JP6982163B2 - Receiver, receiving method, and receiving program - Google Patents

Description

The present invention relates to a signal configuration device for transmitting data, a signal configuration system, a signal configuration method, and a signal configuration program.

Emergency warning broadcasting may be performed in television broadcasting. The broadcasting station transmits an emergency warning signal when performing an emergency warning broadcast. Then, the receiver that has received the transmitted emergency warning signal notifies that the emergency warning has been issued.

In digitized television broadcasting, when an emergency warning broadcast is performed, data corresponding to the emergency warning signal is transmitted.

Patent Document 1 describes a receiving device for notifying that an emergency warning has been issued when an emergency warning broadcast is performed in a digitized television broadcast.

Patent Document 2 describes a device for transmitting TMCC (Transmission and Multiplexing Control) basic information including an emergency bit that can be used in an emergency over one superframe.

Regarding emergency warning broadcasting in BS (Broadcasting Satellite) / wideband CS (Communications Satellite) digital broadcasting, operational regulations (ARIB (Association of Radio Industries and Businesses) TR-B15) have been established.

Further, a standard (ARIB STD-B44) has been established for emergency warning broadcasting in advanced broadband satellite digital broadcasting.

Japanese Unexamined Patent Publication No. 2013-153305 Japanese Unexamined Patent Publication No. 2003-37573

Emergency warning broadcasting is performed to encourage viewers to evacuate. Therefore, it is desirable that audio and image output in response to the emergency warning broadcast be performed more quickly. Then, in order to output audio and images in response to the emergency warning broadcast more quickly, it is desirable that the data corresponding to the emergency warning signal be transmitted more quickly in the digitized television broadcasting.

However, in the apparatus described in Patent Document 2 based on the operation regulation of TR-B15, the same TMCC basic information is transmitted over one super frame. Therefore, it is necessary to transmit the TMCC basic information in which the emergency bit is set when the processing related to the transmission of one super frame in which the emergency bit set when the emergency warning broadcast is performed is being performed. When it occurs, the superframe after the one superframe is transmitted by including the TMCC basic information in which the emergency bit is set. Therefore, in order to transmit the TMCC basic information in which the emergency bit is set, it takes about 11 msec, which is the transmission time of one super frame, and it is desirable to transmit the TMCC basic information in which the emergency bit is set more quickly.

Further, in the standard of STD-B44, TMCC information including the start control signal corresponding to the start of the emergency warning broadcast is included only in the 1st to 24th slots, and the signal transmission according to the 25th to 120th slots is included. Even if an attempt is made to start the emergency warning broadcast during the operation, the emergency warning broadcast is not started until the next signal transmission corresponding to the first slot is started, and the emergency warning broadcast cannot be started promptly. Therefore, in order to transmit the TMCC basic information in which the emergency bit is set, it takes about 33 msec, which is the transmission time of one frame, and it is desirable to transmit the TMCC basic information in which the emergency bit is set more quickly.

Therefore, an object of the present invention is to provide a signal configuration device, a signal configuration system, a signal configuration method, and a signal configuration program capable of promptly transmitting data corresponding to an emergency warning signal.

The signal configuration device according to the present invention includes an information generation means for generating a frame so that each of the plurality of slots constituting the transmitted frame includes an activation control signal depending on whether or not an emergency warning is being broadcast. It is characterized by that.

The signal configuration system according to the present invention is characterized by comprising a signal configuration device of any aspect and a multiplexing device that multiplexes a plurality of input signals with each other and inputs them to the signal configuration device.

The signal configuration method according to the present invention includes an information generation step of generating a frame so that each of the plurality of slots constituting the transmitted frame includes an activation control signal depending on whether or not an emergency warning broadcast is in progress. It is characterized by that.

The signal configuration program according to the present invention provides information to the computer to generate a frame so that each of the plurality of slots constituting the frame to be transmitted includes an activation control signal depending on whether or not an emergency warning broadcast is in progress. It is characterized in that the generation process and the error correction process of adding a code for error correction to the frame are executed.

According to the present invention, data corresponding to an emergency warning signal can be transmitted more quickly.

It is a block diagram which shows the operation example of the broadcast signal composition apparatus of 1st Embodiment of this invention. It is a block diagram which shows the structural example of the broadcast signal composition apparatus of 1st Embodiment of this invention. It is explanatory drawing which shows the structural example of the frame configured by the frame constituent part. It is explanatory drawing which shows the content of TMCC basic information. It is explanatory drawing which shows the content of TMCC basic information. It is explanatory drawing which shows the content of TMCC basic information. It is explanatory drawing which shows the structural example of the lower side 165Bytes in the region of a transmission TMCC signal. It is a flowchart which shows the operation when the broadcast transmission system transmits the information corresponding to the emergency warning broadcast. It is explanatory drawing which shows the change of the value according to the start control signal. It is explanatory drawing which shows the setting method of the TMCC start bit. It is a block diagram which shows the structural example of the signal composition apparatus of the 2nd Embodiment of this invention.

Embodiment 1.
The broadcast signal configuration device 130 according to the first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing an operation example of the broadcast signal configuration device 130 according to the first embodiment of the present invention. As shown in FIG. 1, the broadcast signal configuration device 130 of the first embodiment of the present invention is included in a broadcast transmission system 100 that transmits multimedia information 600a by radio waves via an antenna 300. Further, the broadcast transmission system 100 transmits multimedia information 600b via a communication line (which may be a communication network such as the Internet) 400. Then, the receiving device 200 receives the multimedia information 600a via the antenna 500. Further, the receiving device 200 receives the multimedia information 600b via the communication line 400. The multimedia information 600a and 600b are both information including television program information and the like.

FIG. 2 is a block diagram showing a configuration example of the broadcast signal configuration device 130 according to the first embodiment of the present invention. As shown in FIG. 2, the broadcast signal configuration device 130 of the first embodiment of the present invention is arranged between the multiplexer 102b and the time division multiplexing / quadrature modulation processing unit 103. The broadcast signal configuration device 130 includes a main signal system coding unit 110 and a control signal system coding unit 120. The content coding unit 101-1 to 101-n is connected to the multiplexer 102b via the multiplexers 102a-1 to 102a-n. Further, an amplification device 104 is connected to the time division multiplexing / quadrature modulation processing unit 103, and an antenna 300 is connected to the amplification device 104.

