JP2010035088A - Digital broadcast receiving apparatus and method of acquiring ip packet multiplexed to digital broadcasting - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide "a digital broadcast receiving apparatus and a method of acquiring IP packets multiplexed to digital broadcast" which allow users to receive as quickly as possible the IP data formed of IP packets, acquired by acquiring missing IP packets within a period as short as possible, even when packets are lost for poor receiving conditions of the digital broadcast waves. <P>SOLUTION: Missing packets which cannot be acquired via the broadcast link can be obtained via a mobile phone terminal 200, and the missing packets can be acquired immediately, without having to wait for the retransmission of the same packets (missing packets) by the carousel system, by identifying the missing packets which cannot be acquired, on the basis of serial number code data, or the like, of the IP packets acquired via the broadcast link and by receiving the identified missing packets via the mobile phone terminal 200 from the Web server 220 through the communication link. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a digital broadcast receiving apparatus and a method for obtaining an IP packet multiplexed in a digital broadcast, and more particularly to a technique for receiving a digital broadcast in which IP packet data is multiplexed in addition to a normal streaming broadcast.

In recent years, IP packets constituting IP (Internet Protocol) data are multiplexed into MPEG2-TS (Transport Stream) packets (hereinafter referred to as TS packets) including MPEG-2 data, and broadcast stations receive broadcast receivers. A broadcasting system that transmits TS packets using digital broadcasting signals has been realized (see, for example, Patent Document 1).
JP 2006-287750 A

  FIG. 9 is a block diagram illustrating a configuration example of a conventional broadcast receiving apparatus. The broadcast tuner 3 of the broadcast receiving apparatus 1 receives a digital broadcast signal via the receiving antenna 2 and performs a demodulation process. By the demodulation processing by the broadcast tuner 3, TS packets are extracted from the received digital broadcast signal and sent to the TS decoder 4. The TS decoder 4 performs a predetermined decoding process on the TS packet, and separates and extracts the MPEG-2 packet (video / audio packet) and the IP packet. The video / audio decoder 5 decodes (decompresses) the video / audio packets separated and extracted by the TS decoder 4 and outputs the decoded video data to the OSD (On Screen Display) display processing unit 6, while similarly decoded audio Data is output to the external speaker 7. On the other hand, the data decoder 9 decodes the IP packet separated and extracted by the TS decoder 4 and outputs the decoded IP data (for example, HTML data, XML data, etc.) to the OSD display processing unit 6 via the WWW browser 9. . The OSD display processing unit 6 generates an OSD display image based on the IP data output from the data decoder 8 via the WWW browser 9, and uses the generated OSD display image and the video data output from the video / audio decoder 5. A synthesized image obtained by synthesizing the image is output to the monitor 10.

  By the way, in the case of a broadcast receiving apparatus for in-vehicle use or portable use, when the radio wave is moved while receiving a digital broadcast signal, the reception radio wave condition changes each time due to a change in the reception environment. However, some TS packets may not be acquired. Even in this case, since the same TS packet is periodically and repeatedly transmitted from the broadcasting station by the carousel method, the missing TS packet can be acquired later.

  However, since the retransmission interval of the carousel method is a parameter that is generally arbitrarily determined on the broadcast station side, the time until the TS packet is retransmitted is not known at all on the reception side. Therefore, when it takes a long time to receive a TS packet retransmitted by the carousel method from the broadcasting station (that is, when the retransmission cycle of the carousel method is long), the IP data retransmitted by that amount is acquired and presented to the user. There was a problem that the time to do it would also be long. This problem is particularly the data in which the IP data included in the IP packet included in the TS packet is required to be real-time (for example, Web data required to be synchronized with the video output from the video / audio decoder 5). In some cases it appears prominently.

In addition, even when it is difficult to receive terrestrial digital television broadcasts due to poor reception conditions, a technology has been proposed that enables seamless viewing of terrestrial digital broadcasts (see, for example, Patent Document 2). . Specifically, the error occurrence level in terrestrial digital television broadcast reception is constantly monitored, and the mobile phone network is used to connect to the IP network immediately before the received electric field strength decreases and the error correction limit is reached. Receive transmitted content.
JP 2007-158492 A

  However, in the technique described in Patent Document 2, when it is difficult to receive terrestrial digital television broadcasts, the program is seamlessly switched from program viewing by digital terrestrial television reception to program viewing through IP network communication. When the TS packet cannot be acquired, the missing TS packet cannot be acquired later. That is, the Web data that is required to be synchronized with the video output from the video / audio decoder 5 may remain undisplayed.

  The present invention has been made to solve such a problem, and even when a reception state of a digital broadcast wave is bad and a lost packet is generated, the lost IP packet is removed in as short a time as possible. It is an object of the present invention to shorten the time required for obtaining and presenting IP data including the obtained IP packet to a user as much as possible.

  In order to solve the above-described problem, in the present invention, a packet that has not been acquired among a plurality of packets constituting IP data acquired via a broadcast line is specified as a lost packet, and transmission of the specified lost packet is performed. A request is made to the server for storing the IP data via the communication line, and a missing packet is received from the server via the communication line in response to the request.

