JP4922910B2 - Retransmission device, remodulation device and broadcasting system - Google Patents

Description

  The present invention relates to a technique for time-division multiplex transmission of TS (Transport Stream) using a plurality of digital broadcasting systems.

  Digital broadcasting systems in Japan include ISDB-T (Integrated Services Digital Broadcasting) system, ISDB-S (ISDB-Satelite) system, ITU-T J.I. There is a method recommended by 83 Annex C (hereinafter referred to as “J.83 method”). The ISDB-T system is a broadcasting system used in terrestrial digital broadcasting, the ISDB-S system is a broadcasting system used in satellite digital broadcasting, The 83 system is a broadcasting system used in digital cable television.

  The reference clock used in such a broadcasting system is different for each broadcasting system. For example, in the ISDB-T system, 512/63 = 8.1126984126... MHz (frequency of IFFT sample clock). In the 83 system, it is 5.274 MHz (symbol clock frequency).

  Broadcast signal transmission forms include signals transmitted by broadcast stations (hereinafter referred to as “transmitters”) via radio waves, and signals received by transmitters via radio waves, in addition to forms where each receiver directly receives signals via an antenna or the like. Is once received by the retransmitting device and retransmitted to the receiving device via a transmission line such as a coaxial cable or an optical fiber. Broadcasting in such a transmission form is realized by cable television.

  Also, in cable television, a retransmission device may transmit broadcast content that has been converted into MPEG-2 TS (Moving Picture Experts Group-2 Transport Stream) unique to a cable television operator, that is, a unique broadcast signal. This is called a cable TV voluntary broadcast or community channel. Such a broadcast signal is not transmitted by the transmission device.

[Broadcasting system]
FIG. 1 is a diagram illustrating an overall configuration of a broadcasting system. The broadcasting system 1 includes a transmitting device 10, a retransmitting device 200, a remodulating device 300, and receiving devices 40-1 and 40-2. The transmitting apparatus 10 transmits a broadcast signal (modulated signal) of MPEG-2 TS using the ISDB-T system and MPEG-2 TS using the ISDB-S system via an antenna.

  The re-transmission device 200 transmits an MPEG-2 TS broadcast signal (modulation signal) using the ISDB-T method transmitted by the transmission device 10 and an MPEG-2 TS broadcast signal (modulation signal) using the ISDB-S method. ), The received broadcast signal and the broadcast signal possessed by the retransmission apparatus 200 are multiplexed, converted into a signal format suitable for a pass-through or retransmission transmission path (retransmission transmission path), and the broadcast signal (Baseband signal) is retransmitted through the retransmission transmission path. Here, multiplexing methods performed by the retransmission apparatus 200 include frequency axis multiplexing of modulated waves, time division multiplexing of MPEG-2 TS that is a baseband signal, and the like.

  The remodulating apparatus 300 receives the broadcast signal (baseband signal) retransmitted by the retransmitting apparatus 200, and converts the MPEG-2 TS of the received broadcast signal into the ISDB-T system, the ISDB-S system, and the J.B. The signal is remodulated by a modulation method according to the 83 method and transmitted as a broadcast signal (remodulated signal). Here, the re-transmission apparatus 200 has the ISDB-T method, ISDB-S method, and J.I. When MPEG-2 TS using the 83 method is time-division multiplexed and retransmitted, the receivers 40-1 and 40-2 cannot directly receive the broadcast signal. Therefore, the remodulator 300 is provided between the retransmitter 200 and the receivers 40-1 and 40-2. That is, in the remodulation apparatus 300, the receiving apparatuses 40-1 and 40-2 are ISDB-T system, ISDB-S system and J.I. The MPEG-2 TS of the received broadcast signal is installed at the entrance of a home or the like so that it can be received in accordance with the 83 system, and the ISDB-T system, ISDB-S system, and J. It has a function of performing re-modulation by a modulation method according to the 83 method. Receiving devices 40-1 and 40-2 receive and reproduce the broadcast signal (remodulated signal) transmitted by remodulating device 300. When the receiving apparatuses 40-1 and 40-2 are compatible with the ISDB-T system, the transmission parameter is a value defined in the ISDB-T system operation regulations (see ARIB TR-B14). If so, the broadcast signal (remodulation signal) can be received in the same manner as in the case of receiving directly from the transmission device 10.

  In such a broadcasting system 1, each MPEG-2 TS before multiplexing transmitted by the retransmission apparatus 200 (hereinafter referred to as “each MPEG-2 TS transmitted by the retransmission apparatus 200”) and retransmission. Broadcast signals that are multiplexed and transmitted by the transmission apparatus 200, that is, baseband signals (hereinafter referred to as “baseband signals multiplexed by the retransmission apparatus 200”) may or may not be synchronized with each other. In some cases (asynchronous). Here, “synchronized” indicates that the ratio of the speeds of each other is accurately expressed as an integer ratio. Hereinafter, the fact that each MPEG-2 TS transmitted by the retransmission apparatus 200 and the baseband signal multiplexed by the retransmission apparatus 200 are in synchronization with each other is referred to as “in the same clock domain” and asynchronous with each other. It is said that it is in a different clock domain.

[When MPEG-2 TS of different clock domains are mixed]
When the retransmission apparatus 200 performs time division multiplexing of a plurality of MPEG-2 TSs and transmits them as broadcast signals (baseband signals), different clock domains may be mixed. FIG. 2 is a diagram illustrating a relationship between a broadcast signal and a clock when different clock domains are mixed. In FIG. 2, transmitters 10-1 to 10-n transmit n MPEG-2 TS1 to n broadcast signals (modulated signals) using the ISDB-T system, and n retransmitters 200 MPEG-2 TS and P MPEG-2 TSn + 1 to n + p are time-division multiplexed and transmitted as broadcast waves (baseband signals). Further, the remodulation apparatus 300 receives a broadcast signal (baseband signal) including these MPEG-2 TSs, and modifies x MPEG-2 TSs out of n + p signals in a modulation method according to the ISDB-T method. And the remaining n + p−x MPEG-2 TS are converted into J.P. It is assumed that modulation is performed by a modulation method according to the 83 method.

  Retransmitting apparatus 200 includes modulated wave receiving units 201-1 to 201-n, broadcast signal output unit 202 that performs processing using clock Q, and TS time division multiplexing unit that performs processing using clock M by oscillator 204. 203. The modulated wave receiving units 201-1 to 201-n are broadcast signals of MPEG-2 TS1 to n (clocks T1 to Tn) using the ISDB-T system transmitted by the transmission devices 10-1 to 10-n. Each (modulation signal) is received and demodulated, and n pieces of MPEG-2 TS1 to n are output.

  The broadcast signal output unit 202 also generates and outputs p pieces of MPEG-2 TS based on the clock Q. The TS time division multiplexing unit 203 inputs n MPEG-2 TS1 to n (clocks T1 to Tn) from the modulated wave receiving units 201-1 to 201-n, and receives p MPEG from the broadcast signal output unit 202. -2 TSn + 1 to n + p (clock is Q) are input, time division multiplexing is performed by the clock M to generate a multiplexed frame, and it is transmitted as a broadcast signal (baseband signal).

  The remodulation apparatus 300 receives a broadcast signal (baseband signal) including n + p MPEG-2 TS from the retransmission apparatus 200, and converts x MPEG-2 TS out of n + p to clocks T1 to Tx, respectively. And the remaining n + p−x MPEG-2 TSs according to the clock Q. according to the ISDB-T method. It modulates and outputs with the modulation system according to 83 system.

