JP2018137625A - Synchronization processor, signal processing system, synchronization processing method, and synchronization processing program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a synchronization processor capable of preventing occurrence of problems due to processing based on a reference clock signal, even if periods of a clock signal of a transmission source and a reference clock signal generated separately therefrom are different from each other.SOLUTION: A receiving section 11 receives a transmitted frame. A packet included in the received frame is stored in a storage section 13. A transmission frame generating section 14 generates a transmission frame based on the stored packet, at timing based on a reference clock signal. The transmission frame is subjected to modulation processing by modulation means. The reference clock signal is generated separately from the clock signal of the frame transmission source, and is synchronized with the clock signal in the modulation processing. The transmission frame generating section 14 performs addition or deletion of a null type TLV packet, based on a difference of frame reception timing and transmission frame generation timing, and generates a transmission frame.SELECTED DRAWING: Figure 8

Description

  The present invention relates to a synchronization processing device that transmits and receives a frame, a signal processing system, a synchronization processing method, and a program for synchronization processing.

  In satellite broadcasting, a signal based on broadcast data transmitted from a signal processing device of each broadcaster (also referred to as a consignment station) is processed by a signal processing device of a consignment station (also referred to as an uplink station). Sent to broadcast satellite. Each signal processing device of each consignment station and each signal processing device of the consignment station operate at timing based on the clock signal.

  Therefore, the signal processing device of the trust station receives the data transmitted from the signal processing device of each trust station via the communication line, and the data at a timing based on the reference clock signal that is a clock signal used as a reference in the trust station. Is subjected to transmission processing to generate a signal for transmission to the broadcasting satellite.

  Patent Document 1 describes a transmission system that generates and transmits a transmission main signal in which a TLV (Type Length Value) packet is stored in a predetermined slot. Patent Document 1 describes that a transmission slotting device in a transmission system performs processing based on a transmission clock.

  Patent Document 2 describes a method in which a transmitting side synchronizes a reference clock with data transmitted by an NTP (Network Time Protocol) server, transmits information indicating a clock, and a receiving side generates a clock signal based on the information. ing.

  Patent Document 3 describes a system in which a transmission side and a reception side reproduce a clock signal based on data received from a broadcasting satellite.

Japanese Patent Laid-Open No. 2006-174299 JP, 2006-195380, A Japanese Patent No. 5987529

  There may be a difference between the period of each clock signal used in the signal processing apparatus of each consignment station and the period of the reference clock signal used in the signal processing apparatus of the consignment station. Then, a part of the signal to be transmitted in the trust station may be lost. Then, when a signal to be transmitted is partially lost in the trust station, there arises a problem that video and audio based on the signal may be disturbed.

  Therefore, the system described in Patent Document 1 has a problem that video and audio may be disturbed. Further, the system described in Patent Document 2 has a problem that a communication line for transmitting and receiving reference clock information must be prepared, which requires a large amount of cost. In the system described in Patent Document 3, each broadcaster's signal processing device must receive data transmitted by a broadcasting satellite, and there is still a problem that a large amount of cost is required.

  Therefore, the present invention prevents problems caused by processing based on the reference clock signal even when the periods of the clock signal and the separately generated reference clock signal in the transmission source processing are different from each other. An object of the present invention is to provide a synchronization processing device, a signal processing system, a synchronization processing method, and a synchronization processing program.

  A synchronization processing apparatus according to the present invention includes a receiving unit that receives a transmitted frame, a storage unit that stores a packet included in the frame received by the receiving unit, and a reference clock signal that is a reference clock signal Transmission frame generation means for generating a transmission frame based on the packet stored in the storage means at a timing based on the transmission frame, and the transmission frame generated by the transmission frame generation means is subjected to modulation processing by the modulation means. The reference clock signal is a signal generated separately from the clock signal in the generation process and transmission process performed at the transmission source of the frame received by the reception unit, and the transmission frame generation unit generates the reference clock signal. A signal synchronized with the clock signal in the modulation processing applied to the transmission frame, and the transmission frame The frame generation means adds or deletes a null type TLV packet in the packet stored in the storage means based on the difference between the timing at which the receiving means receives the frame and the timing at which the transmission frame is generated. And generating the transmission frame.

