JP2009218732A - Transmission system, communication apparatus, transmission method, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform restoration from a trouble for transmission routes, without impairing simultaneous outputs, in a transmission system with sink apparatuses which are connected in a daisy chain, and to perform simultaneous outputting of data. <P>SOLUTION: In the transmission system in which a plurality of sink apparatuses are separated into two routes for a source apparatus and are connected in a daisy-chain fashion, the system can perform restoration from a trouble for the transmission routes, without impairing simultaneous outputs, even if the trouble of the transmission routes occurs, by calculating and notifying the output correction time which is assigned to the respective sink apparatus, in order to perform synchronous outputtings, based on respective internal processing delay times in network topologies and the sink apparatus, after circumventing the trouble of the transmission routes. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a transmission system, a communication apparatus, a transmission method, and a program, and is particularly suitable for use in a transmission system in which a plurality of sink devices are daisy chain connected to a source device.

  As a configuration example of a data transmission system having simultaneous output means by daisy chain connection, there is a surround system using a communication system conforming to the IEEE 1394 standard as shown in FIG.

  In FIG. 13, 3000 is an AV amplifier. The AV amplifier 3000 decodes audio data sent from a DVD player, a TV, and the like, performs digital-analog (D / A) conversion processing, amplification processing, and the like, and transmits them to the speakers 3001 to 3006.

  Reference numerals 3001 to 3006 denote six speakers (SP) constituting a 5.1 channel surround system. For example, 3001 is a subwoofer, 3002 is a center SP, 3003 is a main SP (L channel), 3004 is a main SP (R channel), 3005 is a rear SP (L channel), and 3006 is a rear SP (R channel).

  The AV amplifier 3000 and the speakers 3001 to 3006 are communicably connected via SP cables 3101 to 3105. In the example shown in FIG. 13, speakers 3003, 3001, and 3005 are daisy chain connected to the AV amplifier 3000, and the speakers 3002, 3004, and 3006 are daisy chain connected.

  In the data transmission system configured as shown in FIG. 13, for example, when the cable 3100 has a fault such as disconnection, it is not possible to transmit audio data to the subwoofer 3001, the speaker 3003, and the speaker 3005. End up. As a conventional example of a data transmission system using a daisy chain connection in which measures against such a transmission path failure are taken, there is a network described in Patent Document 1 below.

  The network connected in a daisy chain described in the first embodiment in Patent Document 1 includes a spare wiring for connecting terminal nodes to each other. This spare wiring is not used for communication in the normal state, and when a network failure such as disconnection occurs, the spare wiring can be used for communication to ensure communication with all nodes and to restore the network failure. It can be done.

  Further, in a data transmission system such as the surround system shown in FIG. 13, it is necessary to output predetermined data simultaneously. However, each speaker 3001 to 3006 has a unique delay time. Therefore, even if the AV amplifier 3000 transmits the respective data to the speakers 3001 to 3006 at the same time, the time until the speakers 3001 to 3006 output predetermined data does not match. In order for the speakers 3001 to 3006 to output predetermined data at the same time, it is necessary to perform time alignment taking into account signal processing inside the speakers and delay time in the transmission path.

  Incidentally, a data transmission system having means for simultaneously outputting a video signal and an audio signal is described in Patent Document 2 below. The multimedia data playback apparatus described in Patent Document 2 has a storage unit that stores a delay time from when a video signal and an audio signal are transmitted until the video and audio are output to a playback device. Simultaneous reproduction is possible by matching the timing at which data is played back by each playback device to the playback device having the longest delay time (maximum delay time) stored in the storage means. In addition, even if the playback device is switched during playback of multimedia data, the media data can be simultaneously output while maintaining continuity.

Japanese Patent No. 3745770 JP 2006-197013 A

  In the surround system shown in FIG. 13, when a transmission line failure as described above occurs, the entire network can be recovered by using the conventional transmission line failure recovery method described in Patent Document 1. . However, the network topology changes with recovery. Each device has its own delay time, and the transmission path is changed by changing the network topology. Therefore, the maximum delay time of the entire network also changes according to the network topology. Therefore, in a data transmission system that realizes simultaneous output based on the maximum delay time, simultaneous output is not guaranteed if the maximum delay time changes. In the technique described in Patent Document 2, a change in the maximum delay time caused by switching of the playback device is taken into consideration, but a plurality of playback devices connected in a daisy chain like the surround system shown in FIG. 13 are installed. The case is not considered.

  An object of the present invention is to make it possible to recover a transmission path failure without impairing simultaneous output in a transmission system having a plurality of sink devices that are daisy chain connected and simultaneously output data.

The transmission system of the present invention includes a source device, one or more sink devices connected in a daisy chain to the first interface of the source device, and one or more connected in a daisy chain to the second interface of the source device. A transmission system having a sink device, wherein the source device avoids the transmission path failure based on a first detection means for detecting a transmission path fault and a detection result of the first detection means. The sink device outputs data from the source device based on a determination unit that determines the network topology after the determination, and the network topology determined by the determination unit and the internal processing delay time of each of the sink devices Output delay time and the output correction time allocated to each sink device to synchronize the data output. Characterized in that it has a calculation means for, and a notification means for notifying the sink device output correction time calculated by said calculating means.
The communication device of the present invention is a communication device for transmitting data to a plurality of sink devices connected to a first interface and a second interface for daisy chain connection of one or more sink devices, and a transmission path failure Determined by the first detection means, the determination means for determining the network topology after avoiding the transmission path failure based on the detection result of the first detection means, and the determination means Based on the network topology and the internal processing delay time of each sink device, the maximum delay time until the sink device outputs data from the communication device and the output assigned to each sink device to synchronize the data output Calculation means for calculating the correction time, and notification for notifying each sink device of the output correction time calculated by the calculation means And having a stage, a.
The transmission method according to the present invention includes a source device, a sink device daisy chained to the first interface of the source device, and a sink device daisy chained to the second interface of the source device. In the transmission method of simultaneously outputting data from the source device by each sink device, a detection step of detecting a failure of the transmission path of the data, and a failure of the transmission path detected in the detection step In order to synchronize the maximum delay time until the sink device outputs data from the source device and the output of the data based on the avoided network topology and the internal processing delay time of each of the sink devices, A calculation step for calculating an output correction time to be assigned; And having a notification step of notifying the output correction time to each sink device.
The program of the present invention is a transmission system having a source device, a sink device daisy chained to the first interface of the source device, and a sink device daisy chained to the second interface of the source device. A program for causing a computer to execute control to simultaneously output data from the source device by each sink device, the detection step detecting a failure in the data transmission path, and the detection step The maximum delay time until the sink device outputs data from the source device and the data output are synchronized based on the network topology that avoids the failure of the transmission path and the internal processing delay time of each of the sink devices. Output correction time allocated to each sink device A calculating step of calculating, wherein the output correction time calculated in said calculation step be executed and a notification step of notifying each sink device to the computer.