  Here, since the transmitters 10-1 to 10-n have independent oscillators, the IFFT sample clocks T1 to Tn are not synchronized. That is, these MPEG-2 TS1 to n are in different clock domains. Also, IFFT sample clocks T1 to Tn used when the transmitters 10-1 to 10-n perform modulation using the modulation scheme according to the ISDB-T scheme, and the J.P. Similarly, the clock Q used for modulation by the modulation method according to the 83 method is not synchronized. Therefore, in the remodulation apparatus 300, x MPEG-2 TSs modulated by the modulation scheme according to the ISDB-T scheme, N + p−x MPEG-2 TSs modulated by the modulation method according to the 83 method are also in different clock domains.

  In the retransmitting device 200, the clock (clock for transmitting the broadcast signal (baseband signal) multiplexed by the retransmitting device 200) M and the clock Q in the broadcast signal (baseband signal) on the retransmission transmission path are set. These clocks can be generated by frequency division and multiplication using a common oscillator, for example, a PLL (Phase Lock Loop) circuit, so that these clocks can have an integer ratio relationship. In this case, in FIG. It can be said that n + p−x MPEG-2 TSs modulated in the 83 system are in the same clock domain.

  First, the remodulation device 300 regenerates the clock M of the retransmission transmission path from the received broadcast signal (baseband signal) using, for example, a PLL circuit. Next, MPEG-2 TS is converted to ISDB-T and J.I. In order to perform modulation by the modulation method according to the 83 method, it is necessary to regenerate the clock Q and the clocks T1 to Tn. Specifically, the remodulator 300 divides and multiplies the clock M of the retransmitted transmission path that has been regenerated to regenerate the clock Q.

  However, the remodulator 300 cannot regenerate the clocks T1 to Tn even if the clock M of the retransmission transmission path is divided and multiplied. Therefore, the clocks T1 to Tn are regenerated using the following method (1) or (2).

[Regeneration method of clocks T1 to Tn]
(1) Method Using Time Stamp In this method using a time stamp, the retransmission apparatus 200 counts one cycle of the MPEG-2 TS clock to be transmitted by the clock M of the retransmission transmission path, and the value (hereinafter referred to as “the time stamp”). , "Time stamp") is periodically transmitted, and the remodulation apparatus 300 reproduces the clocks T1 to Tn from the clock M and the time stamp of the retransmission transmission path using, for example, a PLL circuit. .

  For example, when reproducing the clock T1, the retransmitting apparatus 200 periodically transmits the time stamp 1 in which one cycle of the clock T1 is counted by the clock M of the retransmission transmission path. The remodulator 300 regenerates the clock T1 from the clock M and the time stamp 1 of the retransmission transmission path. Examples of time stamps used to realize such clock recovery include a method using a residual time stamp for synchronization (see Patent Document 1) and a method using a residual time stamp in an ATM network (Non-Patent Document 1). See).

  However, in the method using these time stamps, it is necessary to transmit the same number of time stamps 1 to n as the clock domain, so that the retransmission transmission path is inefficient for the band for transmitting the time stamps 1 to n. Invite use. Further, in the remodulation apparatus 300, the number of PLL circuits for clock recovery is required for the number of clock domains, and the circuit scale of the remodulation apparatus 300 increases.

(2) Method Using Buffer Memory In this method using buffer memory, remodulation apparatus 300 prepares a buffer memory for storing broadcast signals (baseband signals), and broadcasts so that the remaining amount of buffer memory is constant. The clocks T1 to Tn are reproduced by adjusting the clock for reading the signal.

  This method does not cause inefficient use of the retransmission transmission path because the time stamp is not transmitted, but a buffer memory is required for the remodulator 300, so that the circuit scale of the remodulator 300 increases. End up.

(3) Other methods In addition to the methods (1) and (2) described above, when the retransmitting apparatus 200 converts the clocks T1 to Tn into the clocks T1 ′ to Tn ′, the clocks T1 ′ to Tn ′. And the retransmission transmission path clock M have an integer ratio relationship, and the remodulation apparatus 300 divides and multiplies the retransmission transmission path clock M to regenerate the clocks T1 ′ to Tn ′. It is possible. In this case, the remodulation device 300 remodulates the MPEG-2 TS using the clocks T1 ′ to Tn ′.

  That is, the retransmitting apparatus 200 divides and multiplies the clock M of the retransmitting transmission line to generate T1 ′ to Tn ′, and the remodulating apparatus 300 remodulates in accordance with the clocks T1 ′ to Tn ′. Convert to MPEG-2 TS speed and send.

  However, with this method, in order to divide and multiply the clock M of the retransmission transmission path in the remodulation apparatus 300, a maximum of n PLL circuits are required, and the circuit scale of the remodulation apparatus 300 increases. . Further, since the retransmission apparatus 200 may not be able to convert the MPEG-2 TS speed, this method is not always applicable.

  Generally, MPEG-2 TS speed conversion is performed by inserting or deleting null packets from the original MPEG-2 TS in accordance with the speed of the converted MPEG-2 TS, and by PCR included in the MPEG-2 TS. This is realized by correcting (Program Clock Reference: program time reference value information). When the speed of the MPEG-2 TS after the speed conversion is made slower than the speed before the speed conversion, it is necessary to delete the null packet included in the MPEG-2 TS before the conversion. In 2 TS, when a null packet does not exist at a timing that needs to be deleted, or when no null packet is included in the MPEG-2 TS before speed conversion, speed conversion cannot be performed. Therefore, in such a case, the above-described method (3) cannot be applied.

US Pat. No. 5,260,978 ITU-T I.I. 363.1

  Therefore, the present invention is necessary for reproducing a clock of each broadcasting system in a broadcasting system in which a plurality of TSs in different clock domains are time-division multiplexed and remodulated by a modulation system according to a plurality of broadcasting systems. The purpose is to reduce the number of PLL circuits and the circuit scale.

  First, the outline of the present invention will be briefly described with specific examples. Transmitter for transmitting MPEG-2 TS by ISDB-T system, receiving and demodulating the MPEG-2 TS, a plurality of asynchronous MPEG-2 TSs (the MPEG-2 TS of ISDB-T system and other systems) ) Is retransmitted via a retransmission transmission path, MPEG-2 TS is received from the retransmission apparatus, a clock is regenerated, and MPEG-2 TS is remodulated and transmitted using the clock. The following (1) and (2) are characterized in a broadcasting system including a remodulating device that performs the above and a receiving device that receives MPEG-2 TS from the remodulating device.

(1) Generation of modulation clock The retransmitting device divides the clock of the retransmitting transmission path by 1 / integer without multiplying it, so that the remodulating device follows the ISDB-T method and other methods. The modulation clock is generated so that the clock for modulation by the modulation method is reproduced. The remodulator regenerates the clock of the retransmission transmission path by using one PLL circuit. Then, a clock for remodulation by the ISDB-T method and other methods is generated by a circuit that divides the frequency by a whole number. Here, the circuit that divides the frequency into 1 / integer does not need to be a PLL circuit, and for example, a counter having a much simpler configuration than the PLL circuit can be used. As a result, only one PLL circuit is required for the remodulation device in order to regenerate the clock of the retransmission transmission path. However, the re-modulation of the ISDB-T method and other methods requires a clock that satisfies the frequency and accuracy in accordance with the standard, and the retransmission apparatus needs to generate a clock so as to satisfy the condition.

(2) Increasing the information speed In addition, the retransmitting device uses the ISDB-T method in accordance with the generated clock so that the remodulating device can modulate with the modulation method according to the ISDB-T method. The MPEG-2 TS transmission rate is converted by the following method. First, the retransmission apparatus increases the information speed of the MPEG-2 TS when converting the transmission speed of the MPEG-2 TS. Specifically, the retransmission apparatus changes the value of the transmission parameter defined by the ISDB-T method so that the information rate is higher than when it is received, and converts the value to the information rate determined by the value of the transmission parameter. . At that time, a null packet is inserted into the MPEG-2 TS. For example, when receiving at an information rate when the guard interval ratio, which is one of the transmission parameters, is 1/8, the guard interval ratio is converted to 1/16, and a null packet is inserted to thereby receive the information rate at the time of reception. Convert to a speed exceeding.