  The signal processing system according to the present invention includes any one of the synchronization processing devices and the signal processing device including the modulation unit.

  The synchronization processing method according to the present invention stores a packet included in a frame received in the reception step at a reception step of receiving a transmitted frame and a timing based on a reference clock signal which is a reference clock signal. A transmission frame generation step for generating a transmission frame based on the packet stored in the storage means, wherein the transmission frame generated in the transmission frame generation step is subjected to a modulation process by a modulation means, and the reference clock signal Is a signal generated separately from the generation process performed at the transmission source of the frame received in the reception step and the clock signal in the transmission process, and is applied to the transmission frame generated in the transmission frame generation step. A signal synchronized with the clock signal in the modulation process, In the frame generation step, a null type TLV packet is added to or deleted from the packet stored in the storage means based on the difference between the timing of receiving the frame in the reception step and the timing of generating the transmission frame. The transmission frame is generated.

  A program for synchronization processing according to the present invention is included in a frame received by the reception processing at a timing based on a reception processing for receiving a frame transmitted to a computer and a reference clock signal which is a reference clock signal. A transmission frame generation process for generating a transmission frame based on the packet stored in the storage means for storing the packet, and the transmission frame generated by the transmission frame generation process is subjected to a modulation process by the modulation means. The reference clock signal is a signal generated separately from the generation process performed at the transmission source of the frame received in the reception process and the clock signal in the transmission process, and is generated in the transmission frame generation process. A signal synchronized with a clock signal in the modulation processing applied to the transmission frame Yes, in the transmission frame generation process, a null type TLV packet is added to the packet stored in the storage means based on the difference between the timing of receiving the frame in the reception process and the timing of generating the transmission frame. Alternatively, the transmission frame is generated by performing erasure.

  According to the present invention, it is possible to prevent problems caused by processing based on the reference clock signal even when the clock signal and the reference clock signal generated separately in the transmission source processing have different periods. it can.

It is a block diagram which shows the structural example of the signal processing system of 1st Embodiment. It is a block diagram which shows the structural example of a transmission side signal processing apparatus. It is a block diagram which shows the structure of a synchronous processing apparatus. It is a block diagram which shows the structural example of the receiving side signal processing apparatus. It is a flowchart which shows operation | movement of the transmission side signal processing apparatus. It is a flowchart which shows operation | movement of a synchronous processing apparatus. It is a flowchart which shows operation | movement of the receiving side signal processing apparatus. It is a block diagram which shows the structural example of the synchronous processing apparatus of 2nd Embodiment.

Embodiment 1. FIG.
A first embodiment will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration example of a signal processing system 100 according to the first embodiment.

  As illustrated in FIG. 1, the signal processing system 100 according to the first embodiment includes a synchronization processing device 310 and a reception-side signal processing device 320. The synchronization processing device 310 and the reception side signal processing device 320 are connected to each other. The synchronization processing device 310 and the reception-side signal processing device 320 are connected to the reference clock signal providing device 330. The synchronization processing device 310, the reception side signal processing device 320, and the reference clock signal providing device 330 are installed in the trust station 300.

  For example, a transmission-side signal processing device 210 is connected to the synchronization processing device 310 via a communication line. A clock signal providing device 220 is connected to the transmission side signal processing device 210. The transmission side signal processing device 210 and the clock signal providing device 220 are installed in the consignment station 200.

  The consignment station 200 is, for example, a broadcaster's office. The commissioned station 300 is, for example, a station of a business that transmits a signal to a broadcasting satellite.

  For example, data corresponding to video or audio is input to the transmission-side signal processing device 210. The clock signal providing device 220 is provided with an oscillator that generates a signal having a frequency of 10 MHz, for example. Then, the clock signal providing device 220 generates a clock signal having a frequency such as 33.7561 MHz based on the signal generated by the oscillator, and provides the generated clock signal to the transmission-side signal processing device 210.

