KR102663341B1 - Receiving device and receiving method - Google Patents

Abstract

This technology relates to a receiving device and a receiving method that allow a desired stream to be output more easily. A reception device comprising a control unit that controls selection of an output stream extracted from a transport stream based on the presence or absence of a multi-frame header included in a transport stream transmitted for one or a plurality of carriers, or header information of the multi-frame header. A device is provided. This technology can be applied to a receiver corresponding to digital cable television broadcasting, for example.

Description

Receiving device and receiving method

This technology relates to a receiving device and a receiving method, and in particular, to a receiving device and a receiving method that allow a desired stream to be output more easily.

In order to transmit large-capacity signals that cannot be transmitted through one channel, a multi-carrier transmission method is known, which extends the existing transmission method and divides the large-capacity signal and transmits it on multiple carriers (for example, see Patent Document 1). ).

Patent Document 1: International Publication No. 2016/117283

However, when various types of streams, such as streams based on a multi-carrier transmission method, become available for output, there is a request to easily output a desired stream.

This technology was developed in consideration of such situations, and aims to make it easier to output a desired stream.

A receiving device according to one aspect of the present technology is an output object extracted from the transport stream based on the presence or absence of a multi-frame header included in a transport stream transmitted for each one or a plurality of carriers, or header information of the multi-frame header. It is a receiving device including a control unit that controls stream selection.

A reception method of one aspect of the present technology is that a receiving device detects the presence or absence of a multi-frame header included in a transport stream transmitted for each one or a plurality of carriers, or output extracted from the transport stream based on header information of the multi-frame header. This is a reception method that performs control to select the target output stream.

In the reception device and method of one aspect of the present technology, the presence or absence of a multi-frame header included in a transport stream transmitted for each one or a plurality of carriers, or the output extracted from the transport stream based on header information of the multi-frame header Control is performed to select the target output stream.

Additionally, the receiving device in one aspect of the present technology may be an independent device or an internal block constituting one device.

According to one aspect of the present technology, a desired stream can be output more easily.

Additionally, the effects described here are not necessarily limited, and any effect described in the present disclosure may be used.

1 is a diagram showing the configuration of one embodiment of a transmission system to which the present technology is applied.
Fig. 2 is a block diagram showing an example of the configuration of a transmission device.
Fig. 3 is a diagram showing an example of a stream processed in a receiving device.
Fig. 4 is a diagram showing an example of a configuration of multiple frames.
Fig. 5 is a diagram showing an outline of the syntax of a multi-frame header.
Fig. 6 is a diagram showing an example of the configuration of a TLV packet and a split TLV packet.
Fig. 7 is a block diagram showing an example of the configuration of a receiving device with current functions.
Fig. 8 is a flow chart explaining the flow of stream output setting processing corresponding to the current function.
Fig. 9 is a flow chart explaining the flow of stream output setting processing corresponding to the current function.
Fig. 10 is a block diagram showing an example of the configuration of a receiving device with new functions.
Fig. 11 is a diagram showing an example of reception settings, discrimination criteria, and automatic output selection by cable television transmission method.
Fig. 12 is a diagram showing an example of station selection and TS/TLV discrimination.
Fig. 13 is a diagram showing an example of a carrier wave in the table A system.
Fig. 14 is a diagram showing an example of signal flow in the demodulation IC in the case of the table A system.
Fig. 15 is a diagram showing an example of a carrier wave in the table B system.
Fig. 16 is a diagram showing an example of signal flow in the demodulation IC in the case of the table B system.
Fig. 17 is a diagram showing an example of a carrier wave in the table Ca system.
Fig. 18 is a diagram showing an example of signal flow in a demodulation IC in the case of the table Ca system.
Fig. 19 is a diagram showing an example of a carrier wave in the table Da system.
Fig. 20 is a diagram showing an example of signal flow in a demodulation IC in the case of the table Da system.
Fig. 21 is a diagram showing an example of a carrier wave in the case of the table Eb system.
Fig. 22 is a diagram showing an example of signal flow in the demodulation IC in the case of the table Eb system.
Fig. 23 is a diagram showing an example of a carrier wave in the case of the table Fa system.
Fig. 24 is a diagram showing an example of signal flow in the demodulation IC in the case of the table Fa system.
Fig. 25 is a diagram showing an example of a carrier wave in the table Fc system.
Fig. 26 is a diagram showing an example of signal flow in the demodulation IC in the case of the table Fc system.
Fig. 27 is a diagram showing an example of a carrier wave in the table Ga system.
Fig. 28 is a diagram showing an example of signal flow in the demodulation IC in the case of the table Ga system.
Fig. 29 is a diagram showing an example of a carrier wave in the table Hb system.
Fig. 30 is a diagram showing an example of signal flow in a demodulation IC in the case of the table Hb system.
Fig. 31 is a flow chart explaining the processing flow on the transmitting side and the receiving side.
Fig. 32 is a flow chart explaining the flow of stream output setting processing corresponding to the new function.
Fig. 33 is a flow chart explaining the flow of demodulation and synthesis processing.
Fig. 34 is a diagram showing a configuration example of a computer.

Hereinafter, embodiments of the present technology will be described with reference to the drawings. In addition, the explanation shall be carried out in the following order.

1. Embodiment form of this technology

2. Variation example

3. Computer configuration

<1. Embodiment form of this technology>

(Configuration example of transmission system)

1 is a diagram showing the configuration of one embodiment of a transmission system to which the present technology is applied. Additionally, a system refers to a logical collection of multiple devices.

The transmission system 1 in FIG. 1 is a system corresponding to a broadcasting method of digital cable television broadcasting, such as ISDB-C (Integrated Services Digital Broadcasting for Cable).

In this digital cable television broadcasting (cable television), a multiple-carrier transmission method is adopted, where the transmitting side divides and transmits a stream exceeding the transmission capacity of one carrier using multiple carriers, and the receiving side transmits the stream using multiple carriers. Splitly transmitted streams are synthesized. Additionally, in the multi-carrier transmission method, a modulation method such as 64QAM (Quadrature Amplitude Modulation) or 256QAM is used for each of the plurality of carriers.

The transmission system 1 is comprised of a transmission device 10, a reception device 20, and a CATV transmission line 30. In Fig. 1, one receiving device 20 is shown to simplify the explanation, but in reality, a receiving device 20 is installed in each cable television subscriber's home.

The transmitting device 10 is a head end installed in a cable television broadcasting station.

The transmitting device 10 receives broadcast signals of terrestrial broadcasting or satellite broadcasting, processes streams of content such as broadcast programs, and transmits (retransmits) them to the receiving device 20 through the CATV transmission line 30. In addition, in addition to retransmission, the transmission device 10 also transmits a stream of content, such as a broadcast program produced by a cable television station itself or a broadcast program received through a communication line such as the Internet, through the CATV transmission line 30. It can be transmitted to the receiving device 20.

The CATV transmission line 30 is made of a transmission medium such as, for example, a coaxial cable or an optical fiber, and connects the head end of the cable television broadcasting station with the home of the cable television subscriber by wire.

The receiving device 20 is, for example, a fixed receiver such as a television receiver or a set top box (STB) installed in a cable television subscriber's home.

The receiving device 20 receives a broadcast signal transmitted from the transmitting device 10 through the CATV transmission line 30 and processes a stream of content, thereby displaying images such as the broadcast program on the display. Audio synchronized with the video is output from the speaker. As a result, cable television subscribers can watch content such as broadcast programs.

(Example of configuration of transmitting device)

FIG. 2 is a block diagram showing an example of the configuration of the transmission device 10 in FIG. 1.

In FIG. 2, the transmitting device 10 includes input ports 101-1 to 101-3, a front-end signal processing unit 102, a slot allocation unit 103, a TSMF processing unit 104-1 to 104-3, and a QAM It consists of a modulation section (105-1 to 105-3) and a mixing section (106).

The input port 101-1 is a port for inputting a transport stream format signal (TS signal), and supplies the TS signal input there to the slot allocation unit 103.

The input port 101-2 is a port through which a TLV (Type Length Value) format signal (TLV signal) is input, and the TLV signal input there is supplied to the slot allocation unit 103.

The input port 101-3 supplies the IF signal or RF signal input thereto to the front-end signal processing unit 102.

The front-end signal processing unit 102 performs front-end signal processing on the IF signal or RF signal supplied from the input port 101-3 and supplies it to the slot allocation unit 103.

The slot allocation unit 103 multiplexes (division multiplexes) the signals input thereto by assigning them to slots on a transport stream multiplexing frame (TSMF), and sends the resulting signals to the TSMF processing units 104-1 to 104-3. ) is supplied to.

The TSMF processing unit 104-1 performs TSMF processing on the signal supplied from the slot allocation unit 103, and supplies the resulting signal to the QAM modulation unit 105-1.

The TSMF processing unit 104-2 performs TSMF processing on the signal supplied from the slot allocation unit 103, and supplies the resulting signal to the QAM modulation unit 105-2.

The TSMF processing unit 104-3 performs TSMF processing on the signal supplied from the slot allocation unit 103, and supplies the resulting signal to the QAM modulation unit 105-3.

The QAM modulator 105-1 modulates the signal supplied from the TSMF processing unit 104-1 based on information such as NIT (Network Information Table) or TSMF header information, with a modulation method such as 64QAM or 256QAM. Modulation processing according to is performed, and the resulting signal is supplied to the mixing section 106.

The QAM modulation unit 105-2 performs modulation processing on the signal from the TSMF processing unit 104-2 based on NIT, TSMF header information, etc., and supplies the resulting signal to the mixing unit 106.

The QAM modulation unit 105-3 performs modulation processing on the signal from the TSMF processing unit 104-3 based on NIT, TSMF header information, etc., and supplies the resulting signal to the mixing unit 106.

The mixing unit 106 mixes the signals supplied from the QAM modulation units 105-1 to 105-3 and transmits (sends out) them as a broadcast signal.

(Processing example of receiving device)

FIG. 3 is a diagram showing an example of a stream processed in the receiving device 20 of FIG. 1.

The reception device 20 includes a reception system 200 including, for example, a demodulation IC and a synthesis device. The receiving system 200 processes and outputs a stream extracted from the broadcast signal transmitted from the transmitting device 10.

Here, the stream processed by the reception device 20 (the reception system 200) is, for example, a single transport stream (single TS) based on the single TS multiplexing method, and a multiple transport stream based on the multiple TS multiplexing system. Since streams (multiple TS) and transport streams based on the multi-carrier transmission method are included, the reception system 200 needs to support various types of streams.

A single TS is used for normal broadcasting, for example. On the other hand, a transport stream using multiple TS and multiple carrier transmission methods is used, for example, when retransmitting satellite broadcast content on cable television.

In addition, as satellite broadcasting (BS broadcasting), operation of advanced broadband satellite digital broadcasting (advanced BS broadcasting) begins. For example, multiple TSs are used for retransmission of normal BS broadcasting, while multi-carrier transmission method transport The stream can be used for retransmission of advanced BS broadcasting that provides 4K/8K ultra-high-definition television broadcasting services.

(Composition of multiple frames)

Fig. 4 is a diagram showing an example of a multi-frame configuration.

In FIG. 4, a multiple frame (TSMF) such as multiple TS includes 1 slot allocated to a multiple frame header (TSMF header) and 52 slots allocated to data of each broadcast program such as broadcast program A, broadcast program B, or broadcast program C. One frame consists of a total of 53 slots. Additionally, each broadcast program, such as broadcast program A, broadcast program B, or broadcast program C, becomes a broadcast program of a channel of another broadcasting station.

(Overview of TSMF headers)

Fig. 5 is a diagram showing an outline of the syntax of a multi-frame header (TSMF header).

The TSMF header includes the following fields as header information: packet header, frame_sync, version_number, relative_stream_number_mode, frame_type, stream_status, stream_id/original_network_id, receive_status, reserved_for_future_use, emergency_indicator, relative_stream_number, extension information, and CRC. Parameters of header information are specified by these fields.

