JP2004266480A - Hitless switching system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve problems that system structure is complicated and in addition, a part of overhead byte in an original signal is overwritten and in order to impart an identifier for phase recognition on the transmitting side and all POHs, SOHs to be specified by ITU-T, G.707 can not be transparently transferred in the case of applying hitless switching by unit of VC path to a digital multiplex transmission system based on synchronous digital hierarchy. <P>SOLUTION: An ODU signal form to be specified by ITU-T G.709 is used and on the transmitting side, processing for newly adding byte for control is performed without changing the original signal before branching the original signal into two different paths. A specific pattern is imparted to a part of the byte for control which is added by this signal form conversion as the identifier. On the receiving side, the signal form which is converted by the signal form conversion is restored to an original signal form after switching of selection systems. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a path switching method for a digital transmission system, and to an ITU-TG. The present invention relates to a path switching method of a transmission system having an interface conforming to the optical transport network specified in 709.
[0002]
[Prior art]
Instantaneous interruption switching is a method in which a signal to be instantaneous interruption switching is transmitted after branching to a different path (a working transmission line and a protection transmission line) on the transmission side, and a signal received from the working transmission line and a protection transmission are transmitted. By storing the signals received from the paths in the active memory and the standby memory for an arbitrary time, the phases at the time of reading from each memory are adjusted, and by external control, the signal reading is switched from the active system to the standby system. It is feasible.
[0003]
In conventional non-stop switching, ITU-T G. Switching of the synchronous digital hierarchy defined by 707 in units of paths such as "VC-3" or "VC-4" is realized.
[0004]
In the path-based instantaneous interruption switching system, the phases of the working path and the protection path that are multiplexed and demultiplexed are adjusted by the ITU-TG. A specific multi-frame pattern (identifier) is overwritten and inserted into the J1 byte and the H4 byte of the POH specified in 707, and branched and transmitted to the active system and the standby system. On the receiving side, the paths of the active and standby systems are specified. The read timing of the backup path from the backup memory is matched with the read timing of the backup path from the backup memory based on the phase difference recognized by the multi-frame pattern (identifier). The phase of the path signal and the backup VC path signal can be adjusted.
[0005]
[Problems to be solved by the invention]
However, the above-described conventional non-instantaneous switching in VC path units has the following problems. ITU-T G. In a digital multiplex transmission system conforming to the synchronous digital hierarchy specified in 707, a VC path corresponding to a low-speed line such as 50 Mbps or 150 Mbps is placed in a payload of an STM16 frame or STM64 frame having a high bit rate of 2.4 Gbps or 10 Gbps. Multiple transmissions are performed.
[0006]
In the case where the conventional non-stop switching in VC path units is applied to such a digital multiplex transmission system conforming to the synchronous digital hierarchy, the switching control circuits on the transmission side and the reception side are provided for each VC path unit to be demultiplexed and separated. Since they are configured independently, there is a problem that the device configuration is complicated in the transmission unit and the reception unit of the digital multiplex transmission system as shown in FIGS.
[0007]
A switching control circuit is also required in accordance with the number of multiplexed VC paths to be interrupted without interruption, which makes the configuration of the device and the size of the mounting volume remarkable, and is suitable for recent large-capacity digital multiplex transmission systems. No (first issue).
[0008]
Also, according to ITU-TG. Various overheads of POH and SOH defined by the 707 Synchronous Digital Hierarchy are specified for their respective applications, and signals to be multiplexed may need to be transmitted transparently without overwriting the overhead. is there. In the conventional technique, a part of an overhead byte in an original signal is overwritten in order to provide an identifier for phase recognition on a transmission side. That is, in the conventional hitless switching technology, the ITU-T G. All of the POH and SOH defined in 707 cannot be transferred transparently (second problem).
[0009]
The present invention has been made in such a background, and it is an object of the present invention to solve the first and second problems and to provide a hitless switching function suitable for a recent large-capacity digital multiplex transmission system. Aim.
[0010]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided a transmitting subsystem that transmits an original signal to two different paths, a working path and a standby path, and a receiving subsystem that receives an original signal from the two paths. The subsystem includes means for branching and transmitting the phase adjustment identifier together with the original signal to a different path, and the receiving subsystem includes a phase difference of the phase adjustment identifier received from two different paths together with the same original signal. Is a non-interruptible switching system including phase difference absorbing means for measuring the phase difference and measuring the phase difference, and switching means for switching the signal having the phase difference absorbed between the working and the standby.