  According to the present invention configured as described above, a missing packet that could not be acquired via a broadcast line among a plurality of packets constituting IP data can be reacquired via a communication line. Even if an IP packet is lost due to a bad condition, it is not necessary to wait until the same packet is retransmitted by the carousel method, and the lost packet can be acquired immediately. Therefore, it is possible to present the IP data including the IP packet lost via the broadcast line to the user in as short a time as possible.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, a first embodiment of the invention will be described with reference to the drawings. FIG. 1 is a diagram illustrating an example of the overall configuration of a digital broadcast receiving system 100 according to the first embodiment. As shown in FIG. 1, the digital broadcast receiving system 100 includes a digital broadcast transmitting device 120, a digital broadcast receiving device 140, a speaker 160, a monitor 180, a mobile phone terminal 200, and a Web server 220. Among these, the digital broadcast transmission apparatus 120 is installed in a broadcast station, for example. The digital broadcast receiving device 140, the speaker 160, the monitor 180, and the mobile phone terminal 200 are installed, for example, in a viewer's house where the digital broadcast is viewed. The web storage server 220 is installed in a data distribution center, for example. The digital broadcast transmitter 120 and the digital broadcast receiver 140 are connected by a broadcast line. Further, the digital broadcast receiving apparatus 140, the mobile phone terminal 200, and the Web server 220 are connected by a wired or wireless communication line.

  Next, the functional configuration of the digital broadcast transmission apparatus 120 will be described. As shown in FIG. 1, the digital broadcast transmission apparatus 120 includes a video / audio data storage unit 300, an IP data storage unit 320, a program schedule information storage unit 340, a transmission control unit 360, a multiplexing unit 380, a transmission unit 400, and an IP packet. A transmission unit 420 is provided.

  The video / audio data storage unit 300 stores video data and audio data including digital moving image data and digital still image data. Each digital video data is given a video data ID as a unique identification number. Each voice data is assigned a voice data ID as a unique identification number. The IP data storage unit 320 stores, for example, IP data such as HTML data or XML data. Each IP data is given an IP data ID as a unique identification number.

  The program schedule information storage unit 340 stores program schedule information. The program schedule information includes program ID information indicating a program ID for identifying the program, broadcast start date / time information indicating the broadcast start date / time of the program, and video data ID information corresponding to one or more video data used in the program. , Audio data ID information corresponding to one or more audio data used in the program, IP data ID information corresponding to one or more IP data used in the program, and a TS packet to which each IP data is described later at what timing Is table information associated with timing information indicating whether or not to be multiplexed.

  The transmission control unit 360 refers to the broadcast start date / time information in the program schedule information stored in the program schedule information storage unit 320, and the current date / time acquired from the clock unit (not shown) is indicated by the broadcast start date / time information. It is determined whether or not the broadcast start date / time has been reached. If the transmission control unit 360 determines that the current date / time has reached the broadcast start date / time, the video data ID information, the audio data ID information, and the IP data ID information associated with the broadcast start date / time information, A multiplexing request signal for requesting a process of multiplexing voice data and IP data into TS packets is output to multiplexing section 380. Here, the multiplexing request signal includes video data ID information, audio data ID information, and IP data ID information associated with broadcast start date / time information in the program schedule information.

  When the multiplexing unit 380 receives the multiplexing request signal output from the transmission control unit 360, the multiplexing unit 380 converts the video data and audio data corresponding to the video data ID information and the audio data ID information included in the multiplexing request signal into video and audio. It is taken out from the data storage unit 300. Then, the multiplexing unit 380 divides the video data and audio data extracted from the video / audio data storage unit 300 into a predetermined size, packetizes the divided video data and audio data, and generates a plurality of video / audio packets. . The multiplexing unit 380 attaches a serial number code to each video / audio packet. For example, serial numbers are assigned sequentially from the smallest number, such as “1” to “10”.

  Further, upon receiving the multiplexing request signal output from transmission control unit 360, multiplexing unit 380 takes out IP data corresponding to the IP data ID information included in the multiplexing request signal from IP data storage unit 320. Then, the multiplexing unit 380 divides the IP data extracted from the IP data storage unit 320 into a predetermined size, packetizes the divided IP data, and generates a plurality of IP packets. The multiplexing unit 380 attaches a serial number code to each IP packet. For example, serial numbers are assigned sequentially from the smallest number, such as “1” to “10”. Each IP packet includes serial number code information indicating a serial number code attached to the IP packet and a range of serial number codes (for example, 1 to 100) of a plurality of IP packets constituting a group of IP data. The configuration information shown and IP data ID information unique to each IP data are included. In the present embodiment, a group of IP data refers to, for example, the entire IP data constituting one web page.

  The multiplexing unit 380 multiplexes one or more video / audio packets and one or more IP packets to generate a TS packet. Note that the serial number codes of video / audio packets and IP packets included in TS packets are not always in order from the smallest number. The multiplexing unit 380 outputs the TS packet to the transmission unit 400 every time a TS packet is generated. In addition, each time the multiplexing unit 380 generates an IP packet that constitutes a TS packet, the multiplexing unit 380 outputs each IP packet, its serial number information, and IP data ID information to the IP packet transmission unit 420.