The packet header includes a sync byte, frame_PID, and continuity indicator. frame_sync is a field of the TSMF synchronization signal. version_number is a field for indicating change of the TSMF header.

relative_stream_number_mode is a field to distinguish the slot arrangement method. frame_type is a field to distinguish the TSMF format. stream_status is a field to indicate validity or invalidity for the relative stream number.

stream_id/original_network_id is a field for identifier/relative stream number correspondence information. In addition, hereinafter, stream_id is also referred to as a stream identifier, and original_network_id is also referred to as a network identifier. In addition, the stream identifier (stream_id) and the network identifier (original_network_id) are combined and referred to as identification information.

receive_status is a field indicating reception information from the head end. reserved_for_future_use is a field (undefined) for future expansion. emergency_indicator is a field for indicating an emergency alert. relative_stream_number is a field for relative stream number to slot correspondence information.

The extension information is arranged by expanding the area using private_data when expanding the header information of the TSMF header. CRC is a field of CRC (Cyclic Redundancy Check) value for error detection.

Here, information for synthesis is defined in the extension information, for example. The extension information includes the following fields: earthquake_early_warning, stream_type, group_id, number_of_carriers, carrier_sequence, number_of_frames, frame_position, and field_for_extension.

earthquake_early_warning is a field for earthquake motion warning information in terrestrial digital broadcasting.

stream_type is a field for indicating the stream type. As stream_type, “TS” or “TLV” is specified. That is, “TS” is designated for the transport stream (TS) containing TS packets, and “TLV” is designated for the transport stream (TLV) containing TLV packets (split TLV packets).

In addition, hereinafter, stream_type is also referred to as type information. Additionally, since the TS packet is a packet of fixed length (for example, 188 bytes), it is also called a fixed-length packet. On the other hand, since the TLV packet is a packet of variable length, it is also called a variable length packet.

group_id is a field for identifying the carrier group.

number_of_carriers is a field to indicate the total number of carriers constituting the carrier group. carrier_sequence is a field for indicating the synthesis order of the demodulated output of the carrier wave. In addition, hereinafter, the total number of carriers (number_of_carriers) and the order of carriers (carrier_sequence) are combined and referred to as composite information.

number_of_frames is a field to indicate the number of frames included in a super frame. frame_position is a field for frame position information. field_for_extension is a field (undefined) for future extension.

(Configuration of TLV and split TLV)

Fig. 6 is a diagram showing an example of the configuration of a TLV packet and a split TLV packet.

Here, in the broadcasting system of digital cable television broadcasting (e.g., ISDB-C, etc.), what is demodulated and output is a TS format signal (TS signal), whereas in broadcasting systems such as advanced BS broadcasting, a TLV format signal (TS signal) is used. TLV signal). Therefore, in order to convey (transmit) a TLV signal in a broadcasting system such as advanced BS broadcasting in a broadcasting system such as ISDB-C, it is necessary to convert it into a TS format signal.

That is, the TLV packet is divided, and the variable TLV vector is converted into a fixed length format of 188 bytes as the divided TLV packet. In addition, a TS packet is 188 bytes, and a multi-frame (TSMF) slot is also composed of 188 bytes, the same size as the TS packet.

Specifically, in FIG. 6, for example, when the TLV packet (P1) and the TLV packet (P2) are consecutive, the TLV packet (P1) is divided into three 185-byte units and divided into TLV packets (DP1, DP2, DP3). Stored in each payload. The split TLV packet (DP) has a payload of 185 bytes, and a 3-byte split TLV packet header is added. That is, there are 3 bytes of the split TLV packet header and 185 bytes of the payload, making a total of 188 bytes.

In the example of Fig. 6, a part of the TLV packet P1 (a signal of 185 bytes) is sequentially stored in the payload of the split TLV packets DP1 and DP2, and the remaining part (a signal of less than 185 bytes) is stored in the payload of the split TLV packet (DP3). That is, the payload of the split TLV packet DP3 stores the remaining part of the TLV packet P1 (signal less than 185 bytes) and the part of the TLV packet P2 that follows it (signal less than 185 bytes). Total is 185 bytes.

In the multi-carrier transmission method, synthesis is performed using a format using multiple frames (TSMF header) as shown in FIG. 4 and the split TLV packet shown in FIG. 6. At that time, by adding a TSMF header (FIG. 5) to the divided TLV packetized TLV signal (TLV stream), it becomes possible to process it as a transport stream with a multi-frame structure.

(Example of status quo function)

Here, the configuration and operation of the receiving device 20 with the current function will be described with reference to FIGS. 7 to 9 for comparison with the new function to which the present technology is applied.

FIG. 7 is a block diagram showing an example of the configuration of the receiving device 20 with the current function.

In FIG. 7, the receiving device 20 having the current function includes a microcontroller 900, tuners 901-1 to 901-4, demodulation ICs 902-1 to 902-4, and system-on-chip 903. and a display 904.

The microcontroller 900 controls the operation of each part of the receiving device 20.

The tuners 901-1 to 901-4 receive broadcast signals transmitted from the transmitting device 10, perform necessary processing, and output them to the demodulation ICs 902-1 to 902-4, respectively.

Demodulation ICs 902-2 to 902-4 perform demodulation processing on signals received from tuners 901-2 to 901-4, and output the resulting transport stream to demodulation IC 902-1. .

The demodulation IC 902-1 performs demodulation processing on the signal received from the tuner 901-1. The demodulation IC 902-1 performs processing such as synthesis on the transport stream obtained through its own demodulation process and the transport streams from the demodulation ICs 902-2 to 902-4, and produces the resulting output stream. is output to the system-on-chip 903.

The system-on-chip 903 performs processing such as decoding on the output stream from the demodulation IC 902-1, and outputs the resulting video data to the display 904.

The display 904 displays an image corresponding to image data from the system-on-chip 903. Additionally, although not shown in Fig. 7, audio data processed by the system-on-chip 203 is output to a speaker, and audio corresponding to the audio data is output.

As described above, in the receiving device 20 (FIG. 7) with the current function, the demodulation IC 902-1 has the function of demodulating the received signal from the tuner 901-1 and the function of demodulating the signal received from the tuner 901-1 and The tuners (901-1 to 901-4) and the demodulator ICs (902-1 to 902-4) are controlled to output a composite stream or transport stream (single TS or multiple TS) from the demodulator IC (902-1). It has the function to

Next, the flow of the stream output setting process executed by the receiving device 20 (FIG. 7) with the current function will be explained with reference to the flow charts in FIGS. 8 and 9.

Here, first, stream_id and original_network_id are set in the demodulation IC 902-1 (S11), and the TS packet of the demodulation IC 902-1 is read (S12). Then, in the determination process of step S13, it is determined whether or not a TSMF packet exists in the demodulation IC 902-1.

If it is determined in step S13 that a TSMF packet exists (“YES” in S13), the process proceeds to step S14. Then, the TSMF header data is read from the demodulation IC 902-1 (S14) and stored in the memory (S15). Also, at this time, extension information is extracted from the TSMF header (S16), and whether or not extension information exists is determined in the determination process of step S17.

If it is determined in step S17 that extended information exists (“YES” in S17), the process proceeds to step S18. In step S18, TSMF header processing for other demodulation ICs 902-N is performed. Here, details of TSMF header processing corresponding to step S18 in FIG. 8 will be described with reference to the flow chart in FIG. 9.

In this TSMF header processing, first, N=2 is set as the initial value of the demodulation IC 902 (S31), and the value of N is incremented until N>=4 (“YES” in S38). While doing so (S37), the loop of steps S32 to S38 is repeated.

That is, stream_id and original_network_id are set in the demodulation IC 902-N (S32), and the TS packet of the demodulation IC 902-1 is read (S33). Then, in the determination process of step S34, it is determined whether or not a TSMF packet exists in the demodulation IC 902-N.

If it is determined in step S34 that a TSMF packet exists (“YES” in S34), the process proceeds to step S35. Then, the TSMF header data is read from the demodulation IC 902-N (S35) and stored in the memory (S36).

Here, if it is determined that the condition of N>=4 is not satisfied after the value of N is incremented (“NO” in S37 and S38), the process returns to step S32 and the loop of steps S32 to S38 is repeated. do. Then, when it is determined that the condition of N>=4 is satisfied (“YES” in S38), or when it is determined that there is no TSMF packet (“NO” in S34), TSMF header processing ends, and processing , returns to step S18 in FIG. 8.

In step S19 of FIG. 8, the extension information acquired in the process of step S16 and the extension information obtained from the TSMF header acquired in the TSMF header process (FIG. 9) are processed. Then, in the determination process of step S20, it is determined whether synthesis is possible based on the result of the extended information process (S19).

If it is determined in step S20 that synthesis is possible (“YES” in S20), the process proceeds to step S21. Then, the synthesis target stream is set as the output format in the demodulation IC 902-1 (S21). Subsequently, in the determination process of step S22, it is determined whether the stream type is "TLV" based on the result of the extension information process (S19).

If the stream type is determined to be "TLV" in step S22, the process proceeds to step S23. Then, a TLV stream (TLV conversion target stream) is set as the stream format in the demodulation IC 902-1 (S23). On the other hand, if the stream type is determined to be "TS" in step S22, the process proceeds to step S24. Then, TS stream (TLV conversion non-target stream) is set as the stream format in the demodulation IC 902-1 (S24).

On the other hand, when it is determined that no TSMF packet exists (“NO” in S13), when it is determined that extension information does not exist (“NO” in S17), or when it is determined that composition is impossible (“NO” in S20 "), the processing proceeds to step S25. Then, the composite non-target stream is set as the output format in the demodulation IC 902-1 (S25).

When the processing of steps S23, S24, or S25 is completed, the processing proceeds to step S26. Then, the ON state is set to the demodulation IC 902-1 as a stream output.

Above, the flow of stream output setting processing corresponding to the current function has been explained. In this stream output setting process, for example, in steps S11, S12, S14, and S18 in FIG. 8 (S32, S33, and S35 in FIG. 9), S21, S22, S23, S24, and S26, the demodulation IC 902 It is necessary to read and record data, which requires time. In particular, in Fig. 7, since a plurality of tuners 901 are provided and a plurality of demodulation ICs 902 are also provided corresponding thereto, additional time is required to read data from each demodulation IC 902. As a result, in the receiving device 20 (receiving system 200) with the current function, the time until an image is displayed after switching a broadcast program, for example, increases.

Additionally, in the reception device 20 (the reception system 200), synthesis is performed on the stream to be synthesized based on the header information (extension information) of the TSMF header of the TSMF packet, and the header information contains many parameters. Because it exists, control of which stream is output as the output stream becomes complicated. In addition, as shown in FIG. 3, the reception device 20 (the reception system 200) uses, for example, a transport stream based on the single TS multiplexing method or a transport stream based on the multiple TS multiplexing method, Furthermore, there is a need to process and output various types of streams, such as transport streams based on a multi-carrier transmission method, and there is a request to easily output a desired stream.

Furthermore, in the stream output setting process corresponding to the current function, it is necessary to hold the TSMF packet data in memory (S15 in FIG. 8, S36 in FIG. 9), so the reception system 200 needs extra memory. It becomes necessary. And there is a risk that this could become a factor and cause problems in terms of cost and processing speed.

Taking this problem into consideration, a new function using this technology makes it easier to output a desired stream. In addition, in the new function to which this technology is applied, for example, the time until an image is displayed after switching a broadcast program is shortened and the reception system 200 is completed without providing extra memory. Hereinafter, the configuration and operation of the receiving device 20 with new functions will be described.

(Example of configuration of new function receiving device)

FIG. 10 is a block diagram showing an example of the configuration of a receiving device 20 with a new function.

In FIG. 10, the receiving device 20 with new functions includes tuners 201-1 to 201-4, demodulation ICs 202-1 to 202-4, system-on-chip 203, and display 204. It is composed. Additionally, the tuner 201, demodulation IC 202, and system-on-chip 203 correspond to at least a part of the receiving system 200 in FIG. 3.

