JP6521330B2 - Receiving apparatus and receiving method - Google Patents

Description

  The present technology relates to a receiving device and a receiving method, and in particular, in channel bonding, a receiving device capable of minimizing the influence of double wrap of time information indicating the order of selection of BB frames; It relates to the reception method.

  In digital broadcasting, a high data rate stream is divided into a plurality of (channel) divided streams and transmitted, and the receiving side reconstructs the plurality of divided streams into an original data rate stream (Channel Bonding) )It has been known. According to the DVB-C2 (Digital Video Broadcasting-Cable second generation) standard, PLP bundling (PLP (Physical Layer Pipe) bundling) is defined as one of channel bonding (see, for example, Non-Patent Document 1).

DVB-C.2: ETSI EN 302 769 V1.2.1 (2011-04)

  By the way, in the DVB-C2 standard, data is transmitted in BB (Baseband) frames, but when PLP bundling is performed, on the receiver side, ISSY (Input Stream) included in the BB header added to the BB frame By referring to the Input Stream Time Reference (ISCR) of the Synchronizer, the order of BB frames constituting the plurality of divided streams is specified, and the original stream is reconstructed (restored).

  As described above, ISCR is the only order information (time information) for specifying the order of BB frames transmitted as a plurality of divided streams, but since this ISCR is a 15-bit or 22-bit counter If the maximum value of the counter is exceeded, it will be counted again from zero.

  Therefore, when counter values of different orbits coexist (hereinafter referred to as "double wrap") and an ISCR becomes double wrap, an appropriate BB frame can not be determined from selectable BB frames. Therefore, BB frames can not be rearranged accurately. Therefore, in channel bonding, there is a demand to minimize the influence of the double wrap of ISCR, which is time information indicating the order of selection of BB frames.

  The present technology has been made in view of such a situation, and is intended to minimize the influence of double wrapping of time information indicating the order of selection of BB frames in channel bonding.

  A receiving apparatus according to an aspect of the present technology includes: a receiving unit that receives a plurality of divided streams obtained by distributing a BB frame of a BB stream, which is a stream of BB (Base Band) frames, into a plurality of data slices; Among the BB frames that can be selected based on bit information indicating the number of remaining bits necessary to configure the packet that stores the BB header added to the BB frame when the frame is stored in the packet And a selection unit for selecting the next BB frame, and a reconstruction unit for reconstructing the original BB stream from the plurality of divided streams by processing the BB frames in the order selected by the selection unit. And a receiver.

  The receiving device according to one aspect of the present technology may be an independent device or an internal block that constitutes one device. Further, a receiving method according to an aspect of the present technology is a receiving method corresponding to the receiving device according to the aspect of the present technology described above.

  In the receiving device and the receiving method according to one aspect of the present technology, a plurality of divided streams obtained by distributing a BB frame of a BB stream, which is a stream of BB frames, into a plurality of data slices are received. Among the BB frames that can be selected based on bit information indicating the number of remaining bits necessary to configure the packet that stores the BB header added to the BB frame when the frame is stored in the packet The next BB frame is selected, and the BB frame is processed in the selected order to reconstruct the original BB stream from the plurality of divided streams.

  According to one aspect of the present technology, in channel bonding, it is possible to minimize the influence of double wrapping of time information indicating the order of selection of BB frames.

  In addition, the effect described here is not necessarily limited, and may be any effect described in the present disclosure.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram illustrating a configuration of an embodiment of a transmission system to which the present technology is applied. It is a figure explaining the outline of PLP bundling. It is a figure which shows the structural example of a transmitter. It is a flowchart explaining the flow of transmission processing. It is a figure which shows the structural example of a receiver. It is a flowchart explaining the flow of reception processing. It is a figure which shows the flow of BB frame processed with a transmitter and a receiver. It is a figure which shows the example of the format of a BB frame. It is a figure which shows the example of the format of ISSY included in a BB header. It is a figure explaining the double wrap of ISCR in PLP bundling. It is a figure explaining the avoidance method of the double lap of ISCR using SYNCD. It is a figure which shows the functional structural example of the control part in the case of performing the selection BB frame determination using SYNCD. It is a flowchart explaining the flow of the 1st BB frame selection processing. It is a figure explaining the avoidance method of the double lap of ISCR using the difference value of ISCR. It is a figure explaining the avoidance method of the double lap of ISCR using the difference value of ISCR. It is a figure which shows the functional structural example of a control part in the case of performing selection BB frame determination using the difference value of ISCR. It is a flowchart explaining the flow of 2nd BB frame selection processing. It is a figure showing an example of composition of a computer.

  Hereinafter, embodiments of the present technology will be described with reference to the drawings. The description will be made in the following order.

1. System configuration Configuration of apparatus compatible with PLP bundling 3. Method of avoiding double overlap of ISCR in PLP bundling (1) Determination of selected BB frame using SYNCD (2) Determination of selected BB frame using difference value of ISCR Computer configuration

<1. System configuration>

  FIG. 1 is a diagram showing the configuration of an embodiment of a transmission system to which the present technology is applied. Note that the system is a logical aggregation of a plurality of devices, and it does not matter whether the devices of each configuration are in the same case.

  In FIG. 1, the transmission system 1 includes a transmitting device 10 and a receiving device 20.

  The transmission device 10 transmits, for example, a television program or the like (digital broadcasting or data transmission). That is, the transmitter 10 transmits, for example, a transmission path 30 which is a cable television network (wired line) as a digital broadcast signal, for example, a stream of target data to be transmitted, such as video data or audio data as a television program. Send via (transmit).

  The receiving device 20 receives the digital broadcast signal transmitted from the transmitting device 10 via the transmission path 30, restores the original stream, and outputs it. For example, the receiving device 20 outputs video data and audio data as a television program.

  The transmission system 1 shown in FIG. 1 includes data transmission based on the DVB-C2 standard, DVB-T2 standard, DVB-S2 standard, Advanced Television Systems Committee standards (ATSC), Integrated Services Digital Broadcasting (ISDB), etc. It can be applied to data transmission conforming to the standard and other data transmission. Further, as the transmission line 30, a satellite communication line, a terrestrial wave, etc. can be adopted other than the cable television network.

<2. Configuration of device compatible with PLP bundling>

(Overview of PLP bundling)
FIG. 2 is a diagram for explaining the outline of PLP bundling.

  In the DVB-C2 standard, PLP bundling is defined as one of channel bonding. In channel bonding, a high data rate stream is divided into a plurality of (channel) divided streams and transmitted, and on the receiving side, the plurality of divided streams are reassembled into a stream of the original data rate.

  In recent years, there has been a demand for digital broadcasting that transmits so-called 8K high resolution images, but for 8K resolution images, when encoding is performed using the High Efficiency Video Coding (HEVC) system, the encoding The throughput required for the transmission of high data rate data obtained as a result of is approximately 100 Mbps. It is difficult to transmit one data slice (Data Slice) for PLP (Physical Layer Pipe) of FIG. 2 corresponding to such high data rate data.