The content encoding unit 101-1 to 101-n and the multiplexer 102a-1 to 102a-n are installed in, for example, a broadcasting station of each broadcasting company, and information for television broadcasting of each broadcasting company is obtained as a multiplexer. Input to 102b respectively.

The broadcast signal configuration device 130 including the multiplexer 102b, the main signal system coding unit 110 and the control signal system coding unit 120, the time division multiplexing / quadrature modulation processing unit 103, the amplification device 104, and the antenna 300 are so-called up. It is installed at the link station.

The broadcast signal configuration device 130 is realized by, for example, a CPU (Central Processing Unit) that executes processing according to program control or a computer equipped with a single or a plurality of circuits.

The content coding unit 101-1 to 101-n converts the input video signal, audio signal, TMCC signal, and SI (Service Information) message into MPEG (Moving Picture Expert Group) -2 TS (Transport Stream) or TLV. It is encoded into a (Type Length Value) format stream, and the encoded stream is input to the multiplexers 102a-1 to 102a-n.

In the SI message, the condition of EWS (Emergency Warning System) (value of start_end_flag indicating whether or not the emergency warning broadcast is in progress, whether the emergency warning broadcast is the first kind or the second kind It contains a PA (Package Access) message, a PMT (Program Map Table), etc., which includes an emergency alert descriptor in which the indicated code and the area code are set.

The multiplexers 102a-1 to 102a-n multiplex the streams input by the connected content coding units 101-1 to 101-n and input them to the multiplexer 102b.

The multiplexer 102b multiplexes the streams input by the multiplexers 102a-1 to 102a-n with each other and inputs them to the main signal system coding unit 110. Further, the multiplexer 102b inputs a TMCC signal corresponding to a transmission parameter when transmitting a stream input to the main signal system coding unit 110 to the control signal system coding unit 120.

The main signal system coding unit 110 forms a frame based on the input stream, and inputs the signal mapped by a predetermined modulation method to the time division multiplexing / quadrature modulation processing unit 103.

Further, the control signal system coding unit 120 generates TMCC information based on the input TMCC signal. The TMCC information will be described later. The control signal system coding unit 120 constitutes a frame based on the generated TMCC information, and inputs a signal mapped by a predetermined modulation method to the time division multiplexing / quadrature modulation processing unit 103.

The time-division multiplexing / quadrature modulation processing unit 103 generates a quadrature-modulated modulated wave by time-dividing and multiplexing the signal input by the main signal system coding unit 110 and the signal input by the control signal system coding unit 120. do. Then, the time division multiplexing / quadrature modulation processing unit 103 inputs the generated modulated wave to the amplification device 104.

Then, the amplification device 104 amplifies the modulation wave generated by the time division multiplexing / quadrature modulation processing unit 103 and inputs it to the antenna 300. The modulated wave is transmitted via the antenna 300 as multimedia information 600a.

Further, as shown in FIG. 2, the control signal system coding unit 120 includes a TMCC information generation unit 121, an external code error correction addition unit 122, a power diffusion unit 123, an internal code error correction addition unit 124, and a mapping unit 125-a. , Synchronous signal generation unit 126, mapping unit 125-b, signal point arrangement information generation unit 127, mapping unit 125-c, and power diffusion unit 128.

The TMCC information generation unit 121 generates TMCC information indicating the modulation method and the like of each stream based on the input TMCC signal.

The external code error correction addition unit 122 generates a signal that has been subjected to a process of adding an external code (BCH code) for error correction to the TMCC information generated by the TMCC information generation unit 121.

The power spreading unit 123 performs a process for preventing the peak power of the OFDM (Orthogonal Frequency Division Multiplexing) signal from becoming excessive due to the continuation of 0s or 1s in the signal generated by the external code error correction addition unit 122. Generate the signal.

The internal code error correction addition unit 124 generates a signal to which an internal code (LDPC (Low Density Parity Check) code) is added to the signal generated by the power diffusion unit 123 for error correction.

The mapping unit 125-a modulates the signal generated by the internal code error correction addition unit 124 by π / 2 shift BPSK (Binary Phase Shift Keying). Then, the modulated signal is input to the time division multiplexing / quadrature modulation processing unit 103.

The synchronization signal generation unit 126 generates a frame synchronization signal for frame synchronization and a slot synchronization signal for slot synchronization, and inputs them to the mapping unit 125-b.

The mapping unit 125-b modulates the signal generated by the synchronization signal generation unit 126 by π / 2 shift BPSK. Then, the modulated signal is input to the time division multiplexing / quadrature modulation processing unit 103.

The signal point arrangement information generation unit 127 generates signal point arrangement information indicating the signal point arrangement in the OFDM signal.

The mapping unit 125-c modulates the signal point arrangement information by any modulation method of π / 2 shift BPSK to 32APSK (Amplitude and Phase Shift Keying) based on the TMCC information.

The power spreading unit 128 performs a process of adding a power spreading signal to the signal point arrangement information modulated by the mapping unit 125-c in order to prevent the peak power of the OFDM signal from becoming excessive due to the continuation of 0 or 1. Generates the transmitted signal point arrangement signal. Then, the power spreading unit 128 inputs the generated transmission signal point arrangement signal to the time division multiplexing / quadrature modulation processing unit 103.

Further, as shown in FIG. 2, the main signal system coding unit 110 includes a frame configuration unit 111, an external code error correction addition unit 112, a power diffusion unit 113, an internal code error correction addition unit 114, a bit interleaving unit 115, and a bit interleaving unit 115. The mapping unit 116 is included.

A stream in which video signals and audio signals are encoded in MPEG-2 TS or TLV format is input to the frame configuration unit 111 by the content coding unit 101-1 to 1-1n. Then, the frame configuration unit 111 configures the input stream into a frame based on the TMCC information generated by the TMCC information generation unit 121.