  Then, the retransmission apparatus inserts an invalid layer packet into the MPEG-2 TS whose information rate has been increased based on the transmission parameter, and converts the MPEG-2 TS transmission rate after the insertion into the information rate after the information rate conversion. Convert to match. At this time, even if the transmission speed of the converted MPEG-2 TS is slightly lower than that before the conversion, the amount of inserted null packets should be adjusted (reduced) if it is within the range that can be accommodated by the inserted null packets. Thus, it is possible to convert the transmission rate without deleting packets necessary as information (without breaking the processing). In addition, the retransmission apparatus rewrites control information in a network information table (NIT) included in the MPEG-2 TS in accordance with the change of the transmission parameter.

  According to the above (1) and (2), the remodulator receives the MPEG-2 TS from the retransmitter, regenerates the clock of the retransmitted transmission path with one PLL circuit, and divides it by a fraction of an integer. A circuit (for example, a counter) is used to generate a clock for modulation by a modulation method according to the ISDB-T method and other methods. Thereby, the remodulation apparatus can remodulate the MPEG-2 TS of the ISDB-T system and other systems without breaking the processing.

  Here, the transmission rate refers to a rate including invalid layer packets after MPEG-2 TS is converted into an outer code (RS: Reed Solomon code) of the ISDB-T system, for example, and the information rate is an invalid layer. This refers to the speed of MPEG-2 TS that does not include packets. An invalid layer packet is a packet that is inserted into an MPEG-2 TS so that transmission path coding processing can be performed with a common clock for MPEG-2 TS of various information rates defined in the ISDB-T system. Yes, it is a packet that is not transmitted with an actual modulated wave. The transmission rate of the MPEG-2 TS after the invalid layer packet is inserted is 32.507793650.

  Therefore, in order to solve the above-described problem, a retransmission apparatus according to the present invention includes a transmission apparatus that transmits a TS and a plurality of TSs that receive TS from the transmission apparatus and are asynchronous with each other using the transmission path clock. A re-transmission apparatus that re-transmits the data via the re-transmission apparatus, a re-transmission apparatus that receives a plurality of TSs from the re-transmission apparatus, re-modulates the plurality of TSs by regenerating the clock of the transmission path, In the re-transmission apparatus in the broadcasting system including a modulation apparatus and a reception apparatus that receives a TS from the re-modulation apparatus, a clock generation unit that generates a clock of the transmission path, and a transmission generated by the clock generation unit A clock divider that divides the path clock by an integer and generates a modulation clock, a receiver that receives and demodulates TS from the transmitter, and a clock divider Based on the modulated clock, a speed converter that increases the information speed of the TS demodulated by the receiver, and a TS that has an information speed increased by the speed converter, are input, time-division multiplexed, and And a time division multiplexing unit that transmits the signal via a transmission line, and causes the remodulator to generate the modulation clock using a clock of the transmission line.

  In the retransmission apparatus according to the present invention, the receiver adds an invalid layer packet to the demodulated TS, and the rate converter deletes the invalid layer packet added by the receiver. And the information rate of the TS from which the invalid layer packet is deleted by the invalid layer packet deleting unit based on the modulation clock generated by the clock dividing unit, by setting the transmission parameter and inserting the null packet, An information rate conversion unit to be increased, and an invalid layer packet insertion unit to insert an invalid layer packet into a TS whose information rate has been increased by the information rate conversion unit are provided.

  The retransmission apparatus according to the present invention is characterized in that the information rate conversion unit of the rate conversion unit sets a transmission parameter so that a guard interval ratio becomes small.

  The retransmission apparatus according to the present invention is characterized in that the information rate conversion unit of the rate conversion unit sets a transmission parameter so as to increase a coding rate.

  In the retransmission apparatus according to the present invention, the speed converter generates a clock corresponding to the information speed that is higher by the information speed converter based on the modulation clock generated by the clock divider. A generation unit is provided.

  In the retransmission apparatus according to the present invention, the receiving unit receives a TS using the first broadcasting system and a TS using another broadcasting system different from the first broadcasting system from the transmitting apparatus. Demodulate, and the clock frequency divider divides the clock of the transmission path by an integer to generate a modulation clock for the first broadcast system and also generates a modulation clock for the second broadcast system Then, the speed conversion unit is configured to transmit the TS of the first and second broadcasting schemes demodulated by the receiving unit based on the modulation clocks of the first and second broadcasting schemes generated by the clock dividing unit. The time division multiplexing unit inputs TSs of the first and second broadcasting schemes whose information rates are increased by the speed conversion unit, and performs time division multiplexing on these TSs so that the transmission path is And transmit it to the remodulator. Characterized in that to generate the first and second modulating clock using click.

  The retransmission apparatus according to the present invention further includes an output unit that generates and outputs a TS of a third broadcasting system different from the first broadcasting system, and the receiving unit receives the first broadcasting system from the transmitting device. And a clock divider that divides the clock of the transmission path by a fraction of an integer to generate a modulation clock for the first broadcast system, and A broadcasting system modulation clock is generated, and the speed conversion unit is configured to generate a first broadcasting system demodulated by the receiving unit based on the first broadcasting system modulation clock generated by the clock frequency dividing unit. The TS is increased in speed, and the output unit outputs a third broadcasting system TS using the third broadcasting system modulation clock generated by the clock frequency dividing unit, and the time division multiplexing unit , The first broadcasting system with higher information speed by the speed converter The TS and the TS of the third broadcasting system output by the output unit are input, these TS are time-division multiplexed and transmitted through the transmission path, and the re-modulation apparatus is connected to the transmission path. The first and third modulation clocks are generated using a clock.

  The retransmission apparatus according to the present invention is characterized in that the rate conversion unit increases the information rate of the TS by replacing some packets constituting the TS demodulated by the reception unit with null packets. And

  Furthermore, the remodulation apparatus according to the present invention is a retransmission apparatus that transmits a TS and a TS that receives TS from the transmission apparatus and retransmits a plurality of asynchronous TSs via the transmission path using a transmission path clock. A re-modulation apparatus that receives a plurality of TSs from the re-transmission apparatus, reproduces a clock of the transmission path, re-modulates the plurality of TSs, and transmits the re-modulated TSs; and the re-modulation In the remodulation apparatus in a broadcasting system including a receiving apparatus that receives a TS from the apparatus, the clock reproducing section that receives the TS transmitted by the retransmitting apparatus and reproduces the clock of the transmission path, and the clock reproducing section The clock of the transmission path regenerated by 1 is divided by a fraction of an integer, a clock dividing unit for generating a modulation clock, and a plurality of TSs from the retransmission apparatus are received, and the clock regenerating unit Based on the generated transmission path clock and the modulation clock generated by the clock frequency divider, the separation unit that separates each TS, and based on the modulation clock generated by the clock frequency divider, And a modulation unit that modulates the TS separated by the separation unit.

  In the remodulation device according to the present invention, the modulation unit modulates the TS separated by the separation unit using a transmission parameter of the TS retransmitted by the retransmission device.

  Furthermore, a broadcasting system according to the present invention is characterized by including the re-transmission device and the re-modulation device.

  As described above, according to the present invention, a clock obtained by dividing the transmission path clock by an integer is used as the modulation clock. Therefore, the transmission path clock and the modulation clock have an integer ratio. Therefore, the remodulator can regenerate the clock of the transmission path by the PLL circuit and generate the modulation clock by, for example, a counter. As a result, in a broadcast system that performs time division multiplex transmission of a plurality of TSs in different clock domains and remodulates with a modulation method according to a plurality of broadcast methods, the PLL circuit necessary for reproducing the clocks of each broadcast method The number can be reduced and the circuit scale can be reduced.