  The transmission unit 400 performs modulation processing on the TS packet output from the multiplexing unit 380 to generate a digital broadcast signal. Each time the transmission unit 400 generates a digital broadcast signal, the transmission unit 400 transmits the digital broadcast signal to the digital broadcast reception device 140 via a wired or wireless broadcast line. Each time the IP packet transmission unit 420 receives each IP packet output from the multiplexing unit 380 and its serial number information and IP data ID information, it sequentially transmits them to the Web server 220.

  Next, the functional configuration of the digital broadcast receiving apparatus 140 will be described. As shown in FIG. 1, the digital broadcast receiving apparatus 140 includes a broadcast tuner 500 (corresponding to a receiving unit in claims), a TS decoder 520 (corresponding to an acquiring unit in claims), and a video / audio decoder 540. , Data decoder 560 (corresponding to claims acquisition unit), IP packet buffer 580, time measuring unit 600, specifying unit 620, transmission request unit 640, packet receiving unit 660, missing packet buffer 680, WWW browser 700 and OSD A display processing unit 720 is provided. Note that a speaker 160 and a monitor 180 are connected to the digital broadcast receiving apparatus 140 as its accessory devices.

  The broadcast tuner 500 receives a digital broadcast signal transmitted from the transmission unit 400 of the digital broadcast transmission device 120 via a broadcast line and performs demodulation processing. Broadcast tuner 500 then extracts a TS packet from the digital broadcast signal by demodulation processing, and outputs the extracted TS packet to TS decoder 520.

  The TS decoder 520 performs a predetermined decoding process on the TS packet output from the broadcast tuner 500, and separates and extracts the video / audio packet and the IP packet. The TS decoder 520 outputs the separated video / audio packet to the video / audio decoder 540. Also, the TS decoder 520 outputs the separated and extracted IP packet to the data decoder 560.

  The video / audio decoder 540 decodes the video / audio packet output from the TS decoder 520 and outputs the video data obtained by the decoding to the OSD display processing unit 720. The video / audio decoder 540 outputs audio data obtained by decoding from the video / audio packet to the speaker 160.

  The data decoder 560 decodes the IP packet output from the TS decoder 520 and stores the decoded serial code information and configuration information in the IP packet buffer 580 in association with the decoded IP data ID information. Further, the data decoder 560 outputs IP data decoded from the IP packet obtained from the TS decoder 520 to the WWW browser 700.

  Further, the data decoder 560 acquires and decodes the missing packet stored in the missing packet buffer 680 as necessary, and outputs the decoded IP data to the WWW browser 700. When the decoding is performed by acquiring the missing packet from the missing packet buffer 680, the data decoder 560 deletes the obtained missing packet from the missing packet buffer 680.

  The timer unit 600 calculates an elapsed time after the broadcast tuner 500 starts receiving a digital broadcast signal. In addition, the timer 600 resets the elapsed time every time a predetermined time (for example, 5 seconds) has elapsed since the calculation of the elapsed time is started (set to 0 second). That is, the time measuring unit 600 repeatedly performs the counting operation for 5 seconds after the reception of the digital broadcast signal is started.

  When the elapsed time calculated by the timer unit 600 reaches a predetermined time, the specifying unit 620 uses the configuration information based on the serial number code information, configuration information, and IP data ID information stored in the IP packet buffer 580. Of the range of serial numbers shown, an IP packet with a missing serial number is specified as a missing packet. For example, the range of the serial number code indicated by the configuration information corresponding to certain IP data ID information is 1 to 10, and the serial number code indicated by the serial number code information stored in the IP packet buffer 580 is 1, In the case of 2, 3, 4, 6, 8, 9, 10, the identifying unit 620 identifies the missing IP packet with the serial number (5, 7) as a missing packet. When a plurality of pieces of IP data ID information are stored in the IP packet buffer 580, the specifying unit 620 specifies a missing packet for each piece of IP data ID information based on configuration information and serial number code information.

  Further, when identifying the missing packet, the identifying unit 620 deletes the information stored in the IP packet buffer 580. The identifying unit 620 outputs, to the transmission requesting unit 640, missing packet information indicating a serial number code of the IP packet identified as a missing packet and a set of IP data ID information corresponding thereto.

  The transmission request unit 640 transmits a lost packet transmission request signal requesting transmission processing of a lost packet indicated by the lost packet information output from the specifying unit 620 to the mobile phone terminal 200. The cellular phone terminal 200 transmits the missing packet transmission request signal transmitted from the transmission request unit 640 to the Web server 220. Here, the missing packet transmission request signal includes serial number code information and IP data ID information of the IP packet corresponding to the missing packet. Further, the transmission request unit 640 holds the address of the Web server 220 and notifies the mobile phone terminal 200 of this.

  The packet receiving unit 660 receives an IP packet (missing packet) transmitted from the Web server 220 via the mobile phone terminal 200 in response to the missing packet transmission request from the transmission request unit 640. Each time the packet receiving unit 660 receives an IP packet from the Web server 220 via the mobile phone terminal 200, the packet receiving unit 660 stores the received IP packet in the missing packet buffer 680.

  The WWW browser 700 analyzes the IP data output from the data decoder 560 and generates a display image. Then, the WWW browser 700 outputs the generated display image to the OSD display processing unit 720. The OSD display processing unit 720 combines the display image output from the WWW browser 700 and the display image based on the video data output from the video / audio decoder 540 to generate a composite image. Then, the OSD display processing unit 720 outputs the generated composite image to the monitor 180.