The external code error correction addition unit 112 generates a transmission main signal that has been processed to add an external code (BCH code) for error correction to the frame configured by the frame configuration unit 111. The transmission main signal is a signal concatenated except for the first byte of the TS packet, a main signal which is a signal concatenated with a TLV packet, and a slot header which is a control information area related to the main signal. And a stuff bit (for example, "1" (111111) for 6 bits), which is a bit string added for adjusting the number of bits of the transmission main signal, is added, and an error is made with respect to the signal to which the power spread signal is added. It is a signal generated in units of slots, which is a signal encoded within the correction.

The power spreading unit 113 is a transmission main signal that has been processed to prevent the peak power of the OFDM signal from becoming excessive due to the continuation of 0 or 1 in the transmission main signal generated by the external code error correction addition unit 112. To generate.

The internal code error correction addition unit 114 generates a transmission main signal that has been subjected to a process of adding an internal code (LDPC code) for error correction to the transmission main signal generated by the power diffusion unit 113.

The bit interleaving unit 115 provides a bit interleaving to the transmission main signal of the stream whose modulation method is indicated to be 8PSK (Phase Shift Keying), 16APSK, or 32APSK by the TMCC information generated by the TMCC information generation unit 121. Then, it is input to the mapping unit 116.

The mapping unit 116 modulates the transmission main signal by any of the modulation methods of π / 2 shift BPSK to 32APSK based on the TMCC information. Then, the transmission main signal after modulation is input to the time division multiplexing / quadrature modulation processing unit 103.

The time-division multiplexing / quadrature modulation processing unit 103 generates an output signal in which each input signal is time-division-multiplexed and quadrature-modulated. Then, the time division multiplexing / quadrature modulation processing unit 103 inputs the generated output signal to the amplification device 104.

FIG. 3 is an explanatory diagram showing a configuration example of a frame configured by the frame configuration unit 111. Note that FIG. 3 shows an example of the configuration, and other configurations may be used. As shown in FIG. 3, the frame is configured so that the transmission main signal and the transmission TMCC signal are included in each of the first to 120th slots.

Then, in each slot, the frame is configured so that the transmission main signal is included in the region of the upper 5610 Bites (44880 bits) and the transmission TMCC signal is included in the region of the lower 200 Bites (1600 bits). In each slot of the frame, the region of the upper 5610 Bites (44880 bits) is referred to as a transmission main signal region, and the region of the lower 200 Bites (1600 bits) is referred to as a transmission TMCC signal region.

In each slot, the area of the transmission main signal includes a slot header of 176 bits, a main signal to which TLV packets are connected, an error correction code, and a stuff bit (denoted as Stf in FIG. 3). As shown in FIG. 3, the error correction code includes a BCH parity bit of 24 Bites (192 bits) and an LDPC parity bit. Further, the stuff bit is a bit string added for adjusting the number of bits of the transmission main signal, and is composed of "1" (111111) for 6 bits. Further, the area of the slot header is a control information area related to the main signal.

Further, in each slot, the transmission TMCC signal region includes TMCC basic information in the upper 35 bytes (280 bits) and TMCC transmission information or NULL in the lower 165 bytes (1320 bits). As shown in FIG. 3, the lower 165 bytes (1320 bits) in the transmission TMCC signal region of the 1st to 7th slots includes TMCC transmission information. Further, in the lower 165 bytes (1320 bits) in the region of the transmission TMCC signal of the eighth slot, the TMCC transmission information is included in the upper 182 bits, and the rest is NULL. Further, the lower 165 Bites (1320 bits) in the region of the transmission TMCC signal of the 9th to 120th slots is NULL.

The TMCC basic information will be described. Here, the TMCC basic information described below may be one that restores the TMCC basic information on the receiving device side to realize the function, or is transmitted by a broadcaster (specifically, for example, a broadcaster). It is a system and corresponds to, for example, the multiplexers 102a-1 to 102a-n shown in FIG. 2. In the following, the "broadcaster" is specifically, for example, a transmission system of a broadcaster, for example. , Corresponding to the multiplexers 102a-1 to 102a-n shown in FIG. 2) and may be operated on the transmitting side including the uplink station to realize the function. Further, it does not have to be generated as a broadcast signal transmitted to the receiving device.

Further, it may be used as information operated as an inter-station signal between the broadcaster on the transmitting side and the uplink station. It should be noted that the broadcaster may need to transmit the TLV stream to the uplink station according to the specified signal format.

Further, in a super high-definition (SHV) broadcasting system or the like, the function may be realized by restoring the TMCC basic information in the receiving device on the transmitting side and outputting the TLV. As an effect of the present invention, the processing load on the transmission system side can be reduced, and for example, the processing load of the TLV synthesizer of the uplink station can be reduced.

As shown in FIG. 3, the TMCC basic information consists of 35 Bytes (280 bits). The TMCC basic information indicates information about the transmission main signal in the frame transmitted two frames after the frame containing the own TMCC basic information. Then, the time division multiplexing / orthogonal modulation processing unit 103 to which the transmission main signal is input is set to the 0th to 5th Byte in the TMCC basic information included in the frame transmitted two frames before the frame including the transmission main signal. Based on the contents, the beginning of the frame and the valid / invalid slot information are determined, and the transmission path processing is performed. In this example, as described above, since the TMCC basic information is composed of 35 bytes (280 bits), more information can be included than the 8 BYte TMCC basic information in the operation regulation of TR-B15.

4a to 4c are explanatory views showing the contents of TMCC basic information. As shown in FIG. 4a, bits corresponding to the synchronization signal are set in the 0th byte (indicated as "0" in the column of the byte in FIG. 4a; the same applies hereinafter) to 2byte in the TMCC basic information.

Specifically, the 0th to 2nd Byte is set to indicate, for example, different identifiers for the slot at the beginning of each frame and the slot not at the beginning of each frame. More specifically, for example, the TMCC basic information 0th to 2nd Byte in the slot at the beginning of each frame is set to indicate 52F886h as an identifier for achieving frame synchronization. Further, for example, the TMCC basic information 0th to 2nd Byte in the slot without the beginning of each frame is set to indicate 36715Ah as an identifier for achieving slot synchronization.

According to such a configuration, since the 0th to 2nd bytes, that is, 3 bytes are used for the frame synchronization and the slot synchronization, the bit error tolerance is improved as compared with the case where the frame synchronization and the slot synchronization are performed with a smaller number of bytes. Can be improved.