  Therefore, in the transmission system 1, in the transmission apparatus 10, actual data as PLP 1 can be divided in BB frame units and transmitted in a plurality of data slices by PLP bundling which is one of channel bonding. It is supposed to be. In FIG. 2, the PLP is divided into data slices 2 to 4 and transmitted to the receiver 20. In the receiving apparatus 20, data slices 2 to 4 are processed by the PLP decoder after being received and processed by the tuners 1 to 3, so that real data as PLP is reconstructed.

  In the DVB-C2 standard, a transmission band for transmitting an orthogonal frequency division multiplexing (OFDM) signal is divided into, for example, (approximately) 6 MHz units. Now, assuming that one transmission band divided into 6 MHz units is referred to as a unit transmission band, the receiving apparatus 20 transmits an OFDM signal of a unit transmission band in which a data slice including PLP of actual data of a desired television program is transmitted. Are received and the data slices contained in that OFDM signal will be processed.

  Also, PLP is a logical channel (data to be transmitted) included in a data slice, and a unique PLP ID for identifying PLP is given to PLP. For example, the PLP of a certain PLP ID corresponds to actual data of a certain television program. Hereinafter, the PLP with PLP ID i will also be described as PLP # i.

  In the following description, a stream of BB frames is referred to as "BB stream", and a plurality of streams obtained by dividing this BB stream are referred to as "divided streams". That is, the divided stream is composed of BB frames.

(Configuration of transmitter)
FIG. 3 is a diagram showing a configuration example of the transmission device 10 of FIG.

  The transmitter 10 divides actual data as one PLP # i (PLP to which the same PLP ID is given) by PLP bundling, which is one of channel bonding, in BB frame units, and a plurality of data slices Can be transmitted by

  In FIG. 3, the transmitting apparatus 10 includes a control unit 111, a BB frame generation unit 112, a BB frame distribution unit 113, data slice processing units 114-1 to 114-N (N is an integer of 1 or more), a frame configuration unit 115, And a transmission unit 116.

  The control unit 111 controls the operation of each unit of the transmission device 10.

  The BB frame generation unit 112 is supplied with actual data (for example, target data such as TS (Transport Stream)) as the PLP # i of the same PLP ID. The BB frame generation unit 112 constructs a BB frame by adding a BB header to actual data supplied thereto. The BB header includes ISCR (Input Stream Time Reference) as ISSY (Input Stream Synchronizer). The BB frame generation unit 112 supplies the BB stream composed of the BB frames to the BB frame distribution unit 113.

  The BB frame distribution unit 113 distributes the BB stream supplied from the BB frame generation unit 112 to one data slice among a plurality of data slices, using the BB stream as a target of division. By repeating the above, the BB stream is divided into a plurality of divided streams in BB frame units. In addition, the BB frame distribution unit 113 distributes a plurality of divided streams obtained by dividing the BB stream to any of the data slice processing units 114-1 to 114-N.

  The data slice processing unit 114-1 performs processing on the divided stream distributed by the BB frame distribution unit 113. The data slice processing unit 114-1 includes a PLP processing unit 131-1, a data slice configuration unit 132-1, and a time / frequency interleaver 133-1.

  The PLP processing unit 131-1 performs error correction coding on the BB frames constituting the divided frames distributed by the BB frame distribution unit 113 and supplied to the data slice processing unit 114-1. Also, the PLP processing unit 131-1 maps the FEC frame obtained as a result of the error correction coding to a signal point on a predetermined constellation in units of a predetermined number of bits as a symbol, and as a mapping result thereof A data slice packet is configured by adding an FEC frame header to an FEC frame obtained by extracting symbols in units of FEC frames.

  One or more data slice packets are supplied to the data slice configuration unit 132-1 from the PLP processing unit 131-1. The data slice configuration unit 132-1 configures a data slice from one or more data slice packets supplied from the PLP processing unit 131-1, and supplies the data slice to the time / frequency interleaver 133-1.

  The time / frequency interleaver 133-1 interleaves the data slice supplied from the data slice configuration unit 132-1 in the time direction and the frequency direction, and supplies the data slice after the interleaving to the frame configuration unit 115.

  Although the data slice processing units 114-2 to 114-N are not shown, the PLP processing units 131-2 to 131-N and the data slice configuration unit 132-2 are similar to the data slice processing unit 114-1. To 132-N and time / frequency interleavers 133-2 to 133-N. Similar to the data slice processing unit 114-1, the data slice processing units 114-2 to 114-N perform processing on the divided stream distributed by the BB frame distribution unit 113, and the data slice obtained thereby is It is supplied to the frame construction unit 115.

  In the following description, the data slice processing units 114-1 to 114 -N will be referred to as the data slice processing unit 114 unless it is necessary to distinguish them. Similarly, the PLP processing units 131-1 to 131-N, data slice configuration units 132-1 to 132-N, and time / frequency interleavers 133-1 to 133-N need not be particularly distinguished. Are referred to as the PLP processing unit 131, the data slice configuration unit 132, and the time / frequency interleaver 133, respectively.

  One or more data slices are supplied to the frame configuration unit 115 from (the time / frequency interleavers 133-1 to 133-N of) the data slice processing units 114-1 to 114-N. The frame configuration unit 115 configures a C2 frame including one or more data slices from the data slice processing units 114-1 to 114-N, and supplies the C2 frame to the transmission unit 116.

  The transmission unit 116 performs IFFT (Inverse Fast Fourier Transform) of the C2 frame supplied from the frame configuration unit 115, and performs digital to analog conversion on the OFDM signal obtained as a result. Then, the transmission unit 116 modulates the OFDM signal converted from the digital signal to the analog signal into an RF (Radio Frequency) signal, and transmits the signal as a digital broadcast signal through the transmission path 30.

  In the configuration of the transmitting apparatus 10 of FIG. 3, for convenience of explanation, illustration of blocks that are not related to PLP bundling is omitted as appropriate.

(Flow of transmission process)
Next, the flow of the transmission process performed by the transmission device 10 of FIG. 3 will be described with reference to the flowchart of FIG.

  In step S111, the BB frame generation unit 112 arranges actual data (for example, target data such as TS) as PLP supplied thereto in the data field of the BB frame, and ISSY (ISCR) in the data field. The BB frame is configured by adding the included BB header.

  In step S112, the BB frame distribution unit 113 distributes the BB frame configured in the process of step S111 to one data slice among a plurality of data slices, thereby providing a plurality of BB streams in BB frame units. Split into split streams of

  In step S113, the BB frame distribution unit 113 distributes the plurality of divided streams obtained in the process of step S112 to any of the data slice processing units 114-1 to 114-N. Thereby, a plurality of divided streams obtained by dividing the BB stream are supplied to any of the data slice processing units 114-1 to 114-N.