The tuner 201-1 receives the broadcast signal transmitted from the transmitting device 10, performs necessary processing, and supplies the resulting received signal (carrier signal) to the demodulation IC 202-1. Like the tuner 201-1, the tuners 201-2 to 201-4 perform necessary processing on the broadcast signal and send the resulting received signals to the demodulation ICs 202-2 to 202-4, respectively. supply.

The demodulation IC 202-2 performs demodulation processing (e.g., demodulation of 64QAM or 256QAM, etc.) on the received signal supplied from the tuner 201-2, and sends the resulting transport stream to the demodulation IC 202-1. ) is supplied to. The demodulation IC 202-3 and the demodulation IC 202-4, like the demodulation IC 202-2, perform demodulation processing on the received signal and transfer the resulting transport stream to the demodulation IC 202-1. supply to.

The demodulation IC 202-1 includes a control unit 210, a demodulation unit 211, a TSMF processing unit (212-1 to 212-4), a synthesis unit 213, a TLV conversion unit 214, a selector 215, and It consists of a selector (216). A received signal from the tuner 201-1 and a transport stream from the demodulation ICs 202-2 to 202-4 are input to the demodulation IC 202-1.

The control unit 210 controls the operation of each part of the demodulation IC 202-1. For example, the control unit 210 is composed of a processor such as a microcontroller.

The demodulation unit 211 performs demodulation processing (e.g., demodulation of 64QAM or 256QAM, etc.) on the signal received from the tuner 201-1, and supplies the resulting transport stream to the TSMF processing unit 212-1. do.

The TSMF processing unit 212-1 performs TSMF processing on TSMF packets on the transport stream supplied from the demodulation unit 211. In this TSMF processing, for example, processing such as detecting a TSMF packet (TSMF header) from a transport stream extracted from a received signal (carrier signal) or extracting extension information of the TSMF header is performed.

The TSMF processing unit 212-1 supplies the control unit 210 with a TSMF notification containing the detection result of a TSMF packet (TSMF header) or header information (extension information) of the TSMF header. Additionally, the TSMF processing unit 212-1 supplies the transport stream supplied from the demodulation unit 211 to the synthesis unit 213. Additionally, the TSMF processing unit 212-1 can extract and output packets corresponding to the specified stream identifier and network identifier.

The TSMF processing units 212-2 to 212-4, like the TSMF processing unit 212-1, perform TSMF processing on the transport streams from the external demodulation ICs 202-2 to 202-4, and process the TSMF packets. TSMF notification including the detection result and header information (extension information) of the TSMF header are supplied to the control unit 210, respectively. Additionally, the TSMF processing units 212-2 to 212-4 respectively supply transport streams from the external demodulation ICs 202-2 to 202-4 to the synthesis unit 213.

The control unit 210 controls to select an output stream to be output based on a TSMF notification containing the detection result of the TSMF packet supplied from the TSMF processing units 212-1 to 212-4 or header information (extension information). Do.

Here, the control unit 210 determines whether the transport stream (output format) is a synthesis target stream based on the TSMF notification including the detection result of the TSMF packet. The control unit 210 supplies a control signal corresponding to the determination result of the stream to be synthesized to the selector 216.

Additionally, the control unit 210 determines whether the stream type (stream format) of the transport stream is “TLV” or “TS” based on the extension information of the TSMF header. The control unit 210 supplies a control signal corresponding to the stream type determination result to the selector 215.

The synthesis unit 213 synthesizes the transport streams supplied from the TSMF processing units 212-1 to 212-4, and converts the composite stream (split TLV stream or TS stream) obtained as a result of the synthesis to the TLV conversion unit 214 or It is supplied to the selector (215).

Additionally, among the composite streams, the split TLV stream has "TLV" specified as its stream type, and becomes the TLV conversion target stream. On the other hand, the TS stream has "TS" designated as its stream type, and is a stream not subject to TLV conversion.

The TLV conversion target stream is input to the TLV conversion unit 214. The TLV conversion unit 214 converts the divided TLV packets included in the TLV conversion target stream (TLV stream) into TLV packets. At this time, since the stream type is "TLV", the selector 215 selects the output side of the TLV converter 214 as its input based on the control signal from the control unit 210, and the TLV converter 214 The TLV conversion target stream (TLV stream) from is input to the selector 215 and output to the selector 216.

On the other hand, the TLV conversion non-target stream (TS stream) is input to the selector 216 as is. At this time, since the stream type is "TS", the selector 215 selects the output side of the synthesis unit 213 as its input based on the control signal from the control unit 210, and the selector 215 selects the output side of the synthesis unit 213 as its input. The non-TLV conversion target stream (TS stream) is input to the selector 215 as is and output to the selector 216.

The selector 216 selects a synthesis non-target stream input from the demodulation unit 211 or the TSMF processing unit 212-1 based on a control signal from the control unit 210, or a synthesis target stream input from the selector 215 ( A stream to be converted to TLV or a stream not to be converted to TLV is selected and output to the system-on-chip 203 as an output stream to be output.

The system-on-chip 203 performs predetermined processing, such as decoding, on the output stream input from the demodulation IC 202-1 (selector 216), and the resulting image data (or image data ) is output to the display 204.

The display 204 is, for example, a display device (display device) such as a liquid crystal display (LCD) or an organic light emitting diode (OLED). The display 204 displays an image (or image) corresponding to image data (or image data) input from the system-on-chip 203.

Additionally, in Figure 10, for convenience of explanation, the illustration is omitted. By providing an audio output device such as a speaker, audio (sound) corresponding to the audio data processed by the system-on-chip 203 is output from the audio output device. You may do so.

The receiving device 20 is configured as described above.

(Example of table)

Fig. 11 is a diagram showing an example of reception settings, discrimination criteria, and automatic output selection according to the cable television transmission method.

In Fig. 11, reception settings, discrimination criteria, and automatic output selection are listed for each cable television transmission method, and tables A to H are assigned correspondingly.

Each transmission method is specified by whether it is a single TS or multiple TSs, whether it is multiple carriers, or whether it is single QAM or multiple QAM, etc., as determined by regulations such as standards and operating specifications.

The reception settings indicate whether ID designation of the stream identifier (stream_id) and network identifier (original_network_id) is necessary or unnecessary. The judgment standard indicates the presence or absence of the TSMF header of the TSMF packet and the presence or absence of extension information of the header information.

Automatic output selection indicates whether the output format is a synthesis target stream or a synthesis non-target stream, and the stream format is a TLV conversion target stream or a TLV conversion non-target stream.

Standard specifications A include, for example, the standards for digital cable television broadcasting established by the Japan CATV Technology Association, as well as the single TS multiplexer standard, multi-TS multiplexer standard, and multi-carrier transmission method standard. It is stipulated.

The operation specification B corresponds to, for example, the transmodulation operation specification developed by the Japan Cable Research Institute, which specifies a single QAM modulation method or a multiple QAM modulation method.

Here, when the single TS method is adopted by a combination of standard specification A and operation specification B, the carrier number is "1" and the multiplexing method is "single TS", and when the multiple TS method is adopted, the carrier wave The number is “1” and the multiplexing method is “multiple TS”. In the following description, the former method is referred to as the table A method, and the latter method is referred to as the table B method.

In addition, when adopting a single QAM system with multiple carriers by combining standard specification A and operation specification B, the number of carriers is "1", the multiplexing method is "split TLV", and the multiple carrier method is When adopting, the carrier number is “1” and the multiplexing method is “split TLV” or “TS”. In the following description, the former method is referred to as the Table C method, and the latter method is referred to as the Table D or Table E method.

In addition, when multiple carriers and multiple QAM systems are adopted by combining standard specification A and operational specification B, the number of carriers is "2 to 4", the multiplexing method is "split TLV", and multiple carriers are used. When the method of is adopted, the carrier number is "2 to 4" and the multiplexing method is "split TLV" or "TS". In the following description, the former method is referred to as the table F method, and the latter method is referred to as the table G or table H method.

In the method of Table A, the carrier number is "1", the multiplexing method is "single TS", and the following conditions are applied as reception settings, judgment criteria, and automatic output selection. In other words, specifying the IDs of stream_id and original_network_id as reception settings is “unnecessary”. Additionally, since the TSMF header is not added as a judgment standard, the extension information (number_of_carriers, stream_type) is "none". Additionally, as an automatic output selection, compositing and TLV conversion are "untargeted".

In the method of Table B, the number of carriers is "1", the multiplexing method is "multiple TS", and the ID designation of stream_id and original_network_id as reception settings is "required." Additionally, the TSMF header is added as a judgment standard, but the extension information (number_of_carriers, stream_type) is "none". Additionally, as an automatic output selection, compositing and TLV conversion are "untargeted".

Additionally, in the TSMF header, the area is expanded using private_data to place extension information, and when all bits of private_data are “1” or “0”, it can be determined that the extension information is “nothing.”

In the method of Table C, the carrier number is "1", the multiplexing method is "split TLV", and ID designation of stream_id and original_network_id as reception settings is "required". Additionally, as a judgment standard, a TSMF header is added and includes extension information. As extension information, number_of_carriers = "1" and stream_type = "0" are specified. Additionally, synthesis and TLV conversion are "targeted" as automatic output selection.

In the method of Table D, the carrier number is "1", the multiplexing method is "split TLV and TS", and ID designation of stream_id and original_network_id as reception settings is "required". Additionally, as a judgment standard, a TSMF header is added and includes extension information. As extension information, number_of_carriers = "1" and stream_type = "0" are specified. Additionally, synthesis and TLV conversion are "targeted" as automatic output selection.

In the method of Table E, the carrier number is "1", the multiplexing method is "split TLV and TS", and ID designation of stream_id and original_network_id as reception settings is "required". Additionally, as a judgment standard, a TSMF header is added and includes extension information. As extension information, number_of_carriers = "1" and stream_type = "1" are specified. Additionally, as an automatic output selection, compositing is "targeted" and TLV conversion is "non-targeted".

In the method of Table F, the number of carriers is "2 to 4", the multiplexing method is "split TLV", and ID designation of stream_id and original_network_id is "required" as reception settings. Additionally, as a judgment standard, a TSMF header is added and includes extension information. As extension information, number_of_carriers = "2 to 4" and stream_type = "0" are specified. Additionally, synthesis and TLV conversion are "targeted" as automatic output selection.

In the method of Table G, the number of carriers is "2 to 4", the multiplexing method is "split TLV and TS", and ID designation of stream_id and original_network_id as reception settings is "required". Additionally, as a judgment standard, a TSMF header is added and includes extension information. As extension information, number_of_carriers = "2 to 4" and stream_type = "0" are specified. Additionally, synthesis and TLV conversion are "targeted" as automatic output selection.

In the method of Table H, the number of carriers is "2 to 4", the multiplexing method is "split TLV and TS", and ID designation of stream_id and original_network_id as reception settings is "required". Additionally, as a judgment standard, a TSMF header is added and includes extension information. As extension information, number_of_carriers = "2 to 4" and stream_type = "1" are specified. Additionally, as an automatic output selection, compositing is "targeted" and TLV conversion is "non-targeted".

(Example of TS/TLV discrimination)

Fig. 12 is a diagram showing an example of station selection and TS/TLV discrimination.

The stream type is identified by stream_type included in the extension information of the TSMF header, and not only when synthesis of multiple carriers is established (successful) when adopting the methods in Tables C to H, that is, the multiple carrier transmission method. There are times when errors occur.

First, in the case of adopting a multi-carrier transmission method, when stream_type = "0" is specified, the stream type is recognized as a TLV packet, and the order and total number of carriers (carrier_sequence, number_of_carriers) are checked and it is determined that synthesis is possible. In this case, multi-carrier synthesis is established. In the following description, such a case is referred to as the case of table a.

Second, in the case of adopting the multi-carrier transmission method, when stream_type = "1" is specified, the stream type is recognized as a TS packet, and the order and total number of carriers are checked and it is determined that synthesis is possible, multi-carrier synthesis is performed. is established. In the following description, such a case is referred to as the case of table b.