Further, as shown in FIG. 4a, "11111111" is set in the third Byte. As shown in FIG. 4a, in the 4th Byte, a value corresponding to an attribute indicating whether the slot is a valid slot or an invalid slot is set in the 0th to 3rd bits. Further, as shown in FIG. 4a, in the 4th Byte, the transmission mode information for each slot is set in the 4th to 7th bits.

The transmission mode information of the slot having the corresponding slot number (also simply referred to as the slot) in the frame transmitted two frames after the frame including the slot is set in the 4th to 7th bits of the 4th byte, which will be described later. It is possible to specify the transmission mode of the slot without collecting the values corresponding to the number of allocated slots of each transmission mode set in the 15th, 17th, 19th, 21st, 23rd, 25th, 27th, and 29th bytes, respectively. It will be possible. Therefore, the processing load of the receiving device can be satisfactorily reduced.

Specifically, for example, a value corresponding to the number of allocation slots of the transmission mode 1 being 10 is set in the 15th byte described later, and a value corresponding to the number of allocation slots of the transmission mode 2 is 5 in the 17th byte. Suppose a value is set. Then, for example, in order to specify that the transmission mode of the 1st to 10th slots is the transmission mode 1 and the transmission mode of the 11th to 16th slots is the transmission mode 2, the value set in the 15th byte is used. It is also considered necessary to collect the value set in the 17th Byte.

However, according to this example, since the transmission mode information of the slot is set in the 4th to 7th bits of the 4th byte, the transmission mode information of the slot is set in the 15th, 17th, 19th, 21st, 23rd, 25th, 27th, and 29th bytes, which will be described later, respectively. It is possible to specify the transmission mode of the slot without collecting the value corresponding to the number of allocated slots of each set transmission mode.

Further, since the values corresponding to the attributes indicating whether the slots are valid slots or invalid slots are set in the 0th to 3rd bits of the 4th Byte, the 14th, 16th, 18th, 20th, and the following will be described later. Depending on the value corresponding to the modulation method set in 22, 24, 26, 28 Byte, and the number of allocated slots set in 15, 17, 19, 21, 23, 25, 27, 29 Byte, which will be described later, respectively. It is possible to identify whether the slot is a valid slot or an invalid slot without collecting the respective values, and the processing load of the receiving device can be satisfactorily reduced.

Specifically, the values corresponding to the modulation methods set in the 14th, 16th, 18th, 20th, 22nd, 24th, 26th, and 28th bytes described later, and the 15th, 17th, 19th, 21st, and 23rd described later. The transmission mode and modulation method of each slot are specified based on the values corresponding to the number of allocated slots of each transmission mode set in 25, 27, and 29 Bytes, respectively. For example, it is assumed that the values corresponding to BPSK are set in the 4th to 7th bits of the 14th Byte, and the values corresponding to 16APSK are set in the 4th to 7th bits of the 16th Byte. Further, it is assumed that the values corresponding to the 1st to 5th slots are set in the 15th Byte and the values corresponding to the 6th to 10th slots are set in the 17th Byte. Then, it is specified that the modulation method of the 1st to 5th slots is BPSK and the modulation method of the 6th to 10th slots is 16APSK based on the values set in the 14th to 17th bytes. In other words, in order to specify that the modulation method of the 1st to 5th slots is BPSK and the modulation method of the 6th to 10th slots is 16APSK, refer to the values set in the 14th to 17th bytes. It is also considered that it must be done.

However, according to this example, since the transmission mode information of the slot is set in the 4th to 7th bits of the TMCC basic information included in each slot, the 14th, 16th, 18th, 20th, 22nd, and 24th described later will be described. , 26, 28 Byte values according to the modulation method, and 15, 17, 19, 21, 23, 25, 27, 29 Byte, which will be described later, according to the number of allocated slots. The modulation method of the slot can be easily specified without collecting each of them.

Further, for example, when the modulation method is set with 5 slots as one unit and the modulation method is BPSK, the first slot of the 5 slots constituting one unit corresponds to the transmission main signal. It is a slot, and the 2nd to 5th slots are slots for error correction. That is, the first slot is a valid slot and the second to fifth slots are invalid slots. Assuming that the modulation method in which 5 slots are set as 1 unit is 16 APSK, the 1st to 4th slots among the 5 slots constituting one unit are the slots corresponding to the transmission main signal, and the 5th slot. Slot is a slot for error correction. That is, the 1st to 4th slots are valid slots, and the 5th slot is an invalid slot. Therefore, in order to determine whether or not each slot is an effective slot, the values corresponding to the modulation methods set in the 14th, 16th, 18th, 20th, 22nd, 24th, 26th, and 28th bytes, which will be described later, respectively. It is also considered that processing based on the values corresponding to the number of allocated slots set in the 15th, 17th, 19th, 21st, 23rd, 25th, 27th, and 29th Bite, which will be described later, is required.

However, according to this example, since the values corresponding to the attributes indicating whether the slot is a valid slot or an invalid slot are set in the 0th to 3rd bits of the 4th Byte, the 0th of the 4th Byte is set. With reference to ~ 3 bits, it is possible to easily identify whether the slot is a valid slot or an invalid slot.

As shown in FIG. 4a, in the 5th Byte, the values corresponding to the slot counters are set in the 0th to 6th bits. Specifically, for example, the first slot of the frame is set to 0 (for example, 0000000), and the values are incremented by 1 in the order of the slots. Therefore, for example, "0000001" is set in the 0th to 6th bits of the 5th byte in the first slot, and "1110111" is set in the 0th to 6th bits of the 5th byte in the 120th slot.

According to such a configuration, an abnormality occurs in the transmission line by detecting that a discontinuity such as "missing" or "changing the order" occurs in the value corresponding to the slot counter in the continuous slot. It becomes possible to easily detect what has been done. This effect cannot be obtained in a system based on the STD-B44 standard in which the frame configuration of the transmission main signal of the TLV does not include information on the slot number.

Further, as shown in FIG. 4a, in the 5th Byte, a value corresponding to the frame head flag for identifying the head of the frame is set in the 7th bit.

According to such a configuration, it becomes possible to identify whether or not the frame is at the beginning of the frame based only on the value set in 1 bit of the 7th bit of the 5th byte, and the processing load of the receiving device can be satisfactorily reduced. can.