  Next, the functional configuration of the Web server 220 will be described. As shown in FIG. 1, the Web server 220 includes an IP packet receiving unit 800, an IP packet storage unit 820, a missing packet acquisition unit 840, and a missing packet transmission unit 860.

  The IP packet receiving unit 800 receives the IP packet transmitted from the IP packet transmitting unit 420 of the digital broadcast transmitting device 120, its serial number information, and IP data ID information. Then, the IP packet receiving unit 800 stores the received IP packet in the IP packet storage unit 820 in association with the serial number code information and the IP data ID information.

  The missing packet acquisition unit 840 receives the missing packet transmission request signal transmitted from the mobile phone terminal 200. After that, the missing packet acquisition unit 840 refers to the sequence number code information and the IP data ID information stored in the IP packet storage unit 820, and the sequence number code information and the IP data included in the received missing packet transmission request signal. An IP packet corresponding to the ID information is acquired from the IP packet storage unit 820. Thereafter, the missing packet acquisition unit 840 outputs the IP packet (missing packet) acquired from the IP packet storage unit 820 to the missing packet transmission unit 860.

  The missing packet transmission unit 860 transmits the IP packet output from the missing packet acquisition unit 840 to the mobile phone terminal 200. The mobile phone terminal 200 transmits the IP packet transmitted from the missing packet transmitter 860 to the packet receiver 660 of the digital broadcast receiver 140.

  Next, the operation of the digital broadcast receiving system 100 in the first embodiment will be described. 2 and 3 are flowcharts showing an operation example of the digital broadcast receiving system 100. FIG. FIG. 3 is a flowchart subsequent to FIG. The processing in step S100 in FIG. 2 is acquired from the clock unit by the transmission control unit 360 of the digital broadcast transmission device 120 with reference to the broadcast start date / time information in the program schedule information stored in the program schedule information storage unit 320. It starts when it is determined that the current date / time has reached the broadcast start date / time indicated by the broadcast start date / time information.

  First, the transmission control unit 360 outputs a multiplexing request signal associated with the broadcast start date / time information to the multiplexing unit 380 (step S100). When the multiplexing unit 380 receives the multiplexing request signal output from the transmission control unit 360, the multiplexing unit 380 converts the video data and audio data corresponding to the video data ID information and the audio data ID information included in the multiplexing request signal into video and audio. It is taken out from the data storage unit 300. Then, the multiplexing unit 380 divides the video data and audio data extracted from the video / audio data storage unit 300 into a predetermined size, packetizes the divided video data and audio data, and generates a plurality of video / audio packets. (Step S120).

  Further, upon receiving the multiplexing request signal output from transmission control unit 360, multiplexing unit 380 takes out IP data corresponding to the IP data ID information included in the multiplexing request signal from IP data storage unit 320. Then, the multiplexing unit 380 divides the IP data extracted from the IP data storage unit 320 into a predetermined size, packetizes the divided IP data, and generates a plurality of IP packets (step S140).

  Next, the IP packet transmission unit 420 transmits each IP packet generated by the multiplexing unit 380 in Step S140, its serial number information, and IP data ID information to the Web server 220 (Step S160). The IP packet receiving unit 800 of the Web server 220 receives the IP packet transmitted from the IP packet transmitting unit 420 of the digital broadcast transmitting apparatus 120, its serial number information, and IP data ID information. Then, IP packet receiving section 800 stores the received IP packet in IP packet storage section 820 in association with the serial code information and IP data ID information (step S180).

  Next, the multiplexing unit 380 multiplexes one or more video / audio packets and one or more IP packets to generate a TS packet (step S200). Next, the transmission unit 400 performs modulation processing on the TS packet generated by the multiplexing unit 380 to generate a digital broadcast signal, and transmits the digital broadcast signal to the digital broadcast reception device 140 via a wired or wireless broadcast line. (Step S220). The broadcast tuner 500 of the digital broadcast receiver 140 receives a digital broadcast signal transmitted from the transmitter 400 of the digital broadcast transmitter 120 via a broadcast line and performs demodulation processing.

  Next, the time measuring unit 600 starts calculating the elapsed time after the broadcast tuner 500 starts receiving the digital broadcast signal (step S240). Next, the TS decoder 520 performs a predetermined decoding process on the TS packet output from the broadcast tuner 500, and separates and extracts the video / audio packet and the IP packet (step S260). The TS decoder 520 outputs the separated video / audio packet to the video / audio decoder 540. Also, the TS decoder 520 outputs the separated and extracted IP packet to the data decoder 560.

  Next, the video / audio decoder 540 decodes the video / audio packet output from the TS decoder 520, and outputs the decoded video data to the OSD display processing unit 720 (step S280). Further, the data decoder 560 decodes the IP packet output from the TS decoder 520 and outputs the decoded IP data to the WWW browser 700 (step S300). In addition, the data decoder 560 stores the serial number code information and the configuration information obtained by the decoding in step S300 in the IP packet buffer 580 in association with the IP data ID information obtained by the decoding (step S320).