[0011]
Here, a feature of the present invention is that the transmitting subsystem newly adds a control byte without changing the original signal before branching the original signal to two different paths. A signal format conversion unit that performs processing, and an identifier assignment unit that assigns a specific pattern as the identifier to a part of a control byte added by the signal format conversion unit, wherein the reception-side subsystem includes: There is provided a signal restoring means for restoring the signal format converted by the signal format converting means to the original signal format after the switching of the signal selection system by the switching means. Thereby, since the original signal is not changed, the above-described second problem can be solved.
[0012]
Further, in order to solve the first problem described above, for example, the signal format conversion means converts the original signal to be switched without interruption into ITU-T G.100. 709, comprising an ODU conversion means for converting the signal into an ODU signal format defined by an optical transport network, wherein the identifier assigning means assigns the specific pattern as a phase adjustment identifier to a part of an overhead byte of the ODU signal. Wherein the phase difference absorbing means comprises: an active identifier detecting means for detecting an identifier represented by the specific pattern from an overhead byte in the ODU signal received from the working transmission line; and an ODU signal received from the protection transmission line. A spare identifier detecting means for detecting an identifier represented by the specific pattern from the overhead bytes, an active memory means for temporarily storing an ODU signal received from the working transmission path, and a temporary storage for an ODU signal received from the protection transmission path. Spare memory means, the working identifier detection means and the spare identifier detection Detecting a phase difference from a difference between arrival times of the specific pattern in the ODU overhead detected in the stage, and adjusting a time stored in the working memory means and the spare memory means based on the phase difference, Memory control means for matching the read phase of the ODU signal from the working memory means and the spare memory means, wherein the switching means reads the ODU signal from the working memory means or the spare memory means to thereby make the current system Alternatively, there is provided a means for performing selection switching of the standby system, and the signal restoration means is provided with means for restoring the ODU signal read by the switching means to the original signal format.
[0013]
As a result, by using a part of the overhead of the ODU signal for inserting a specific pattern for phase recognition, for example, an STM frame in which a plurality of VC paths are multiplexed with a client signal is accommodated in a payload portion of the ODU signal. In order to realize instantaneous interruption switching for all multiplexed lines, there is no need to independently install a plurality of switching circuits for each VC path, and a switching circuit for each ODU having an STM-N frame as a payload is required. It can be realized by mounting only one. This can solve the first problem.
[0014]
Further, at the stage before the insertion of the specific pattern for phase recognition, the STM-N frame is converted into an ODU frame having a different signal format, and the ODU signal format is converted into the STM signal format at the stage subsequent to the switching unit, thereby obtaining the original signal. Signal transmission and switching control can be performed without changing the overhead bytes of the STM-N frame while maintaining the transparency of the STM-N frame. Thereby, the second problem can be solved.
[0015]
At this time, the means for giving the specific pattern is based on ITU-TG. The RES byte described in the 709 optical transport network is used as a phase adjustment identifier as a position for inserting the specific pattern, or the means for adding the specific pattern is defined in ITU-TG. 709 optical transport network as a phase adjustment identifier, and a means for using the specific pattern as an insertion position. It is preferable to include means for using an MFAS byte described in the 709 optical transport network as a phase adjustment identifier as an insertion position of the specific pattern.
[0016]
Note that a RES (Reserved for future standardization) byte is a byte for leaving room to deal with a case where a new standardized item is added in the future, and is an unused byte at present. Therefore, this can be used as a phase adjustment identifier.
[0017]
EXP (Experimental) is a byte reserved for various tests, and is an unused byte when no test is performed. Therefore, this can be used as a phase adjustment identifier.
[0018]
An MFAS (Multi Frame Alignment Signal) byte is an overhead indicating a multi-frame phase. Its value takes a value from 0 to 255, and 256 frames can constitute one multi-frame. Therefore, this can be used as a phase adjustment identifier.
[0019]
A second aspect of the present invention is a transmitting side subsystem including means for branching and transmitting an identifier for phase adjustment along with the original signal to a different path. A feature of the present invention is that the original signal Before branching to the path, the signal format conversion means for adding a new control byte without changing the original signal, and a part of the control byte added by the signal format conversion means. And an identifier assigning means for assigning a specific pattern as the identifier.
[0020]
The signal format converting means converts the original signal to be switched to the uninterruptible power supply to the ITU-TG. 709, comprising an ODU conversion means for converting the signal into an ODU signal format defined by an optical transport network, wherein the identifier assigning means assigns the specific pattern as a phase adjustment identifier to a part of an overhead byte of the ODU signal. It is desirable to provide.