Third, in the case of adopting the multiple carrier transmission method, stream_type = "1" or "0" is undefined, the stream type is recognized as single TS or multiple TS, or the order or total number of carriers is confirmed. When it is determined that synthesis is impossible, multi-carrier synthesis results in an error. Hereinafter, such a case will be referred to as the case of table c.

In addition, in the following description, for convenience of explanation, the cases of tables A to H shown in Fig. 11 and the cases of tables a to c shown in Fig. 12 are combined and expressed as “table x-y format”. do. However, in the notation of “table It corresponds to any one of “a” to “c” in the cases of tables a to c. In addition, in cases that do not correspond to the cases in tables a to c of FIG. 12, the notation of “-y” is omitted.

(1) Method of Table A

(Example of carrier wave)

Fig. 13 is a diagram showing an example of a carrier wave when the method in Table A is adopted.

As shown in Fig. 13, when the conditions of table A are met, one carrier wave C1 is received by the receiving device 20. This carrier C1 contains a single transport stream (single TS) as the transport stream and does not contain TSMF packets. That is, in the method of Table A, the transport stream does not include TSMF packets (TSMF header), and the header information does not include extension information.

(Signal flow)

FIG. 14 is a diagram showing an example of the signal flow in the demodulation IC 202-1 when the method in Table A is adopted.

In Fig. 14, the configuration of the demodulation IC 202-1 in the receiving device 20 is shown, and the signal flow is indicated by bold arrows in the figure. In addition, the meaning of these illustrations is the same in other corresponding drawings (figures showing examples of signal flows) described later.

The demodulation unit 211 performs demodulation processing on the received signal input thereto, and supplies the resulting transport stream (single TS) to the TSMF processing unit 212-1. Additionally, in the case of Table A, since one carrier wave C1 is received, the transport stream is input only to the TSMF processing unit 212-1 among the TSMF processing units 212-1 to 212-4.

The TSMF processing unit 212-1 performs TSMF processing on the transport stream (single TS) from the demodulation unit 211 and attempts to detect TSMF packets. At this time, the TSMF processing unit 212-1 supplies the control unit 210 with a TSMF notification to the effect that the TSMF packet is not detected because the TSMF packet cannot be detected from the single transport stream.

The control unit 210 determines that the transport stream (single TS) is a synthesis non-target stream based on the TSMF notification (notification of non-detection of a TSMF packet) from the TSMF processing unit 212-1, and performs a command according to the determination result. A control signal is supplied to the selector 216.

The selector 216 selects a transport stream (single TS) as a composite non-target stream input from the demodulation unit 211 based on a control signal from the control unit 210, and selects a transport stream (single TS) as the output stream to be output from the later system on. Output to chip 203.

As described above, when the method of Table A is adopted, since the transport stream (single TS) transmitted on one carrier (C1) does not include TSMF packets (TSMF header), the demodulation IC 202-1 , a single transport stream extracted from the received signal of the carrier C1 is selected as a composite non-target stream and output as an output stream.

(2) Table B method

(Example of carrier wave)

Fig. 15 is a diagram showing an example of a carrier wave when the method in Table B is adopted.

As shown in Fig. 15, when the conditions in table B are met, one carrier wave C1 is received by the receiving device 20. This carrier (C1) includes multiple transport streams (multiple TS) and includes TSMF packets, but does not include extension information in the TSMF header.

Additionally, multiple TSs include streams of broadcast program A, broadcast program B, and broadcast program C. The stream of broadcast program A is assigned stream_id = "0x11" as a stream identifier and original_network_id = "0x22" as a network identifier, respectively. Additionally, stream_id = "0x33" and original_network_id = "0x44" are assigned to the stream of broadcast program B, and stream_id = "0x55" and original_network_id = "0x66" are assigned to the stream of broadcast program C.

That is, in the method of Table B, the transport stream includes TSMF packets (TSMF header), but the header information does not include extension information.

(Signal flow)

FIG. 16 is a diagram showing an example of the signal flow in the demodulation IC 202-1 when the method of Table B is adopted.

In the case of the table B method, the carrier C1 includes streams of program A, program B, and program C as multiple TS. Here, stream_id is identification information for identifying the output stream to be output. = "0x11" and original_network_id = "0x22" are respectively specified and set in the control unit 210 and the TSMF processing unit 212.

The demodulation unit 211 performs demodulation processing on the received signal input thereto, and supplies the resulting transport streams (plural TS) to the TSMF processing unit 212-1. Additionally, in the case of Table B, since one carrier (C1) is received, the transport stream is input only to the TSMF processing unit 212-1.

The TSMF processing unit 212-1 performs TSMF processing on the transport streams (multiple TS) from the demodulation unit 211, and TSMF for which stream_id = "0x11" and original_network_id = "0x22" are specified in the header information of the TSMF header. Attempt to detect packets. At this time, the TSMF processing unit 212-1 can detect TSMF packets from multiple transport streams, but since the TSMF header does not include extension information, TSMF packet detection and TSMF packets to the effect of non-existence of extension information are detected. A notification is supplied to the control unit 210. Additionally, the TSMF processing unit 212-1 extracts and outputs the transport stream (stream of broadcast program A) identified by stream_id = "0x11" and original_network_id = "0x22".

The control unit 210 converts the transport streams (multiple TSs) into a composite non-target stream based on a TSMF notification (notification of detection of a TSMF packet and non-existence of extension information) from the TSMF processing unit 212-1. It is determined that there are multiple TSs, and a control signal corresponding to the decision result is supplied to the selector 216.

The selector 216 selects a transport stream (stream of broadcast program A) as a composite non-target stream input from the TSMF processing unit 212-1 based on a control signal from the control unit 210, and multiple TSs. , is output to the system-on-chip 203 as an output stream.

As described above, when the method of Table B is adopted, the transport streams (multiple TSs) transmitted on one carrier (C1) include TSMF packets, but since the header information of the TSMF header does not include extension information, demodulation is required. In the IC 202-1, multiple transport streams extracted from the received signal of the carrier C1 are selected as composite non-target streams and multiple TS, and are output as output streams.

(3) Method of Table C-a

(Example of carrier wave)

Fig. 17 is a diagram showing an example of a carrier wave when the method of table C-a is adopted.

As shown in Fig. 17, when the conditions of table C-a are met, one carrier wave C1 is received by the receiving device 20. This carrier C1 includes a transport stream (TLV) including split TLV packets, a TSMF packet, and extension information in its TSMF header.

That is, in the method of Table C-a, the transport stream (TLV) includes a TSMF packet (a TSMF header), and the header information includes extension information. Additionally, in this extended information, “TLV” is specified for the stream type.

(Signal flow)

FIG. 18 is a diagram showing an example of the signal flow in the demodulation IC 202-1 when the method of Table C-a is adopted.

The demodulation unit 211 performs demodulation processing on the received signal input thereto and supplies the resulting transport stream (TLV) to the TSMF processing unit 212-1. Additionally, in the case of the table C-a method, since one carrier (C1) is received, the transport stream (TLV) is input only to the TSMF processing unit 212-1.

The TSMF processing unit 212-1 performs TSMF processing on the transport stream (TLV) from the demodulation unit 211 and attempts to detect TSMF packets. At this time, the TSMF processing unit 212-1 detects a TSMF packet from a transport stream (TLV) including split TLV packets, and can extract extension information from the TSMF header, thereby providing a TSMF notification to the effect of detecting a TSMF packet. And, the extracted extension information (header information) is supplied to the control unit 210. Additionally, the TSMF processing unit 212-1 supplies the transport stream (TLV) from the demodulation unit 211 to the synthesis unit 213.

The composition unit 213 removes TSMF packets included in the transport stream (TLV) input from the TSMF processing unit 212-1 and supplies the resulting split TLV stream to the TLV conversion unit 214. The TLV conversion unit 214 processes the segmented TLV stream input from the synthesis unit 213 and converts the segmented TLV packets into TLV packets.

The control unit 210 determines that the transport stream (TLV) is a stream to be synthesized based on the TSMF notification (notification of detection of TSMF packet and existence of extension information) from the TSMF processing unit 212-1, and the determination result The corresponding control signal is supplied to the selector 216. Additionally, the control unit 210 determines that the transport stream (TLV) is a TLV conversion target stream based on the extension information (stream type: “TLV”) from the TSMF processing unit 212-1, and provides a TLV conversion target stream according to the determination result. A control signal is supplied to the selector 215.

The selector 215 selects the TLV conversion target stream (TLV stream) input from the TLV conversion unit 214 based on the control signal from the control unit 210 and supplies it to the selector 216. The selector 216 selects the TLV conversion target stream (TLV stream) input from the selector 215 based on the control signal from the control unit 210, and outputs it to the system-on-chip 203 as an output stream.

As described above, when the method of Table C-a is adopted, the transport stream (TLV) transmitted on one carrier (C1) includes a TSMF packet, and the TSMF header contains extension information (stream type: "TLV") ), so in the demodulation IC 202-1, the transport stream (TLV) extracted from the received signal of the carrier C1 is selected as the synthesis target stream and is also selected as the TLV conversion target stream, and the output stream It is output as

(4) Method of table D-a

(Example of carrier wave)

Fig. 19 is a diagram showing an example of a carrier wave when the method of table D-a is adopted.

As shown in Fig. 19, when the conditions of table D-a are met, one carrier wave C1 is received by the receiving device 20. This carrier C1 includes two types of transport streams (TLV/TS), a transport stream (TLV) and a transport stream (TS).

The transport stream (TLV) includes TSMF packets and also includes extension information in the TSMF header. Additionally, to the transport stream (TLV), stream_id = "0x11" as a stream identifier and original_network_id = "0x22" as a network identifier are assigned, respectively.

The transport stream (TS) includes TSMF packets and also includes extension information in the TSMF header. Additionally, to the transport stream (TS), stream_id = "0x33" and original_network_id = "0x44" are assigned as a stream identifier, respectively.

That is, in the method of Table D-a, the two types of transport streams (TLV/TS) each include a TSMF packet (a TSMF header), and the header information includes extension information. Additionally, in this extension information, “TLV” or “TS” is specified for each transport stream as the stream type.

(Signal flow)

FIG. 20 is a diagram showing an example of the signal flow in the demodulation IC 202-1 when the method of Table D-a is adopted.

In the case of the method in Table D-a, the carrier C1 includes two types of transport streams (TLV/TS), a transport stream (TLV) and a transport stream (TS). Here, a transport stream (TLV/TS) is used to identify the output stream to be output. As identification information, stream_id = "0x11" and original_network_id = "0x22" are respectively specified and set in the control unit 210 and the TSMF processing unit 212.

The demodulation unit 211 performs demodulation processing on the received signal input there and supplies the resulting transport stream (TLV/TS) to the TSMF processing unit 212-1. Additionally, in the case of the table D-a method, since one carrier (C1) is received, the transport stream (TLV/TS) is input only to the TSMF processing unit 212-1.

The TSMF processing unit 212-1 performs TSMF processing on the transport stream (TLV/TS) from the demodulation unit 211 based on the set identification information, and sets stream_id = "0x11" and original_network_id = header information of the TSMF header. Attempts to detect TSMF packets with “0x22” specified.

At this time, the TSMF processing unit 212-1 detects the TSMF packet to be detected from the transport stream (TLV) and extracts extension information from the TSMF header. The TSMF processing unit 212-1 supplies the control unit 210 with a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information). Additionally, the TSMF processing unit 212-1 supplies the transport stream (TLV) identified by stream_id = "0x11" and original_network_id = "0x22" to the composition unit 213.

The composition unit 213 removes TSMF packets included in the transport stream (TLV) input from the TSMF processing unit 212-1 and supplies the resulting split TLV stream to the TLV conversion unit 214. The TLV conversion unit 214 processes the segmented TLV stream input from the synthesis unit 213 and converts the segmented TLV packets into TLV packets.