  Next, the timer unit 600 determines whether or not the elapsed time has reached a predetermined time (for example, 5 seconds) (step S340). If elapsed time has not reached the predetermined time in timer unit 600 (NO in step S340), the process transitions to step S440. On the other hand, when time counting unit 600 determines that the elapsed time has reached the predetermined time (YES in step S340), time measuring unit 600 resets the elapsed time and starts counting elapsed time from zero again (step S400). S360). Next, the digital broadcast receiving device 140, the mobile phone terminal 200, and the Web server 220 execute a lost packet acquisition process (see FIG. 4) described later (step S380).

  After completion of the missing packet acquisition process in step S380, the data decoder 560 determines whether or not a missing packet is stored in the missing packet buffer 680 (step S400). If data decoder 560 determines that a missing packet is not stored in missing packet buffer 680 (NO in step S400), the process transitions to step S440. On the other hand, when data decoder 560 determines that the missing packet is stored in missing packet buffer 680 (YES in step S400), data decoder 560 decodes the missing packet stored in missing packet buffer 680. The decrypted IP data is output to the WWW browser 700 (step S420). Thereafter, the data decoder 560 deletes the missing packet stored in the missing packet buffer 680.

  Next, the WWW browser 700 analyzes the IP data output from the data decoder 560 in steps S300 and S420, and generates a display image (step S440). Next, the OSD display processing unit 720 generates a composite image by combining the display image output from the WWW browser 700 and the display image based on the video data output from the video / audio decoder 540 (step S460). Next, the OSD display processing unit 720 outputs the generated composite image to the monitor 180 (step S480). Also, the video / audio decoder 540 outputs the audio data decoded in step S260 to the speaker 160 (step S500).

  Next, the digital broadcast receiving apparatus 140 determines whether or not a power-off operation has been performed by the user (step S520). If digital broadcast receiving apparatus 140 determines that power-off operation has not been performed (NO in step S520), the process transitions to step S260 in FIG. On the other hand, when digital broadcast transmitting apparatus 140 determines that the power-off operation has been performed (YES in step S520), digital broadcast receiving apparatus 140 ends the processes in FIGS.

  On the other hand, in digital broadcast transmitting apparatus 120, multiplexing section 380 determines whether or not TS packets have been generated using all the video / audio packets and IP packets generated in steps S120 and S140 (step S540). ). If multiplexing unit 380 determines that TS packets are not generated using all the video / audio packets and IP packets generated in steps S120 and S140 (NO in step S540), the process is as follows. The process proceeds to step S200 in FIG. On the other hand, when multiplexing unit 380 determines that the TS packet has been generated using all the video / audio packets and IP packets generated in steps S120 and S140 (YES in step S540), the digital broadcast transmission device In step 120, the processing in FIGS. 2 and 3 ends.

  Next, the lost packet acquisition process executed in step S380 in FIG. 2 will be described. FIG. 3 is a flowchart showing an example of a missing packet acquisition operation performed by the digital broadcast receiving device 140, the mobile phone terminal 200, and the Web server 220. First, the identifying unit 620, based on the sequence code information, configuration information, and IP data ID information stored in the IP packet buffer 580, lacks the sequence numbers that are missing from the range of the sequence code indicated by the configuration information. It is determined whether or not there is a signed IP packet (missing packet) (step S600). If determining unit 620 determines that there is no missing packet (NO in step S600), digital broadcast receiving apparatus 140, mobile phone terminal 200, and Web server 220 end the processing in FIG.

  On the other hand, when determining unit 620 determines that there is a missing packet (YES in step S600), specifying unit 620 sets the serial number code of the IP packet specified as the missing packet and the corresponding IP data ID information. Is output to the transmission request unit 640 (step S620). Next, the transmission request unit 640 transmits a lost packet transmission request signal for requesting transmission processing of the lost packet indicated by the lost packet information output from the specifying unit 620 to the mobile phone terminal 200 (step S640). The cellular phone terminal 200 transmits the missing packet transmission request signal transmitted from the transmission request unit 640 to the Web server 220. The missing packet acquisition unit 840 receives the missing packet transmission request signal transmitted from the mobile phone terminal 200.

  Next, the missing packet acquisition unit 840 refers to the sequence number code information and the IP data ID information stored in the IP packet storage unit 820, and the sequence number code information and the IP included in the received missing packet transmission request signal. An IP packet corresponding to the data ID information is acquired from the IP packet storage unit 820 (step S660). The missing packet acquisition unit 840 outputs the IP packet (missing packet) acquired from the IP packet storage unit 820 to the missing packet transmission unit 860.

  Next, the missing packet transmission unit 860 transmits the IP packet output from the missing packet acquisition unit 840 to the mobile phone terminal 200 (step S680). The mobile phone terminal 200 transmits the IP packet transmitted from the missing packet transmitter 860 to the packet receiver 660 of the digital broadcast receiver 140. The packet receiving unit 660 receives the IP packet transmitted from the mobile phone terminal 200.

  Finally, the packet receiving unit 660 stores the IP packet (missing packet) received from the Web server 220 via the mobile phone terminal 200 in the missing packet buffer 680 (step S700). When the processing in step S700 ends, the digital broadcast receiving device 140, the mobile phone terminal 200, and the web server 220 end the processing in FIG.