  In the data slice processing unit 114, the processes of steps S114 to S118 are performed. That is, in step S114, the PLP processing unit 131 performs error correction coding on the BB frames constituting the divided frames distributed by the BB frame distribution unit 113 and supplied to the data slice processing unit 114.

  In step S115, the PLP processing unit 131 maps the FEC frame obtained as a result of the error correction coding to the signal point on the predetermined constellation in units of a predetermined number of bits as a symbol in the process of step S114.

  In step S116, the PLP processing unit 131 adds the FEC frame header to the FEC frame obtained by extracting the symbol as the mapping result in the unit of FEC frame in the process of step S115, thereby a data slice being generated. Construct a packet.

  In step S117, the data slice configuration unit 132 configures a data slice from the one or more data slice packets configured by the process of step S116.

  In step S118, the time / frequency interleaver 133 interleaves the data slice configured by the process of step S117 in the time direction and the frequency direction.

  In step S119, the frame configuration unit 115 configures a C2 frame including one or more interleaved data slices from (the time / frequency interleaver 133 of) the data slice processing units 114-1 to 114-N.

  In step S120, the transmission unit 116 performs an IFFT of the C2 frame configured by the process of step S119. In step S121, the transmission unit 116 performs DA conversion on the OFDM signal obtained as a result of the IFFT in the process of step S120.

  In step S122, the D / A converted OFDM signal obtained in the process of step S121 is modulated into an RF signal, and transmitted as a digital broadcast signal through the transmission path 30 (FIG. 1). When the process of step S122 ends, the transmission process of FIG. 4 ends.

  The flow of transmission processing has been described above.

(Configuration of receiver)
FIG. 5 is a diagram showing a configuration example of the receiving device 20 of FIG.

  The receiving apparatus 20 is configured to be able to reconstruct (reconstruct) actual data that is transmitted (transmitted) by distributing one PLP # i to a plurality of data slices by PLP bundling.

  In FIG. 5, the receiving apparatus 20 includes a control unit 211, receiving units 212-1 to 212-N (N is an integer of 1 or more), data slice processing units 213-1 to 213-N, and buffers 214-1 to 214-. It comprises N, BB frame selection unit 215, and BB frame processing unit 216.

  The control unit 211 controls the operation of each unit of the receiving device 20.

  The receiving unit 212-1 receives and demodulates an RF signal of a predetermined band transmitted from the transmission device 10 through the transmission path 30 as a digital broadcast signal, and obtains a demodulated signal (OFDM signal) obtained as a result of the reception. , AD conversion (Analog to Digital Conversion). Then, the receiving unit 212-1 performs FFT (Fast Fourier Transform) of the demodulated signal converted from an analog signal to a digital signal, and supplies a data slice obtained as a result to the data slice processing unit 213-1.

  The data slice processing unit 213-1 performs processing on the data slice supplied from the reception unit 212-1. The data slice processing unit 213-1 includes a time / frequency deinterleaver 231-1, a data slice decomposition unit 232-1, and a PLP processing unit 233-1.

  The time / frequency deinterleaver 231-1 deinterleaves the data slice supplied from the reception unit 212-1 in the time direction and the frequency direction, and the data slice after the deinterleaving is processed by the data slice decomposition unit 232-. Supply to 1.

  The data slice decomposition unit 232-1 decomposes the data slice supplied from the time / frequency deinterleaver 231-1 into data slice packets, and supplies the data slice packet to the PLP processing unit 233-1.

  The PLP processing unit 233-1 disassembles the data slice packet into an FEC frame by removing the FEC frame header from the data slice packet supplied from the data slice decomposing unit 232-1. Note that the modulation scheme, code length, and the like of the FEC frame are recognized based on the removed FEC frame header, and subsequent demapping, error correction decoding, and the like are performed.

  In addition, the PLP processing unit 233-1 demaps (the symbols of) the FEC frame, and decodes the error correction code on the demapping FEC frame, thereby generating a divided stream configured of the BB frame. Restore. The divided stream (constituting BB frame) restored from the data slice by the data slice processing unit 213-1 is supplied to the buffer 214-1.

  The buffer 214-1 is configured of, for example, a FIFO (First In First Out) memory, and the divided stream (constituting BB frame) supplied from the data slice processing unit 213-1 (the PLP processing unit 233-1) is Store sequentially.

  Although the data slice processing units 213-2 to 213-N are not shown, like the data slice processing unit 213-1, time / frequency deinterleavers 231-2 to 231-N, data slice decomposing units 232-2 to 232-N and PLP processing units 233-2 to 233-N. Similar to the data slice processing unit 213-1, the data slice processing units 213-2 to 213-N perform processing on data slices supplied from the reception units 212-2 to 212-N, and are thereby obtained. The divided streams (constituting BB frames) are sequentially stored in the buffers 214-2 to 214-N.

  In the following description, the data slice processing units 213-1 to 213 -N will be referred to as the data slice processing unit 213 unless it is particularly necessary to distinguish them. Similarly, there is no need to distinguish between the time / frequency deinterleavers 231-1 to 231 -N, the data slice decomposing units 232-1 to 232 -N, and the PLP processing units 233-1 to 233 -N. The time / frequency deinterleaver 231, the data slice decomposition unit 232, and the PLP processing unit 233 will be respectively described. Furthermore, the buffers 214-1 to 214-N will be described as the buffer 214 unless it is necessary to distinguish them.

  The BB frame selection unit 215 selects the original BB stream based on ISSY (ISCR) included in the BB header added to the BB frame that configures the plurality of divided streams stored in the buffers 214-1 to 214-N. The BB frames are read from the buffers 214-1 to 214 -N in the order of the BB frames to be configured, and are supplied to the BB frame processing unit 216.

  The BB frame processing unit 216 rearranges (restores) the original BB stream by rearranging the BB frames in the order supplied from the BB frame selection unit 215. Further, the BB frame processing unit 216 decomposes the BB frame constituting the original BB stream, and restores and outputs actual data (for example, target data such as TS).

  In the configuration of the receiving apparatus 20 of FIG. 5, for the convenience of explanation, illustration is appropriately omitted for blocks that are not related to PLP bundling. Further, in the configuration of the receiving apparatus 20 of FIG. 5, the configuration in which the plurality of receiving units 212 are provided corresponding to the data slice processing unit 213 has been described, but only one receiving unit 212 capable of receiving a wide band RF signal The data slice may be provided to the data slice processing units 213-1 to 213-N by decomposing the data slice included in the C2 frame.

(Flow of reception process)
Next, the flow of the reception process performed by the receiving device of FIG. 5 will be described with reference to the flowchart of FIG.

  In step S <b> 211, the receiving unit 212 receives and demodulates the RF signal of a predetermined band transmitted from the transmission device 10 via the transmission path 30 as a digital broadcast signal.

  In step S212, the receiving unit 212 performs AD conversion of a demodulated signal (OFDM signal) obtained by demodulating an RF signal in the process of step S211.