The control unit 210 determines that the transport stream (TLV) is a stream to be synthesized based on the TSMF notification (notification of detection of TSMF packet and existence of extension information) from the TSMF processing unit 212-1, and the determination result The corresponding control signal is supplied to the selector 216. Additionally, the control unit 210 determines that the transport stream (TLV) is a TLV conversion target stream based on the extension information (stream type: “TLV”) from the TSMF processing unit 212-1, and performs a TLV conversion target stream according to the determination result. A control signal is supplied to the selector 215.

The selector 215 selects the TLV conversion target stream (TLV stream) input from the TLV conversion unit 214 based on the control signal from the control unit 210 and supplies it to the selector 216. The selector 216 selects the TLV conversion target stream (TLV stream) input from the selector 215 based on the control signal from the control unit 210, and outputs it to the system-on-chip 203 as an output stream.

As described above, when the method of Table D-a is adopted, the demodulation IC 202-1 uses set identification information (stream_id = " A transport stream (TLV) containing a TSMF packet (the TSMF header) identified by 0x11", original_network_id = "0x22") is selected as the synthesis target stream, and the TSMF header also contains extension information (stream type: " Since it contains "TLV"), it is also selected as a TLV conversion target stream and output as an output stream.

(5) Method of Table E-b

(Example of carrier wave)

Fig. 21 is a diagram showing an example of a carrier wave when the method of Table E-b is adopted.

As shown in Fig. 21, when the conditions of table E-b are met, one carrier wave C1 is received by the receiving device 20. This carrier C1 includes a transport stream (TLV) and a transport stream (TS).

In the method of table E-b, similarly to the method of table D-a (FIG. 19) described above, stream_id = "0x11" and original_network_id = "0x22" are assigned to the transport stream (TLV), respectively, and to the transport stream (TS), stream_id = "0x33" and original_network_id = "0x44" are assigned, respectively.

That is, in the method of Table E-b, the two types of transport streams (TLV/TS) each include a TSMF packet (a TSMF header), and the header information includes extension information. Additionally, in this extension information, “TLV” or “TS” is specified for each transport stream as the stream type.

(Signal flow)

FIG. 22 is a diagram showing an example of the signal flow in the demodulation IC 202-1 when the method of Table E-b is adopted.

In the case of the method in Table E-b, the carrier C1 includes two types of streams (TLV/TS). Here, as identification information for identifying the output stream to be output, stream_id = "0x33" and original_network_id = “0x44” is respectively specified and set in the control unit 210 and the TSMF processing unit 212.

The demodulation unit 211 performs demodulation processing on the received signal input there and supplies the resulting transport stream (TLV/TS) to the TSMF processing unit 212-1. Additionally, in the case of the table E-b method, since one carrier (C1) is received, the transport stream (TLV/TS) is input only to the TSMF processing unit 212-1.

The TSMF processing unit 212-1 performs TSMF processing on the transport stream (TLV/TS) from the demodulation unit 211 based on the set identification information, and sets stream_id = "0x33" and original_network_id = header information of the TSMF header. Attempts to detect TSMF packets with “0x44” specified.

At this time, the TSMF processing unit 212-1 detects the TSMF packet to be detected from the transport stream (TS) and extracts extension information from the TSMF header. The TSMF processing unit 212-1 supplies the control unit 210 with a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information). Additionally, the TSMF processing unit 212-1 supplies the transport stream (TS) identified by stream_id = “0x33” and original_network_id = “0x44” to the composition unit 213.

The synthesis unit 213 removes TSMF packets included in the stream TS input from the TSMF processing unit 212-1.

The control unit 210 determines that the transport stream TS is a stream to be synthesized based on the TSMF notification (notification of detection of TSMF packet and existence of extension information) from the TSMF processing unit 212-1, and the determination result The corresponding control signal is supplied to the selector 216. Additionally, the control unit 210 determines that the transport stream (TS) is a stream not subject to TLV conversion based on the extension information (stream type: “TS”) from the TSMF processing unit 212-1, and the determination result The corresponding control signal is supplied to the selector 215.

The selector 215 selects the non-TLV conversion target stream (TS stream) input from the synthesis unit 213 based on the control signal from the control unit 210 and supplies it to the selector 216. The selector 216 selects the TLV conversion non-target stream (TS stream) input from the selector 215 based on the control signal from the control unit 210 and outputs it to the system on chip 203.

As described above, when the method of Table E-b is adopted, the demodulation IC 202-1 uses the set identification information (stream_id = " A transport stream (TS) containing a TSMF packet (the TSMF header) identified by 0x33", original_network_id = "0x44") is selected as the synthesis target stream, and the TSMF header also contains extension information (stream type: " Since it contains "TS"), it is also selected as a stream not subject to TLV conversion and output as an output stream.

(6) Method of table F-a

(Example of carrier wave)

Fig. 23 is a diagram showing an example of a carrier wave when the table F-a method is adopted.

As shown in Fig. 23, when the conditions of table F-a are met, four carrier waves (C1 to C4) are received by the receiving device 20. Each of the carriers C1 to C4 includes a transport stream (TLV). Additionally, each transport stream (TLV) includes a TSMF packet and extension information in its TSMF header.

In addition, among the carrier waves (C1 to C4), the three carrier waves (C1, C2, C4) become the carrier waves to be synthesized, and as common identification information, stream_id = "0x11" and original_network_id = "0x22" are assigned. there is. On the other hand, among the carrier waves C1 to C4, one wave of the carrier wave C3 is not subject to synthesis, and stream_id = "0x33" and original_network_id = "0x44" are assigned as unique identification information.

That is, the transport stream (TLV) transmitted on the carriers (C1 to C4) in the table F-a method each includes a TSMF packet (a TSMF header), and the header information includes extension information.

Additionally, in this extended information, "TLV" is commonly specified for each carrier as the stream type, while unique values are specified for each carrier as the order and total number of carriers. For example, in the extension information of the carrier C1, "1" and "3" are specified as the order and total number of carriers, respectively. Additionally, for example, as the order and total number of carriers, "2" and "3" are specified in the extension information of the carrier C2, respectively, and "3" and "3" are specified in the extension information of the carrier C4. Each is designated.

(Signal flow)

FIG. 24 is a diagram showing an example of the signal flow in the demodulation IC 202-1 when the method of table F-a is adopted.

In the case of the method of Table F-a, the four carriers (C1 to C4) each include a transport stream (TVL). Here, as identification information for identifying the output stream of the output target, stream_id = "0x11" and original_network_id = "0x22" is respectively specified and set in the control unit 210 and the TSMF processing unit 212.

The transport stream (TLV) included in the first carrier wave (C1) is input to the TSMF processing unit 212-1 through the demodulation unit 211. The TSMF processing unit 212-1 performs TSMF processing on the transport stream (TLV) from the demodulation unit 211 based on the set identification information, and adds stream_id = "0x11" and original_network_id = "0x22 to the header information of the TSMF header. "Attempts to detect the specified TSMF packet.

At this time, the TSMF processing unit 212-1 detects the TSMF packet to be detected from the transport stream (TLV) and extracts extension information from the TSMF header. The TSMF processing unit 212-1 supplies the control unit 210 with a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information).

Here, in the extension information obtained from the carrier C1, stream_type = "TLV" is specified as the stream type, carrier_sequence = "1" as the order of the carriers, and number_of_carriers = "3" as the total number of carriers. Additionally, the TSMF processing unit 212-1 supplies the transport stream (TLV) identified by stream_id = "0x11" and original_network_id = "0x22" to the composition unit 213.

The transport stream (TLV) included in the second carrier wave (C2) is input to the TSMF processing unit 212-2 from the external demodulation IC 202-2. The TSMF processing unit 212-2 attempts to detect a TSMF packet for which stream_id = "0x11" and original_network_id = "0x22" are specified based on the set identification information. Then, the TSMF processing unit 212-2 supplies a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information) to the control unit 210.

Here, stream_type = "TLV", carrier_sequence = "2", and number_of_carriers = "3" are specified in the extension information obtained from the carrier (C2). Additionally, the TSMF processing unit 212-2 supplies the transport stream (TLV) identified by stream_id = "0x11" and original_network_id = "0x22" to the composition unit 213.

The transport stream (TLV) included in the third carrier wave C3 is input to the TSMF processing unit 212-3 from the external demodulation IC 202-3. The TSMF processing unit 212-3 attempts to detect TSMF packets based on the set identification information. Here, since a TSMF packet with stream_id = "0x33" and original_network_id = "0x44" specified is detected, the TSMF processing unit 212-3 detects the TSMF packet, sends a TSMF notification to the effect of non-existence of target extension information, and extracts Extended information (header information) is supplied to the control unit 210.

The transport stream (TLV) included in the fourth carrier wave (C4) is input to the TSMF processing unit 212-4 from the external demodulation IC 202-4. The TSMF processing unit 212-4 attempts to detect a TSMF packet for which stream_id = "0x11" and original_network_id = "0x22" are specified based on the set identification information. Then, the TSMF processing unit 212-4 supplies a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information) to the control unit 210.

Here, stream_type = "TLV", carrier_sequence = "3", and number_of_carriers = "3" are specified in the extension information obtained from the carrier (C4). Additionally, the TSMF processing unit 212-4 supplies the transport stream (TLV) identified by stream_id = "0x11" and original_network_id = "0x22" to the composition unit 213.

The control unit 210, from the TSMF packets (TSMF headers) processed by the TSMF processing units 212-1 to 212-4, from the TSMF header identified by stream_id = "0x11" and original_network_id = "0x22", Extract header information (e.g. extension information). Here, the carriers including the TSMF header identified by stream_id = "0x11" and original_network_id = "0x22" are 3 of the 1st wave carrier (C1), the 2nd wave carrier (C2), and the 4th wave carrier (C4). It's pie.

The control unit 210 confirms the order and total number of carrier waves based on the extracted header information (composite information of the three-wave extension information). Here, the order of carriers (carrier_sequence) is "1", "2", and "3", with no overlap or shortage, and the total number of carriers (number_of_carriers) is "3" for all three waves, and all are the same value. Since the total number matches and synthesis is possible, the control unit 210 determines that the transport stream (TLV) corresponding to the three waves (carriers (C1, C2, C4)) is the synthesis target stream, and the decision result is The corresponding control signal is supplied to the selector 216.

Additionally, the control unit 210 confirms the stream type specified by the extracted header information (3-wave extension information). Here, since stream_type = "TLV" is specified for all three waves, the control unit 210 determines that the transport stream (TLV) corresponding to the three waves (carriers (C1, C2, C4)) is the TLV conversion target stream. And, a control signal corresponding to the determination result is supplied to the selector 215.

The synthesis unit 213 synthesizes the transport streams (TLV) input from the TSMF processing unit 212-1, TSMF processing unit 212-2, and TSMF processing unit 212-4, and the resulting composite stream (segmentation) TLV stream) is supplied to the TLV conversion unit 214. The TLV conversion unit 214 processes the segmented TLV stream input from the synthesis unit 213 and converts the segmented TLV packets into TLV packets.

The selector 215 selects the TLV conversion target stream (TLV stream) input from the TLV conversion unit 214 based on the control signal from the control unit 210 and supplies it to the selector 216. The selector 216 selects the TLV conversion target stream (TLV stream) input from the selector 215 based on the control signal from the control unit 210, and outputs it to the system-on-chip 203 as an output stream.

As described above, when the method of Table F-a is adopted, the demodulation IC 202-1 stores the set identification information (stream_id = "0x11", A three-wave transport stream (TLV) containing a TSMF packet (TSMF header) identified by original_network_id = "0x22" (however, in the composite information of the three-wave extension information, the order and total number of carriers are matched) ) is selected as the synthesis target stream, and since its TSMF header includes extension information (stream type: "TLV"), it is also selected as the TLV conversion target stream and is output as the output stream.

(7) Scheme of Table F-c

(Example of carrier wave)

Fig. 25 is a diagram showing an example of a carrier wave when the table F-c method is adopted.

As shown in Fig. 25, when the conditions of table F-c are met, three carrier waves (C1 to C3) are received by the receiving device 20. Each of the carriers C1 to C3 includes a transport stream (TLV). Additionally, each transport stream (TLV) includes a TSMF packet and extension information in its TSMF header.