The best mode for carrying out the present invention will be described below in detail with reference to the drawings.
[Broadcasting system]
FIG. 1 is a diagram showing an overall configuration of a broadcasting system that is an object of an embodiment of the present invention. The broadcasting system 1 includes a transmitting device 10, a retransmitting device 20, a remodulating device 30, and receiving devices 40-1 and 40-2. In the broadcast system 1 described above, the retransmitting device 200 and the remodulating device 300 are used. However, in the embodiment of the present invention, the retransmitting device 20 and the remodulating device 30 will be described. Hereinafter, MPEG-2 TS is simply referred to as “TS”.

  The transmission device 10 includes a plurality of transmission devices, and transmits a TS broadcast signal (modulation signal) using the ISDB-T method and a TS broadcast signal (modulation signal) using the ISDB-S method via an antenna. To do. Here, it is assumed that broadcast signals (modulated signals) transmitted from a plurality of transmission apparatuses have different clock domains.

  The retransmitting device 20 receives the broadcast signal (modulated signal) transmitted from the transmitting device 10, demodulates the received broadcast signal, extracts the TS, and time-division multiplex together with the TS that is the broadcast content of the retransmitting device 200. Then, it is retransmitted as a broadcast signal (baseband signal) through the retransmission transmission path.

  The remodulator 30 receives the broadcast signal (baseband signal) retransmitted by the retransmitter 20, separates one or a plurality of TSs from the plurality of TSs of the received broadcast signal, and determines each TS. It modulates according to the broadcast system and transmits it as a broadcast signal (remodulation signal). In addition, the remodulation device 30 modulates some of the TS broadcast signals transmitted by the transmission device 10 using the ISDB-T method with a modulation method according to the ISDB-T method. Further, the remaining broadcast signals that are not modulated by the ISDB-T method among the TS broadcast signals that are transmitted by the transmission device 10 using the ISDB-T method, and the ISDB-S method that is transmitted by the transmission device 10 are used. The broadcast signal of the received TS and the broadcast signal possessed by the retransmission apparatus 20 are J. It is assumed that modulation is performed using the 83 method. Furthermore, when transmitting a plurality of modulated waves, the remodulating device 30 modulates each with a carrier wave having a different frequency, and frequency-multiplexes and transmits it as a broadcast signal (remodulated signal).

  The receiving devices 40-1 and 40-2 receive the broadcast signal (remodulation signal) transmitted by the remodulation device 30, demodulate the received broadcast signal, extract TS, and decode video and audio.

[Retransmission device]
Next, the retransmission apparatus 20 illustrated in FIG. 1 will be described. FIG. 3 is a diagram illustrating the configuration of the retransmission apparatus 20 according to the embodiment of the present invention and the relationship between broadcast signals and clocks. The retransmitting device 20 includes a modulated wave receiving unit 21, a broadcast signal output unit 22, a TS time division multiplexing unit 23, a clock generation unit (oscillator) 24, a clock frequency division unit 25, and a speed conversion unit 26.

  The modulated wave receiving unit 21 receives and demodulates the TS broadcast signals (modulated signals) using the ISDB-T method by the modulated wave receiving units 21-1 to 21-i + j, respectively, and modulates the modulated wave receiving units 21-i + j + 1 to 1. 21-i + j + k receives and demodulates TS broadcast signals (modulated signals) using the ISDB-S system, and outputs TSs respectively. That is, the modulated wave receiving unit 21 receives and demodulates i + j ISDB-T modulated waves and k ISDB-S modulated waves, and outputs i + j + k TSs. In a remodulation apparatus 30 described later, i TSs (TS1 to TSi) are remodulated by a modulation method according to the ISDB-T method, and j TSs (TSi + 1 to TSi + j) and k TSs (TSi + j + 1 to TSi + j + k). ) It is assumed that re-modulation is performed by a modulation method according to the 83 method. Hereinafter, J. et al. The modulation method according to the 83 method is 64QAM.

  Specifically, the modulated wave receiving units 21-1 to 21-i add invalid layer packets to the demodulated TS1 to TSi, respectively, and further, 189 to 196 bytes (hereinafter referred to as “dummy bytes”) of each packet. Information indicating whether the hierarchy is invalid or not. Then, RS (204, 196) encoding is performed on the packet including the dummy byte and output. Also, the modulated wave receiving units 21-i + 1 to i + j + k perform RS (204, 188) encoding on the demodulated TSi + 1 to TSi + j + k and output them. With the above processing, the TS packet size becomes 204 bytes, and the TS transmission rates are 32.507793650... Mbps for TS1 to TSi and 31.644 Mbps for TSi + 1 to TSi + j + k + p, respectively.

  The broadcast signal output unit 22 performs RS (204, 188) encoding on p TS (TSi + j + k + 1 to TSi + j + k + p) in accordance with the clock Q generated by the clock frequency dividing unit 25-2 described later, and performs 6-bit parallel processing. Output. These TS are broadcast contents possessed by the retransmitting apparatus 20, such as independent broadcasting of cable television.

  The clock generator 24 generates a clock M of the transmission path (retransmission transmission path). The clock divider 25 divides the clock M of the transmission path and generates a clock for converting the speed of the TS. Specifically, the clock divider 25-1 generates an ISDB-T modulation clock T ', and the clock divider 25-2 83 type modulation clock Q is generated. The modulation clocks T ′ and Q are also generated as modulation clocks in the remodulation device 30 described later.

  Here, the modulation clocks T ′ and Q will be briefly described. The remodulation apparatus 30 described later uses an IFFT sample clock of 8.1126984126... MHz as the modulation clock T ′ in order to remodulate the TS using the ISDB-T system. In order to remodulate a TS using the 83 method, a 5.274 MHz symbol clock is used as the modulation clock Q.

The relationship between these modulation clocks T ′ and Q and the clock for transmitting TS is as follows.
(1) In the case of ISDB-T system, 8.1126984126... MHz (clock T ′) × 4 = 32.2.57933650... MHz
The clock of 32.507793650... MHz corresponds to a clock for serially transmitting a TS that is remodulated by a modulation method according to the ISDB-T method, that is, a transmission speed in the above-described retransmission transmission path.
(2) J. Org. In the case of 83 system, 5.274 MHz (clock Q) × 6 = 31.644 MHz
This 31.644 MHz clock is the same as J.I. This corresponds to a clock for serially transmitting a TS that is remodulated by the modulation method according to the 83 method, that is, the transmission speed in the above-described retransmission transmission path. In the remodulation device 30 described later, it is only necessary to divide the clock M of the transmission path by 1 / integer to generate the modulation clocks T ′ and Q, so that 32.507793650... MHz and 31.644 MHz. No clock is required.

  The clock divider 25 of the retransmitting device 20 generates the modulation clocks T ′ and Q from the clock M of the transmission path, but the serial transmission clock of the TS is 32.507793650. MHz and 31.644 MHz may be generated. Also, the TS 8-bit parallel transmission clock (byte clock), 4.063492063... MHz and 3.9555 MHz may be generated. In the embodiment of the present invention, as described above, in order for the remodulation device 30 described later to remodulate with a modulation method according to the ISDB-T method, a modulation clock T ′ that is a 4-bit parallel transmission clock of TS. And J. In order to perform re-modulation by the modulation method according to the 83 method, a modulation clock Q that is a 6-bit parallel transmission clock of TS is generated. Therefore, the re-transmission device 20 uses the ISDB-T method and J.P. The TS remodulated by the modulation method according to the 83 method is processed in parallel in units of 4 bits and 6 bits, respectively.