  The transmission-side signal processing device 210 generates and transmits an IP (Internet Protocol) packet based on the input data. The signal transmitted by the transmission side signal processing device 210 is received by the synchronization processing device 310 via the communication line.

  The reference clock signal providing device 330 is provided with an oscillator that generates a signal having a frequency of, for example, 5 MHz. Then, the reference clock signal providing device 330 generates a reference clock signal having a frequency such as 33.7561 MHz based on the signal generated by the oscillator, and provides it to the synchronization processing device 310 and the reception side signal processing device 320.

  It is assumed that the oscillator provided in the reference clock signal providing apparatus 330 and the oscillator provided in the clock signal providing apparatus 220 are not subjected to processing for synchronizing with each other. Therefore, the reference clock signal provided by the reference clock signal providing device 330 and the clock signal provided by the clock signal providing device 220 are generated separately from each other.

  Also, as shown in FIG. 1, in this example, for simplicity of explanation, one synchronization processing device 310 installed in one trust station 300 and one transmission side signal installed in one trust station 200 are used. A description will be given assuming that the processing device 210 is connected. However, a plurality of transmission side signal processing devices installed in each of a plurality of consignment stations may be connected to the synchronization processing device 310 installed in the consignment station 300.

  The synchronization processing device 310 receives the IP packet transmitted by the transmission side signal processing device 210. Then, the synchronization processing device 310 performs pseudo synchronization processing on the IP packet. The pseudo-synchronization process is a process for making it possible to cope with an operation based on the reference clock signal by the reception-side signal processing device 320.

  Then, the reception-side signal processing device 320 generates a transmission signal based on the IP packet that has been subjected to the pseudo-synchronization processing by the synchronization processing device 310.

  The generated transmission signal is transmitted by the transmission facility 340 toward the broadcasting satellite. Then, the broadcast satellite that has received the transmission signal transmits a broadcast signal based on the transmission signal, and the receiver that has received the broadcast signal reproduces video and audio based on the broadcast signal, or for data broadcasting. Data, program layout information, electronic program guides, etc. are output. The transmission facility 340 includes, for example, a satellite communication antenna installed outside the station building of the trust station 300.

  FIG. 2 is a block diagram illustrating a configuration example of the transmission side signal processing device 210. As illustrated in FIG. 2, the transmission-side signal processing device 210 includes an MMT (Moving Picture Experts Group) media transport (MMT) multiplexing unit 211 and a TLV multiplexing unit 212.

  The MMT multiplexing unit 211 includes reproduction data, which is data corresponding to video and audio reproduced by the receiver, data broadcasting data, program arrangement information, and electronic program guide (SI (Service Information) / EPG (Electronic). Program Guide)) data is input.

  Then, the MMT multiplexing unit 211 multiplexes the input data, and generates an MMT packet that is an MMT format IP packet including the data.

  To the TLV multiplexing unit 212, the MMT packet generated by the MMT multiplexing unit 211 and the NTP packet including data indicating time are input. The NTP packet is received from an external NTP server, for example. The TLV multiplexing unit 212 multiplexes the input MMT packet and the NTP packet with each other, and generates a TLV packet that is an IP packet including the packet.

  Then, the TLV multiplexing unit 212 synchronizes a frame configured by the generated TLV packet and a TMCC (Transmission and Multiplexing Configuration Control) signal indicating information of a stream type and a modulation scheme of each slot in the frame. To 310.

  FIG. 3 is a block diagram illustrating a configuration of the synchronization processing device 310. As illustrated in FIG. 3, the synchronization processing device 310 includes a reception unit (reception unit) 311, a distribution unit 312, buffer units (storage units) 313-1 to n, a multiplexing unit (transmission frame generation unit) 314, and a transmission Part 315.

  The receiving unit 311 receives the frame and the TMCC signal transmitted from the transmission side signal processing device 210 via the communication line. The reception unit 311 inputs the received frame and TMCC signal to the distribution unit 312.