As shown in FIG. 4b, values are set in the 6th and 7th bytes according to the pointer indicating the first packet head position of the slot / slot information top pointer. Further, as shown in FIG. 4b, a pointer indicating a value obtained by adding 1 to the number of bytes from the beginning of the slot excluding the header of the last byte of the last placement completed packet in the slot of the slot to the 8th and 9th bytes. / Slot information A value is set according to the last pointer.

Since the TLV packet of this example has a variable length, the required top pointer and last pointer of the slot are indicated by the 6th to 9th bytes. It should be noted that a configuration indicating the top pointer and the last pointer of the slot can be applied to the TS packet having a fixed length as in the sixth to ninth bytes in this example.

Further, the top pointer and the last pointer of the slot, which are indicated by the 6th to 9th Byte, are also indicated by, for example, the pointer / slot information of the TMCC transmission information shown in FIG. 5 described later. However, as shown in FIG. 5, the pointer / slot information of the TMCC transmission information is included in the 2nd to 4th slots. Therefore, in the TMCC transmission information, the information indicating the top pointer and the last pointer of the 1st to 120th slots is included in the 2nd to 4th slots. Therefore, when a problem occurs in the transmission / reception of the 2nd to 4th slots, the top pointer and the last pointer of the remaining slots are not indicated by the TMCC transmission information, and there is a possibility that the receiving side cannot decode the top pointer and the last pointer. However, according to this example, since the top pointer and the last pointer of the slot are indicated by the 6th to 9th bytes of the TMCC basic information, there is a problem in transmission / reception of any of the slots 1 to 120. Even if it occurs, it is possible to prevent the influence on the slots other than the slot concerned.

As shown in FIG. 4b, a value corresponding to the switching control signal indicating the completion state of the placement completion packet in the slot of the corresponding slot is set in the 10th Byte. Specifically, for example, a 1-system broadcast signal configuration device which is one broadcast signal configuration device 130 and a 2-system broadcast signal configuration device which is the other broadcast signal configuration device 130 are prepared, and the first to 60th are prepared. It is assumed that the slots are configured to be transmitted by the broadcast signal configuration device of the first system, and the 61st to 120th slots are transmitted by the broadcast signal configuration device of the second system. That is, between the timing at which the 60th slot is transmitted and the timing at which the 61st slot is transmitted, the broadcast signal configuration device 130 used for data transmission is one of the broadcast signal configuration devices 130. It is assumed that the signal component device is configured to be switched from the other broadcast signal component device 130, which is a two-system broadcast signal component device.

In such a configuration, if the TLV data is arranged from the 60th slot to the 61st slot, the receiving side cannot properly decode the TLV data.

Therefore, in this example, a value corresponding to the switching control signal indicating the completion state of the placement completion packet in the slot of the corresponding (corresponding) slot of the 10th Byte of the TMCC basic information is set. Specifically, for example, in the 0th bit of the 10th byte of the TMCC basic information, the broadcast signal configuration device 130 used for data transmission at the head of the next slot is broadcast by one system of the broadcast signal configuration device 130. If the slot (packet) is completed so that it can be switched from the signal configuration device to the other broadcast signal configuration device 130, which is the second broadcast signal configuration device, 1 is set, and the slot (packet) is completed. If it is not switched and switching is not possible, 0 is set.

Therefore, by referring to the 0th bit of the 10th byte of the TMCC basic information, the broadcast signal configuration device of the 1 system which is one broadcast signal configuration device 130 to the broadcast signal configuration device of 2 systems which is the other broadcast signal configuration device 130. Whether or not to switch to is appropriately determined.

As shown in FIG. 4b, in the 11th byte, "0" is set in the 0th to 3rd bits, and in the 4th to 6th bits, the uplink control information indicating the site diversity implementation frame instruction, the main station, and the sub station instruction is used. Corresponding values are set, and in the 7th bit, a value corresponding to the activation control signal used for activating the receiving device at the time of emergency warning broadcasting is set. Regarding the activation control signal, specifically, the 7th bit of the 11th Byte is set to 1 during the emergency warning broadcast, and is usually set to 0.

As shown in FIG. 4b, "11111111" is set for the 12th Byte and the 13th Byte.

As shown in FIG. 4c, in the 14th Byte, values corresponding to the coding rate of the transmission mode 1 in the slots licensed by the broadcaster are set in the 0th to 3rd bits, and the 4th to 6th bits are set. A value corresponding to the modulation method of the transmission mode 1 is set.

As shown in FIG. 4c, a value corresponding to the number of allocated slots in the transmission mode 1 is set in the 15th Byte.

As shown in FIG. 4c, values corresponding to the modulation method, the coding rate, and the number of allocated slots of the transmission modes 2 to 7 in the slots licensed by the broadcaster are set in the 16th to 27th bytes, respectively. .. As shown in FIG. 4c, in the 28th Byte, values corresponding to the coding rate of the transmission mode 8 are set in the 0th to 3rd bits, and values corresponding to the modulation method of the transmission mode 8 are set in the 4th to 7th bits. Is set. As shown in FIG. 4c, a value corresponding to the number of allocated slots in the transmission mode 8 is set in the 29th Byte.

Specifically, for example, values corresponding to the coding rates of the transmission modes 2 to 8 are set in the 0th to 3rd bits of the 16th, 18th, 20th, 22nd, 24th, 26th, and 28th bytes, and the 4th to 7th bits are set. Is set to a value corresponding to the modulation method of the transmission modes 2 to 8, respectively. Further, values corresponding to the number of allocated slots in the transmission modes 2 to 7 are set in the 17th, 19th, 21st, 23rd, 25th, 27th, and 29th bytes.

It should be noted that each information indicated by each value set in the 14th to 29th Byte is also included in the TMCC transmission information. However, the TMCC transmission information is information transmitted by using the 1st to 8th slots in one frame, and if the TLV packet in this portion is missing, the TMCC information corresponding to the frame may be missing. be. Then, the receiving side that has received the frame may not be able to decode all of the frame.

On the other hand, in this example, the TMCC basic information contained in each slot of one frame is transmitted, and each information indicated by each value set in the 14th to 29th bytes is transmitted, so that the TLV packet is missing. In particular, the error tolerance of TMCC information due to the omission of the 1st to 8th slots can be satisfactorily improved.