In this case, the ISDB-T modulation clock T ′ needs to be within the following range.
8.1126984126... MHz (512/63 MHz) within ± 1 ppm In addition, when the output of the remodulation device 30 described later is 0.05 W or less and is recognized as a very small power station, within ± 20 kHz It becomes. In addition, J.H. The 83-type modulation clock Q needs to be in the range of 5.274 MHz ± 20 ppm.

In the embodiment of the present invention, the clock M of the transmission line is extracted so that the modulation clocks T ′ and Q that fall within the above-described range can be extracted by dividing the clock M of the transmission line by an integer. Must be set. That is, the transmission path clock M is set so as to satisfy the following relationship, where X and Y are integers.
M / X = Q Formula (1)
M / Y = T ′ (2)

Examples of combinations of the integers X and Y and the transmission path clock M that satisfy the above-described two expressions are as follows.
X = 715, Y = 464, M = 3770.920634 MHz
(In this case, T ′ = 8.1298984125 MHz, Q = 5.274014873... MHz)
X = 809, Y = 525, M = 4266.666666 MHz
(In this case, T ′ = 8.1298984126... MHz, Q = 5.274000823... MHz)
A combination of X, Y, and M is determined from these.

  In the following description, it is assumed that a combination of X = 715, Y = 464, M = 3770.920634 MHz is selected. That is, the clock generator 24 of the retransmitting device 20 generates a clock M of 3770.920634 MHz, and the clock divider 25-1 divides the clock M by 464 to obtain a frequency of 8.1126984125 MHz. Clock T ′ is generated, and the clock divider 25-2 divides the clock M by 1/715 to generate a modulation clock Q of 5.274140473.

  The speed converter 26 receives the TS from the modulated wave receiver 21, converts the transmission speed of the input TS using the modulation clocks T ′ and Q generated by the clock divider 25, and performs a 4-bit parallel. Processing and 6-bit parallel processing are output. Along with this speed conversion, a null packet (packet size 204 bytes) after RS encoding is inserted.

  Specifically, the speed converters 26-1 to 26-i receive TS of 32.507793650... Mbps from the modulated wave receivers 21-1 to 21-i and are received by the clock divider 25-1. Using the generated 8.2126984125 MHz modulation clock T ′, the input TS speed is converted, 4-bit parallel processing is performed, and a 32.50779365 Mbps TS slightly different from the input TS transmission speed is output. . The speed difference between the input TS and the TS after speed conversion is caused by the frequency difference between the clocks T1 to Tn and the clock T '.

  The speed converters 26-i + 1 to 26-i + j + k receive 31.644 Mbps TS from the modulated wave receivers 21-i + 1 to 21-i + j + k and are generated by the clock divider 25-2. .. Using the clock Q of MHz, the speed of the input TS is converted, 6-bit parallel processing is performed, and a TS with a transmission speed different from the input TS is output. Details of the speed converter 26 will be described later.

  The TS time division multiplexing unit 23 receives a 4-bit parallel TS and a 6-bit parallel TS from the speed conversion unit 26, and inputs a 6-bit parallel TS from the broadcast signal output unit 22, and the clock generation unit 24 generates the TS. Using a transmission path clock M, a multiplex frame composed of a slot containing a header and TS including control information (basic unit when data is time-division multiplexed on one physical transmission path) is generated, and the multiplexing is performed. The frame is transmitted to the retransmission transmission path as a broadcast signal (baseband signal). Here, the slot size of the multiplexed frame is assumed to be 204 bytes, which is the same as the TS packet after RS encoding. The control information includes a table for identifying a slot in which each TS in the multiplexed frame is stored.

  The number of multiplexed frame slots assigned to each TS is determined as follows. When the transmission path clock M and the modulation clocks T ′ and Q satisfy the relationship of the above-described formulas (1) and (2), the ratio of the slots of the multiplexed frame used by a certain TS is the modulation clock T ′. In the TS that has been speed-converted at 4, the speed is 4 / Y, and in the TS that is speed-converted by the clock Q, the speed is 6 / X. For example, the number of slots of a multiplexed frame with a transmission rate of 3770.920634 MHz is assumed to be 331760 (= the least common multiple of X and Y 464 × 715). At this time, the number of slots allocated to a certain TS is 331760 × 4/464 = 2860 slots for the TS converted by the modulation clock T ′, and 331760 × 6 for the TS converted by the clock Q. / 715 = 2784 slots. The transmission speed of TS is 32.50779365 Mbps, 31.64408924... Mbps, respectively.

(Speed converter)
Next, the speed conversion units 26-1 to 26-i in the retransmission apparatus 20 illustrated in FIG. 3 will be described in detail. FIG. 4 is a diagram illustrating the configuration and processing of the speed conversion units 26-1 to 26-i. FIG. 6 is a diagram illustrating the transmission rate of TS input to the rate conversion units 26-1 to 26-i and the transmission rate of TS to be output. The rate conversion units 26-1 to 26-i have a function of converting the transmission rate of the TS modulated by the modulation method according to the ISDB-T method by a remodulation device 30 described later, and an invalid layer packet deletion unit 271, a clock frequency division / multiplication unit 272, an information rate conversion unit 273, and an invalid layer packet insertion unit 274.

  The invalid layer packet deletion unit 271 transmits the transmission rate 32.5077943650... Mbps (the transmission rate based on the clocks T1 to Ti: the transmission rate based on the clock T in FIG. 4) from the modulated wave receiving units 21-1 to 21-i. ) TS is input, the invalid layer packet and the valid layer packet are separated by referring to the dummy byte of TS (see FIG. 6 (1)), only the invalid layer packet is deleted, and the transmission rate is the information rate (invalid (TS rate not including layer packet). For example, when the transmission parameters are mode 3, guard interval ratio 1/8, modulation scheme 64QAM, coding rate 3/4, and all 13 segments are this parameter, the TS information after deleting the invalid layer packet The speed is 19.80952380 ... Mbps. In this case, the invalid layer packet deletion unit 271 outputs a TS with an information rate of 19.80952380... Mbps from which the invalid layer packet has been deleted.

The clock frequency division / multiplication unit 272 generates a clock for outputting a TS having an information rate exceeding the information rate of 19.80952380... Mbps from which the invalid layer packet has been deleted. That is, the clock used in the information rate conversion unit 273, that is, the clock when the transmission parameter corresponding to the information rate exceeding the information rate of the input TS is selected is calculated by the following equation.
T ′ × 4 × A / B × S (3)
Here, A is the number of TS packets transmitted with one OFDM frame length, and is an integer value determined by the setting of the mode, modulation scheme, and coding rate. For example, in the case of mode 3, modulation scheme 64QAM, and coding rate 3/4, it is 216. B is the number of TS packets in one TS multiplexed frame, and is an integer value determined by the setting of the mode and guard interval ratio. For example, when mode 3 and guard interval ratio 1/8, 4608, and when mode 3 and guard interval ratio 1/16, 4352. S is the number of segments that transmit the TS to be modulated, and is a value from 1 to 13.