  In step S213, the receiving unit 212 performs FFT of the digital signal obtained as a result of AD conversion in the process of step S212.

  In step S214, the time / frequency deinterleaver 231 deinterleaves the data slice obtained as a result of the process of step S213 in the time direction and in the frequency direction.

  In step S215, the data slice decomposition unit 232 decomposes the deinterleaved data slice obtained as a result of the process of step S214 into a data slice packet.

  In step S216, the PLP processing unit 233 decomposes the data slice packet into an FEC frame by removing the FEC frame header from the data slice packet decomposed in the process of step S215.

  In step S217, the PLP processing unit 233 demaps (the symbols of) the FEC frame obtained in the process of step S216.

  In step S218, the PLP processing unit 233 decodes the error correction code with respect to the FEC frame after the demapping in the process of step S217 to restore a divided stream configured of the BB frame.

  In step S219, the buffer 214 stores (buffers) the BB frame constituting the divided stream restored in the process of step S218.

  In step S220, the BB frame selection unit 215 performs BB frame selection processing. In this BB frame selection process, based on ISSY (ISCR) included in the BB header added to the BB frame constituting the plurality of divided streams stored in the buffers 214-1 to 214-N in the process of step S219. A process of selecting a BB frame to be read from the buffers 214-1 to 214-N is performed.

  That is, the BB frames constituting the divided stream stored in the buffers 214-1 to 214-N are stored in the buffers 214-1 to 214-N until the timing in the order of arrangement in the original BB stream, and the original BB stream is stored. When it comes to the timing of the arrangement order in, the buffers 214-1 to 214-N are read out. The detailed contents of the BB frame selection process will be described later with reference to the flowcharts of FIGS. 13 and 17.

  In step S221, the BB frame processing unit 216 performs stream reconstruction processing. In the stream reconstruction process, the BB frame selected in the process of step S220 is rearranged in the selection order to reconstruct (restore) the original BB stream.

  In step S222, the BB frame processing unit 216 decomposes the BB frame constituting the original BB stream reconstructed in the process of step S221, and restores and outputs actual data (for example, target data such as TS). When the process of step S222 ends, the reception process of FIG. 6 ends.

  The flow of the reception process has been described above.

(BB frame flow)
Next, the flow of the BB frame processed by the transmitting device 10 of FIG. 3 and the receiving device 20 of FIG. 5 in the case of performing PLP bundling will be described with reference to FIG. In addition, in FIG. 7, the transmitter 10 and the receiver 20 are abbreviate | omitting the structure of the one part. Further, a square with numbers in the figure represents a BB frame, and the numbers described therein represent the value (time stamp) of ISCR.

  In FIG. 7, in the transmitting device 10, the BB frame generation unit 112 generates a BB frame from actual data (for example, target data such as TS), and a BB header including ISSY (ISCR) is included in this BB frame. , In order. That is, in this example, although the BB frame of ISCR which is “10” to “80” is generated, the value of ISCR included in the BB header is increased by “10” at a time.

  Here, as shown in FIG. 8, the BB frame (BBFrame) is configured of a BB header (BBHeader) and a data field (DATA) in which actual data is arranged. In the BB header, 2-byte MATYPE, 2-byte ISSY, 2-byte DFL, 1-byte ISSY, 2-byte SYNCD, and 1-byte CRC-8 are arranged in this order.

  Further, FIG. 9 shows an example of the format of ISSY included in the BB header. As shown in FIG. 9, ISSY includes ISCR, BUFS, and BUFSTAT.

  ISCR is information indicating the transmission time of data (BB frame), and is 2 or 3 bytes of information. When PLP bundling is performed, ISCR is always disposed in the 3-byte field of ISSY, and is counted up every 7/48 μs as the minimum time unit of the system. The receiving apparatus 20 specifies the order of BB frames transmitted as a plurality of divided streams by referring to the ISCR having the role of this time stamp.

  The BUFS is (substantially) 2-byte information representing a buffer capacity (a required Buffer amount) of a buffer necessary to compensate for a delay variation when processing data in the receiving device 20. The receiving device 20 secures a storage area as a buffer of the buffer capacity represented by the BUFS, and compensates (absorbs) the delay variation by reading and writing data to the buffer.

  BUFSTAT is (substantially) 2-byte information indicating a read start time to read data from the buffer of the buffer capacity represented by the BUFS in the receiving device 20. In the receiving device 20, reading of data stored in the buffer of the buffer capacity represented by BUFS is started from the time represented by BUFSTAT (the timing when the remaining amount of data in the buffer becomes the value represented by BUFSTAT).

  When PLP bundling is performed, the ISCR, BUFS, and BUFSTAT ISCRs are arranged in the 3-byte field of ISSY in the BB header of each BB frame. On the other hand, when PLP bundling is not performed, any one of ISCR, BUFS, and BUFSTAT is selectively arranged for each BB frame in the 3-byte field of ISSY in the BB header.

  Returning to the description of FIG. 7, the BB frame distribution unit 113 divides the divided stream obtained by dividing the BB frame generated by the BB frame generation unit 112 into the data slice processing unit 114-1 or the data slice processing unit 114-2. Distribute to As a result, the data slice processing unit 114-1 is supplied with a divided stream composed of an ISCR BB frame of, for example, "10" to "20" and processed. Further, the data slice processing unit 114-2 is supplied with, and processed, for example, a divided stream composed of an ISCR BB frame of “30” to “40”.

  Then, in the transmission device 10, a C2 frame including those data slices is configured, and processing such as modulation is performed, whereby an RF signal is transmitted via the transmission path 30. On the other hand, in FIG. 7, in the receiving device 20, the RF signal from the transmitting device 10 is received via the transmission path 30. Then, the data slice processing unit 213-1 and the data slice processing unit 213-2 perform processing on the data slice obtained from the RF signal. Thereby, the divided stream (constituting the BB frame) restored by the data slice processing unit 213-1 is stored in the buffer 214-1, and the division stored by the data slice processing unit 213-2 is stored in the buffer 214-2. Streams (BB frames that compose the stream) are sequentially stored.

  The BB frame selection unit 215 reads the BB frame from the buffer 214-1 or the buffer 214-2 based on the ISCR included in the BB header of the BB frame stored in the buffer 214-1 and the buffer 214-2, The frame processing unit 216 is supplied. In the case of this example, the BB frame of ISCR which is "10" to "40" stored in either one of the buffer 214-1 and the buffer 214-2 is in ascending order of its value based on the value of ISCR. It has been read. Also, the "50", "60" and "90" BB frames of ISCR stored in buffer 214-1 and the "70" and "80" framework of ISCR BB frames stored in buffer 214-2 Similarly, the values of ISCR are read in ascending order.

<3. Method of avoiding double wrap of ISCR in PLP bundling>

(Influence of double lap of ISCR)
When PLP bundling is performed, ISCR is always arranged in the 3-byte field of ISSY, and on the receiving apparatus 20 side, the value (time stamp) of this ISCR is referred to as unique order information to be divided into a plurality of divided streams. As described above, the order of BB frames being distributed and transmitted is specified.