  According to the present invention, the output timing of data from each sink device is adjusted based on the network topology after avoiding a failure in the transmission path. Thereby, even if a failure occurs in the transmission line, the transmission line failure in the transmission system can be recovered without impairing the simultaneous output.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
A first embodiment of the present invention will be described.
FIG. 1 is a diagram illustrating a configuration example of a transmission system according to the first embodiment. The transmission system in the present embodiment performs data transmission by a time division multiplexing method. In FIG. 1, 10 is a source device, and 100a, 100b, 100c, and 100d are sink devices. The source device 10 and the sink devices 100a to 100d are communicably connected via transmission lines 1 to 4.

  In the example illustrated in FIG. 1, sink devices 100 a to 100 d are connected to the source device 10 in two paths. Specifically, sink devices 100 a and 100 b are daisy chain connected to the first interface (output terminal) 30 of the source device 10 via the transmission paths 1 and 2. In addition, sink devices 100 c and 100 d are daisy chain connected to the second interface (output terminal) 31 of the source device 10 via the transmission lines 3 and 4. The sink devices 100b and 100d at the end of the sink devices connected in a daisy chain are connected by a transmission path 5 set as a backup line (backup transmission path). Here, the standby line 5 is in a communication activated state in which communication is disconnected in an initial state, that is, in a communication inactivated state in which communication is impossible, and communication is possible in accordance with a command from the source device or sink device. .

  Further, the source device 10 and each of the sink devices 100a to 100d transmit and receive diagnostic signals to each other at regular time intervals, and detect the occurrence of a failure in the transmission path and the location of the occurrence based on the result of success or failure of detection of the diagnostic signal. Do. In the present embodiment, each diagnostic signal has uniqueness, and each device can determine which device has received the diagnostic signal. The source device 10 and each of the sink devices 100a to 100d may transmit / receive a diagnostic signal at an arbitrary timing without cooperation, or each of the sink devices 100a to 100d responds to the diagnostic signal from the source device 10. A diagnostic signal may be transmitted to the source device 10.

  The transmission path switches 12, 12 'and 102a to 102d, which are the first transmission path control means and the second transmission path control means, are switches that physically connect or disconnect each device and the transmission path. In the initial state, the transmission line switches 12, 12 ', 102a and 102c are in a closed state (transmission line connection state), and the transmission line switches 102b and 102d are in an open state (transmission line disconnection state). In this way, in the initial state, the transmission lines 1 to 4 other than the spare transmission line are set in the communication activated state, and the spare line 5 is held in the communication inactivated state.

  The high-frequency crosspoint switches 103a to 103d and 103a 'to 103d' are for switching the modems 101a to 101d and 101a 'to 101d'. By switching the high-frequency crosspoint switches 103a to 103d and 103a 'to 103d', the input / output direction of data (signal), that is, the data transmission direction is switched.

  The transmission line switches 12, 12 ′, 102a to 102d, and the high-frequency cross point switches 103a to 103d and 103a ′ to 103d ′ are respectively the control units 14 and 104a to 104d of the devices 10 and 100a to 100d in which the transmission line switches are provided. Controlled by.

The source device 10 further includes a storage unit 13, a signal processing unit (first detection unit, determination unit) 15, a calculation unit (calculation unit) 16, a signal generation unit (notification unit) 20, and a source generation unit 21.
The storage unit 13 stores information on the network topology of the entire data transmission system and internal processing delay times of the sink devices 100a to 100d described later. FIG. 2 is a diagram illustrating a configuration example of a table stored in the storage unit 13. As shown in FIG. 2, the table includes internal processing delay time, hierarchy information, and connected output terminal information related to each sink device.

  Here, the hierarchy information indicates the number of hops from the source device 10 to each of the sink devices 100a to 100d. The hierarchical information is investigated as follows, for example. First, the source device 10 transmits a layer command with layer code = 0 to the sink devices 100a and 100c, respectively. Each of the sink devices 100 a and 100 c that have received the layer command returns a layer code = 1 obtained by adding 1 to the layer code of the received layer command to the source device 10. At the same time, the sink devices 100a and 100c transmit a layer command with layer code = 1 to the sink devices 100b and 100d connected to the next stage. Each of the sink devices 100b and 100d that have received the layer command with the layer code = 1 from the sink devices 100a and 100c returns to the source device 10 the layer code = 2 obtained by adding 1 to the layer code of the received layer command. In this way, each of the sink devices 100 a to 100 d can transmit its own hierarchy to the source device 10.

In FIG. 2, the output terminal indicates which of the output terminals 30 as the first interface or the output terminal 31 as the second interface is connected to each of the sink devices 100a to 100d. ing.
Based on this hierarchical information and information on the output terminals, the source device 10 can grasp the network topology of the entire transmission system.

  The signal processing unit 15 detects a diagnostic signal and an internal processing delay time notification transmitted from each of the sink devices 100a to 100d. Based on the detection result, the signal processing unit 15 transmits a command to the control unit 14 and rewrites (updates) the information on the network topology stored in the storage unit 13 and the internal processing delay time of each sink device. Or

  The calculation unit 16 calculates the maximum delay time in the entire transmission system using the information on the network topology and the internal processing delay time stored in the storage unit 13. Further, the calculation unit 16 calculates the output correction time of each of the sink devices 100a to 100d based on the calculated maximum delay time.

  The signal generation unit 20 includes various command generation units 17, a frame configuration unit 18, and a diagnostic signal generation unit 19. The various command generation unit 17 serving as notification means includes various commands to the sink devices 100a to 100d such as a transmission line activation / deactivation command (transmission channel connection command / transmission channel disconnection command), a delay time notification command, and an output correction command. Is generated.

The frame configuration unit 18 time-divides the digital data from the source generation unit 21 for each slot assigned to each sink device 100a to 100d, arranges the data in the slot, and transmits it to each sink device ( Data frame). When the digital data from the source generation unit 21 is time-divided for each slot and arranged in the slot, the frame configuration unit 18 selects and arranges the optimal frame configuration.
The diagnostic signal generator 19 generates a diagnostic signal and transmits it to each sink device 100a to 100d.

  The source generation unit 21 generates digital data to be output simultaneously by the sink devices 100a to 100d. In the example illustrated in FIG. 1, the source generation unit 21 is provided inside the source device 10, but may be provided outside the source device 10.

  The signal processing units (second detection means) 105a to 105d of the sink devices 100a to 100d detect a diagnostic signal transmitted from the source device 10 and process various commands. In addition, the signal processing units 105a to 105d perform processing such as extracting data from a slot assigned to itself included in the received synchronous transmission frame (data frame) and transmitting the data to the next sink device.