  The information rate conversion unit 273 receives the information rate 19.80952380... Mbps TS from which the invalid layer packet has been deleted by the invalid layer packet deletion unit 271, and uses the clock generated by the clock frequency division / multiplication unit 272. The transmission parameters are set to be higher than the information rate (19.80952380... Mbps) of the TS received by the modulated wave receiving units 21-1 to 21-i, and a null packet is inserted into the input TS. (Refer to FIG. 6 (2)) By modifying the PCR, the information rate of the input TS is converted, and the TS of the converted information rate is output. The value of the transmission parameter to be set is determined in advance. For example, if a guard interval ratio of 1/16 (the original guard interval ratio is 1/8) is set as a transmission parameter, the information rate at this time is 20.94778991... Mbps (= 512/63 × 4 × 216/4352) X13), which is 1.16526611... Mbps higher. In this case, the information rate conversion unit 273 inputs TS of information rate 19.80952380... Mbps, sets the guard interval ratio 1/16 as a transmission parameter, inserts the input null packet, corrects the PCR, Using the clock generated by the clock divider / multiplier 272, the information is converted to an information rate 20.94778991... Mbps higher than the information rate of the input TS (= 8.1126984125 × 4 × 216/4352 × 13). The TS of this information rate is output. In this case, even if the transmission rate is lowered by the rate conversion units 26-1 to 26-i, by adjusting the amount of null packets inserted by the information rate conversion unit 273, the original TS packet is not lost. It is possible to convert the transmission rate.

  Here, the information rate conversion unit 273, when changing the value of the transmission parameter defined in the ISDB-T method, assumes a plurality of transmission path conditions and prepares a plurality of transmission parameters for transmission path encoding prepared in advance. A transmission parameter adapted to the transmission path condition is selected in advance, and the selected transmission parameter is set. For example, there are three types of transmission parameters with different carrier frequency intervals, and there are three types of guard interval ratios related to the resistance to multipath interference of the retransmission transmission path: 1/4, 1/8, and 1/16. Further, there are three types of modulation methods for data such as video and audio, excluding control information, 64QAM, 16QAM, and QPSK, and the encoding rate of the error correction inner code (convolutional code) is 7/8, 5/6, There are 5 types: 3/4, 2/3, 1/2. Refer to ARIB STD-B31 for details. Some transmission parameters are related to the information rate of the TS. For example, if the guard interval ratio is reduced (1/4 → 1/8, etc.), the information rate is increased although it is easily affected by multipath interference. Further, when the coding rate is increased (3/4 → 5/6, etc.), the error correction capability decreases, but the information speed increases. Some of the transmission parameters of terrestrial digital broadcasting currently being carried out are mode 3, guard interval ratio 1/8, modulation method 64QAM, coding rate 3/4, and all 13 segments are this parameter. The information speed of TS is 19.80952380... Mbps.

  The invalid layer packet insertion unit 274 receives the TS whose information rate has been converted by the information rate conversion unit 273 (information rate has increased), and in accordance with the transmission parameter set by the information rate conversion unit 273 for the input TS. , An invalid layer packet is inserted at a predetermined position in the TS (see FIG. 6 (2)), and the TS transmission rate 32.50779350... Mbps input to the rate conversion units 26-1 to 26-i A TS having a slightly different transmission rate of 32.50779365 Mbps (a transmission rate based on the clock T ′ in FIG. 4) is generated and output. Specifically, for example, when the number of segments is 13, (B-13 × A) invalid layer packets are inserted into 13 × A TS packets. As described above, A is the number of TS packets transmitted with one OFDM frame length, and B is the number of TS packets in the TS multiplexed frame.

  Next, the speed conversion units 26-i + 1 to 26-i + j + k in the retransmission apparatus 20 illustrated in FIG. 3 will be described in detail. The speed conversion units 26-i + 1 to 26-i + j + k are transmitted by the remodulation device 30 described later to J.P. It has a function of converting the transmission rate of TS modulated by the 64QAM modulation method according to the 83 method.

  When converting the TS transmission speed in accordance with the clock Q, the speed converters 26-i + 1 to 26-i + j + k delete invalid layer packets or null packets from the input TS (if there are insufficient or no null packets) Delete invalid layer packets.), Modify PCR. Thereby, the transmission rate of TS falls. Further, the modulation method is changed from the modulation method according to the ISDB-T method and the ISDB-S method at the time of reception to J.P. Since the system is changed to the system according to the 83 system, the control information including the modulation system included in the NIT is rewritten (the ground distribution system descriptor included in the NIT is replaced with a cable distribution system descriptor). Here, the reason why the invalid layer packet or the null packet is deleted from the input TS is that the transmission rate of the TS of the ISDB-T system is 32.507793650. This is because the transmission rate of the TS of the 64QAM modulation system according to the 83 system is 31.644 Mbps, and the former is higher. That is, approximately 1 Mbps (= 32.507393650, which is the result of subtracting the output transmission speed (transmission speed using the J.83 system) from the input transmission speed (TS transmission speed using the ISDB-T system). Delete invalid layer packets or null packets for (Mbps-31.644 Mbps). The transmission rate can be lowered by deleting invalid layer packets or null packets even if the information rate of TS using the ISDB-T method (the rate of TS not including invalid layer packets) is about the highest. This is because the invalid layer packet of 23 Mbps and at least about 9 Mbps (= 32.507793650... Mbps−about 23 Mbps) is included in the TS. Therefore, the transmission rate of the TS can be reduced without deleting packets necessary as information (packets other than null packets and invalid layer packets).

[Remodulation device]
Next, the remodulation device 30 shown in FIG. 1 will be described. FIG. 5 is a diagram showing the configuration of the remodulation device 30 according to the embodiment of the present invention and the relationship between the broadcast signal and the clock. The remodulation device 30 includes a TS separation unit 31, a clock recovery unit (PLL circuit) 32, a clock frequency division unit 33, a modulation unit 34, and a transmission parameter storage unit 35.

  The TS separation unit 31 receives a broadcast signal (baseband signal) transmitted from the retransmitting apparatus 20, refers to control information in a multiplex frame header, separates a TS to be remodulated, and an ISDB-T system TS is 4-bit parallel processed and output. 83-type TS is subjected to 6-bit parallel processing and output.

  The clock recovery unit 32 receives the broadcast signal (baseband signal) transmitted by the retransmitting device 20, and recovers the transmission path clock M from the multiplexed baseband signal using a PLL circuit.

  The clock frequency divider 33 divides the clock M of the transmission line regenerated by the clock regenerator 32 by 1 / integer by the clock frequency divider 33-1, thereby modulating the ISDB-T modulation clock. T ′ is generated, and the clock frequency dividing unit 33-2 divides the clock M of the transmission path by 1 / integer. 83 type modulation clock Q is generated. These modulation clocks T ′ and Q are used not only for modulation processing by the modulation unit 34 but also for processing when the TS separated by the TS separation unit 31 is output to the modulation unit 34.

  In the transmission parameter storage unit 35, transmission parameter values set by the information speed conversion unit 273 of the speed conversion unit 26 in the retransmission apparatus 20 are stored in advance.

  The modulation unit 34 receives the TS from the TS separation unit 31 and uses the modulation clocks T ′ and Q generated by the clock dividing unit 33 to convert the input TS into the ISDB-T method and the J.J. It modulates with the modulation system according to 83 system, and transmits. Specifically, the modulation unit 34-1 receives an ISDB-T 4-bit parallel TS from the TS separation unit 31, inputs a transmission parameter from the transmission parameter storage unit 35, and a clock divider 33-1. Is modulated by a modulation method according to the ISDB-T method and transmitted as a broadcast signal (remodulated signal) to the receiving devices 40-1 and 40-2. Also, the modulation unit 34-2 is connected to the J.P. 83 type 6-bit parallel TS is input, and the clock Q generated by the clock frequency divider 33-2 is used. It modulates with the modulation system (64QAM) according to 83 system, and transmits to the receivers 40-1 and 40-2 as a broadcast signal (remodulation signal).

  The transmission parameter is transmitted as TMCC (Transmission and Multiplexing Configuration Control) information in a modulated wave of a broadcast signal (remodulation signal) transmitted by the remodulation device 30. As described above, the control information in the NIT is rewritten in the TS transmitted as a broadcast signal. The receiving devices 40-1 and 40-2 refer to the TMCC information and the control information in the NIT, thereby receiving the broadcast signal transmitted by the remodulating device 30, and the broadcast signal transmitted by the transmitting device 10. Can be handled in the same way.