  The distribution unit 312 inputs the TLV packet included in the input frame to the buffer units 313-1 to 313-n according to the input TMCC signal.

  Input TLV packets are stored in the buffer units 313-1 to n. Note that the buffer units 313-1 to 313-n are prepared according to the modulation method applied to the TLV packet by the reception-side signal processing device 320. Specifically, for example, the reception-side signal processing device 320 stores a buffer that stores a TLV packet that performs modulation using a QPSK (Quadrature Phase-Shift Keying) method, or a TLV that performs modulation using an 8PSK (Phase-Shift Keying) method. A buffer for storing a packet and a buffer for storing a TLV packet subjected to 16PSK modulation are prepared.

  The multiplexing unit 314 reads the TLV packet stored in the buffer units 313-1 to 313-n, and generates a transmission frame including the read TLV packet.

  The transmission unit 315 transmits the transmission frame generated by the multiplexing unit 314 to the reception-side signal processing device 320.

  The receiving unit 311 and the transmitting unit 315 are realized by a communication module, for example. The distribution unit 312 and the multiplexing unit 314 are realized by, for example, a CPU (Central Processing Unit) that executes processing according to program control and a plurality of circuits. The buffer units 313-1 to n are realized by storage means such as a memory, for example.

  FIG. 4 is a block diagram illustrating a configuration example of the reception-side signal processing device 320.

  As illustrated in FIG. 4, the reception-side signal processing device 320 includes a reception unit 321, a modulation unit 322, and a transmission unit 323.

  The reception unit 321 receives the transmission frame transmitted by the transmission unit 315 of the synchronization processing device 310.

  The modulation unit 322 performs a modulation process of a predetermined modulation method on the transmission frame received by the reception unit 321 and generates a transmission signal that is a signal after the modulation process.

  The transmission unit 323 transmits the transmission signal generated by the modulation unit 322.

  Next, the operation of the first embodiment will be described. FIG. 5 is a flowchart showing the operation of the transmission side signal processing apparatus 210.

  Note that the MMT multiplexing unit 211 and the TLV multiplexing unit 212 in the transmission side signal processing device 210 perform each process at a timing based on the clock signal provided by the clock signal providing device 220.

  The MMT multiplexing unit 211 multiplexes the reproduction data, data broadcasting data, program arrangement information, and electronic program guide data, and generates an MMT packet that is an IP packet in the MMT format including each data. (Step S101).

  The TLV multiplexing unit 212 multiplexes the MMT packet and the NTP packet generated by the MMT multiplexing unit 211 in the process of step S101, and generates a TLV packet that is an IP packet including the packet (step S102). .

  Then, the TLV multiplexing unit 212 configures a frame with the generated TLV packet, and transmits the configured frame and the TMCC signal indicating the stream type and modulation scheme information of each slot in the frame to the synchronization processing device 310. Transmit (step S103).

  FIG. 6 is a flowchart showing the operation of the pseudo-synchronization processing by the synchronization processing device 310. Note that the synchronization processing device 310 performs each process at a timing based on the reference clock signal provided by the reference clock signal providing device 330.

  As illustrated in FIG. 6, the reception unit 311 receives the frame and the TMCC signal transmitted by the transmission-side signal processing device 210 via the communication line (step S201). The reception unit 311 inputs the received frame and TMCC signal to the distribution unit 312.

  The distribution unit 312 inputs the TLV packet included in the input frame to the buffer units 313-1 to n in accordance with the input TMCC signal (step S202). The TLV buckets input to the buffer units 313-1 to n are stored in the buffer units 313-1 to n. For example, the distribution unit 312 receives the TLV packet included in the input frame according to the information on the modulation scheme of the stream of each slot in the frame, which is indicated by the TMCC signal. ˜n are input to a buffer corresponding to the corresponding modulation method. Specifically, for example, the distribution unit 312 can transmit a TLV packet based on an NTP packet in accordance with a TMCC signal, such as QPSK, which is a modulation scheme that can transmit data more reliably even when radio wave propagation conditions deteriorate. Input to the buffer corresponding to the modulation method with the smaller number of values. Further, for example, according to the TMCC signal, the distribution unit 312 inputs a TLV packet based on the MMT packet to a buffer corresponding to a modulation scheme having a larger multi-level number such as 16PSK which is a modulation scheme having higher transmission efficiency. .