Additionally, all of the carriers (C1 to C3) are carriers to be synthesized, and stream_id = "0x11" and original_network_id = "0x22" are assigned as common identification information.

That is, the transport stream (TLV) transmitted on the carriers C1 to C3 in the manner of Table F-c includes a TSMF packet (a TSMF header), and the header information includes extension information.

Additionally, in this extended information, "TLV" is commonly designated for each carrier as the stream type, while unique values are designated for each carrier as the order and total number of carriers. For example, as the order and total number of carriers, "1" and "3" are in the extension information of the carrier (C1), "1" and "3" are in the extension information of the carrier (C2), and "1" and "3" are in the extension information of the carrier (C3). “2” and “3” are designated for the information, respectively.

(Signal flow)

FIG. 26 is a diagram showing an example of the signal flow in the demodulation IC 202-1 when the table F-c method is adopted.

In the case of the table F-c method, each of the three carriers (C1 to C3) includes a transport stream (TLV). Here, as identification information for identifying the output stream of the output target, stream_id = "0x11" and original_network_id = "0x22" is respectively specified and set in the control unit 210 and the TSMF processing unit 212.

The transport stream (TLV) included in the first carrier wave (C1) is input to the TSMF processing unit 212-1 through the demodulation unit 211. The TSMF processing unit 212-1 performs TSMF processing on the transport stream (TLV) from the demodulation unit 211 based on the set identification information, and adds stream_id = "0x11" and original_network_id = "0x22 to the header information of the TSMF header. "Attempts to detect the specified TSMF packet.

At this time, the TSMF processing unit 212-1 detects the TSMF packet to be detected from the transport stream (TLV) and extracts extension information from the TSMF header. The TSMF processing unit 212-1 supplies the control unit 210 with a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information). Here, the extension information obtained from the carrier C1 is specified as stream_type = "TLV", carrier_sequence = "1", and number_of_carriers = "3", respectively.

The transport stream (TLV) included in the second carrier wave (C2) is input to the TSMF processing unit 212-2 from the external demodulation IC 202-2. The TSMF processing unit 212-2 attempts to detect a TSMF packet for which stream_id = "0x11" and original_network_id = "0x22" are specified based on the set identification information. Then, the TSMF processing unit 212-2 supplies a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information) to the control unit 210. Here, stream_type = "TLV", carrier_sequence = "1", and number_of_carriers = "3" are specified in the extension information obtained from the carrier (C2).

The transport stream (TLV) included in the third carrier wave C3 is input to the TSMF processing unit 212-3 from the external demodulation IC 202-3. The TSMF processing unit 212-3 attempts to detect a TSMF packet for which stream_id = "0x11" and original_network_id = "0x22" are specified based on the set identification information. Then, the TSMF processing unit 212-3 supplies a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information) to the control unit 210. Here, the extension information obtained from the carrier C3 is specified as stream_type = "TLV", carrier_sequence = "2", and number_of_carriers = "3".

The control unit 210 selects header information (e.g., For example, extended information) is extracted. Here, the carriers including the TSMF header identified by stream_id = "0x11" and original_network_id = "0x22" are 3 of the 1st wave carrier (C1), the 2nd wave carrier (C2), and the 3rd wave carrier (C3). It's pie.

The control unit 210 confirms the order and total number of carrier waves based on the extracted header information (composite information of the three-wave extension information). Here, the order (carrier_sequence) of the carrier waves is "1", "1", and "2", and since "1" is duplicated and cannot be synthesized, the control unit 210 creates a transport stream (TLV) corresponding to the three waves. It is determined that this is a non-target stream for synthesis, and a control signal corresponding to the decision result is supplied to the selector 216.

The selector 216 selects the transport stream (TLV) as a composite non-target stream input from the demodulator 211 based on the control signal from the control unit 210, and outputs it to the system on chip 203 as an output stream. do.

As described above, when the method of table F-c is adopted, in the demodulation IC 202-1, the transport stream (TLV) transmitted in three waves of carrier waves (C1 to C3) has set identification information (stream_id = "0x11", It contains a TSMF packet (TSMF header) identified by original_network_id = "0x22"), but since the order and total number of carriers are not matched in the composite information of the three-wave extension information, only one carrier (e.g. The transport stream (TLV) of the carrier (C1) is selected as the composite non-target stream and output as the output stream.

(8) Scheme of Table G-a

(Example of carrier wave)

Fig. 27 is a diagram showing an example of a carrier wave when the table G-a method is adopted.

As shown in Fig. 27, when the conditions of table G-a are met, two carrier waves C1 and C2 are received by the receiving device 20. Each of the carriers C1 and C2 includes two types of transport streams (TLV/TS): a transport stream (TLV) and a transport stream (TS). Additionally, each transport stream includes a TSMF packet and also includes extension information in its TSMF header.

Additionally, the two carrier waves (C1, C2) become the carrier waves to be synthesized, and stream_id = "0x11" and original_network_id = "0x22" are assigned as common identification information to the transport stream (TLV). On the other hand, stream_id = "0x33" and original_network_id = "0x44" are assigned to the transport stream (TS) as common identification information.

That is, the transport stream (TLV/TS) transmitted on the carriers C1 and C2 in the manner of Table G-a includes a TSMF packet (a TSMF header), and the header information includes extension information.

Additionally, in the extension information of the transport stream (TLV), "TLV" is commonly designated for each carrier as the stream type, while unique values are designated for each carrier as the order and total number of carriers. For example, as the order and total number of carriers, "1" and "2" are specified in the extension information of the carrier C1, and "2" and "2" are specified in the extension information of the carrier C2. Additionally, in the extension information of the transport stream (TS), “TS” is commonly designated for each carrier as the stream type.

(Signal flow)

FIG. 28 is a diagram showing an example of the signal flow in the demodulation IC 202-1 when the method of Table G-a is adopted.

In the case of the method of Table G-a, the two carriers (C1, C2) each include a transport stream (TLV/TS). Here, as identification information for identifying the output stream of the output target, stream_id = "0x11" and , original_network_id = "0x22" are respectively specified and set in the control unit 210 and the TSMF processing unit 212.

The stream (TLV/TS) included in the first carrier wave (C1) is input to the TSMF processing unit 212-1 through the demodulation unit 211. The TSMF processing unit 212-1 performs TSMF processing on the transport stream (TLV/TS) from the demodulation unit 211 based on the set identification information, and sets stream_id = "0x11" and original_network_id = header information of the TSMF header. Attempts to detect TSMF packets with “0x22” specified.

At this time, the TSMF processing unit 212-1 detects the TSMF packet to be detected from the transport stream (TLV) and extracts extension information from the TSMF header. The TSMF processing unit 212-1 supplies the control unit 210 with a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information).

Here, the extension information obtained from the carrier C1 is specified as stream_type = "TLV", carrier_sequence = "1", and number_of_carriers = "2", respectively. Additionally, the TSMF processing unit 212-1 supplies the transport stream (TLV) identified by stream_id = "0x11" and original_network_id = "0x22" to the composition unit 213.

The stream (TLV/TS) included in the second carrier wave (C2) is input to the TSMF processing unit 212-2 from the external demodulation IC 202-2. The TSMF processing unit 212-2 attempts to detect a TSMF packet for which stream_id = "0x11" and original_network_id = "0x22" are specified based on the set identification information. Then, the TSMF processing unit 212-2 supplies a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information) to the control unit 210.

Here, stream_type = "TLV", carrier_sequence = "2", and number_of_carriers = "2" are specified in the extension information obtained from the carrier (C2). Additionally, the TSMF processing unit 212-2 supplies the transport stream (TLV) identified by stream_id = "0x11" and original_network_id = "0x22" to the composition unit 213.

The control unit 210 identifies the TSMF packets (TSMF headers) processed by the TSMF processing unit 212-1 and TSMF processing unit 212-2 by stream_id = "0x11" and original_network_id = "0x22". Header information (for example, extension information) is extracted from the TSMF header. Here, the carrier wave including the TSMF header identified by stream_id = "0x11" and original_network_id = "0x22" is two waves, the first wave carrier (C1) and the second wave carrier (C2).

The control unit 210 confirms the order and total number of carrier waves based on the extracted header information (composite information of the two-wave extension information). Here, the order of carriers (carrier_sequence) is "1" and "2", and there is no overlap or shortage, and the total number of carriers (number_of_carriers) is "2" for both waves, and both have the same value and match the total number. Since there is and synthesis is possible, the control unit 210 determines that the transport stream (TLV) corresponding to the two waves (carrier waves (C1, C2)) is the stream to be synthesized, and sends a control signal according to the determination result to the selector ( 216).

Additionally, the control unit 210 confirms the stream type specified by the extracted header information (second-wave extension information). Here, since stream_type = "TLV" is specified for both waves, the control unit 210 determines that the transport stream (TLV) corresponding to the two waves (carriers (C1, C2)) is the TLV conversion target stream, A control signal corresponding to the determination result is supplied to the selector 215.

The synthesis unit 213 synthesizes the transport streams (TLV) input from the TSMF processing unit 212-1 and the TSMF processing unit 212-2, and converts the resulting composite stream (split TLV stream) into a TLV conversion unit ( 214). The TLV conversion unit 214 processes the segmented TLV stream input from the synthesis unit 213 and converts the segmented TLV packets into TLV packets.

The selector 215 selects the TLV conversion target stream (TLV stream) input from the TLV conversion unit 214 based on the control signal from the control unit 210 and supplies it to the selector 216. The selector 216 selects the TLV conversion target stream (TLV stream) input from the selector 215 based on the control signal from the control unit 210, and outputs it to the system-on-chip 203 as an output stream.

As described above, when the method of Table G-a is adopted, the demodulation IC 202-1 uses set identification information (stream_id) among the two types of transport streams (TLV/TS) transmitted in two waves of the carrier waves (C1, C2). = "0x11", original_network_id = "0x22"), the transport stream (TLV) containing the TSMF packet (its TSMF header) is selected as the synthesis target stream, and its TSMF header also contains extension information (stream type specific : "TLV"), it is also selected as a target stream for TLV conversion and output as an output stream.

(9) Method of Table H-b

(Example of carrier wave)

Fig. 29 is a diagram showing an example of a carrier wave when the method of Table H-b is adopted.

As shown in Fig. 29, when the conditions of table H-b are met, two carrier waves C1 and C2 are received by the receiving device 20. Each of the carriers C1 and C2 includes a transport stream (TLV) and a transport stream (TS), respectively. Additionally, each transport stream includes a TSMF packet and also includes extension information in its TSMF header.

Additionally, the two carrier waves (C1, C2) become the carrier waves to be synthesized, and stream_id = "0x11" and original_network_id = "0x22" are assigned as common identification information to the transport stream (TLV). On the other hand, stream_id = "0x33" and original_network_id = "0x44" are assigned to the transport stream (TS) as common identification information.

That is, the transport stream (TLV/TS) transmitted on the carriers C1 and C2 in the manner of Table H-b includes a TSMF packet (a TSMF header), and the header information includes extension information.

In addition, in the extension information of the transport stream (TS), "TS" is commonly designated for each carrier as the stream type, while unique values are designated for each carrier as the order and total number of carriers. For example, as the order and total number of carriers, "1" and "2" are specified in the extension information of the carrier C1, and "2" and "2" are specified in the extension information of the carrier C2. Additionally, in the extension information of the transport stream (TLV), "TLV" is commonly designated for each carrier as the stream type.

(Signal flow)

FIG. 30 is a diagram showing an example of the signal flow in the demodulation IC 202-1 when the method of Table H-b is adopted.

In the case of the method of Table H-b, the two carriers (C1, C2) each include a transport stream (TLV/TS). Here, as identification information for identifying the output stream of the output target, stream_id = "0x33" and , original_network_id = "0x44" are respectively specified and set in the control unit 210 and the TSMF processing unit 212.

The stream (TLV/TS) included in the first carrier wave (C1) is input to the TSMF processing unit 212-1 through the demodulation unit 211. The TSMF processing unit 212-1 performs TSMF processing on the transport stream (TLV/TS) from the demodulation unit 211 based on the set identification information, and includes stream_id = "0x33" and original_network_id in the header information of the TSMF header. = Detects a TSMF packet with “0x44” specified.