The delay time adjustment units 106a to 106d serving as output correction means correct the delay time from when the data to be output is transmitted from the source device 10 to when it is output, based on the set output correction time. When the data is received, the output units 107a to 107d output predetermined data after the set output correction time has elapsed.
The delay time notification units 108a to 108d respond to the source device 10 with their own internal processing delay time in response to the delay time notification command. The diagnostic signal generators 109 a to 109 d generate a diagnostic signal to be transmitted to the source device 10.

<Transmission path failure recovery operation (transmission path failure avoidance operation)>
Hereinafter, a recovery operation (avoidance operation) when a failure occurs in the transmission path in the transmission system according to the present embodiment will be described.
FIG. 3A and FIG. 3B are flowcharts showing the operation from when a failure occurs in the transmission path until the recovery is completed. In the following, for the sake of convenience, a recovery operation when a failure occurs in the transmission line 2 in the transmission system illustrated in FIG. 1 will be described as an example.

First, an operation performed by the source device 10 when a failure occurs in the transmission path 2 will be described with reference to FIG. 3A.
When a failure occurs in the transmission path 2, the signal processing unit 15 of the source device 10 cannot detect a diagnostic signal from the transmission path 2 or lower where the failure occurs, that is, the sink device 100b, and detects the occurrence of the failure. (Step S1). Here, since each diagnostic signal has uniqueness, the signal processing unit 15 detects that the diagnostic signal from the sink device 100b has not been received and determines that a failure has occurred in the transmission path 2. .

  Based on the detection result, the signal processing unit 15 rewrites the network topology stored in the storage unit 13 to the network topology after the failure occurs (step S2). Subsequently, the various command generation unit 17 determines whether or not the transmission path in which the failure has occurred is a transmission path connected to the source device 10 itself (step S3). Here, since the transmission path 2 is not directly connected to the source device 10, the various command generation units 17 issue a transmission path activation / deactivation command (transmission path disconnection command) for physically disconnecting the transmission path 2. It is generated and transmitted to the sink device 100a (step S5).

  When a failure occurs in the transmission line 1 directly connected to the source device 10 instead of the transmission line 2, the control unit 14 of the source device 10 opens the transmission line switch 12 and passes through the transmission line 1. The transmission line 1 is disconnected so that the communication that has been performed becomes impossible (step S4).

  After transmitting the transmission path disconnection command to the sink device 100a, the various command generation units 17 generate a transmission path activation inactivation command (transmission path connection command) for bringing the standby line 5 into a communication activation state. Then, the various command generation unit 17 transmits the generated transmission path connection command to the sink device 100d to which the backup line 5 is connected via the sink device 100c (step S6).

  Next, an operation performed by the sink device 100b when a failure occurs in the transmission path 2 will be described with reference to FIG. 3B.

  When a failure occurs in the transmission path 2, the signal processing unit 105b of the sink device 100b cannot detect the diagnostic signal from the source device 10, and detects the occurrence of the failure (step S11).

  When the signal processing unit 105b detects the occurrence of a failure because the diagnosis signal from the source device 10 cannot be detected, the signal processing unit 105b notifies the control unit 104b of the failure detection. Receiving the notification of the failure detection, the control unit 104b first switches the data transmission direction using the high-frequency crosspoint switches 103b and 103b ′ (step S16).

  Next, the signal processing unit 105b determines whether or not the backup line 5 is connected to the own device (step S17). Since the standby line 5 is connected to the sink device 100b, the control unit 104b closes the transmission line switch 102b to activate the standby line 5 based on an instruction from the signal processing unit 105b. (Step S18).

  When a failure occurs in the transmission path 1 that is not directly connected to the sink device 100b instead of the transmission path 2, the sink device 100a and the sink device 100b can detect the diagnostic signal from the source device 10. Therefore, the recovery operation is performed by detecting the occurrence of a failure. Here, the recovery operation performed by the sink device 100b is the same as the recovery operation when a failure occurs in the transmission path 2 described above. However, since the sink device 100a does not have a transmission line set as a backup line, the control unit 104a only switches the data transmission direction (step S16) and does not control the transmission line switch 102a.

Finally, operations performed by the sink devices 100a, 100c, and 100d other than the sink device 100b when a failure occurs in the transmission path 2 will be described with reference to FIG. 3B.
The signal processing unit 105a of the sink device 100a that has received the transmission path activation / deactivation command (transmission path disconnection command) transmitted from the source device 10 in step S5 illustrated in FIG. 3A sends a transmission path disconnection command to the control unit 104a. Send. Upon receiving this transmission path disconnection command, the control unit 104a opens the transmission path switch 102a (steps S12 and S13). By this operation, the transmission path 2 in which a failure has occurred can be physically disconnected. Thereby, for example, the transmission path 2 in which the failure has occurred can be repaired or replaced without stopping the data transmission system. Here, the reason for disconnecting the transmission path in which the failure has occurred is that there is a possibility that data collision may occur through the transmission path when the failure is recovered at some moment.

Further, the signal processing unit 105d of the sink device 100d that has received the transmission path activation inactivation command (transmission path connection command) transmitted from the source device 10 in step S6 illustrated in FIG. 3A connects the transmission path to the control unit 104d. Send instructions. Upon receiving this transmission path connection command, the control unit 104d closes the transmission path switch 102d (steps S14 and S15). The sink devices 100b and 100d are physically connected through the backup line 5 by the operations in steps S15 and S18 described above. That is, the standby line 5 can be activated.
On the other hand, since the sink device 100c does not receive either the transmission line disconnection instruction or the transmission line connection instruction, no operation other than the normal operation is performed.

  As described above, the source device 10 and each of the sink devices 100a to 100d perform the series of recovery operations shown in FIGS. 3A and 3B, so that the transmission path in which the failure has occurred can be bypassed, and the data transmission system Can be automatically recovered. Further, after the restoration, the transmission path in which the failure has occurred is maintained in the communication inactive state, so that the transmission path in which the failure has occurred can be replaced with a new transmission line without stopping the operation of the system. When a transmission path in which a failure has occurred is replaced with a new transmission path, the replaced new transmission path is maintained in a communication inactive state during system operation. However, by restarting the data transmission system by the initial setting operation of the spare line described later, the new transmission line is maintained in the communication activated state, and the spare line in the communication activated state is deactivated again. Kept in a state.

<Initial setting of spare line>
In order to perform the transmission line failure recovery operation as described above, it is necessary to set which transmission line is used as a backup line when the transmission system is started. The spare line setting method will be described below using the transmission system shown in FIG. 1 as an example.

