signal necessary for generating the control program in the storage means without losing it. Therefore, the accuracy of generation and update of the control program can be improved. Further, it is not always necessary to monitor the broadcast signal received by the receiving means, and only the broadcast signal received at the time determined by the schedule data need be stored in the storage means. And the processing speed of the control means can be maintained.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, specific correspondence of the present invention will be described with reference to the drawings. However, the scope of the invention is not limited to the illustrated examples.
[0017]
First, the data structure of MPEG2-TS will be described with reference to FIG.
The transport stream (hereinafter referred to as TS) 200 is time-sequentially added to the compressed video signal, audio signal, and data in a plurality of programs, or time-divisionally added to the control program, and sequentially added in time series. It is a single data string that is multiplexed side by side.
[0018]
The TS 200 is composed of one or more TS packets 210, and one TS 200 is transmitted by one transponder (transponder) of the communication satellite to be one TS 200 per position channel. The TS packet 210 has a fixed length of 188 times, and includes a TS header 220 having a fixed length of 4 bytes and a data area 230 having a fixed length of 184 bytes. In the TS header 220, information such as a synchronization byte 240 indicating a packet public bath and a PID (Packet IDentifier) 250 for identifying the packet is shown.
[0019]
The TS packet 210 is classified into one in which program data constituting a program is stored in the data area 230 and one in which PSI (Program Specific Information: program usage information) is stored in the data area 230. The program data is a video signal, audio signal, data, or the like of each program, or a control program divided and multiplexed.
[0020]
The control program in the present embodiment is a program for the television receiver 1 (see FIG. 2) to be described later to control its own device. Specifically, for example, a communication control program, a broadcast signal conversion program, an error correction processing program, and the like.
[0021]
PSI is classified into PAT (Program Association Table), PMT (Program Map Table), NIT (Network Information Table), and CAT (Conditional Access Table). Is done.
[0022]
The PAT is information for designating the PID of the TS packet 210 including the PMT for each program. The PMT is information for designating the PID of the TS packet 210 including program data. For example, the PID of the video signal, the PID of the audio signal, the PID of the data, or the PID of the control program is described. CAT is information for designating a PID of a packet including decryption information for scrambling in pay broadcasting. NIT is physical information (for example, frequency for each transponder) regarding the transmission path.
[0023]
Next, a digital broadcast receiving apparatus to which the present invention is applied will be described.
FIG. 2 is a schematic block diagram showing a functional configuration of the television receiver 1 according to the embodiment to which the present invention is applied. As shown in FIG. 2, the television receiver 1 includes a television antenna 11, a tuner 12, a demodulator / FEC unit 13, a descrambler 14, a demultiplexer 15, a memory 16, a program information demodulator 17, The OSD processing unit 18, HDD 19, decoder 20, frame memory 21, signal conversion circuit 22, CPU 23, operation unit 24 and the like are configured.
[0024]
The television antenna 11 is a receiving means, and receives a broadcast signal transmitted from a digital broadcast transmission station (not shown).
The types of broadcast signals received by the television antenna 11 include broadcast signals in which audio / video signals and data are multiplexed, and broadcast signals in which a control program for controlling each part of the television receiver 1 is divided and multiplexed. And an SDTT broadcast signal for notifying the scheduled time for transmitting the control program from the transmitting station. The SDTT (Software Download Trigger Table) is data indicating the scheduled transmission time of the control program, and is transmitted several hours before the control program is transmitted from the transmitting station.
[0025]
The tuner 12 selects a broadcast signal of a specific channel from the broadcast signals received by the television antenna 11 and outputs the selected broadcast signal to the demodulation and FEC unit 13.
[0026]
The demodulator and FEC (Forward Error Correction) unit 13 demodulates the broadcast signal input from the tuner 12 and converts it into a digital broadcast signal to restore the TS, and then performs error correction processing and outputs the result to the demultiplexer 15. .
[0027]
The descrambler 14 is a pay channel TS that requires a viewing contract, and the TS demodulated by the demodulation and FEC unit 13 and input from the demultiplexer 15 is a scramble signal for preventing unauthorized viewing. If the CPU 23 determines that the viewing contract is made by referring to the viewing contract information in the memory 16, the scramble signal added to the TS is released, and the decoded TS is output to the demultiplexer 15.
[0028]
The demultiplexer 15 separates and extracts various data from each TS packet included in the decoded TS input from the descrambler 14. The demultiplexer 15 extracts the audio video signal and the program information from the TS packet when the TS packet to be processed is a signal in which the audio video signal including the audio signal and the video signal and the program information are multiplexed, A digital video signal and a digital audio signal are separated and extracted from the audio / video signal. Next, the extracted program information is output to the program information demodulator 17, and the digital video signal and the digital audio signal are output to the decoder 20. On the other hand, when the TS input from the descrambler 14 is SDTT data, the demultiplexer 15 outputs the TS to the memory 16 for storage.