  In FIG. 10, a situation when a double wrap occurs in ISCR in the case where a plurality of divided streams divided by the transmitting apparatus 10 on the transmitting side are reconstructed (restored) to the original BB stream by the receiving apparatus 20 on the receiving side. Is schematically represented focusing on the BB frame. Here, double wrap refers to a state in which counter values of different orbits coexist, and although there is continuity in the value of each ISCR of a selectable BB frame, normally, when ISCR becomes double wrap, ISCR The value of will lose continuity.

  In FIG. 10, the left side of the transmission line 30 represented by a dotted line in the figure represents the transmission side, that is, the process performed by the transmission device 10, and the right side of the transmission line 30 represents the reception side, ie, the reception device 20. Represents the processing to be performed. Further, in FIG. 10, a square with a number in the figure represents a BB frame, and the number described therein represents the value (time stamp) of ISCR.

  Further, FIG. 10 exemplifies the case where (the stream of) actual data as PLP # i of 1 is divided in BB frame units and transmitted in 4 data slices by PLP bundling. Here, an example in which four data slices are transmitted is shown, but the number of data slices used for transmission of one PLP # i is not limited to four, and two, three, or five or more Any value of 255 or less can be adopted.

  In FIG. 10, in the transmitting device 10, a BB stream composed of a plurality of BB frames is generated, and the BB stream generated by the BB frame distribution unit 113 is divided into four divided streams in BB frame units. . In FIG. 10, assuming that data slices composed of 4 divided streams are data slices DS # 1 to DS # 4 in order from the upper side in the figure, an ISCR of "450000" in data slice DS # 1. And an ISCR BB frame that is "2450000".

  Also, the data slice DS # 2 includes an ISCR BB frame of “950000” and an ISCR BB frame of “2950000”. Further, data slice DS # 3 includes an ISCR BB frame of "1450000" and an ISCR BB frame of "3450000", and data slice DS # 4 of ISCR BB of "3950000". It contains a frame and an ISCR BB frame that is "1950000".

  The C2 frame composed of the data slice including the BB frame distributed in this way is transmitted from the transmitter 10 to the receiver 20 via the transmission path 30 as an RF signal.

  In FIG. 10, in the receiving device 20, an RF signal from the transmitting device 10 is received through the transmission path 30, the data slice processing unit 213-1 processes the data slice DS # 1, and from the data slice DS # 1. The BB frame of ISCR that is "450000" and the BB frame of ISCR that is "2450000", which constitute the restored divided stream, are sequentially stored in the buffer 214-1.

  The buffer 214-2 also includes an ISCR BB frame of "950000" and an ISCR of "2950000", which constitute a divided stream restored from the data slice DS # 2 by the data slice processing unit 213-2. BB frames are stored in order.

  In the buffer 214-3, an ISCR BB frame of "1450000" and an ISCR BB frame of "3450000", which constitute a divided stream restored from the data slice DS # 3 by the data slice processing unit 213-3. Are stored in order.

  Also, in the buffer 214-4, an ISCR BB frame of "3950000" and an ISCR of "1950000" that constitute a divided stream reconstructed from the data slice DS # 4 by the data slice processing unit 213-4. BB frames are stored in order.

  Thus, although the BB frame stored in the buffers 214-1 to 214-4 is selected by the BB frame selection unit 215, the BB frame selection unit 215 selects the buffers 214-1 to 214-4. The BB frame processing unit 216 in the subsequent stage is selected sequentially from the BB frame of the ISCR which becomes the minimum value with reference to the value (time stamp) of the ISCR of the BB header added to each BB frame stored at the beginning of It will be supplied.

  In FIG. 10, BB frames of ISCR "450000", "950000", "1450000", and "3950000" are stored at the beginning of the buffers 214-1 to 214-4, and they become selectable BB frames. However, ISCR is a 15-bit or 22-bit counter, and if it exceeds the maximum value of the counter, it is counted again from 0. Therefore, it is necessary to recognize the influence of the double overlap of ISCR and select a BB frame. For example, BB frames can not be properly rearranged. For example, in the case of a 22-bit ISCR, the maximum value thereof is "4194303".

  In the case of the example of FIG. 10, if the BB frame of ISCR having the minimum value is selected from the selectable BB frames stored at the beginning of the buffers 214-1 to 214-4, the beginning of the buffer 214-1 is selected. Although the stored "450000" ISCR BB frame is to be selected, here, assuming that the ISCR counter reaches the maximum value and is counted again from 0, the counter values of different rounds are counted. May co-exist.

  That is, in the case of the example of FIG. 10, when the value of ISCR which is "450000" is being counted by the counter value reaching the maximum value and counting being started again from 0, before the maximum value is reached. There is a possibility that the value of ISCR which is "3950000" is being counted. In this case, since the BB frame of ISCR which is "3950000" stored at the beginning of the buffer 214-4 is the BB frame to be selected next, "450000" stored at the beginning of the buffer 214-1. If a certain ISCR BB frame is selected, the BB frames will be rearranged in the wrong order.

  In this way, if the order of BB frame selection is incorrect due to the effect of ISPR double wrap, the BB frame to be selected after that BB frame (for example, “950000” or “1450000 in FIG. Even "ISCR's BB frame)" may be rearranged in the wrong order, and the influence will be expanded in frame units.

  Therefore, in channel bonding such as PLP bundling, it is required to minimize the influence of ISCR double wrap. Hereinafter, a method of avoiding double wrap of ISCR when performing PLP bundling will be described.

(1) Selection BB frame determination using SYNCD

  First, referring to FIG. 11 to FIG. 13, as one of the methods of avoiding the ISPR double wrap in PLP bundling, a method of avoiding the ISCR double wrap by determining the next BB frame using SYNCD. explain.

(A method to avoid ISPR double wrap using SYNCD)
The SYNCD is information indicating the number of remaining bits necessary to construct a TS packet storing the BB header when the BB frame is stored in the TS packet (TSP: TSPacket). For example, although FIG. 11 exemplifies a plurality of BB headers stored in a TS packet (TSP), in each BB header, the remaining required to construct a TS packet in which the BB header is stored. A 2-byte SYNCD indicating the number of bits of is arranged.

  In the selection BB frame determination using SYNCD, paying attention to this SYNCD, the value (set value) of SYNCD in the BB header is compared with the expected value of SYNCD, and the selectable BB can be selected according to the comparison result. The next BB frame is determined from the frames.

  Note that the expected value of SYNCD is the remaining value necessary to construct a TS packet when the BB frame selected one before is stored in the TS packet when determining the BB frame to be selected next. The number of bits is the same as the number of bits indicated by SYNCD placed in the BB header of the BB frame to be selected next. In other words, the expected value of SYNCD can be said to be the value of SYNCD in the BB header of the next BB frame, which is predicted from the value of the break of the TS packet storing the actual data placed in a certain BB frame.