  The multiplexing unit 314 generates a transmission frame including the TLV packets stored in the buffer units 313-1 to n (step S203). In this example, it is assumed that the transmission frame includes 120 slots. Then, the multiplexing unit 314 configures a transmission frame so that a predetermined packet is stored in a predetermined slot, for example.

  Here, when the packets for configuring the transmission frame are not stored in the corresponding buffer units 313-1 to 313-1, that is, when the packets for configuring the transmission frame are insufficient, the multiplexing unit 314 Then, a null type TLV packet (TLV Null) having a length corresponding to the shortage is generated, and a transmission frame including the packet is generated. The multiplexing unit 314 is configured to change the length of the null type TLV packet to a length that satisfies the shortage when the null type TLV packet is stored in the buffer units 313-1 to n. It may be.

  Note that the shortage of packets for constructing a transmission frame is caused by the frequency of the clock signal provided by the clock signal providing device 220 of the consignment station 200 being the frequency of the reference clock signal provided by the reference clock signal providing device 330 of the consignment station 300. It can occur when it becomes lower.

  In other words, the shortage of packets for constructing the transmission frame means that the period of the clock signal provided by the clock signal providing device 220 of the entrusting station 200 is equal to the reference clock signal provided by the reference clock signal providing device 330 of the entrusting station 300. It can occur when the period becomes longer than

  However, this process can solve the problem of a shortage of packets for configuring the transmission frame.

  Also, when packets are input at an interval shorter than the interval at which the multiplexing unit 314 reads packets from the buffer units 313-1 to n to form a transmission frame, that is, input to the buffer units 313-1 to n. When a remainder occurs in the received packet, the multiplexing unit 314 deletes at least a part of the null-type TLV packet (TLV Null) in the input packet and includes the remaining packet. Generate a frame. The multiplexing unit 314 is configured to change the length of the null type TLV packet to a length that eliminates the surplus when the null type TLV packet is stored in the buffer units 313-1 to n. It may be.

  The generation of surplus packets is such that the frequency of the clock signal provided by the clock signal providing device 220 of the entrusting station 200 is higher than the frequency of the reference clock signal provided by the reference clock signal providing device 330 of the entrusting station 300. Sometimes it can happen.

  In other words, the shortage of packets for constructing the transmission frame means that the period of the clock signal provided by the clock signal providing device 220 of the entrusting station 200 is equal to the reference clock signal provided by the reference clock signal providing device 330 of the entrusting station 300. This can occur when the period is shorter than

  This processing can solve the problem that a surplus packet is generated when a transmission frame is generated.

  That is, in the process of step S203, the TLVs stored in the buffer units 313-1 to n are based on the difference between the timing at which the receiving unit 311 receives the frame and the timing at which the multiplexing unit 314 generates the transmission frame. In the packet, the null type TLV packet is added or deleted, or the length of the null type TLV packet is changed.

  In addition, the multiplexing unit 314 stores the TLV packet corresponding to the NTP packet stored in the buffer having a smaller multi-value number in the buffer unit 313-1 to n in the 101st slot which is a predetermined slot. The transmission frame is configured as described above.

  The transmission unit 315 transmits the transmission frame generated by the process of step S203 to the reception-side signal processing device 320 (step S204).

  FIG. 7 is a flowchart showing the operation of the reception-side signal processing device 320. The reception-side signal processing device 320 performs each process at a timing based on the reference clock signal provided by the reference clock signal providing device 330.

  As illustrated in FIG. 7, the reception unit 321 receives the transmission frame transmitted by the transmission unit 315 of the synchronization processing device 310 (step S301).

  Based on the transmission frame received by the reception unit 321, the modulation unit 322 performs modulation processing of a predetermined modulation method on the carrier wave, and generates a transmission signal that is a signal after modulation processing (step S <b> 302).