[0029]
The case where the TS decoded by the descrambler 14 and input to the demultiplexer 15 is data for the control program will be described below with reference to the drawings.
FIG. 3A is a diagram illustrating the data of the section that is separated and extracted from the TS packet by the demultiplexer 15, and FIG. 3B is a diagram illustrating the data configuration of the section illustrated in FIG. When the TS input from the descrambler 14 is a control program, the demultiplexer 15 uses the 188-byte TS packets obtained by dividing the control program signal as shown in FIG. Data (each section is 4096 bytes) is extracted and output to the HDD 19.
[0030]
As shown in FIG. 3B, the section data is composed of a plurality of data blocks. Each data block includes a header that stores an identifier for identifying the data block and a data area that stores actual data. Data blocks include DII that stores composite data and DDB that stores block data obtained by dividing control program data. The combined data is data for generating a control program that can be processed by the CPU 23 by combining the control programs that are divided and stored in a plurality of data blocks.
[0031]
An HDD (Hard Disk Drive) 19 is a second storage unit, stores section data input from the demultiplexer 15, and outputs section data to the CPU 23 in accordance with an instruction from the CPU 23.
[0032]
When the digital audio signal is input from the demultiplexer 15, the decoder 20 decodes the compressed digital audio signal into an analog audio signal and outputs the analog audio signal to the speaker 2. When a digital video signal is input, the compressed digital video signal is expanded and decoded into an RGB signal and output to the frame memory 21.
[0033]
The frame memory 21 stores the RGB signal input from the decoder 20 for one frame and outputs it to the signal conversion circuit 22.
[0034]
The signal conversion circuit 22 down-converts the RGB signal input from the frame memory 21 into a video signal and outputs the video signal to the monitor 3. The signal conversion circuit 22 down-converts the program guide table data input from the OSD processing unit 22 into a video signal and outputs the video signal to the monitor 3.
[0035]
The program information demodulator 17 demodulates the program information (SI; Service Information) input from the demultiplexer 15 and outputs it to the memory 16.
[0036]
The memory 16 is a first storage unit and is configured by a nonvolatile semiconductor memory. The memory 16 stores a system program, various processing programs corresponding to the system, data processed by the various processing programs, and the like. The various programs are stored in a computer-readable form, and the CPU 23 sequentially executes operations according to the program code.
[0037]
Specifically, the memory 16 includes viewing contract information related to a pay channel viewing contract, program information demodulated and input by the program information demodulator 17, SDTT data input from the demultiplexer 15, and the CPU 23 serving as the television receiver 1. A control program for controlling the respective units, a control program generation processing program, and the like are stored. The memory 16 outputs program information to the OSD processing unit 18 in accordance with an instruction from the CPU 23. Further, when a control program generated by the CPU 23 is input to the memory 16, the existing control program is updated in the memory 16 by the input control program.
[0038]
An OSD (On Screen Display) processing unit 18 creates program guide table data to be displayed on the monitor 3 based on the demodulated program information input from the program information demodulation unit 17 and outputs the program guide table data to the signal conversion circuit 22. .
[0039]
A CPU (Central Processing Unit) 23 is a control unit, a detection unit, a synthesis unit, and an update unit, and centrally controls each part of the television receiver 1 according to a system program and a control program stored in the memory 16. Further, the CPU 23 executes processing based on the instruction data input from the operation input unit 24 and saves processing results of various processings in a predetermined storage destination in the memory 16. Further, the CPU 23 executes a control program generation process using the control program stored in the memory 16.
[0040]
In the control program generation process, the CPU 23 stores the SDTT data received from the transmission station in the memory 16, and when the scheduled data transmission time of the control program indicated by the SDTT comes, it is received from the transmission station and converted by the demultiplexer 15. The obtained section data is stored in the HDD 19. Further, the CPU 23 reads the section data stored in the HDD 19 and detects the DII and DDB data blocks when the real-time service data such as the video / audio signal is not being processed. Further, the composite data is extracted from the data block of DII, the block data obtained by dividing the control program from the data block of DDB and the identifier of each data block are extracted, and the block data is based on the extracted composite data and identifier. To generate a control program. Then, the CPU 23 outputs the generated control program to the memory 16 and updates the existing control program with the newly generated control program.
[0041]
The operation unit 24 includes input elements such as an operation panel and a remote controller (not shown). When the user performs operations such as cursor operation, icon designation, and numeric input using these input elements, instruction data instructing execution of various processes such as program playback, stop, recording, and reservation is input, and the operation unit 24 outputs the input instruction data to the CPU 23.