  As described above in detail, in the first embodiment, each time the elapsed time calculated by the time measuring unit 600 exceeds a predetermined time, the specifying unit 620 includes the serial number included in the IP packet acquired by the data decoder 560. Based on the code information, the configuration information, and the IP data ID information, an IP packet having a missing serial number code is specified as a missing packet in the range of the serial code indicated by the configuration information. Then, the transmission request unit 640 requests the Web server 220 to transmit the identified missing packet via the communication line, and in response to the request, the packet receiving unit 660 sends the missing packet from the Web server 220 via the communication line. I try to receive it.

  As described above, even if an IP packet is lost in the digital broadcast signal received by the broadcast tuner 500, the lost packet can be acquired via the communication line. As a result, even when the reception status of the digital broadcast wave is bad and the IP packet is lost, it is not necessary to wait until the same packet is retransmitted by the carousel method, and the lost packet can be acquired immediately. Therefore, it is possible to present the IP data including the IP packet lost via the broadcast line to the user in as short a time as possible.

  In the first embodiment, the example in which the missing packet specifying process is performed every time the elapsed time calculated by the time measuring unit 600 reaches the predetermined time has been described. However, the timing for specifying the missing packet is not limited thereto. . For example, every time a predetermined number of IP packets accumulate in the IP packet buffer 580, the missing packet identification process may be performed.

  Alternatively, the missing packet identification process may be performed every time information is stored in the entire storage area of the IP packet buffer 580. Alternatively, the missing packet identification process may be performed each time the IP data ID information stored in the IP packet buffer 580 is switched. In this way, it is possible to accurately identify the IP packet that is actually missing for each group of IP data.

  In the first embodiment, the example in which the IP packet in which the serial number code is missing in the range of the serial number code indicated by the configuration information has been described as the missing packet. However, the missing packet is identified. The embodiment is not limited to this. For example, the minimum serial number code and the maximum serial number code among the serial number code information stored for each IP data ID information in the IP packet buffer 580 are obtained, and the obtained minimum serial number code and the maximum serial number code are obtained. An IP packet corresponding to a serial number that is missing from the serial number may be specified as a lost packet. In this way, for example, even when missing packet identification processing is performed in units of a predetermined time and a predetermined number of packets, an actually missing IP packet can be accurately identified.

  Next, a second embodiment of the present invention will be described with reference to the drawings. FIG. 5 is a block diagram showing an example of the overall configuration of a digital broadcast receiving system 100 ′ according to the second embodiment. In FIG. 5, those given the same reference numerals as those shown in FIG. 1 have the same functions, and therefore redundant description is omitted here.

  In the second embodiment, the digital broadcast receiving device 140 ′ does not include the time measuring unit 600 of FIG. 1. Further, the digital broadcast receiving apparatus 140 'includes a data decoder 560' instead of the data decoder 560 of FIG. Further, the digital broadcast receiving apparatus 140 ′ includes a specifying unit 620 ′ instead of the specifying unit 620 of FIG. 1. In the second embodiment, it is assumed that the serial number codes of video / audio packets and IP packets included in TS packets generated by the multiplexing unit 380 are in order from the smallest number.

  In the second embodiment, the data decoder 560 ′ acquires IP packets from the TS decoder 520 in the order of serial numbers. The data decoder 560 ′ decodes the IP packet output from the TS decoder 520, and stores the serial number code information obtained by decoding in the IP packet buffer 580 in association with the IP data ID information obtained by the decoding. The IP packet buffer 580 only needs to have a storage area that can store serial number code information regarding at least two IP packets together with IP data ID information by a FIFO (First-In First-Out) method. The data decoder 560 ′ outputs IP data decoded from the IP packet to the WWW browser 700.

  Further, the data decoder 560 ′ acquires and decodes the missing packet stored in the missing packet buffer 680 as necessary, and outputs the decoded IP data to the WWW browser 700. When the decoding is performed by acquiring the missing packet from the missing packet buffer 680, the data decoder 560 deletes the obtained missing packet from the missing packet buffer 680.

  Based on the serial number code information stored in the IP packet buffer 580, the identifying unit 620 ′ adds the serial number code added to the IP packet acquired this time by the data decoder 560 ′ and the IP packet acquired last time. It is determined whether or not the consecutive serial number codes are consecutive in order. If it is determined that the serial number codes are not consecutive in order, the identifying unit 620 ′ determines the serial number assigned to the IP packet acquired this time and the serial number assigned to the IP packet acquired last time. The IP packet corresponding to the serial number code existing between the codes is specified as a missing packet.

  For example, when the serial number attached to the IP packet acquired this time by the data decoder 560 ′ is 5, and the serial number attached to the IP packet acquired last time is 2, the identifying unit 620 ′ Corresponds to the serial numbers (3 and 4) existing between the serial number (5) attached to the IP packet acquired this time and the serial number (2) attached to the IP packet acquired last time. An IP packet is identified as a missing packet. The identifying unit 620 ′ outputs, to the transmission request unit 640, missing packet information indicating a set of serial number codes of IP packets identified as missing packets and corresponding IP data ID information.

  Next, the operation of the digital broadcast receiving system 100 'in the second embodiment will be described. 6 and 7 are flowcharts showing an operation example of the digital broadcast receiving system 100 '. FIG. 7 is a flowchart subsequent to FIG. The process of step S800 in FIG. 6 is acquired from the clock unit by referring to the broadcast start date / time information in the program schedule information stored in the program schedule information storage unit 320 by the transmission control unit 360 of the digital broadcast transmission device 120. It starts when it is determined that the current date / time has reached the broadcast start date / time indicated by the broadcast start date / time information. In FIG. 6, steps S800 to S1000 are the same as steps S100 to S220 and steps S260 to S320 of FIG.