As shown in FIG. 4c, the value of the upper 8 bits of the transmission stream IDs transmitted in the slot is set in the 30th byte.

As shown in FIG. 4c, the lower 8 bits of the transmission stream IDs transmitted in the slot are set in the 31st Byte.

As shown in FIG. 4c, "11111111" is set in the 32nd to 34th Byte.

In addition, as information transmitted from a broadcasting company for generating TMCC (specifically, for example, TMCC transmission information) in an uplink station, among the above-mentioned TMCC basic information, for example, it is shown by 6th to 9th Byte. The pointer / slot information provided, the activation control signal indicated by the 11th Byte, the modulation scheme, the coding factor, and the number of allocated slots indicated by the 14th to 29th Byte, and the 30th to 31st Byte. The transmission stream ID is used.

Further, in the uplink station, among the above-mentioned TMCC basic information transmitted from the broadcaster, for example, the synchronization information indicated by the 0th to 2nd Byte and the transmission mode information for each slot indicated by the 4th Byte. TMCC (specifically, for example, TMCC transmission information) is generated by the attribute information for each slot, the frame head flag and slot counter indicated by the 5th Byte, and the switching control signal indicated by the 10th Byte. Can be generated.

By using this information, in TMCC generation (specifically, for example, TMCC transmission information generation) in the uplink station, the effect of improving error tolerance can be obtained, and the TLV synthesizer of the uplink station can be obtained. (Specifically, for example, it corresponds to the multiplexer 102b shown in FIG. 2) can also obtain the effect of reducing the processing load.

Further, as the processing in the uplink station, specifically, the TLV stream sent from the broadcaster to the uplink station and the TMCC basic information about the TLV stream are used, and the TMCC (specifically, for example, TMCC) is used in the uplink station. TMCC transmission information) may be generated. Needless to say, the above-mentioned settings in each Byte are merely examples and can be appropriately set as needed.

FIG. 5 is an explanatory diagram showing a configuration example of the lower 165 bytes in the region of the transmission TMCC signal. As shown in FIG. 5, among the TMCC transmission information, the change instruction, the transmission mode / slot information, the stream type / relative stream information, the packet format / relative stream information, and the pointer / slot information are stored in the first slot. A value is set according to a part of.

Further, as shown in FIG. 5, a value corresponding to the remaining portion of the pointer / slot information is set in the second to fourth slots.

As shown in FIG. 5, a value corresponding to a part of the relative stream / slot information is set in the fourth slot. Further, in the fifth slot, values corresponding to the remaining portion of the relative stream / slot information, the relative stream / transmission stream ID correspondence table information, the transmission / reception control information, and a part of the extended information are set.

As shown in FIG. 5, a value corresponding to the rest of the expansion information is set in a part of the sixth to eighth slots.

The rest of the 8th slot to the 120th slot are NULL.

Next, the operation of the broadcast transmission system 100 will be described. FIG. 6 is a flowchart showing an operation when the broadcast transmission system 100 transmits information according to the emergency warning broadcast.

As shown in FIG. 6, the broadcast signal configuration device 130 according to the first embodiment of the present invention is a transmission TMCC based on the input transmission parameters when the transmission parameters for transmitting each stream are input. Generate a signal (step S101).

More specifically, the broadcast signal configuration device 130 according to the first embodiment of the present invention is the first of the TMCC basic information in each slot (specifically, for example, the first to 120th slots) in the process of step S101. A transmission TMCC signal is generated in which a value (for example, “1”) corresponding to an activation control signal indicating that an emergency warning broadcast is being broadcast is set in the 7th bit of 11Byte.

Further, it is shown that the broadcast signal configuration device 130 of the first embodiment of the present invention is broadcasting an emergency warning as TMCC transmission information in a predetermined slot (in this example, the fifth slot) in the process of step S101. A transmission TMCC signal is generated in which a value (for example, "1") corresponding to the start control signal is set.

That is, the broadcast signal configuration device 130 of the first embodiment of the present invention is the 7th Bit of the 11th Byte of the TMCC basic information in each slot (specifically, for example, the 1st to 120th slots) in the process of step S101. A value (for example, "1") corresponding to the activation control signal indicating that the emergency alarm is being broadcast is set, and the emergency alarm is being broadcast as TMCC transmission information in a predetermined slot (in this example, the fifth slot). Generates a transmission TMCC signal set to a value (eg, "1") corresponding to the activation control signal indicating that it is present.

Further, the transmission TMCC signal has the slot in the 0th to 3rd bits of the 4th Byte of the TMCC basic information in each slot in the process of step S101 by the broadcast signal configuration device 130 of the first embodiment of the present invention. A value is set according to the attribute indicating whether the slot is a valid slot or an invalid slot.

Further, the transmitted TMCC signal is connected to the 4th to 7th bits of the 4th Byte of the TMCC basic information in each slot by the processing of step S101 by the broadcasting signal configuration device 130 of the first embodiment of the present invention. The value is set according to the transmission mode.

The transmitted TMCC signal was subjected to the slot counter in the 5th to 7th bits of the 5th Byte of the TMCC basic information in each slot in the process of step S101 by the broadcast signal configuration device 130 of the first embodiment of the present invention. The value is set.

Further, the transmission TMCC signal has a value corresponding to the switching control signal in the 10th byte of the TMCC basic information in each slot in the process of step S101 by the broadcast signal configuration device 130 of the first embodiment of the present invention. It is set.

FIG. 7 is an explanatory diagram showing a change in the value according to the activation control signal. In this example, it is assumed that the value corresponding to the activation control signal changes in accordance with the operation rules of BS / wideband CS digital broadcasting. As shown in FIG. 7, the broadcaster A (specifically, the content coding unit 101-a installed in the broadcast station of the broadcaster A) is broadcasting an emergency warning from time t1 to t3. A TMCC signal set with a value corresponding to the activation control signal indicating that the signal is set is generated and input to the multiplexer 102b.

Further, the activation indicating that the broadcaster B (specifically, the content coding unit 101-b installed in the broadcast station of the broadcaster B) is in the emergency warning broadcast from time t2 to t4. A TMCC signal set with a value corresponding to the control signal is generated and input to the multiplexer 102b.