  Thus, in the selection BB frame determination using SYNCD, SYNCD is referred to with reference to the value of SYNCD in (selectable BB header) of selectable BB frame, not using ISCR in which double wrap may occur. Since the BB frame to be selected next is determined depending on whether or not it matches the expected value of, it is possible to avoid the effect of double wrapping of ISCR.

  That is, when using ISCR to determine the BB frame to be selected next, it is not always correct to select the minimum ISCR BB frame because ISCR has a double-wrap possibility. The use of SYNCD can ensure that the correct BB frame is selected because a phenomenon such as double wrap does not occur.

  Also, when operating in a mode called Null Packet Deletion (NPD: Null Packet Deletion), when a large number of Null packets are added, the value of ISCR becomes irregular, but here, with ISCR, Since the BB frame is selected using SYNCD, it is not affected by irregular ISCR.

  Note that if there is no SYNCD value that matches the expected value of SYNCD due to padding (padding), or if a large amount of data is added due to padding, etc., then all SYNCD values will be "1" and the TS packet Since it is not possible to use SYNCD to determine the BB frame to be selected next, for example, when the start position does not exist in the BB frame, ISCR may be used in these cases.

(Example of functional configuration of control unit)
FIG. 12 is a diagram showing a functional configuration example of the control unit 211 (FIG. 5) in the case of performing selection BB frame determination using SYNCD.

  In FIG. 12, the control unit 211 includes a BB header analysis unit 251, a SYNCD expected value calculation unit 252, a selected BB frame determination unit 253, and a BB frame selection control unit 254.

  The BB header analysis unit 251 analyzes the BB header of the BB frame stored at the beginning of the buffers 214-1 to 214-N, and supplies the analysis result to the selected BB frame determination unit 253.

  The SYNCD expected value calculation unit 252 calculates an expected value of SYNCD from the BB frame selected one before by the BB frame selection unit 215, and supplies the expected value to the selected BB frame determination unit 253.

  The selected BB frame determination unit 253 is supplied with the analysis result of the BB header from the BB header analysis unit 251 and the expected value of SYNCD from the SYNCD expected value calculation unit 252. The analysis results of the BB header include the values of SYNCD and ISCR obtained from the selectable BB frame stored at the beginning of the buffers 214-1 to 214-N.

  The selection BB frame determination unit 253 compares the value of SYNCD obtained from the selectable BB frame with the expected value of SYNCD, and determines whether there is a value of SYNCD that matches the expected value of SYNCD.

  If there is a value of SYNCD that matches the expected value of SYNCD, the selection BB frame determination unit 253 determines that the BB frame of (the BB header including the value of) SYNCD is the next BB frame, and determines that The result is supplied to the BB frame selection control unit 254.

  Also, if there is no SYNCD value that matches the expected value of SYNCD, the selection BB frame determination unit 253 determines whether the buffers 214-1 to 214-N are based on the analysis result of ISCR supplied from the BB header analysis unit 251. Among the selectable BB frames stored at the beginning of the frame, the BB frame of ISCR having the minimum value is determined to be the next BB frame, and the determination result is supplied to the BB frame selection control unit 254.

  The BB frame selection control unit 254 controls the BB frame selection unit 215 on the basis of the determination result supplied from the selection BB frame determination unit 253, and selection is stored at the beginning of the buffers 214-1 to 214-N. From among the BB frames, the next BB frame according to the determination result is selected.

(Flow of the first BB frame selection process)
Next, the flow of a first BB frame selection process corresponding to the process of step S220 of FIG. 6 will be described with reference to the flowchart of FIG.

  In step S241, the selection BB frame determination unit 253 compares the value of SYNCD of the selectable BB frame analyzed by the BB header analysis unit 251 with the expected value of SYNCD calculated by the SYNCD expectation value calculation unit 252. Then, it is determined whether there is a SYNCD value that matches the expected value of SYNCD.

  If it is determined in step S241 that there is a value of SYNCD that matches the expected value of SYNCD, the process proceeds to step S242. In step S 242, the selection BB frame determination unit 253 determines that the BB frame of SYNCD having a value that matches the expected value of SYNCD to be the next BB frame, and supplies the determination result to the BB frame selection control unit 254. Do.

  In step S243, the BB frame selection unit 215 executes the process in step S242 out of selectable BB frames stored at the beginning of the buffers 214-1 to 214-N under the control of the BB frame selection control unit 254. A BB frame (a BB frame of SYNCD of a value matching the expected value of SYNCD) according to the determination result is selected.

  If it is determined in step S241 that there is no value of SYNCD that matches the expected value of SYNCD, the process proceeds to step S244. In step S244, the selection BB frame determination unit 253 selects the BB frame of the ISCR having the minimum value from among the selectable BB frames stored at the beginning of the buffers 214-1 to 214-N as the next BB. The frame is determined to be a frame, and the determination result is supplied to the BB frame selection control unit 254.

  In step S245, the BB frame selection unit 215 executes the processing in step S244 out of selectable BB frames stored at the beginning of the buffers 214-1 to 214-N under the control of the BB frame selection control unit 254. The BB frame (the BB frame of ISCR having a minimum value) is selected according to the determination result.

  When the process of step S243 or S245 ends, the process returns to the process of step S220 of FIG. 6, and the subsequent processes are performed.

  The first BB frame selection processing has been described above. In this first BB frame selection processing, the value of SYNCD of (the BB header of) the selectable BB frame stored at the beginning of the buffers 214-1 to 214-N is referred to and matches the expected value of SYNCD. Since the BB frame to be selected next is determined depending on whether or not, it is possible to avoid the influence of the double wrap of ISCR and minimize the influence.

(2) Selection BB frame determination using the ISCR difference value

  Next, with reference to FIGS. 14 to 17, as one of the methods for avoiding the ISPR double wrap in PLP bundling, the ISCR double wrap is determined by determining the next BB frame using the ISCR difference value. Describe how to avoid it.

(A method to avoid ISPR double wrap using ISCR difference value)
Here, first, with reference to FIG. 14 and FIG. 15, a method of avoiding the double wrap of ISCR using the difference value of ISCR will be described.

  In FIG. 14, BB frames of ISCR "450000", "950000", "1450000", and "3950000" are stored at the beginning of the buffers 214-1 to 214-4, and they become selectable BB frames. However, as described above, BB frames can not be properly rearranged unless BB frames are selected by recognizing the influence of ISCR double wrap. Therefore, in the ISCR double-wrap avoidance method using the ISCR difference value, the ISCR values of selectable BB frames are sorted (sorted) in ascending or descending order, and the ISCR difference value is a predetermined threshold value. If, it is considered that double wrap has occurred in ISCR.