  First, the source device 10 checks the number of sink devices connected to the entire transmission system when the system is activated. There are the following methods for investigating the number of sink devices. For example, first, only the transmission line switch 12 ′ of the source device 10 is opened, and the remaining transmission line switches 12 and 102a to 102d are all closed. In such a connection form, the source device 10 transmits a diagnostic signal to each of the sink devices 100a to 100d, and receives the diagnostic signal of each sink device, thereby investigating how many sink devices are connected to the entire system. can do. The above-described method for checking the number of sink devices is merely an example, and the present invention is not limited to this.

  After grasping the number of sink devices as described above, the source device 10 determines the optimal network topology that minimizes the difference in the number of hops of the sink devices connected to the two paths, that is, the number of connected sink devices. And the network topology is written in the storage unit 13. In accordance with the network topology written in the storage unit 13, the various command generation units 17 transmit a transmission path activation inactivation command (a transmission path connection command and a transmission path disconnection command) to each of the sink devices 100a to 100d. The predetermined sink devices 100a to 100d that have received the transmission path activation / deactivation command from the source device 10 control the transmission path switches 102a to 102d to an open state or a closed state according to the command. At this time, the transmission path that is not used for communication is physically disconnected by a transmission path switch and set as a backup line.

<Generation of delay time>
By reconstructing the network topology by the above-described transmission path failure recovery operation, communication of the entire transmission system can be recovered. However, the maximum delay time of the entire transmission system changes as the network topology changes, so in a transmission system such as a surround system that requires simultaneous output, the simultaneous output after recovery from a transmission line failure is guaranteed. Can not do it.

Hereinafter, a mechanism for generating the delay time will be described.
FIG. 4 is a diagram illustrating an example of a network topology and a configuration of a synchronous transmission frame before a transmission path failure occurs in the transmission system according to the present embodiment. FIG. 4 shows a simplified configuration of the transmission system using the daisy chain connection shown in FIG.

  In FIG. 4, reference numeral 400 denotes a data group to be output simultaneously by the sink devices 100 a to 100 d generated by the source generation unit 21. The data group 400 is time-divided for each piece of data of each of the sink devices 100a to 100d and is assigned to each slot constituting a synchronous transmission frame.

  4001 included in the data group 400 is a slot a to which data to be output to the sink device 100a is assigned. Similarly, reference numeral 4002 denotes a sink device 100b, reference numeral 4003 denotes a sink device 100c, and reference numeral 4004 denotes a slot (slot b, slot c, slot d) to which data to be output to the sink device 100d is assigned.

  As shown in FIG. 4, the data group 400 is converted into a frame configuration such as a synchronous transmission frame 410 and a synchronous transmission frame 430, and transmitted to the transmission path 1 and the transmission path 3, respectively. The synchronous transmission frame 410 includes slots a and b to which data to be output from the sink devices 100a and 100b are allocated. The synchronous transmission frame 430 includes slots c and d to which data to be output by the sink devices 100c and 100d are allocated. The sink devices 100a to 100d that have received the synchronous transmission frames 410 and 430 transmitted from the source device 10 take out data to be output from the received synchronous transmission frames 410 and 430, and execute simultaneous output.

  Here, when data is transmitted / received in the baseband, since signal processing such as modulation / demodulation is not required, the sink device that has received the data can immediately transmit the data to the next-stage sink device. However, when modulation processing such as OFDM (Orthogonal Frequency Division Multiplex) modulation is performed for each synchronous transmission frame, the sink device needs to buffer the data of the synchronous transmission frame and then demodulate it. Therefore, there is always a delay of one frame length from when the sink device receives data to when the data is transmitted to the next sink device. This is shown in FIG.

  FIG. 5 shows the passage of time from when the source device 10 transmits the synchronous transmission frame 410 to when it reaches the sink device 100b. In FIG. 5, it is assumed that the time axis advances as it goes to the right.

  In FIG. 5, 600 is a frame synchronization signal, 720 is the timing when the source device 10 starts transmitting the synchronous transmission frame 410, and 2200 is the time when both of the sink devices 100 a and 100 b have finished receiving the synchronous transmission frame 410. It is timing. Further, 1200 indicates a difference in timing when the sink device 100a and the sink device 100b have finished receiving the synchronous transmission frame 410, that is, a delay difference between the sink device 100a and the sink device 100b, and the delay difference 1200 indicates the synchronous transmission frame 410. It matches the frame length of.

  When a synchronous transmission frame modulated by OFDM modulation or the like is transmitted from the sink device to the next sink device, a delay difference corresponding to the frame length proportional to the number of hops, that is, a delay time occurs. . Hereinafter, the delay time corresponding to the frame length that occurs every time it passes through the sink device is referred to as a frame delay time.

  Here, in FIG. 5, the delay time generated by signal processing or the like from when each sink device receives the synchronous transmission frame to when it is transmitted to the lower sink device is not considered. However, in an actual data transmission system, FEC (Forward Error Collection) execution time and delay time due to general signal processing and the like are also included. Therefore, in order to realize simultaneous output, it is necessary to consider internal processing delay time generated by signal processing in each sink device.

FIG. 6 shows the passage of time from when the source device transmits the synchronous transmission frame until it is simultaneously output by the sink device, including the internal processing delay time at each sink device.
In FIG. 6, reference numeral 600 denotes a frame synchronization signal, and reference numeral 700 denotes a timing at which the source device 10 starts transmission of the synchronous transmission frames 410 and 430. Reference numeral 2000 denotes a simultaneous output timing, and the sink devices 100a to 100d simultaneously output data included in the synchronous transmission frame at the simultaneous output timing 2000. A represents the internal processing delay time of the sink device 100a, B represents the internal processing delay time of the sink device 100b, C represents the internal processing delay time of the sink device 100c, and D represents the internal processing delay time of the sink device 100d.

  Here, for example, the internal processing delay time A of the sink device 100a includes a demodulation delay time, a signal processing delay time, and a modulation delay time. The demodulation delay time is a delay time generated by demodulating the synchronous transmission frame in the modem unit 101a. The signal processing delay time is a delay time generated by performing signal processing in the signal processing unit 105a. The modulation delay time is a delay time generated by modulating the synchronous transmission frame by the modem unit 101a ′.

  For example, the internal processing delay time B of the sink device 100b includes a demodulation delay time and a signal processing delay time. The demodulation delay time is a delay time generated by demodulating the synchronous transmission frame in the modem unit 101b, and the signal processing delay time is a delay time generated by performing signal processing in the signal processing unit 105b.

  The synchronous transmission frame 410 transmitted by the source device 10 is transmitted to the sink device 100a through the transmission path 1, and temporarily buffered by the sink device 100a. After completion of the buffer, the sink device 100a restores and demodulates the synchronous transmission frame 410, and reads data to be output from the slot a by itself. Then, the sink device 100a remodulates the synchronous transmission frame 410 and transmits it to the next-stage sink device 100b.