  After the data decoder 560 ′ associates the serial number code information, configuration information, and IP data ID information in step S1000 of FIG. 6 and stores them in the IP packet buffer 580, in step S1020 of FIG. The telephone terminal 200 and the Web server 220 execute a lost packet acquisition process (see FIG. 8) described later. The subsequent processes in steps S1040 to S1180 are the same as the processes in steps S400 to S540 of FIG.

  Next, the lost packet acquisition process executed by the digital broadcast receiving device 140 ′, the mobile phone terminal 200, and the Web server 220 in step S <b> 1020 of FIG. 7 will be described. FIG. 8 is a flowchart showing an operation example of missing packet acquisition by the digital broadcast receiving device 140 ′, the mobile phone terminal 200, and the Web server 220.

  First, the identifying unit 620 ′ determines the serial number code attached to the IP packet acquired this time by the data decoder 560 ′ and the IP packet acquired last time based on the serial number code information stored in the IP packet buffer 580. It is determined whether or not the serial numbers attached to are consecutive in order (step S1300). If the identifying unit 620 ′ determines that the serial number code assigned to the IP packet acquired this time and the serial number code assigned to the IP packet acquired last time are consecutive in order (step In S1300, NO), digital broadcast receiving device 140 ′, mobile phone terminal 200, and Web server 220 end the process in FIG.

  On the other hand, if the identifying unit 620 ′ determines that the serial number code assigned to the IP packet acquired this time and the serial number code assigned to the IP packet acquired last time are not consecutive in order (step) In S1300, YES), the specifying unit 620 ′ determines the serial number code existing between the serial number code assigned to the IP packet acquired this time and the serial number code assigned to the IP packet acquired last time, and this The missing packet information indicating the set of IP data ID information corresponding to is output to the transmission request unit 640 (step S1320). The subsequent processing in steps S1340 to S1400 is the same as the processing in steps S640 to S700 in FIG.

  As described above in detail, in the second embodiment, the identifying unit 620 ′ uses the serial number attached to the IP packet acquired this time by the data decoder 560 ′ and the serial number attached to the IP packet acquired last time. When the serial number is not consecutive in order, it corresponds to the serial number code existing between the serial number code attached to the packet acquired this time and the serial number code attached to the packet acquired last time Identify the packet as a missing packet. Then, the transmission request unit 640 requests the Web server 220 to transmit the identified missing packet via the communication line, and in response to the request, the packet receiving unit 660 sends the missing packet from the Web server 220 via the communication line. I try to receive it.

  As described above, every time an IP packet is acquired by the data decoder 560 ′, the serial number code assigned to the IP packet acquired this time and the serial number code assigned to the IP packet acquired last time are consecutive in order. If not, the missing packet can be acquired via the communication line. Thereby, a missing packet can be acquired earlier than the first embodiment in which a missing packet is obtained via a communication line when the elapsed time calculated by the time measuring unit 600 reaches a predetermined time.

  In the first and second embodiments, the example in which the Web server 220 includes the IP packet storage unit 820 has been described. However, the present invention is not limited to this. For example, the digital broadcast transmission device 120 may include the IP packet storage unit 820. In this case, when a missing packet transmission request signal is transmitted from the transmission request unit 640 to the Web server 220, the Web server 220 accesses the digital broadcast transmission device 120 to acquire the missing packet, and the packet reception unit 660 Send to. Specifically, the missing packet acquisition unit 840 refers to the serial number code information and the IP data ID information stored in the IP packet storage unit 820 of the data broadcast transmission device 120, and sets the received missing packet transmission request signal. An IP packet corresponding to the included serial number code information and IP data ID information is acquired from the IP packet storage unit 820. Thereafter, the missing packet transmission unit 860 transmits the IP packet (missing packet) acquired by the missing packet acquisition unit 840 to the packet reception unit 660 of the digital broadcast receiving device 140 via the mobile phone terminal 200. In this way, it is possible to prevent useless communication between the digital broadcast transmission device 120 and the Web server 220 from occurring when a missing packet transmission request has not occurred.

  In the first and second embodiments, the transmission request unit 640 transmits only the missing packet specified by the specifying unit 620 (620 ′) among the plurality of IP packets constituting the IP data. However, the present invention is not limited to this. For example, the transmission request unit 640 performs a process of transmitting all the IP packets constituting a group of IP data including the missing packet identified by the missing packet identifying unit 620 (620 ′) and other IP packets. The request may be made to the Web server 220. However, from the viewpoint of acquiring only the missing IP packet in the shortest possible time, the Web server transmits only the missing packet identified by the missing packet identifying unit 620 (620 ′) among the plurality of IP packets constituting the IP data. It is preferable to request to 220.

  In the first and second embodiments described above, the communication line between the digital broadcast receiving apparatus 140 (140 ′) and the Web server 220 is a communication line formed via the mobile phone terminal 200. Although described, a communication line formed via another communication terminal (for example, a personal computer) may be used.