  The transmission unit 323 transmits the transmission signal generated by the modulation unit 322 (step S303).

  According to the present embodiment, the transmission-side signal processing device 210 and the reception-side signal processing device 320 each operate based on the separately generated clock signals, and there is a difference in the cycle of the clock signals. However, the synchronization processing device 310 generates a transmission frame corresponding to the frame received from the transmission side signal processing device 210 based on the reference clock signal that is a clock signal in the reception side signal processing device 320.

  Therefore, even if there is a difference between the cycle of the clock signal of the transmission side signal processing device 210 and the cycle of the reference clock signal of the reception side signal processing device 320, some of the signals to be transmitted at the trust station It can be prevented from disappearing. Therefore, it is possible to prevent the occurrence of a problem that the video and audio based on the signal may be disturbed when the signal to be transmitted is partially lost in the trust station.

Embodiment 2. FIG.
Next, a synchronization processing device 31 according to the second embodiment will be described with reference to the drawings. FIG. 8 is a block diagram illustrating a configuration example of the synchronization processing device 31 according to the second embodiment.

  As illustrated in FIG. 8, the synchronization processing device 31 according to the second embodiment includes a reception unit 11, a storage unit 13, and a transmission frame generation unit 14.

  The synchronization processing device 31 corresponds to, for example, the synchronization processing device 310 in the first embodiment illustrated in FIGS. 1 and 3. The receiving unit 11 corresponds to, for example, the receiving unit 311 in the first embodiment illustrated in FIG. The storage unit 13 corresponds to, for example, the buffer units 313-1 to n in the first embodiment illustrated in FIG. The transmission frame generation unit 14 corresponds to, for example, the multiplexing unit 314 in the first embodiment illustrated in FIG.

  The receiving unit 11 receives the transmitted frame.

  The storage unit 13 stores a packet included in the frame received by the reception unit 11.

  The transmission frame generation unit 14 generates a transmission frame based on the packet stored in the storage unit 13 at a timing based on a reference clock signal that is a reference clock signal.

  The transmission frame generated by the transmission frame generation unit 14 is subjected to modulation processing by the modulation means. The modulation means corresponds to, for example, the modulation unit 322 of the reception-side signal processing device 320 in the first embodiment shown in FIG.

  The reference clock signal is a signal generated separately from the generation process performed at the transmission source of the frame received by the reception unit 11 and the clock signal in the transmission process, and the transmission clock generated by the transmission frame generation unit 14 It is a signal synchronized with the clock signal in the applied modulation process.

  Note that the transmission source of the frame received by the reception unit 11 corresponds to, for example, the transmission-side signal processing device 210 in the first embodiment. The generation process and the transmission process performed on the frame received by the reception unit 11 correspond to, for example, the process of step S103 illustrated in FIG.

  The transmission frame generation unit 14 adds or deletes the null type TLV packet in the packet stored in the storage unit 13 based on the difference between the timing at which the reception unit 11 receives the frame and the timing at which the transmission frame is generated. To generate a transmission frame.

  According to the present embodiment, the frame processing source and the modulation unit operate based on the separately generated clock signals, respectively, and even if there is a difference between the periods of the clock signals, the synchronization processing device 31 generates a transmission frame corresponding to the received frame based on a reference clock signal which is a clock signal synchronized with the clock signal of the modulation means.

  Therefore, even if there is a difference between the period of the clock signal that is the transmission source of the frame and the period of the reference clock signal, it is possible to prevent a part of the frame-based signal to be transmitted from being lost or the like. be able to. Therefore, it is possible to prevent the occurrence of a problem that a video or audio based on the signal may be disturbed due to a part of the signal based on the frame to be transmitted or the like being lost.