  Due to such a series of processing, the internal processing delay time A and the frame delay time of the synchronous transmission frame 410 are from when the sink device 100a receives the synchronous transmission frame 410 until it is transmitted to the next sink device 100b. Elapse. In addition, the sink device 100b that has received the synchronous transmission frame 410 generates an internal processing delay time B and a frame delay time corresponding to one frame length by data restoration and signal processing in the same manner as the sink device 100a.

Therefore, the elapsed time Δt_410 (s) from when the source device 10 transmits the synchronous transmission frame 410 to the transmission path 1 until the sink device 100b can output data is
Δt — 410 = A + B + 2 × ΔF — 410 (Expression 1)
It becomes. In (Formula 1), A is the internal processing delay time (s) of the sink device 100a, B is the internal processing delay time (s) of the sink device 100b, and ΔF_410 is the frame delay time (s) of the synchronous transmission frame 410. .

Similarly, the elapsed time Δt_430 (s) from when the source device 10 transmits the synchronous transmission frame 430 to the transmission path 3 until the sink device 100d can output data is
Δt_430 = C + D + 2 × ΔF_430 (Expression 2)
It becomes. In (Formula 2), C is the internal processing delay time (s) of the sink device 100c, D is the internal processing delay time (s) of the sink device 100d, and ΔF_430 is the frame delay time (s) of the synchronous transmission frame 430. .

Here, when the frame lengths of the synchronous transmission frame 410 and the synchronous transmission frame 430 are the same, and Δt_410> Δt_430, the maximum delay time TM1 (s) shown in FIG.
Maximum delay time TM1 = Δt_410 = A + B + 2 × ΔF_410 (Expression 3)
It becomes.

  In order to realize simultaneous output of the entire data transmission system, it is necessary to set the output timing of each of the sink devices 100a to 100d in accordance with the maximum delay time TM1. That is, the sink devices 100a, 100c, and 100d need to match the output timing of the sink device 100b having the maximum delay time.

Here, the time that each sink device corrects to realize simultaneous output is defined as output correction time. When the output correction time of the sink device 100b is set to 0, the output correction time TA1 of the sink device 100a, the output correction time TC1 of the sink device 100c, and the output correction time TD1 of the sink device 100d are respectively represented by the following (formula 4) and ( Equations 5) and (Equation 6) are obtained.
Output correction time TA1 = B + ΔF — 410 (Expression 4)
Output correction time TC1 = A + B−C + ΔF — 410 (Expression 5)
Output correction time TD1 = A + B−C−D (Expression 6)
However, ΔF_410 = ΔF_430.

  As described above, the sink devices 100a to 100d output the received data after the elapse of the output correction time set for each, thereby enabling simultaneous output in the entire transmission system.

  When a failure occurs in the transmission path 2 shown in FIG. 4, the network topology is reconstructed as shown in FIG. 7 by the transmission path failure recovery operation described above. The data group 400 is reconstructed from the frame configuration such as the synchronous transmission frames 410 and 430 shown in FIG. 4 to the frame configuration such as the synchronous transmission frames 411 and 431 shown in FIG. Alternatively, it is transmitted to the transmission path 3.

FIG. 8 is a diagram illustrating a lapse of time from when the source device simultaneously transmits the synchronous transmission frames 411 and 430 to when the sink device simultaneously outputs data.
In FIG. 8, reference numeral 600 denotes a frame synchronization signal, and reference numeral 701 denotes a timing at which the source device 10 starts transmitting synchronous transmission frames 411 and 431. Reference numeral 2001 denotes a simultaneous output timing, and the sink devices 100a to 100d simultaneously output data included in the synchronous transmission frame at this timing. A ′ is the internal processing delay time of the sink device 100a, B ′ is the internal processing delay time of the sink device 100b, C ′ is the internal processing delay time of the sink device 100c, and D ′ is the internal processing delay time of the sink device 100d. Represents.

  Here, as the network topology changes, the internal processing delay time inside the sink device also changes. Therefore, the internal processing delay time of each sink device 100a to 100d in the network topology shown in FIG. 7 is A ′, B ′, C ′, and D ′, and the internal processing delay time in the network topology shown in FIG. It is distinguished from. In the network topology shown in FIG. 4, for example, the internal processing delay time A includes a demodulation delay time related to processing in the modem unit 101a, a signal processing delay time related to processing in the signal processing unit 105a, and a modem unit 101a ′. The modulation delay time related to the above process is included. However, in the network topology shown in FIG. 7, the internal processing delay time A ′ of the sink device 100a includes the demodulation delay time related to the processing in the modem unit 101a and the signal processing delay time related to the processing in the signal processing unit 105a. Is included, and modulation delay time is not included. As described above, the internal processing delay time of the sink device also changes as the network topology changes.

When the network topology is changed as shown in FIG. 7, the maximum delay time TM2 shown in FIG.
Maximum delay time TM2 = C ′ + D ′ + B ′ + 3 × ΔF — 431 (Expression 7)
It becomes. In (Expression 7), B ′ is the internal processing delay time (s) of the sink device 100b, C ′ is the internal processing delay time (s) of the sink device 100c, and D ′ is the internal processing delay time (s) of the sink device 100d. ), ΔF_431 is the frame delay time (s) of the synchronous transmission frame 431.

  The value of the maximum delay time TM2 shown in (Expression 7) is different from the maximum delay time TM1 before the occurrence of a failure shown in (Expression 3). Accordingly, if the output correction time of each of the sink devices 100a to 100d is a set value based on the maximum delay time TM1 before the failure occurs, simultaneous output cannot be guaranteed. That is, in order to realize simultaneous output even after failure recovery, the output correction time of each sink device 100a to 100d is reset after the failure of the transmission path is reset with reference to the maximum delay time TM2 shown in (Formula 7). There is a need.

<Resetting output correction time>
The operation for guaranteeing the simultaneous output after the transmission line failure recovery in the transmission system according to the present embodiment will be described below. FIG. 9 is a flowchart showing the operation from the restoration of the transmission path failure to the restoration of the simultaneous output function. FIG. 9A shows an operation performed by the source device, and FIG. 9B shows an operation performed by the sink device. In the following, for the sake of convenience, the operation in the case where a failure occurs in the transmission line 2 in the transmission system shown in FIG.

  Upon completion of recovery from the failure that has occurred in the transmission path 2, the various command generation units 17 of the source device 10 generate a delay time notification command for notifying each of the sink devices 100a to 100d of its own internal processing delay time, It transmits to each sink device 100a-100d (step S7).