The broadcaster N (specifically, the content coding unit 101-n installed in the broadcast station of the broadcaster N) has a value corresponding to an activation control signal indicating that normal broadcasting is in progress (for example, "" 0 ”) is set to generate a TMCC signal, which is input to the multiplexer 102b via the multiplexer 101-n.

Then, these signals are multiplexed with each other by the multiplexer 102b and input to the broadcast signal configuration device 130. The broadcast signal configuration device 130 is set with a value corresponding to the activation control signal indicating that the TMCC activation bit is in the emergency warning broadcast in the TMCC signal transmitted by any of the broadcasters A to N. During the period, a transmission TMCC signal set with a value corresponding to the emergency warning broadcasting is generated.

Then, the time division multiplexing / quadrature modulation processing unit 103 time-division-multiplexes the signal input by the main signal system coding unit 110 and the transmission TMCC signal generated in the processing of step S101 to each other (step S102). , Generate a modulated wave.

The modulated waves generated by being multiplexed and modulated by each other in the process of step S102 are amplified by the amplification device 104 and transmitted via the antenna 300 (step S103).

In this example, from time t1 to t4, a signal set with a value corresponding to the emergency warning broadcasting of the TMCC activation bit is transmitted.

FIG. 8 is an explanatory diagram showing a method of setting the TMCC activation bit. In this example, it is assumed that the TMCC activation bit is set in accordance with the operation rules of BS / wideband CS digital broadcasting. In the example shown in FIG. 8, while the value corresponding to the activation control signal indicating that the emergency warning is being broadcast is set in the TMCC signal transmitted by any of the broadcasters A to C in the xCH. , The value corresponding to the emergency warning broadcasting is set and sent.

The signal transmitted in the process of step S103 is received by a receiving device such as the receiving device 200.

Then, the content as an emergency warning broadcast based on the main signal processed by the main signal system coding unit 110, which is transmitted by each broadcaster and is multiplexed with the PA message and the transmission TMCC signal in the process of step S102, is It is played back by the receiving device.

Further, the receiving device refers to the information set in the 0th to 3rd bits of the 4th byte of the TMCC basic information included in each slot of the frame, and whether the slot is a valid slot or an invalid slot. It becomes possible to identify whether it is.

Further, the receiving device can specify the transmission mode of the slot by referring to the information set in the 4th to 7th bits of the 4th byte of the TMCC basic information included in each slot of the frame. Become.

The receiving device may detect the occurrence of slot omission or order change by referring to the values set in the 0th to 6th bits of the 5th byte of the TMCC basic information included in each slot of the frame. It will be possible.

Further, the receiving device transmits a signal transmitted by the broadcast signal configuration device 130 switched at an appropriate timing according to a set value to the 10th byte of the TMCC basic information included in each slot of the frame. Since it is received, it becomes possible to appropriately decode the data based on the received signal.

According to the present embodiment, the broadcast signal configuration device 130 generates a transmission TMCC signal in which a value corresponding to the activation control signal is set in the TMCC basic information when an emergency warning broadcast is performed. Then, the transmitted TMCC signal is multiplexed and transmitted to the stream of the program. As illustrated in FIG. 3, the TMCC basic information is included in all slots of the frame, unlike the TMCC transmission information.

Therefore, according to the present embodiment, the data corresponding to the emergency warning signal is promptly set with a higher probability than the case where the value corresponding to the activation control signal is set for the TMCC transmission information stored in some slots in the frame. Can be sent.

Specifically, the TMCC basic information in which the emergency bit is set based on the operation regulations of TR-B15 is included in the super frame after the super frame being transmitted, so that it takes about 11 msec to transmit. Further, according to the present embodiment, since the TMCC basic information is included in all the slots of the frame, the TMCC basic information in which the value corresponding to the start control signal is set can be promptly transmitted in about 0.275 msec.

Therefore, according to the present embodiment, the emergency warning signal is responded to more promptly than notifying that the emergency warning broadcasting is performed by being multiplexed with the MPEG-2 TS as in the operation regulation of BS / wideband CS digital broadcasting. Data can be sent.

Further, according to the present embodiment, the receiving device that has received the signal transmitted by the broadcast signal configuration device 130 is set to the 0th to 3rd bits of the 4th Byte of the TMCC basic information included in each slot of the frame. It becomes possible to identify whether the slot is a valid slot or an invalid slot by referring to the information provided. Therefore, the values corresponding to the modulation methods set in the 14th, 16th, 18th, 20th, 22nd, 24th, 26th, and 28th bytes, and the 15th, 17th, 19th, 21st, 23rd, 25th, 27th, and 29th bytes, respectively. It is possible to identify whether the slot is a valid slot or an invalid slot without collecting values according to the set number of allocated slots, and the processing load of the receiving device is good. Can be mitigated.

Further, according to the present embodiment, the receiving device that has received the signal transmitted by the broadcast signal configuration device 130 is set to the 4th to 7th bits of the 4th Byte of the TMCC basic information included in each slot of the frame. It becomes possible to specify the transmission mode of the slot by referring to the information provided. Therefore, it is possible to specify the transmission mode of the slot without collecting the information set in the 15th, 17th, 19th, 21st, 23rd, 25th, 27th, and 29th bytes, respectively, and the processing of the receiving device. The load can be reduced satisfactorily. In addition, the number of receiving devices can be reduced.

According to the present embodiment, the receiving device that has received the signal transmitted by the broadcast signal configuration device 130 is set to the 0th to 6th bits of the 5th Byte of the TMCC basic information included in each slot of the frame. By detecting the occurrence of discontinuity such as "missing" or "changing the order" based on the above, it is possible to easily detect that an abnormality has occurred in the transmission line.

Further, according to the present embodiment, the receiving device that has received the signal transmitted by the broadcast signal configuration device 130 has a value set in the 7th bit of the 5th byte of the TMCC basic information included in each slot of the frame. It is possible to identify whether or not it is the beginning of a frame based only on. Therefore, the processing load of the receiving device can be satisfactorily reduced as compared with the case where it is configured to identify whether or not it is the beginning of the frame based on more information.