[0042]
Next, main operations of the CPU 23 of the television receiver 1 in the present embodiment will be described.
In the control program generation process, the CPU 23 stores the received SDTT data in the memory 16, and when the broadcast signal received at the time indicated by the SDTT is converted into section data by the demultiplexer 15, the data of this section is converted. It is stored in the HDD 19.
[0043]
Next, when the CPU 23 is not processing the real-time service data, the CPU 23 reads the section data stored in the HDD 19 and detects the data block identifier stored in the header for each data block of the section. It is determined whether the data block is DII or DDB.
[0044]
Next, the CPU 23 extracts the composite data from the data area of the DII data block, extracts the data block identifier from the header of each DDB, and extracts the block data obtained by dividing the control program from the data area of the DDB.
[0045]
Subsequently, the CPU 23 generates a control program by rearranging and synthesizing the data blocks extracted from the DDB based on the synthesized data and the data block identifier of the DDB. Then, the generated control program is output to the memory 16 to update the existing control program in the memory 16.
[0046]
As described above, in the present embodiment, in the television receiver 1, the HDD 19 stores the section data into which the control program is divided. Therefore, when the demultiplexer 15 outputs the section data, the CPU 23 Even if it is busy, the CPU 23 detects DII and DDB from the section data stored in the HDD 19 when it is no longer busy, extracts the synthesized data, synthesizes the block data based on the synthesized data, and the control program Can be generated.
[0047]
This also allows the CPU 23 to update the control program in the memory 16 without delay, and to control each part of the television receiver 1 using the updated control program, thereby improving the functionality and operability of the television receiver 1. Can be made.
[0048]
Further, the CPU 23 can reliably store the section data in the HDD 19 based on the scheduled broadcast time indicated by the SDTT. Further, since it is not necessary to constantly monitor the section data output from the demultiplexer 15, the processing load on the CPU 23 can be reduced, and the processing speed of the CPU 23 can be prevented from being lowered.
[0049]
Furthermore, even if the accuracy of the algorithm for detecting the composite data and the block data of the control program from the section data is not high, the CPU 23 can repeatedly execute the block data detection process until the control program can be generated. Can be generated and existing control programs can be updated.
[0050]
In addition, the television receiver 1 according to the present embodiment can be configured without significantly changing the configuration of the conventional digital broadcast receiver, and therefore development costs can be suppressed.
[0051]
The present invention is not limited to the above-described embodiment, and various improvements and changes may be made without departing from the spirit of the present invention.
For example, in the above embodiment, the SDTT data is stored in the memory 16 and the broadcast signal received at the time indicated by the SDTT by the CPU 23 is stored in the HDD 19. And receiving and storing broadcast signals by setting the received SDTT in this timer.
[0052]
【The invention's effect】
As described above, according to the present invention, a digital broadcast receiving apparatus can reliably generate a control program from a broadcast signal and automatically update an existing control program to a new program.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing a data structure of MPEG2-TS.
FIG. 2 is a schematic block diagram showing a functional configuration of a television receiver 1 according to an embodiment to which the present invention is applied.
3A is a diagram showing section data separated and extracted from a TS packet by the demultiplexer 15 in FIG. 2, and FIG. 3B is a diagram showing a data configuration of the section shown in FIG. is there.
[Explanation of symbols]
1 TV receiver 11 TV antenna 12 tuner 13 demodulator and FEC unit 14 descrambler 15 demultiplexer 16 memory 17 program information demodulator 18 OSD processor 19 HDD
20 Decoder 21 Frame memory 22 Signal conversion circuit 23 CPU
24 Operation unit 30 Speaker 31 Monitor 200 Transport stream 210 TS packet 220 TS header 230 Data area 240 Synchronization byte 250 PID

Claims (1)

Receiving means for receiving a broadcast signal of a digital broadcast and schedule data indicating a scheduled broadcast time of the digital broadcast,
In a digital broadcast receiver capable of processing real-time service data and storage service data ,
First storage means for storing a first program for controlling the digital broadcast receiver;
A second storage means;
Control means for storing the storage service data received by the receiving means at the scheduled broadcast time indicated by the schedule data in the second storage means;
A plurality of divided data obtained by dividing the second program for controlling the digital broadcast receiving apparatus from the storage service data stored in the second storage means, and composite data for combining the plurality of divided data Detecting means for detecting
Combining means for generating the second program by combining the plurality of divided data based on the combined data detected by the detecting means;
Updating means for updating the first program stored in the first storage means by the second program generated by the combining means;
A CPU having
With
The second storage means is an HDD (Hard Disk Drive),
The CPU reads out the data of the accumulation type service stored in the second storage means when the data of the real time type service is not being processed, and performs detection, synthesis, and update processing. A digital broadcast receiver characterized by the above.

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