  The delay time notification units 108a to 108d of the sink devices 100a to 100d receive the delay time notification command and measure their own internal processing delay time (step S19). Then, the delay time notification units 108a to 108d transmit an internal processing delay time response that responds to its own internal processing delay time toward the source device 10 (step S20).

  The signal processing unit 15 of the source device 10 that has received the internal processing delay time response from each of the sink devices 100 a to 100 d records the internal processing delay time of each of the sink devices 100 a to 100 d in the storage unit 13. Subsequently, the arithmetic unit 16 of the source device 10 calculates the maximum delay time in the entire transmission system based on the internal processing delay time of each sink device 100a to 100d and the network topology information stored in the storage unit 13. (Step S8).

  Thereafter, the arithmetic unit 16 calculates the output correction time of each sink device 100a to 100d based on the calculated maximum delay time, and transmits an output correction command that causes each of the sink devices 100a to 100d to reset the output correction time. (Step S9). The delay time adjustment units 106a to 106d of the sink devices 100a to 100d that have received the output correction command reset the output correction time in accordance with the output correction command (step S21). By performing such a series of operations, it is possible to guarantee the simultaneous output of the entire transmission system even after recovery from the transmission path failure.

  In the output correction time resetting process described above, the source device 10 causes the sink devices 100a to 100d to notify the respective internal processing delay times, and the maximum delay time is calculated based on the information. However, when the storage unit 13 stores in advance the internal processing delay time of each sink device 100a to 100d in various network topologies, the source device 10 transmits a delay time notification command to each sink device, There is no need to wait for a response from each sink device. That is, the arithmetic unit 16 calculates the maximum delay time of the entire system based on the internal processing delay time data of each of the sink devices 100a to 100d stored in the storage unit 13 in advance and the network topology after recovery from the transmission path failure. Just do it. Then, based on the calculated maximum delay time, the operation shown in FIG. 9 (steps S9 and S21) can be performed to reset the output correction time of each of the sink devices 100a to 100d.

  The output correction time resetting process described above is performed after the signal processing units 105a to 105d of the sink devices 100a to 100d extract data from the synchronous transmission frame until the data is output by the output units 107a to 107d. Output delay time is not considered. That is, it is assumed that the output delay time is negligibly small, or the output delay times of the sink devices are substantially the same. However, if the output delay time is so large that it cannot be ignored, and each sink device has a different output delay time, the output delay time can be included in the internal processing delay time to reset the output correction time. good.

<Slot configuration>
As shown in the synchronous transmission frames 410 and 430 in FIG. 4 and the synchronous transmission frames 411 and 431 in FIG. 7, the synchronous transmission frames that flow in two paths according to the network topology are reconfigured to the optimum slot configuration by the source device 10. Is set. The term “optimal configuration” as used herein means that a synchronous transmission frame to be sent to each path is configured by only slots assigned to sink devices existing in the path.

  A frame configuration unit 18 in the source device 10 selects an optimal slot configuration and generates a synchronous transmission frame. Based on the network topology information stored in the storage unit 13, the frame configuration unit 18 resets the optimal slot configuration by rearranging the slots for the synchronous transmission frame (step S10).

<Initial setting of output correction time>
The initial setting of the output correction time is set by performing the operations of steps S7 to S10 and steps S19 to S21 shown in FIG. 9 described above after determining the network topology at the time of starting the transmission system.

  According to the first embodiment, when it is detected that a failure has occurred in the transmission path, the failure has occurred by setting the transmission path in which the failure has occurred to the communication inactivated state and activating the standby line in the communication state. The transmission path can be bypassed, and the data transmission system can be automatically restored. In addition, the maximum delay time in the network topology changed accordingly is calculated, and the output correction time of each of the sink devices 100a to 100d is reset based on the calculated maximum delay time. Simultaneous output can be performed.

(Second Embodiment)
Next, a second embodiment of the present invention will be described.

  In the transmission path failure recovery operation in the first embodiment described above, the disconnection of the transmission path in which the failure has occurred is performed by the source device detecting the transmission path failure transmitting a transmission path disconnection command to the target sink device. The sink device that received it did so by opening the transmission line switch. On the other hand, if each sink device is provided with a diagnostic signal detection means for detecting a diagnostic signal transmitted from the lower sink device, the sink device itself can detect a failure according to the success or failure of detection of the diagnostic signal. It is possible to disconnect the transmission path in which the failure has occurred. In other words, when the diagnostic signal detection means provided in the sink device cannot detect all the diagnostic signals from one or more sink devices connected to the lower stage, the transmission path connected to the lower sink apparatus is disconnected. It is possible to disconnect the transmission line in which the failure occurred.

  In the second embodiment described below, a diagnostic signal detection unit is provided in a sink device, and a transmission path where a failure has occurred is determined by the determination of the sink device. Note that the operations other than the configuration related to the configuration of the entire data transmission system and the disconnection of the transmission path in which a failure has occurred are the same as those in the first embodiment, and thus description thereof will be omitted.

  FIG. 10 is a diagram illustrating a configuration example of the sink device 170a according to the second embodiment. A sink device 170a illustrated in FIG. 10 includes a sink device 100a illustrated in FIG. 1 and a diagnosis signal detection unit 110a that detects a diagnosis signal from the sink device connected to the lower stage. Each configuration other than the diagnostic signal detection unit 110a in the sink device 170a is the same as each configuration in the sink device 100a shown in FIG. Also, the sink device 170b connected to the lower stage of the sink device 170a is assumed to be provided with the diagnostic signal detection unit 110b in the sink device 100b shown in FIG. 1, similarly to the sink device 170a.

  The diagnostic signal detector 110a of the sink device 170a detects a diagnostic signal from the sink device 170b connected to the lower stage, and determines whether or not a failure has occurred depending on whether or not the diagnostic signal is detected. In addition, the diagnostic signal detection unit 110a transmits the diagnostic signal of the sink device 170b to the source device 10 connected thereafter in the upper stage.

  If a failure occurs in the transmission path 2, the diagnostic signal detection unit 110a cannot detect a diagnostic signal from the sink device 170b, and detects that a failure has occurred in the transmission path 2. The diagnostic signal detection unit 110a that has detected the failure issues a command to the control unit 104a to open the transmission path switch 102a. Upon receiving the command, the control unit 104a opens the transmission line switch 102a and physically disconnects the transmission line 2 where the failure has occurred. In addition, the source device 10 cannot detect the diagnosis signal of the sink device 170b that should be transmitted from the sink device 170a, so that the occurrence of a failure in the transmission path 2 can be detected.