  Specifically, as shown in FIG. 15, if the values of ISCR of the BB frame stored at the beginning of the buffers 214-1 to 214-4 are sorted in ascending order, "450000", "950000", "1450000". "," It is arranged in the order of "3950000". Also, if the difference value of each ISCR value is calculated, the difference value between "450000" and "950000" will be "500000", and the difference value between "950000" and "1450000" will be "500000", The difference value between “1450000” and “3950000” is “2500000”.

  Here, the threshold to be compared with the ISCR difference value is determined by, for example, the transmission rate, but if the threshold is set to "2000000" which is about half of the maximum value of 22 bits of ISCR, Since the difference value between “450000” and “950000” and the difference value between “450000” and “950000” are both “50000”, they are less than the threshold value of “2000000”. Thus, when the difference value of ISCR is less than the threshold value, it is assumed that double wrapping has not occurred in ISCR.

  On the other hand, since the difference value between "1450000" and "3950000" is "2500000", the threshold value which is "2000000" is exceeded. As described above, when the difference value of ISCR exceeds the threshold value, it is considered that double wrap has occurred in ISCR. In this case, the BB frame of the larger value of the two ISCR values that have become the maximum ISCR difference value is determined as the BB frame to be selected next. In this example, since the difference value between "1450000" and "3950000" is the maximum value, the ISCR BB frame "3950000", which is larger than the ISCR "1450000", is used as the next BB frame. It is determined.

  That is, in the case of the example of FIG. 14, the counter value reaches the maximum value and counting is started again from 0, so that when the value of ISCR that is "450000" is being counted, before the maximum value is reached. The value of ISCR which is "3950000" is being counted. Therefore, before the BB frame of ISCR which is "450000" stored at the beginning of buffer 214-1, the BB frame of ISCR "3950000" stored at the beginning of buffer 214-4 is selected. By doing this, the BB frames can be rearranged in the correct order.

  Thus, in the selection BB frame determination using the ISCR difference value, the second selection is made depending on whether the ISCR difference value exceeds the threshold, instead of using the ISCR that may cause double-wrap as it is. Since the BB frame to be determined is determined, it is possible to avoid the influence of the double wrap of ISCR.

  That is, when using ISCR to determine the BB frame to be selected next, it is not always correct to select the minimum ISCR BB frame because ISCR has a double-wrap possibility. By using the ISCR difference value, a phenomenon such as double wrap does not occur, so it is possible to ensure that the correct BB frame is selected.

  In addition, since it becomes difficult to detect that the difference of ISCR does not become fixed when it operate | moves by null packet dilation, and the difference value of ISCR is different, the method of avoiding the double wrap of ISCR is the said method. It is desirable to use it other than the mode.

  Also, for example, in the case of determining the BB frame to be selected next from the BB frames stored at the beginning of the buffer 214-1 and the buffer 214-2, only the two ISCRs are compared, but In this case, the difference may be compared in both cases where the ISCR double-wrapped and the ISCR double-wrapped, and it may be determined that the smaller of the difference values is correct.

(Example of functional configuration of control unit)
FIG. 16 is a diagram showing a functional configuration example of the control unit 211 (FIG. 5) in the case of performing the selection BB frame determination using the ISCR difference value. In addition, in the control part 211 of FIG. 16, about the part corresponding to the control part 211 of FIG. 12, the same code | symbol is attached | subjected and the description is abbreviate | omitted suitably.

  In FIG. 16, the control unit 211 includes a BB header analysis unit 251, a selected BB frame determination unit 253, a BB frame selection control unit 254, and an ISCR difference value calculation unit 261. That is, in the control unit 211 of FIG. 16, an ISCR difference value calculation unit 261 is provided instead of the SYNCD expectation value calculation unit 252 as compared to the control unit 211 of FIG. 12.

  Based on the analysis result of ISCR supplied from the BB header analysis unit 251, the ISCR difference value calculation unit 261 sorts (sorts) the ISCR values of selectable BB frames in ascending order or descending order. The difference value of ISCR is calculated and supplied to the selected BB frame determination unit 253.

  The selected BB frame determination unit 253 compares the ISCR difference value supplied from the ISCR difference value calculation unit 261 with a predetermined threshold to determine whether the ISCR difference value exceeds the threshold.

  If the difference value of all ISCRs is less than the threshold value, the selected BB frame determination unit 253 stores them at the head of the buffers 214-1 to 214-N based on the analysis result of the ISCRs supplied from the BB header analysis unit 251. Among the selectable BB frames, the BB frame of ISCR which is the minimum value is determined to be the next BB frame, and the determination result is supplied to the BB frame selection control unit 254.

  In addition, when the difference value of ISCR exceeds the threshold value, the selection BB frame determination unit 253 selects the BB frame of the ISCR that has the larger value among the two ISCR values that have become the maximum value of the ISCR difference values. Is determined as the BB frame to be selected next, and the determination result is supplied to the BB frame selection control unit 254.

  The BB frame selection control unit 254 controls the BB frame selection unit 215 on the basis of the determination result supplied from the selection BB frame determination unit 253, and selection is stored at the beginning of the buffers 214-1 to 214-N. From among the BB frames, the next BB frame according to the determination result is selected.

(Flow of second BB frame selection processing)
Next, the flow of a second BB frame selection process corresponding to the process of step S220 of FIG. 6 will be described with reference to the flowchart of FIG.

  In step S261, the ISCR difference value calculation unit 261 sorts the values of ISCRs of selectable BB frames in ascending or descending order based on the analysis result of ISCR supplied from the BB header analysis unit 251 (sort And calculate the difference value of each ISCR.

  In step S262, the selected BB frame determination unit 253 determines whether the maximum value of the ISCR difference value exceeds a predetermined threshold value based on the ISCR difference value calculated in the process of step S261.

  If it is determined in step S262 that the maximum value of the difference value of ISCR exceeds the predetermined threshold value, the process proceeds to step S263. In step S263, the selected BB frame determining unit 253 determines that the BB frame of the larger ISCR of the two ISCR values that have become the difference value of the ISCRs that are the maximum value is the next BB frame. Then, the determination result is supplied to the BB frame selection control unit 254.

  In step S264, the BB frame selection unit 215 executes the process in step S263 out of selectable BB frames stored at the beginning of the buffers 214-1 to 214-N under the control of the BB frame selection control unit 254. A BB frame (an ISCR BB frame having a larger one of the two ISCR values that have become the maximum ISCR difference value) according to the determination result is selected.

  When it is determined in step S262 that the maximum value of the difference value of ISCR is smaller than the predetermined threshold value, the process proceeds to step S265. In step S265, the selection BB frame determination unit 253 selects the BB frame of the ISCR having the minimum value from among the selectable BB frames stored at the beginning of the buffers 214-1 to 214-N as the next BB. The frame is determined to be a frame, and the determination result is supplied to the BB frame selection control unit 254.

  In step S266, the BB frame selection unit 215 executes the process of step S265 out of selectable BB frames stored at the beginning of the buffers 214-1 to 214-N under the control of the BB frame selection control unit 254. The BB frame (the BB frame of ISCR having a minimum value) is selected according to the determination result.