  As described above, according to the embodiment of the present invention, the clocks generated by dividing the clock M of the transmission path by 1 / integer are used as the modulation clocks T ′ and Q of a plurality of asynchronous TSs. I did it. Specifically, the re-transmission device 20 divides the clock M of the re-transmission transmission path between the re-transmission device 20 and the re-modulation device 30 by 1 / integer without multiplying the re-modulation device. 30 according to ISDB-T system and J.H. A modulation clock is generated so that a clock for modulation by the modulation method according to the 83 method is reproduced. That is, the remodulator 30 regenerates the clock M of the retransmission transmission path by the clock regenerating unit 32 that is one PLL circuit, and divides the clock by a circuit (for example, a counter) that divides it by an integer. Part 33-1 and 33-2, the ISDB-T system and J.I. Modulation clocks T ′ and Q for modulation in the 83 method are generated. As a result, the remodulating device 30 can reduce the number of PLL circuits because only one PLL circuit is required to regenerate the clock M of the retransmission transmission path. Therefore, the circuit scale of the remodulation device 30 can be reduced.

  Further, according to the embodiment of the present invention, the retransmission apparatus 20 deletes the invalid layer packet of the TS, increases the information rate of the TS according to the modulation clock T ′, and responds to the transmission parameters set at that time. The transmission rate was changed by inserting invalid layer packets. Since the remodulating device 30 can modulate the TS according to the transmission parameters set by the retransmitting device 20, it is possible to realize retransmission and remodulation of the TS without breaking the processing.

  Note that a broadcast signal using the ISDB-T system, in which speed conversion is performed by the speed conversion units 26-1 to 26-i of the retransmitting apparatus 20 and modulated by the modulation unit 34-1 of the remodulating apparatus 30, is more Since transmission parameters that allow large-capacity transmission are used, there is a risk that the resilience to the multipath or error of the retransmission transmission path may be reduced. Therefore, it is desirable that the application target of the embodiment of the present invention is a re-transmission transmission path with multipath or few transmission errors.

  In the embodiment of the present invention, the transmission parameter of the broadcast signal (modulated wave) transmitted by the transmission device 10, that is, the transmission parameter of terrestrial digital broadcasting, increases the information speed in the speed conversion unit 26 of the retransmission device 20. It must be operated at a value that can be done.

  The present invention has been described with reference to the embodiment of the present invention. However, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the technical idea thereof.

[When TS Modulated by Modulation Method According to ISDB-T Method Does Not Contain Invalid Layer Packet]
In the embodiment, the retransmission apparatus 20 inserts an invalid layer packet into the TS by the invalid layer packet insertion unit 274 of the rate conversion units 26-1 to 26-i, and remodulates the TS broadcast signal including the invalid layer packet. Although it was transmitted to the apparatus 30, a broadcast signal of a TS that does not include an invalid layer packet may be transmitted. In this case, the invalid layer packet insertion processing by the invalid layer packet insertion unit 274 of the modulated wave receiving units 21-1 to 21-i in the retransmitting device 20 is not necessary, and the transmission rate of the TS is the clock of the formula (3) described above. The information rate of the TS output by the information rate conversion unit 273 (20.7477991... Mbps) is used.

  When receiving a TS that does not include an invalid layer packet, the remodulation device 30 cannot generate the clock represented by Expression (3) from the clock M of the transmission path. This is because a circuit for this purpose is not provided. However, the remodulation device 30 can obtain the values of A and B in Equation (3) by storing the transmission parameter values set by the retransmission device 20 in advance.

  From the values of A and B, the TS separation unit 31 of the remodulating device 30 inserts invalid layer packets of the number corresponding to the speed difference from the transmission rate of the TS of the above embodiment into the TS that does not include the invalid layer. And output in accordance with the modulation clock T ′. As a result, the modulation unit 34-1 can correctly perform the modulation process in accordance with the modulation clock T '. For example, when the mode is 3, the guard interval ratio is 1/8, the modulation method is 64QAM, the coding rate is 3/4, and the number of segments is 13, 1800 (= 4608−) for 2808 (= 216 × 13) effective packet outputs. 2808), the invalid layer packet is output.

[When TS to be modulated by the modulation system according to the ISDB-T system is a broadcast TS]
In the above embodiment, the remodulation device 30 stores in advance the transmission parameter value of the TS that is modulated by the modulation method according to the ISDB-T method. The value may be transmitted and the remodulator 30 may receive and use it. In this case, the value of the transmission parameter is transmitted by a broadcast TS having a dummy byte and IIP (ISDB-T Information Packet), for example. For details, refer to ARIB STD-B31 Appendix 5.5. The IIP is a packet for transmitting TMCC information including transmission parameters, and the modulation unit 34 of the remodulation device 30 treats this packet as an invalid layer packet and deletes it.

[When 13-segment transmission parameters are different]
In the above-described embodiment, the TS modulated by the modulation method according to the ISDB-T method has been described on the assumption that all 13 segments have the same transmission parameter value. However, one TS can have a maximum of three different transmission parameter values. Therefore, the present invention can also be applied when retransmitting such a TS. In this case, the retransmitting device 20 separates TS packets modulated with different transmission parameters, sets a new transmission parameter value for each separated packet sequence, performs the above-described speed conversion, and again performs a single transmission packet. What is necessary is just to multiplex to TS.

[When retransmitting device 20 converts information rate using null packet]
In the embodiment, the retransmission apparatus 20 converts the information rate by changing the transmission parameters (guard interval ratio and coding rate) of the TS that is modulated by the modulation scheme according to the ISDB-T scheme, and converts the information rate. However, by discarding a part of the received TS without retransmitting it, replacing the band with a null packet, and using the band of the null packet for speed conversion, The failure of the speed conversion process may be prevented. For example, if there is a TS that has two different transmission parameter values, modulates 12 segments for a fixed reception device, and modulates one segment for a mobile reception device, the retransmission device 20 However, one segment's worth of packets are discarded, and a null packet with an adjusted amount is retransmitted instead. In this case, the retransmission apparatus 20 does not change the transmission parameters (guard interval ratio and coding rate) corresponding to the packet for the fixed reception apparatus, and changes the number of segments used by the packet for the fixed reception apparatus from 12 to 13. By changing to, it is possible to increase the information rate of packets for fixed reception devices. In this case, even if the value of the transmission parameter corresponding to the packet for the fixed reception device is the highest information rate, the number of segments to be used is increased, so that the information rate can be increased.

[When using another modulation clock]
In the above embodiment, the modulation unit 34 of the remodulation device 30 uses 8.1126984125 MHz, 5.274140473... MHz as the modulation clocks T ′ and Q, respectively. You may make it use the byte clock of TS.

In this case, the relationship shown in the above-described formulas (1) and (2) indicates that the ISDB-T modulation clock is T ′ _B , J.P. The modulating clock of 83 method When Q _B, as follows. T ′ _B and Q _B are 4.063492063... MHz (= 512/63 × 4/8 MHz) ± 4/8 ppm or less, 3.9555 MHz (= 5.274 × 6/8 MHz) ± 20 × It must be within 6/8 ppm.
M / X = Q _B ... Formula (4)
M / Y = T ′ _B (5)

Examples of combinations of the integers X and Y and the transmission path clock M that satisfy the above-described two expressions are as follows.
X = 301, Y = 293, M = 1190.603174 MHz
(In this case, T ′ _B = 4.063492061... MHz, Q _B = 3.9955492272... MHz)
X = 715, Y = 696, M = 2828.190476 ... MHz
(In this case, T ′ _B = 4.063492063... MHz, Q _B = 3.95511155... MHz)
In order to generate a TS modulation clock required by the modulation unit 34 of the remodulating device 30 without using a multiplier circuit (using only a circuit that performs division by 1 / integer), these What is necessary is just to determine the combination of X, Y, and M from the inside.