  According to the second embodiment, the same effects as those of the first embodiment described above can be obtained, and the diagnostic signal transmitted from the lower sink device can be detected successfully by providing the sink device with the diagnostic signal detection unit. Accordingly, the sink device itself can disconnect the transmission path in which the failure has occurred. Therefore, it is not necessary for the source device to generate a transmission path disconnection command, and the sink device does not need to wait for a transmission path disconnection command from the source device, so that the transmission path in which a failure has occurred can be quickly disconnected.

(Third embodiment)
Next, a third embodiment of the present invention will be described.
In the output correction time resetting process in the first embodiment described above, the output correction time set in each sink device includes the internal processing delay time of each sink device and the frame delay time generated each time it passes through the device. Was included. However, simultaneous output can be guaranteed without correcting the frame delay time on the sink device side by recombining the configuration of the synchronous transmission frame on the source device side. The method will be described below.

Since the configuration and basic operation of the entire transmission system in the third embodiment are the same as those in the first embodiment, description thereof will be omitted.
In the third embodiment, the source device 10 determines the number of hops from the source device for each sink device based on the network topology information stored in the storage unit 13. In accordance with the number of hops, data to be transmitted simultaneously to the sink devices 100a to 100d is shifted and arranged in slots of synchronous transmission frames (data frames) that follow each other. That is, on the source device 10 side, the data frame in which data is arranged by the number of hops is shifted in consideration of the number of hops to each sink device.

  FIG. 11 is a diagram illustrating an example of the network topology of the transmission system and the configuration of the synchronous transmission frame in the third embodiment. FIG. 11 schematically illustrates the configuration of the transmission system using the daisy chain connection illustrated in FIG. 1 and the configuration of the synchronization frame in the third embodiment.

  In FIG. 11, 500, 501, and 502 are data groups that should be output simultaneously by the sink devices 100 a to 100 d generated by the source device 10. Each of the data groups 500, 501, and 502 should be simultaneously output by the sink devices 100a to 100d at a predetermined output timing.

  Data to be output to the sink device 100a is assigned to slots a (a0 to a2) included in the data groups 500 to 502. Similarly, slot b (b0 to b2) is assigned to the sink device 100b, slot c (c0 to c2) is assigned to the sink device 100c, and slot d (d0 to d2) is assigned to the sink device 100d. Yes.

  Note that the data allocated to the slots a0, b0, c0, and d0 in the data group 500 is data that should be output simultaneously by the sink devices 100a to 100d. Similarly, the data assigned to the slots a1, b1, c1, and d1 in the data group 501 are data to be output simultaneously, and are assigned to the slots a2, b2, c2, and d2 in the data group 502. Data to be output simultaneously.

  Reference numerals 510 and 511 denote synchronous transmission frames transmitted to the transmission path 1, and reference numerals 530 and 531 denote synchronous transmission frames transmitted to the transmission path 3. The synchronous transmission frame 510 includes a slot a0 and a slot b1, and the synchronous transmission frame 511 includes a slot a1 and a slot b2. Similarly, the synchronous transmission frame 530 includes a slot c0 and a slot d1, and the synchronous transmission frame 531 includes a slot c1 and a slot d2.

  The source device 10 transmits synchronous transmission frames 510 and 511 to the transmission path 1 and transmits synchronous transmission frames 530 and 531 to the transmission path 3. Here, it is assumed that the synchronous transmission frame 511 is transmitted immediately after the transmission of the synchronous transmission frame 510 is completed, and the synchronous transmission frame 531 is transmitted immediately after the transmission of the synchronous transmission frame 530 is completed. The synchronous transmission frames 510 and 530 and the synchronous transmission frames 511 and 531 are assumed to be transmitted simultaneously to a predetermined transmission path.

  In the following, for the convenience of explanation, the explanation will focus on the slot a1 (5001), slot b1 (5002), slot c1 (5003), and slot d1 (5004) included in the data group 501 to be output simultaneously.

  FIG. 12 shows the time from when the source device 10 transmits each synchronous transmission frame until the sink devices 100a to 100d simultaneously output the data assigned to the slots a1, b1, c1, and d1 at the simultaneous output timing 2101. Shows progress. In FIG. 12, it is assumed that the time axis advances as it goes to the right. In FIG. 12, a simultaneous output timing 2100 represents a timing for simultaneously outputting the data group 500, and a simultaneous output timing 2102 represents a timing for simultaneously outputting the data group 502.

  As shown in FIG. 12, the synchronous transmission frame 510 is loaded with the slot b1, and the synchronous transmission frame 511 transmitted with a delay of one frame length from the synchronous transmission frame 510 is loaded with the slot a1 and the sink devices 101a and 101b. Sent to. The synchronous transmission frame 530 is loaded with the slot d1, and the synchronous transmission frame 531 transmitted with a delay of one frame length from the synchronous transmission frame 530 is loaded with the slot c1 and transmitted to the sink devices 101c and 101d.

  The internal processing delay time of the sink device 100a is A (s), the internal processing delay time of the sink device 100b is B (s), the internal processing delay time of the sink device 100c is C (s), and the internal processing delay time of the sink device 100d is Is D (s). Further, it is assumed that (A + B)> (C + D).

In this case, the output correction time TA3 of the sink device 100a, the output correction time TC3 of the sink device 100c, and the output correction time TD3 of the sink device 100d are
Output correction time TA3 = B (Expression 8)
Output correction time TC3 = A + B−C (Expression 9)
Output correction time TD3 = A + B−C−D (Expression 10)
By doing so, simultaneous output can be realized. However, the output correction time of the sink device 100b at this time is zero.

  As described above, the source device 10 side shifts the data frame in which slots are arranged by the number of hops in consideration of the number of hops to each sink device, thereby removing the difference due to the frame delay on the source device 10 side. be able to. That is, as shown in the (Expression 4) to (Expression 6), it is not necessary to correct the frame delay time on the sink devices 100a to 100d side. Further, it is possible to recover the transmission path failure without impairing the simultaneous output.

(Other embodiments of the present invention)
For realizing the functions of the above-described embodiment for a computer (CPU or MPU) in an apparatus or system connected to the various devices so that the various devices are operated to realize the functions of the above-described embodiments. Supply software programs. And what was implemented by operating the said various devices according to the program stored in the computer of the system or the apparatus is also contained under the category of this invention.
In this case, the software program itself realizes the functions of the above-described embodiments, and the program itself constitutes the present invention. Further, means for supplying the program to the computer, for example, a recording medium storing the program constitutes the present invention. As a recording medium for storing such a program, for example, a flexible disk, a hard disk, an optical disk, a magneto-optical disk, a CD-ROM, a magnetic tape, a nonvolatile memory card, a ROM, or the like can be used.
In addition, such a program is also included in the embodiment of the present invention when the function of the above-described embodiment is realized in cooperation with an operating system running on a computer or other application software. Needless to say.
Further, after the supplied program is stored in a memory provided in a function expansion board or a function expansion unit related to the computer, a CPU or the like provided in the function expansion board or the like based on an instruction of the program may be a part of actual processing or Do everything. Needless to say, the present invention includes the case where the functions of the above-described embodiments are realized by the processing.