At this time, the TSMF processing unit 212-1 detects the TSMF packet to be detected from the transport stream (TS) and extracts extension information from the TSMF header. The TSMF processing unit 212-1 supplies the control unit 210 with a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information).

Here, the extension information obtained from the carrier C1 is specified as stream_type = "TS", carrier_sequence = "1", and number_of_carriers = "2", respectively. Additionally, the TSMF processing unit 212-1 supplies the transport stream (TS) identified by stream_id = “0x33” and original_network_id = “0x44” to the composition unit 213.

The stream (TLV/TS) included in the second carrier wave (C2) is input to the TSMF processing unit 212-2 from the external demodulation IC 202-2. The TSMF processing unit 212-2 attempts to detect a TSMF packet in which stream_id = "0x33" and original_network_id = "0x44" are specified based on the set identification information. Then, the TSMF processing unit 212-2 supplies a TSMF notification indicating detection of a TSMF packet and the extracted extension information (header information) to the control unit 210.

Here, stream_type = "TS", carrier_sequence = "2", and number_of_carriers = "2" are specified in the extension information obtained from the carrier (C2). Additionally, the TSMF processing unit 212-2 supplies the transport stream (TS) identified by stream_id = “0x33” and original_network_id = “0x44” to the composition unit 213.

The control unit 210 identifies the TSMF packets (TSMF headers of) processed by the TSMF processing unit 212-1 and TSMF processing unit 212-2 by stream_id = "0x33" and original_network_id = "0x44". Header information (for example, extension information) is extracted from the TSMF header. Here, the carrier wave including the TSMF header identified by stream_id = "0x33" and original_network_id = "0x44" is two waves, the first wave carrier (C1) and the second wave carrier (C2).

The control unit 210 confirms the order and total number of carrier waves based on the extracted header information (composite information of the two-wave extension information). Here, the order of carriers (carrier_sequence) is "1" and "2", and there is no overlap or shortage, and the total number of carriers (number_of_carriers) is "2" for both waves, and both have the same value and match the total number. Since the two waves (carriers C1 and C2) are available for synthesis, the control unit 210 determines that the transport stream (TS) corresponding to the two waves (carriers (C1, C2)) is the stream to be synthesized, and sends a control signal according to the determination result to the selector (216). ) is supplied to.

Additionally, the control unit 210 confirms the stream type specified by the extracted header information (second-wave extension information). Here, since stream_type = "TS" is specified for both waves, the control unit 210 determines that the transport stream (TS) corresponding to the two waves (carriers (C1, C2)) is a stream not subject to TLV conversion. , a control signal corresponding to the determination result is supplied to the selector 215.

The synthesis unit 213 synthesizes the transport streams (TS) input from the TSMF processing unit 212-1 and the TSMF processing unit 212-2, respectively, and outputs the resulting composite stream (TS stream).

The selector 215 selects the non-TLV conversion target stream (TS stream) input from the synthesis unit 213 based on the control signal from the control unit 210 and supplies it to the selector 216. The selector 216 selects the TLV conversion non-target stream (TS stream) input from the selector 215 based on the control signal from the control unit 210 and outputs it to the system-on-chip 203 as an output stream.

As described above, when the method of Table H-b is adopted, the demodulation IC 202-1 uses set identification information (stream_id) among the two types of transport streams (TLV/TS) transmitted in two waves of the carrier waves (C1, C2). = "0x33", original_network_id = "0x44"), the transport stream (TS) containing the TSMF packet (its TSMF header) is selected as the synthesis target stream, and the TSMF header also contains extension information (stream type specific : "TS"), it is also selected as a non-target stream for TLV conversion and output as an output stream.

(Processing flow on the sending and receiving sides)

Next, referring to the flow charts in FIGS. 31 to 33, the flow of processing on the transmitting side and processing on the receiving side will be explained.

Figure 31 is a flow chart explaining the processing flow on the transmitting side and the receiving side.

31, the processing of steps S111 to S113 is performed by the transmitting device 10, such as a head end, and the processing of steps S211 to S213 is performed by a receiving device, such as a television receiver installed in the home of a cable television subscriber ( 20) is executed.

In the transmitting device 10, content such as broadcast programs of terrestrial broadcasting, satellite broadcasting, and broadcasting programs produced by cable television broadcasting stations is processed (S111), and after being divided for each carrier wave as necessary, for example, 64QAM or 256QAM. By performing modulation processing according to the modulation method, etc. (S112), it is transmitted as a cable television broadcast signal (S113).

This broadcast signal is, for example, a signal corresponding to a stream such as a single TS, multiple TS, or a transport stream of a multi-carrier transmission method. The broadcast signal transmitted from the transmitting device 10 is received by the receiving device 20 through the CATV transmission line 30.

In step S211, the tuners 201-1 to 201-4 receive the broadcast signal transmitted from the transmitting device 10. Additionally, the demodulation ICs 202-2 to 202-4 perform demodulation processing on the received signals received by the tuners 201-2 to 201-4, and supply the signals to the demodulation IC 202-1.

In step S212, the demodulation IC 202-1 performs demodulation processing on the signal received from the tuner 201-1, the transport stream obtained through the demodulation processing, and transmission from the demodulation ICs 202-2 to 202-4. Performs synthesis processing on the stream. Details of this demodulation and synthesis process will be described later with reference to the flow chart in FIG. 33.

In step S213, the system-on-chip 203 performs processing, such as decoding, on the output stream from the demodulation IC 202-1. Accordingly, in the receiving device 20, images of contents such as broadcast programs are displayed on the display 204, and audio synchronized with the images is output from the speaker.

Above, the processing flow on the transmitting side and the receiving side has been explained.

(Stream output setting processing flow of new function)

Next, the flow of stream output setting processing corresponding to the new function will be explained with reference to the flow chart in FIG. 32.

In step S221, the control unit 210 or a control device (for example, a microcontroller or processor, etc.) including an external control unit operates the demodulation IC 202- 1) Set stream_id and original_network_id. Here, for example, stream_id and original_network_id are set as identification information for the control unit 210 and the TSMF processing units 212-1 to 212-4.

In step S222, the control unit 210 or a control device including an external control unit sets the demodulation IC 202-1 to be on as a stream output.

In addition, the stream output setting processing of this new function is performed, for example, before the processing of step S212 (demodulation/synthesis processing) begins, and the processing ends when the processing of step S222 ends.

The above explains the stream output setting processing flow corresponding to the new function.

(Flow of demodulation and synthesis processing)

Next, with reference to the flow chart in FIG. 33, the flow of demodulation and synthesis processing corresponding to the processing in step S212 in FIG. 31 will be described. This demodulation and synthesis process is performed by the demodulation IC 202-1.

In step S231, the demodulation unit 211 performs demodulation processing on the signal received from the tuner 201-1.

In step S232, the TSMF processing units 212-1 to 212-4 perform TSMF processing on the transport stream input thereto.

For example, here, TSMF processing is performed for each transport stream based on the identification information (stream_id, original_network_id) set in the process in step S221 in FIG. 32, and the identification information (stream_id, original_network_id) is specified in the header information of the TSMF header. Attempts to detect TSMF packets. And, if extension information is included as header information of the TSMF header and a TSMF notification indicating whether or not a TSMF packet (TSMF header) has been detected, the extension information (header information) is sent to the control unit 210.

In step S233, the control unit 210 checks the presence or absence of a TSMF header and, if there is a TSMF header, extension information of the header information based on the information from the TSMF processing units 212-1 to 212-4.

In step S234, the control unit 210 determines whether or not the TSMF header is included based on the confirmation result in step S233.

If it is determined in step S234 that the TSMF header is not included, the process proceeds to step S235. In step S235, the control unit 210 controls the selector 216 so that the transport stream (single TS) as a composite non-target stream input from the demodulator 211 is output as an output stream. Additionally, this processing flow corresponds to the method of Table A (FIGS. 13 and 14).

Additionally, if it is determined in step S234 that a TSMF header is included, the process proceeds to step S236. In step S236, the control unit 210 determines whether the header information of the TSMF header includes extension information based on the confirmation result in step S233.

If it is determined in step S236 that the header information of the TSMF header does not include extension information, the process proceeds to step S237. In step S237, the control unit 210 controls the selector 216 to select a composite non-target stream input from the TSMF processing unit 212-1, as well as a transport stream as multiple TS (for example, a stream of broadcast program A). , so that it is output as an output stream. Additionally, this processing flow corresponds to the table B method (FIGS. 15 and 16).

Additionally, if it is determined in step S236 that the header information of the TSMF header includes extension information, the process proceeds to step S238. In step S238, the synthesis unit 213 performs synthesis processing on the transport stream input from at least one of the TSMF processing units 212-1 to 212-4.

In step S239, the control unit 210 determines whether the stream type included in the extension information is “TLV” or “TS”.

If it is determined in step S239 that the stream type included in the extension information is "TLV", the process proceeds to step S240.

In step S240, the TLV conversion unit 214 processes the segmented TLV stream input from the composition unit 213 and converts the segmented TLV packets into TLV packets.

In step S241, the control unit 210 controls the selector 215 and the selector 216 to output the TLV conversion target stream (TLV stream) as the synthesis target stream as an output stream. In addition, the flow of this process includes the table C-a method (FIGS. 17 and 18), the table D-a method (FIGS. 19 and 20), the table F-a method (FIGS. 23 and 24), and the table G-a method (FIG. 27). , corresponds to Figure 28).

Additionally, if it is determined in step S239 that the stream type included in the extension information is "TS", the process proceeds to step S242.

In step S242, the control unit 210 controls the selector 215 and the selector 216 to output the non-TLV conversion target stream (TS stream) as the synthesis target stream as an output stream. Additionally, this processing flow corresponds to the table E-b method (FIGS. 21 and 22) and the table H-b method (FIGS. 29 and 30).

When the processing of steps S235, S237, S241, and S242 is completed, the processing returns to step S212 in FIG. 31 and the subsequent processing is performed.

In addition, it is omitted in the demodulation/synthesis process shown in FIG. 33, but when extension information is included in the header information of the TSMF header, the composition information (carrier_sequence, number_of_carriers) of the extension information is checked to determine the total number and order of carriers. Composition processing (S238) can be performed only when matching is achieved. For example, the processing flow when the total number and order of carriers do not match corresponds to the method of Table F-c (FIGS. 25 and 26).

Above, the flow of demodulation and synthesis processing has been explained. By executing the processing shown in the flow charts of FIGS. 31 to 33 described above, the receiving device 20 (FIG. 10) with the new function can easily output a desired stream.

That is, in the receiving device 20 (FIG. 10) with a new function, as shown in the table shown in FIG. 11, a transport stream based on a single TS multiplexing method or a transport stream based on a multiple TS multiplexing method, and even multiple It is necessary to process and output various types of streams, such as transport streams based on the carrier wave transmission method. In contrast, in the new function to which this technology is applied, the demodulation IC 202-1 (control unit 210) controls the output stream based on the presence or absence of a TSMF header included in the transport stream, or header information (extension information) of the TSMF header. Since control is performed to select , the desired stream can be output more easily.

In addition, in the new function to which this technology is applied, identification information (stream_id, original_network_id) is set in the demodulation IC 202-1 (control unit 210 and TSMF processing units 212-1 to 212-4), so the TSMF processing unit In (212-1 to 212-4), processing regarding the TSMF header is performed based on the set identification information, and in the control unit 210, the set identification information and the TSMF header from the TSMF processing units (212-1 to 212-4) are performed. Control is performed to select the output stream based on information about the header information.

As a result, as shown in the stream output setting process corresponding to the new function (FIG. 32), software for receiving each broadcast program is implemented with fewer processing steps (software processing), so that, for example, after switching broadcast programs, The time until the image is displayed can be shortened. More specifically, compared to the stream output setting processing corresponding to the new function (Figure 32) compared to the stream output setting processing corresponding to the current function (Figures 8 and 9), the processing steps are significantly reduced, and the processing time is reduced significantly. It is clear that can be shortened.