DESCRIPTION OF SYMBOLS 100 Signal processing system 200 Consignment station 210 Transmission side signal processing apparatus 211 MMT multiplexing part 212 TLV multiplexing part 220 Clock signal provision apparatus 300 Trust station 310 Synchronous processing apparatus 311, 321 Receiving part 312 Distribution part 313-1 to 313-n Buffer part 314 Multiplexer 315, 323 Transmitter 320 Receiving side signal processor 322 Modulator 330 Clock signal provider 340 Transmission equipment

Claims (9)

Receiving means for receiving the transmitted frame;
Storage means for storing a packet included in a frame received by the receiving means;
Transmission frame generation means for generating a transmission frame based on a packet stored in the storage means at a timing based on a reference clock signal that is a reference clock signal;
The transmission frame generated by the transmission frame generation means is subjected to modulation processing by a modulation means,
The reference clock signal is a signal generated separately from a generation process performed at a transmission source of a frame received by the reception unit and a clock signal in the transmission process, and the transmission generated by the transmission frame generation unit A signal synchronized with the clock signal in the modulation processing applied to the frame,
The transmission frame generation means includes
Based on the difference between the timing at which the receiving means receives the frame and the timing at which the transmission frame is generated, a null type TLV packet is added to or deleted from the packet stored in the storage means, and the transmission frame is A synchronous processing device characterized by generating. The transmission frame generation unit generates a null type TLV packet having a length corresponding to the shortage when the packet for configuring the transmission frame is insufficient in the storage unit, and includes the TLV packet. The synchronization processing device according to claim 1. The transmission frame generation means deletes a null type TLV packet having a length corresponding to the remainder when a remainder is generated in the packet for constituting the transmission frame in the storage means, and a remaining TLV packet is obtained. The synchronization processing apparatus according to claim 1, wherein a transmission frame including the synchronization frame is generated. The transmission frame generation means, when a null type TLV packet is stored in the storage means, based on the difference between the timing at which the reception means receives the frame and the timing at which the transmission frame is generated, The synchronization processing apparatus according to claim 1, wherein a length of the null type TLV packet is changed instead of the erasure. The transmission frame generation unit changes the length of the null type TLV packet to a length that satisfies the shortage when the packet for configuring the transmission frame is insufficient in the storage unit, and the TLV packet The synchronization processing device according to claim 4, wherein a transmission frame including The transmission frame generation means changes the length of the null type TLV packet to a length that eliminates the remainder when a remainder occurs in the packet for constituting the transmission frame in the storage means, The synchronization processing device according to claim 4 or 5, wherein a transmission frame including a TLV packet is generated. A synchronization processing device according to any one of claims 1 to 6,
And a signal processing device including the modulation means. A receiving step for receiving the transmitted frame;
Transmission frame generation for generating a transmission frame based on a packet stored in a storage means in which a packet included in the frame received in the reception step is stored at a timing based on a reference clock signal that is a reference clock signal Including steps,
The transmission frame generated in the transmission frame generation step is subjected to modulation processing by a modulation means,
The reference clock signal is a signal generated separately from the clock signal in the generation process and transmission process performed at the transmission source of the frame received in the reception step, and the transmission generated in the transmission frame generation step It is a signal synchronized with the clock signal in the modulation process applied to the frame,
In the transmission frame generation step,
Based on the difference between the timing of receiving the frame in the receiving step and the timing of generating the transmission frame, a null type TLV packet is added to or deleted from the packet stored in the storage means, and the transmission frame is A synchronization processing method characterized by generating. On the computer,
A receiving process for receiving the transmitted frame;
Transmission frame generation for generating a transmission frame based on a packet stored in a storage unit in which a packet included in the frame received in the reception process is stored at a timing based on a reference clock signal that is a reference clock signal Process and
The transmission frame generated by the transmission frame generation processing is subjected to modulation processing by a modulation means,
The reference clock signal is a signal generated separately from the generation process performed at the transmission source of the frame received in the reception process and the clock signal in the transmission process, and is generated in the transmission frame generation process. It is a signal synchronized with the clock signal in the modulation process applied to the transmission frame,
In the transmission frame generation process,
Based on the difference between the timing of receiving the frame in the reception process and the timing of generating the transmission frame, a null type TLV packet is added to or deleted from the packet stored in the storage means, and the transmission frame is A program for synchronous processing to generate.

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