  The above-described embodiments are merely examples of implementation in carrying out the present invention, and the technical scope of the present invention should not be construed as being limited thereto. That is, the present invention can be implemented in various forms without departing from the technical idea or the main features thereof.

It is a figure which shows the structural example of the transmission system which concerns on 1st Embodiment. It is a figure which shows the structural example of the table memorize | stored in the memory | storage part of a source device. It is a flowchart which shows the transmission path failure recovery operation | movement of the source device in 1st Embodiment. It is a flowchart which shows the transmission path failure recovery operation | movement of the sink device in 1st Embodiment. It is a figure which shows an example of the structure of the network topology before transmission-path failure generation | occurrence | production of the transmission system in 1st Embodiment, and a synchronous transmission frame. It is a figure for demonstrating generation | occurrence | production of a frame delay. It is a figure for demonstrating the delay before the transmission line failure generation in the transmission system in 1st Embodiment. It is a figure which shows an example of the structure of the network topology after the transmission line failure recovery of the transmission system in 1st Embodiment, and a synchronous transmission frame. It is a figure for demonstrating the delay after the transmission line failure recovery in the transmission system in 1st Embodiment. It is a flowchart which shows the operation | movement after the transmission line failure recovery in 1st Embodiment. It is a figure which shows the structural example of the sink device in 2nd Embodiment. It is a figure which shows an example of the structure of the network topology and synchronous transmission frame of the transmission system in 3rd Embodiment. It is a figure for demonstrating the delay in the transmission system in 3rd Embodiment. It is a figure which shows the Example of the conventional network surround system.

Explanation of symbols

1-4 Transmission line 5 Backup line (Reserve transmission line)
DESCRIPTION OF SYMBOLS 10 Source apparatus 12, 12 ', 102a-102d, Transmission path switch 13 Memory | storage part 14, 104a-104d Control part 15, 105a-105d Signal processing part 16 Arithmetic part 17 Various command generation parts 18 Frame structure part 19 Diagnostic signal generation part 20 Signal generator 30, 31 Output terminal (interface)
100a to 100d Sink devices 103a to 103d, 103a ′ to 103d ′ High-frequency crosspoint switches 106a to 106d Delay time adjustment units 107a to 107d Output units 108a to 108d Delay time notification units 109a to 109d Diagnostic signal generation units

Claims (13)

Transmission comprising a source device, one or more sink devices daisy chained to a first interface of the source device, and one or more sink devices daisy chained to a second interface of the source device A system,
The source device is
First detecting means for detecting a transmission line failure;
A determination unit that determines a network topology after performing the avoidance of the transmission path failure based on a detection result of the first detection unit;
Based on the network topology determined by the determining means and the internal processing delay time of each sink device, the maximum delay time until the sink device outputs data from the source device and the data output are synchronized. Computing means for calculating an output correction time allocated to each sink device,
Notification means for notifying each sink device of the output correction time calculated by the calculation means;
A transmission system comprising:   The said determination means determines the network topology after performing the said transmission path failure avoidance using the spare transmission path provided between the said predetermined | prescribed sink devices. Transmission system. The sink device is
A second detection means for detecting a transmission line failure;
A first transmission line control unit that activates the spare transmission line in a communication activated state when the second detection unit detects a transmission line failure when a spare transmission line is connected;
The transmission system according to claim 1, further comprising: The sink device is
The transmission system according to claim 1, further comprising an output correction unit that corrects an output timing of data based on the output correction time notified from the source device. The source device is
5. The apparatus according to claim 1, further comprising: a second transmission path control unit that sets a transmission path in which a failure has occurred to a communication inactive state based on a detection result of the first detection unit. The transmission system according to item 1.   The source device checks the number of the sink devices when the transmission system is activated, and determines the transmission system according to a network topology that minimizes the difference in the number of sink devices connected to the first and second interfaces. The transmission system according to claim 1, wherein the transmission system is constructed.   The source device connects a terminal sink device in the sink device daisy chained to the first interface in the network topology and a terminal sink device in the sink device daisy chain connected to the second interface. The transmission system according to any one of claims 1 to 6, wherein a transmission path for the transmission is a backup transmission path.   8. The source device according to claim 1, further comprising: a configuration unit configured to configure data frames in a time division manner and output data to be transmitted to each of the sink devices based on the network topology. The transmission system according to item 1. The configuration means includes
The number of hops from the source device is determined for each sink device from the network topology, and the data to be transmitted simultaneously to each of the sink devices is arranged in the data frame according to the number of hops. 9. The transmission system according to claim 8, wherein   The first detection means transmits and receives a predetermined signal between the source device and each sink device, and detects a transmission path in which a failure has occurred depending on whether or not the predetermined signal is detected. The transmission system according to any one of claims 1 to 9. A communication device for transmitting data to a plurality of sink devices connected to a first interface and a second interface for daisy chain connection of one or more sink devices,
First detecting means for detecting a transmission line failure;
A determination unit that determines a network topology after performing the avoidance of the transmission path failure based on a detection result of the first detection unit;
In order to synchronize the maximum delay time until the sink device outputs data from the communication device and the output of the data based on the network topology determined by the determining means and the internal processing delay time of each of the sink devices Computing means for calculating an output correction time allocated to each sink device,
Notification means for notifying each sink device of the output correction time calculated by the calculation means;
A communication apparatus comprising: Each transmission device includes a source device, a sink device daisy chained to the first interface of the source device, and a sink device daisy chained to the second interface of the source device. A transmission method for simultaneously outputting data from the source device,
A detection step of detecting a failure in the data transmission path;
The maximum delay time until the sink device outputs data from the source device based on the network topology detected in the detection step and the internal processing delay time of each sink device avoiding the transmission path failure And a calculation step for calculating an output correction time allocated to each sink device in order to synchronize the output of data,
A notification step of notifying each sink device of the output correction time calculated in the calculation step;
A transmission method characterized by comprising: Each transmission device includes a source device, a sink device daisy chained to the first interface of the source device, and a sink device daisy chained to the second interface of the source device. A program for causing a computer to execute control to simultaneously output data from the source device,
A detection step of detecting a failure in the data transmission path;
The maximum delay time until the sink device outputs data from the source device based on the network topology that avoids the transmission path failure detected in the detection step and the internal processing delay time of each of the sink devices And a calculation step for calculating an output correction time allocated to each sink device in order to synchronize the output of data,
A notification step of notifying each sink device of the output correction time calculated in the calculation step;
A program that causes a computer to execute.

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