[When using other modulation methods]
In the above embodiment, J. Org. Although the modulation scheme according to the 83 scheme has been described as 64QAM, other modulation schemes may be used. For example, although no recommendation has been made as of September 2007, it may be 256 QAM or more multi-value QAM. For example, when the modulation scheme is 256QAM, the transmission rate of the TS to be retransmitted is 5.274 × 8 = 42.192 Mbps, and the number of assigned slots in the multiplexed frame is 8/6 times that of 64QAM. In addition, the modulation unit 34-2 of the remodulation device 30 inputs an 8-bit parallel TS from the TS separation unit 31. In this case, the symbol clock (5.274 MHz) is equal to the TS byte clock.

[When using other TS]
In the above embodiment, the case where MPEG-2 TS is time-division multiplexed has been described, but the present invention is also applicable to other TS such as MPEG-4 TS.

It is a figure which shows the whole structure of a broadcast system. It is a figure which shows the relationship between a broadcast signal and a clock when a different clock domain is mixed. It is a figure which shows the structure of the re-transmission apparatus by embodiment of this invention, and the relationship between a broadcast signal and a clock. It is a figure which shows the structure and process of the speed conversion part of FIG. It is a figure which shows the structure of the remodulation apparatus by embodiment of this invention, and the relationship between a broadcast signal and a clock. It is a figure which shows the transmission speed of TS input into a speed conversion part, and the transmission speed of TS output.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Broadcasting system 10 Transmitting device 20,200 Retransmitting device 21,201 Modulated wave receiving unit 22,202 Broadcast signal output unit 23,203 TS time division multiplexing unit 24 Clock generation unit 25 Clock division unit 26 Speed conversion unit 30,300 Remodulator 31 TS separation unit 32 Clock recovery unit 33 Clock division unit 34 Modulation unit 35 Transmission parameter storage unit 40 Reception device 204 Oscillator 271 Invalid layer packet deletion unit 272 Clock division / multiplication unit 273 Information rate conversion unit 274 Invalid layer Packet insertion part

Claims (11)

A transmission apparatus that transmits a TS (Transport Stream); a retransmission apparatus that receives the TS from the transmission apparatus and retransmits a plurality of asynchronous TSs via the transmission path with a transmission path clock; and Receiving a plurality of TSs from a transmitting device, re-modulating the plurality of TSs by regenerating the clock of the transmission path, transmitting a plurality of re-modulated TSs, and receiving the TS from the remodulating device In the retransmission apparatus in a broadcasting system comprising a receiving apparatus,
A clock generator for generating a clock of the transmission path;
A clock dividing unit that divides the clock of the transmission path generated by the clock generation unit by an integer to generate a modulation clock;
A receiver that receives and demodulates the TS from the transmitter;
Based on the modulation clock generated by the clock divider, a speed converter that increases the information rate of the TS demodulated by the receiver;
A time division multiplexing unit that inputs TS with an increased information rate by the speed conversion unit, performs time division multiplexing, and transmits the transmission through the transmission path, and
A re-transmission apparatus that causes the re-modulation apparatus to generate the modulation clock using a clock of a transmission line. The re-transmission apparatus according to claim 1,
The receiver adds an invalid layer packet to the demodulated TS,
The speed converter is
An invalid layer packet deleting unit that deletes the invalid layer packet added by the receiving unit;
Information for increasing the information rate of the TS from which the invalid layer packet is deleted by the invalid layer packet deleting unit based on the modulation clock generated by the clock dividing unit by setting the transmission parameter and inserting a null packet A speed converter,
A retransmission apparatus comprising: an invalid layer packet insertion unit that inserts an invalid layer packet in a TS whose information rate is increased by the information rate conversion unit. The re-transmission apparatus according to claim 1 or 2,
The information rate conversion unit of the rate conversion unit sets a transmission parameter so that a guard interval ratio becomes small. The re-transmission apparatus according to claim 1 or 2,
The information rate conversion unit of the rate conversion unit sets a transmission parameter so as to increase a coding rate. The re-transmission apparatus according to claim 2,
The re-transmission characterized in that the speed conversion unit includes a clock generation unit that generates a clock according to an information rate that is increased by the information speed conversion unit based on the modulation clock generated by the clock frequency division unit. apparatus. In the retransmission apparatus according to any one of claims 1 to 5,
The receiving unit receives and demodulates the TS using the first broadcasting system from the transmitting device and the TS using another broadcasting system different from the first broadcasting system,
The clock dividing unit divides the clock of the transmission path by an integer to generate a modulation clock for the first broadcast system and a modulation clock for the second broadcast system,
The speed conversion unit is configured to transmit information rates of the first and second broadcasting system TSs demodulated by the receiving unit based on the first and second broadcasting system modulation clocks generated by the clock frequency dividing unit. A speed converter that increases
The time division multiplexing unit inputs TSs of the first and second broadcasting schemes whose information speed is increased by the speed conversion unit, performs time division multiplexing on these TSs, transmits the TS through the transmission path,
A re-transmission apparatus that causes the re-modulation apparatus to generate the first and second modulation clocks using a transmission path clock. In the retransmission apparatus according to any one of claims 1 to 5,
An output unit for generating and outputting a TS of a third broadcasting system different from the first broadcasting system;
The receiving unit receives and demodulates the TS using the first broadcasting system from the transmitting device,
The clock dividing unit divides the clock of the transmission path by an integer to generate a modulation clock for the first broadcast system, and generates a modulation clock for the third broadcast system,
The speed conversion unit increases the information speed of the first broadcasting system TS demodulated by the receiving unit based on the first broadcasting system modulation clock generated by the clock frequency dividing unit,
The output unit outputs a third broadcasting system TS using the third broadcasting system modulation clock generated by the clock frequency dividing unit;
The time division multiplexing unit inputs the TS of the first broadcasting system whose information speed is increased by the speed conversion unit and the TS of the third broadcasting system output from the output unit, and time-divides these TSs Multiplex and transmit through the transmission path,
A re-transmission apparatus that causes the re-modulation apparatus to generate the first and third modulation clocks using a transmission path clock. The re-transmission apparatus according to claim 1,
The re-transmission apparatus, wherein the rate conversion unit increases the information rate of the TS by replacing some packets constituting the TS demodulated by the reception unit with null packets. A transmission apparatus that transmits a TS, a retransmission apparatus that receives the TS from the transmission apparatus and retransmits a plurality of asynchronous TSs via the transmission path using a transmission path clock; and a plurality of transmission apparatuses from the retransmission apparatus. A re-modulation device that re-modulates a plurality of TSs by regenerating the TS of the transmission path, transmits the re-modulated TSs, and a receiving device that receives the TSs from the re-modulation device. In the remodulation device in a broadcasting system comprising:
A clock recovery unit that receives the TS transmitted by the retransmission apparatus and recovers the clock of the transmission path;
A clock divider for dividing the transmission path clock regenerated by the clock regenerator by an integer to generate a modulation clock;
A separation unit that receives a plurality of TSs from the re-transmission device and separates the TSs based on the clock of the transmission path regenerated by the clock regenerating unit and the modulation clock generated by the clock frequency dividing unit;
A remodulating apparatus comprising: a modulating unit that modulates the TS separated by the separating unit based on the modulation clock generated by the clock dividing unit. The remodulation device according to claim 9, wherein
The modulation unit modulates the TS separated by the separation unit using a transmission parameter of the TS retransmitted by the retransmission device.   A broadcasting system comprising: the retransmitting device according to any one of claims 1 to 8; and the remodulating device according to claim 9 or 10.

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