In addition, for example, in the case of the stream output setting processing corresponding to the new function (FIG. 32), the same TSMF packet as the stream output setting processing corresponding to the current function (FIG. 8, FIG. 9) is stored in the memory (S15 in FIG. 8) , S36 in FIG. 9 is unnecessary, so the memory of the receiving system 200 can be reduced. As a result, concerns regarding cost and processing speed in the receiving system 200 can be resolved.

<2. Variation example>

(Different configurations of the receiving device)

In addition, in the above description, it has been explained that the receiving device 20 (FIG. 1) is configured as a fixed receiver such as a television receiver or a set top box (STB), but fixed receivers include, for example, a recorder, a game console, and a personal receiver. It may also include computers, network storage, etc. In addition, the receiving device 20 is not limited to a fixed receiver, but for example, mobile receivers such as smartphones, mobile phones, and tablet computers, vehicle-mounted devices such as vehicle-mounted televisions, and head-mounted displays ( It may also include electronic devices such as wearable computers such as HMD (Head Mounted Display).

Additionally, the demodulation IC 202-1 (demodulation device) constituting the reception device 20 (FIG. 1) may be regarded as a reception device or demodulation device to which the present technology is applied. In addition, in the above description, the number of multiple carriers is 2 to 4, but the number of carriers may be any number as long as it is 2 or more (for example, it may be 5 or more).

At this time, in the receiving device 20 (FIG. 10), tuners 201-1 to 201-N and demodulation ICs 202-1 to 202-N in accordance with the number of N carrier waves (N is an integer of 2 or more). ) is prepared. Additionally, in the demodulation IC 202-1 (FIG. 10), one demodulation unit 211 and N TSMF processing units 212-1 to 212-N are provided. Additionally, the number of tuner 201, demodulation IC 202, and TSMF processing unit 212 is not limited to the same number as the number of carrier waves, but may be provided in a number greater than the number of carrier waves.

(Configuration including communication lines)

In addition, in the transmission system 1 (FIG. 1), although not shown, various servers are connected to a communication line such as the Internet, and a receiving device 20 (FIG. 1) having a communication function is connected to a communication line such as the Internet. It may be possible to receive various data such as content and applications by accessing various servers through two-way communication.

(etc)

Additionally, the terms described in this specification are only examples and do not intentionally exclude other terms from being used. For example, in the above description, frame may be replaced with another term, such as packet.

<3. Computer Configuration>

The series of processes described above can be executed by hardware or software. When a series of processes is executed using software, a program constituting the software is installed on the computer. Fig. 34 is a diagram showing an example of the hardware configuration of a computer that executes the above-described series of processes using a program.

In the computer 1000, a central processing unit (CPU) 1001, a read only memory (ROM) 1002, and a random access memory (RAM) 1003 are interconnected by a bus 1004. An input/output interface 1005 is also connected to the bus 1004. The input/output interface 1005 is connected to an input unit 1006, an output unit 1007, a recording unit 1008, a communication unit 1009, and a drive 1010.

The input unit 1006 consists of a keyboard, mouse, microphone, etc. The output unit 1007 consists of a display, a speaker, etc. The recording unit 1008 is made of a hard disk, non-volatile memory, etc. The communication unit 1009 consists of a network interface and the like. The drive 1010 drives a removable recording medium 1011 such as a magnetic disk, optical disk, magneto-optical disk, or semiconductor memory.

In the computer 1000 configured as above, the CPU 1001 loads the program recorded in the ROM 1002 or the recording unit 1008 into the RAM 1003 through the input/output interface 1005 and the bus 1004 and executes it. By doing so, the series of processes described above are performed.

The program executed by the computer 1000 (CPU 1001) can be provided by being recorded on a removable recording medium 1011 such as package media, for example. Additionally, programs can be provided through wired or wireless transmission media such as local area networks, the Internet, and digital satellite broadcasting.

In the computer 1000, a program can be installed in the recording unit 1008 through the input/output interface 1005 by mounting the removable recording medium 1011 in the drive 1010. Additionally, the program can be received from the communication unit 1009 and installed in the recording unit 1008 through a wired or wireless transmission medium. Additionally, programs can be installed in advance into the ROM 1002 or the recording unit 1008.

Here, the processing performed by the computer according to the program in this specification does not necessarily need to be performed in time series according to the order described as a flow chart. In other words, processing that a computer performs according to a program also includes processing that is executed in parallel or individually (for example, parallel processing or processing by objects). Additionally, a program may be processed by one computer (processor), or may be distributed and processed by multiple computers.

In addition, the embodiment of the present technology is not limited to the above-described embodiment, and various changes are possible without departing from the gist of the present technology.

Additionally, this technology can have the following configuration.

(1) Controlling the selection of an output target output stream extracted from the transport stream based on the presence or absence of a multi-frame header included in a transport stream transmitted for one or a plurality of carriers, or header information of the multi-frame header. A receiving device having a control unit.

(2) The receiving device according to (1) above, wherein the control unit selects the output stream based on extension information included in the header information of the multi-frame header identified by set identification information.

(3) The control unit selects the synthesis target stream as the output stream when the multi-frame header is included in the transport stream and the extension information is included in the header information, as described in (2) above. Device.

(4) The control unit synthesizes the output stream when the transport stream does not include the multi-frame header, or when the transport stream includes the multi-frame header and does not include the extension information in the header information. The receiving device according to (2) or (3) above, which selects a non-target stream.

(5) The extension information includes synthesis information of the carrier wave,

The receiving device according to (3) or (4) above, wherein the control unit selects the synthesis target stream or the synthesis non-target stream as the output stream based on the synthesis information.

(6) The receiving device according to (5) above, wherein the combined information includes at least information indicating the total number and order of the carrier waves.

(7) The receiving device according to (6) above, wherein the control unit selects the synthesis target stream as the output stream when the total number and order of the carrier waves match.

(8) The receiving device according to (6) or (7) above, wherein the control unit selects the composite non-target stream as the output stream when the total number and order of the carriers do not match.

(9) The extension information includes type information indicating the type of the transport stream,

The receiving device according to any one of (3) to (8) above, wherein the control unit selects a stream to be converted or a stream not to be converted as the output stream based on the type information.

(10) The receiving device according to (9) above, wherein the synthesis target stream includes the conversion target stream or the conversion non-target stream.

(11) The receiving device according to (9) or (10) above, wherein the type information includes information indicating a variable length packet or a fixed length packet.

(12) The receiving device according to (11), wherein, when the type of the transport stream indicates the variable length packet, the control unit selects the conversion target stream for converting segmented variable length packets into variable length packets.

(13) The receiving device according to (11) or (12), wherein the control unit selects the non-conversion stream when the type of the transport stream indicates the fixed length packet.

(14) The transport stream includes a transport stream based on the single TS multiplexing method, a transport stream based on the multiple TS multiplexing system, or a transport stream based on the multiple carrier transmission system (1) to (1) above. The receiving device described in any one of 13).

(15) Also provided is a plurality of processing units provided in accordance with the number of carrier waves,

The identification information is set in the control unit and the processing unit,

The processing unit performs processing on the multi-frame header based on the set identification information,

The receiving device according to (2) above, wherein the control unit selects the output stream based on the set identification information and the header information in the processing unit.

(16) The receiving device according to (15) above, wherein the identification information includes a stream identifier and a network identifier.

(17) a synthesis unit that synthesizes a stream to be synthesized;

The receiving device according to (15) or (16) above, further comprising a conversion unit that converts the stream to be converted.

(18) The receiving device according to any one of (1) to (17) above, which is configured as a demodulation device.

(19) When the number of carrier waves is N (N is an integer of 2 or more), the control unit,

A demodulator that demodulates a signal of one carrier wave,

N number of processing units,

a synthesis unit that synthesizes a stream to be synthesized;

a first demodulation device having a conversion unit that converts a stream to be converted;

Equipped with a second demodulation device that demodulates the signal of one carrier wave,

The first demodulation device is provided,

N-1 second demodulation devices are provided,

The receiving device according to (15) or (16) above, wherein the N processing units respectively process the transport stream from the demodulation units and the transport stream from the N-1 second demodulators.

(20) The receiving device selects the target output stream extracted from the transport stream based on the presence or absence of a multi-frame header included in the transport stream transmitted for each one or multiple carriers, or the header information of the multi-frame header. A receiving method that performs control.

1: Transmission system 10: Transmission device
20: receiving device 30: CATV transmission line
201, 201-1 to 201-4: Tuner 202, 202-1 to 202-4: Demodulation IC
203: System on Chip (SoC) 210: Control unit
211: Demodulation unit 212, 212-1 to 212-4: TSMF processing unit
213: synthesis unit 214: TLV conversion unit
215: selector 216: selector
1000: Computer 1001: CPU

Claims (20)

Control is performed to select an output target output stream extracted from the transport stream based on the presence or absence of a multi-frame header included in the transport stream transmitted for each one or a plurality of carriers, or header information of the multi-frame header, and set identification a control unit that selects the output stream based on extension information included in the header information of the multi-frame header identified by information;
A plurality of processing units installed according to the number of carrier waves,
The identification information is set in the control unit and the processing unit,
The processing unit performs processing on the multi-frame header based on the set identification information,
The control unit selects the output stream based on the set identification information and the header information in the processing unit. delete According to paragraph 1,
The control unit selects a synthesis target stream as the output stream when the transport stream includes the multi-frame header and the header information includes the extension information. According to paragraph 1,
The control unit, when the transport stream does not include the multi-frame header, or when it includes the multi-frame header and does not include the extension information in the header information, synthesizes a non-target stream as the output stream. A receiving device characterized in that selection. According to paragraph 3,
The extension information includes synthesis information of the carrier wave,
The receiving device, wherein the control unit selects the synthesis target stream or the synthesis non-target stream as the output stream based on the synthesis information. According to clause 5,
The receiving device, wherein the combined information includes at least information indicating the total number and order of the carrier waves. According to clause 6,
The receiving device, wherein the control unit selects the synthesis target stream as the output stream when the total number and order of the carrier waves match. According to clause 6,
The control unit selects the composite non-target stream as the output stream when the total number and order of the carrier waves are not matched. According to paragraph 3,
The extension information includes type information indicating the type of the transport stream,
The receiving device, wherein the control unit selects a stream to be converted or a stream not to be converted as the output stream based on the type information. According to clause 9,
The receiving device, wherein the synthesis target stream includes the conversion target stream or the conversion non-target stream. According to clause 9,
The receiving device, wherein the type information includes information indicating a variable length packet or a fixed length packet. According to clause 11,
Wherein the control unit selects the conversion target stream for converting segmented variable length packets into variable length packets when the type of the transport stream indicates the variable length packet. According to clause 11,
The receiving device, wherein the control unit selects the non-conversion stream when the type of the transport stream indicates the fixed length packet. According to paragraph 1,
A receiving device characterized in that the transport stream includes a transport stream based on a single TS multiplexing method, a transport stream based on a multiple TS multiplexing method, or a transport stream based on a multiple carrier transmission method. delete According to paragraph 1,
The identification information includes a stream identifier and a network identifier. According to paragraph 1,
a synthesis unit that synthesizes a stream to be synthesized;
A receiving device characterized by further comprising a conversion unit that converts the stream to be converted. According to paragraph 1,
A receiving device characterized in that it is configured as a demodulation device. According to paragraph 1,
When the number of carrier waves is N (N is an integer of 2 or more), the control unit,
A demodulator that demodulates a signal of one carrier wave,
N number of processing units,
a synthesis unit that synthesizes a stream to be synthesized;
a first demodulation device having a conversion unit that converts a stream to be converted;
Equipped with a second demodulation device that demodulates the signal of one carrier wave,
The first demodulation device is provided,
N-1 second demodulation devices are provided,
A reception device characterized in that the N processing units each process the transport stream from the demodulator and the transport stream from the N-1 second demodulators. delete

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