  When the process of step S264 or S266 is completed, the process returns to the process of step S220 of FIG. 6, and the subsequent processes are performed.

  The second BB frame selection process has been described above. In this second BB frame selection process, next, depending on whether the ISCR differential value of (the BB header of) the selectable BB frame stored at the beginning of the buffers 214-1 to 214-N exceeds the threshold value, Since the BB frame to be selected is determined, it is possible to avoid the effect of the double wrap of ISCR and minimize the effect.

<4. Computer Configuration>

  The series of processes described above can be performed by hardware or software. When the series of processes are performed by software, a program that configures the software is installed on a computer. FIG. 18 is a diagram showing an example of a hardware configuration of a computer that executes the series of processes described above according to a program.

  In the computer 900, a central processing unit (CPU) 901, a read only memory (ROM) 902, and a random access memory (RAM) 903 are mutually connected by a bus 904. Further, an input / output interface 905 is connected to the bus 904. An input unit 906, an output unit 907, a recording unit 908, a communication unit 909, and a drive 910 are connected to the input / output interface 905.

  The input unit 906 includes a keyboard, a mouse, a microphone, and the like. The output unit 907 includes a display, a speaker, and the like. The recording unit 908 includes a hard disk, a non-volatile memory, and the like. The communication unit 909 is formed of a network interface or the like. The drive 910 drives removable media 911 such as a magnetic disk, an optical disk, a magneto-optical disk, or a semiconductor memory.

  In the computer 900 configured as described above, the CPU 901 loads the program stored in the ROM 902 or the recording unit 908 into the RAM 903 via the input / output interface 905 and the bus 904 and executes the program. A series of processing is performed.

  The program executed by the computer 900 (CPU 901) can be provided by being recorded on, for example, a removable medium 911 as a package medium or the like. Also, the program can be provided via a wired or wireless transmission medium such as a local area network, the Internet, or digital satellite broadcasting.

  In the computer 900, the program can be installed in the recording unit 908 via the input / output interface 905 by attaching the removable media 911 to the drive 910. The program can be received by the communication unit 909 via a wired or wireless transmission medium and installed in the recording unit 908. In addition, the program can be installed in advance in the ROM 902 or the recording unit 908.

  Here, in the present specification, the processing performed by the computer according to the program does not necessarily have to be performed chronologically in the order described as the flowchart. That is, the processing performed by the computer according to the program includes processing executed in parallel or separately (for example, parallel processing or processing by an object). Further, the program may be processed by one computer (processor) or may be distributed and processed by a plurality of computers.

  Note that the embodiments of the present technology are not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present technology.

  Further, the present technology can have the following configurations.

(1)
A receiver that receives a plurality of divided streams obtained by distributing a BB frame of a BB stream, which is a stream of BB (Base Band) frames, into a plurality of data slices;
When the BB frame is stored in a packet, the BB frame selectable based on bit information indicating the number of remaining bits necessary to configure the packet that stores the BB header added to the BB frame A selection unit for selecting the next BB frame from among
A receiver configured to process the BB frame in the order selected by the selector to reconstruct the original BB stream from the plurality of divided streams.
(2)
The receiver according to (1), wherein the bit information is a SYNCD defined by the DVB-C2 (Digital Video Broadcasting-Cable second generation) standard.
(3)
The selection unit selects a BB frame in which the value of SYNCD included in the BB header matches the expected value of SYNCD predicted from the BB frame selected one before among the selectable BB frames. The receiver apparatus according to (2), which selects as the next BB frame.
(4)
The selection unit may add, to the selectable BB frame, the BB header including a value of the SYNCD that matches an expected value of SYNCD predicted from the BB frame selected one before. The receiving device according to (2) or (3), wherein, when there is no BB frame, the BB frame to which the BB header including time information which has a minimum value is added is selected as the next BB frame.
(5)
The receiving device according to (4), wherein the time information is an input stream time reference (ISCR) of an input stream synchronizer (ISSY) defined in the DVB-C2 standard.
(6)
In the receiving method of the receiving device,
The receiving device
Receiving a plurality of divided streams obtained by distributing a BB frame of a BB stream, which is a stream of BB frames, into a plurality of data slices,
When the BB frame is stored in a packet, the BB frame selectable based on bit information indicating the number of remaining bits necessary to configure the packet that stores the BB header added to the BB frame Select the next BB frame from among
And receiving the BB frames in a selected order to reconstruct the original BB stream from the plurality of divided streams.

  Reference Signs List 1 transmission system, 10 transmitting apparatus, 20 receiving apparatus, 30 transmission path, 111 control unit, 112 BB frame generating unit, 113 BB frame distributing unit, 114 data slice processing unit, 115 frame configuration unit, 116 transmitting unit, 211 control unit , 212 reception unit, 213 data slice processing unit, 214 buffer, 215 BB frame selection unit, 216 BB frame processing unit, 251 BB header analysis unit, 252 SYNCD expectation value calculation unit, 253 selection BB frame determination unit, 254 BB frame selection Control unit, 261 ISCR difference value calculation unit, 900 computer, 901 CPU

Claims (6)

A receiver that receives a plurality of divided streams obtained by distributing a BB frame of a BB stream, which is a stream of BB (Base Band) frames, into a plurality of data slices;
When the BB frame is stored in a packet, the BB frame selectable based on bit information indicating the number of remaining bits necessary to configure the packet that stores the BB header added to the BB frame A selection unit for selecting the next BB frame from among
A receiver configured to process the BB frame in the order selected by the selector to reconstruct the original BB stream from the plurality of divided streams. The receiving apparatus according to claim 1, wherein the bit information is a SYNCD defined by the DVB-C2 (Digital Video Broadcasting-Cable second generation) standard. The selection unit selects a BB frame in which the value of SYNCD included in the BB header matches the expected value of SYNCD predicted from the BB frame selected one before among the selectable BB frames. The receiving apparatus according to claim 2, wherein the next BB frame is selected. The selection unit is configured to select time information that is a minimum value when the BB frame including the value of the SYNCD that matches the expected value of the SYNCD does not exist in the selectable BB frames. The receiving apparatus according to claim 3, wherein the BB frame to which the BB header including A is added is selected as the next BB frame. The receiving apparatus according to claim 4, wherein the time information is an input stream time reference (ISCR) of an input stream synchronizer (ISSY) defined by the DVB-C2 standard. In the receiving method of the receiving device,
The receiving device
Receiving a plurality of divided streams obtained by distributing a BB frame of a BB stream, which is a stream of BB frames, into a plurality of data slices,
When the BB frame is stored in a packet, the BB frame selectable based on bit information indicating the number of remaining bits necessary to configure the packet that stores the BB header added to the BB frame Select the next BB frame from among
And receiving the BB frames in a selected order to reconstruct the original BB stream from the plurality of divided streams.

Images