Further, according to the present embodiment, based only on the value set in the 0th bit of the 10th Byte of the TMCC basic information included in each slot of the frame, one of the broadcast signal configuration devices 130 is the 1st system. Whether or not switching from the broadcast signal constituent device to the second broadcast signal constituent device, which is the other broadcast signal constituent device 130, is appropriately determined.

Therefore, as described above, in the present embodiment, the TMCC basic information included in each slot is configured to include information appropriately selected according to the priority, the processing load, and the like. It is possible to promptly start emergency warning broadcasting and reduce the processing load of the receiving device.

Further, the present invention not only has the effect of reducing the processing load on the receiving side, but also reduces the processing load of the transmitting device and the transmitting system on the transmitting side, for example, a TLV synthesizer of an uplink station (specifically, for example, for example. It also has the effect of reducing the processing load of the device (device corresponding to the multiplexer 102b shown in FIG. 2).

More specifically, in a transmission system on the transmitting side, including, for example, at least one of the multiplexers 102a-1 to n shown in FIG. 2 and the multiplexer 102b, the multiplexers 102a-1 to n are TMCCs as described above. Suppose you have generated basic information. In such a case, the processing load of the multiplexer 102b can be satisfactorily reduced by setting the above-mentioned information in the 4th to 7th bits of the 4th byte of the TMCC basic information. Further, when the above-mentioned information is set in the 0th to 6th bits of the 5th byte of the TMCC basic information, the multiplexer 102b detects that a discontinuity such as "missing" or "changing the order" has occurred. As a result, it is possible to easily detect that an abnormality has occurred in the transmission line. Further, by setting the above-mentioned information in the 7th bit of the 5th byte of the TMCC basic information, the processing load of the multiplexer 102b can be satisfactorily reduced. By setting the above-mentioned information in the 0th bit of the 10th byte of the TMCC basic information, the multiplexer 102b is the one broadcast signal configuration device 130 from the one system broadcast signal configuration device to the other broadcast signal configuration device 130. It is possible to appropriately determine whether or not switching to the two-system broadcast signal configuration device is possible.

The present invention is suitably applicable to advanced wideband satellite digital broadcasting as shown in the specific example of TLV data above, but each setting as shown above is only an example. Therefore, it goes without saying that it is not limited to advanced wideband satellite digital broadcasting, and can be applied to various broadcasting systems including terrestrial broadcasting as long as it has the same configuration and information or has an effect.

The direction of the arrow in the drawing shows an example, and does not limit the direction of the signal between the blocks.

Embodiment 2.
The signal configuration device 12 according to the second embodiment of the present invention will be described with reference to the drawings. FIG. 9 is a block diagram showing a configuration example of the signal configuration device 12 according to the second embodiment of the present invention.

As shown in FIG. 9, the signal configuration device 12 of the second embodiment of the present invention includes an information generation unit 21. The information generation unit 21 corresponds to the TMCC information generation unit 121 in the first embodiment shown in FIG. The signal configuration device 12 including the information generation unit 21 may correspond to, for example, the multiplexers 102a-1 to 102an in the first embodiment shown in FIG. 2, or corresponds to the multiplexer 102b. May be good.

The information generation unit 21 generates a frame so that each of the plurality of slots constituting the transmitted frame includes an activation control signal depending on whether or not an emergency warning broadcast is in progress.

According to the present embodiment, data corresponding to the emergency warning signal is quickly transmitted with a high probability as compared with the case where a value corresponding to the activation control signal is set for the TMCC transmission information stored in some slots in the frame. can do.

12 Signal configuration device 21 Information generation unit 100 Broadcast transmission system 101-a-101-n Transmission path coding unit 102a-1 to 102a-n, 102b multiplexer 103 Amplification device 110 Main signal system coding unit 111 Frame configuration unit 112, 122 External code error correction addition part 113, 128 Power spread part 114, 124 Internal code error correction addition part 115 Bit interleaving part 116, 125-a, 125-b, 125-c Mapping part 120 Broadcast signal configuration device 121 TMCC information generation Part 123 Power diffusion part 126 Synchronous signal generation part 127 Signal point arrangement information generation part 130 Content coding part 140 Time division multiplex / orthogonal modulation processing part 200 Receiver device 300, 500 Antenna 400 Communication network 600a, 600b Multimedia information

Claims (3)

Each of the plurality of slots constituting the frame shows the information corresponding to the activation control signal depending on whether or not the emergency alarm is being broadcast, and the transmission mode for each slot of the slot corresponding to each of the plurality of slots. A receiving means for receiving a signal including transmission mode information and information on the coding rate of each transmission mode for the slots corresponding to each of the plurality of slots in one frame.
A transmission mode specifying means for specifying the transmission mode of the slot based on the transmission mode information indicating the transmission mode of each slot corresponding to each of the plurality of slots.
A decoding means for decoding data based on the signal according to the transmission mode specified by the transmission mode specifying means, and a decoding means.
A receiving device characterized by being equipped with. Each of the plurality of slots constituting the frame shows the information corresponding to the activation control signal depending on whether or not the emergency alarm is being broadcast, and the transmission mode for each slot of the slot corresponding to each of the plurality of slots. A step of receiving a signal including transmission mode information and information on the coding rate of each transmission mode for the slots corresponding to each of the plurality of slots in one frame.
A step of specifying the transmission mode of the slot based on the transmission mode information indicating the transmission mode of each slot corresponding to each of the plurality of slots.
A step of decoding data based on the signal according to the specified transmission mode, and
A receiving method characterized by comprising. On the computer
Each of the plurality of slots constituting the frame shows the information corresponding to the activation control signal depending on whether or not the emergency alarm is being broadcast, and the transmission mode for each slot of the slot corresponding to each of the plurality of slots. A reception process for receiving a signal including transmission mode information and information on the coding rate of each transmission mode for the slots corresponding to each of the plurality of slots in one frame.
The transmission mode specifying process for specifying the transmission mode of the slot based on the transmission mode information indicating the transmission mode for each slot of the slot corresponding to each of the plurality of slots, and the transmission mode specifying process.
A decoding process that decodes data based on the signal according to the transmission mode specified by the transmission mode specifying process, and a decoding process.
Receiving program to execute.

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