  In the first and second embodiments, the example in which the digital broadcast transmission device 120 and the Web server 220 have different configurations has been described. However, the digital broadcast transmission device 120 and the Web server 220 have an integrated configuration. May be.

  In the first and second embodiments, the missing packet is specified using the serial number code information and the IP data ID information, but the present invention is not limited to this. For example, if a unique serial number code is assigned to each IP packet belonging to different IP data ID information, the missing packet may be specified based only on the serial number code information.

  Further, in the first and second embodiments, each time the multiplexing unit 380 generates a TS packet, the IP packet included in the TS packet, its serial number information, and IP data ID information are transferred to the IP packet. Although the example which transmits to the Web server 220 via the transmission part 420 was demonstrated, this invention is not limited to this. For example, the multiplexing unit 380 transmits each IP packet, its serial number code information, and IP data ID information to the Web server 220 via the IP packet transmission unit 420 when all the IP packets are generated. Alternatively, each IP packet, its serial number code information, and IP data ID information may be transmitted to the Web server 220 in advance before multiplexing and actually transmitting a digital broadcast signal.

  In the first and second embodiments, the example in which the digital broadcast transmission device 120 includes the IP data storage unit 320 has been described. However, the Web server 220 may include the IP data storage unit 320. In this case, when the multiplexing unit 380 receives the multiplexing request signal output from the transmission control unit 360, the multiplexing unit 380 stores the IP data corresponding to the IP data ID information included in the multiplexing request signal in the IP data storage of the Web server 220. Obtained from the unit 320. Then, the multiplexing unit 380 divides the IP data extracted from the IP data storage unit 320 into a predetermined size, packetizes the divided IP data, and generates a plurality of IP packets.

  In addition, each of the first and second embodiments described above is merely an example of a specific example for carrying out the present invention, and the technical scope of the present invention should not be interpreted in a limited manner. It will not be. In other words, the present invention can be implemented in various forms without departing from the spirit or main features thereof.

1 is a block diagram illustrating an example of the overall configuration of a digital broadcast receiving system according to a first embodiment. It is a flowchart which shows the operation example of the digital broadcast receiving system by 1st Embodiment. It is a flowchart which shows the operation example of the digital broadcast receiving system by 1st Embodiment. It is a flowchart which shows the operation example of the digital broadcast receiving system by 1st Embodiment. It is a block diagram which shows the example of whole structure of the digital broadcast receiving system by 2nd Embodiment. It is a flowchart which shows the operation example of the digital broadcast receiving system by 2nd Embodiment. It is a flowchart which shows the operation example of the digital broadcast receiving system by 2nd Embodiment. It is a flowchart which shows the operation example of the digital broadcast receiving system by 2nd Embodiment. It is a block diagram which shows the structural example of the conventional digital broadcast receiver.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100,100 'Digital broadcast receiver system 120 Digital broadcast transmitter 140,140' Digital broadcast receiver 200 Mobile phone terminal 220 Web server 500 Broadcast tuner 520 TS decoder 560,560 'Data decoder 620,620' Specific part 640 Transmission request part 660 packet receiver

Claims (5)

A receiver for receiving a digital broadcast signal via a broadcast line;
An acquisition unit for acquiring a plurality of packets constituting IP data from the digital broadcast signal received by the reception unit;
A specifying unit that identifies, as a missing packet, a packet that has not been acquired by the acquiring unit among a plurality of packets that form the IP data;
A transmission requesting unit for requesting the server storing the IP data via a communication line to transmit the missing packet identified by at least the identifying unit among the plurality of packets;
A digital broadcast receiving apparatus comprising: a packet receiving unit configured to receive a packet transmitted from the server via the communication line in response to a request from the transmission request unit. The digital broadcast receiver according to claim 1,
The digital broadcast receiving apparatus, wherein the transmission request unit requests the server to transmit only the missing packet. In the digital broadcast receiver according to claim 1 or 2,
The packet includes serial number code information indicating a serial number code attached to the packet and configuration information indicating a range of serial number codes of a plurality of packets constituting the IP data,
Based on the serial number code information and the configuration information included in the packet acquired by the acquisition unit, the specifying unit includes a serial number code that is missing from a range of serial numbers indicated by the configuration information. A digital broadcast receiver characterized by identifying a packet as a missing packet. In the digital broadcast receiver according to claim 1 or 2,
The packet includes serial number code information indicating a serial number code attached to the packet,
The acquisition unit acquires the packets in the order of the serial numbers,
When the serial number code attached to the packet acquired this time by the acquisition unit and the serial number code attached to the packet acquired last time are not consecutive in order, the specifying unit is acquired this time A digital broadcast receiver characterized in that a packet corresponding to a serial number code existing between a serial number code assigned to a packet and a serial number code assigned to the previously acquired packet is specified as a missing packet. . A first step of receiving a digital broadcast signal via a broadcast line;
A second step of obtaining a plurality of packets constituting IP data from the digital broadcast signal received in the first step;
A third step of identifying, as a missing packet, a packet that has not been acquired by the second step among the plurality of packets;
A fourth step of requesting transmission of the missing packet identified by the third step to a server storing the IP data via a communication line;
And a fifth step of receiving the missing packet from the server via the communication line in response to a request in the fourth step, and a method for obtaining an IP packet multiplexed in digital broadcasting. .