[0021]
At this time, the means for giving the specific pattern is based on ITU-TG. The RES byte described in the 709 optical transport network is used as a phase adjustment identifier as a position for inserting the specific pattern, or the means for adding the specific pattern is defined in ITU-TG. 709 optical transport network as a phase adjustment identifier, and a means for using the specific pattern as an insertion position. It is preferable to include means for using an MFAS byte described in the 709 optical transport network as a phase adjustment identifier as an insertion position of the specific pattern.
[0022]
A third aspect of the present invention is a phase difference absorbing means for measuring a phase difference between phase adjustment identifiers received from two different paths, current and standby, together with the same original signal and absorbing the phase difference, A receiving subsystem including a switching means for switching a signal having a phase difference absorbed between a working signal and a standby signal. A feature of the present invention is that the transmitting signal is transmitted before branching and sending out the original signal to two different paths. In addition, without changing the original signal, performing a process of newly adding a control byte, a part of the control byte added by this signal format conversion, a specific pattern is given as the identifier, There is provided a signal restoring means for restoring the signal format converted by the signal format conversion to the original signal format after the switching of the signal selection system by the switching means.
[0023]
In the signal format conversion, the original signal to be switched without interruption is defined as ITU-TG. 709 is converted into an ODU signal format defined by the optical transport network, and the specific pattern is added as a phase adjustment identifier to a part of an overhead byte of the ODU signal. Working identifier detecting means for detecting an identifier represented by the specific pattern from overhead bytes in the ODU signal received from the ODU signal; and an identifier represented by the specific pattern from overhead bytes in the ODU signal received from the protection transmission line. , A working memory means for temporarily storing the ODU signal received from the working transmission path, a working memory means for temporarily storing the ODU signal received from the protection transmission path, the working identifier detecting means, The specific packet in the ODU overhead detected by the spare identifier detecting means. A phase difference is detected from the difference between the arrival times of the active memory and the spare memory by adjusting the time stored in the working memory and the spare memory based on the phase difference. Memory control means for matching the read phase of the ODU signal, wherein the switching means switches between the active system and the standby system by reading the ODU signal from the active memory unit or the standby memory unit. Preferably, the signal restoring means includes means for restoring the ODU signal read by the switching means to the original signal format.
[0024]
As a result, instantaneous interruption switching while preserving the original signal is realized, and furthermore, the instantaneous interruption switching system, which can avoid complication of the device configuration, and the transmission side subsystem and the reception side used for the system Subsystems can be implemented.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a block diagram of the instantaneous interruption switching system of the present embodiment. FIG. 2 is an ODU structure diagram. FIG. 3 is a diagram for explaining the first embodiment. FIG. 4 is a diagram for explaining the second embodiment.
[0026]
In this embodiment, as shown in FIG. 1, a transmitting subsystem 10 that transmits an original signal to two different paths A and B for working and protection, and a receiving subsystem that receives the original signal from the two paths A and B The transmitting subsystem 10 includes a branching unit 3 for branching and transmitting an identifier for phase adjustment together with the original signal to a different path, and the receiving subsystem 20 includes two different units together with the same original signal. A phase difference absorbing unit that measures the phase difference of the phase adjustment identifier received from the paths A and B and absorbs the phase difference, and a switching unit 18 that switches the signal having the phase difference absorbed between the working and the standby. A feature of the present embodiment is a non-interruptible switching system that includes a change in the original signal before splitting the original signal into two different paths A and B in the transmitting subsystem 10. That An ODU conversion unit 1 for performing a process of newly adding a control byte, and an identifier providing unit 2 for providing a specific pattern as the identifier to a part of the control byte added by the ODU conversion unit 1. The receiving subsystem 20 includes an original signal restoring unit 19 that restores the signal format converted by the ODU converting unit 1 to the original signal format after the switching of the signal selection system by the switching unit 18. .
[0027]
Next, the operation of the instantaneous interruption switching system of this embodiment will be described together with its configuration. The ODU conversion unit 1 converts the original signal to be subjected to instantaneous interruption switching to ITU-TG. 709 is converted into an ODU signal format defined by the optical transport network, and the identifier assigning unit 2 assigns the specific pattern as a phase adjustment identifier to a part of an overhead byte of the ODU signal.
[0028]
The phase difference absorbing unit includes an identifier detection unit 13 that detects an identifier represented by the specific pattern from an overhead byte in the ODU signal received from the path A, and an identifier detection unit 13 that detects the identifier from the overhead byte in the ODU signal received from the path B. An identifier detecting unit 15 for detecting an identifier represented by a specific pattern, a memory unit 16 for temporarily storing an ODU signal received from the path A, a memory unit 17 for temporarily storing an ODU signal received from the path B, A phase difference is detected from a difference between arrival times of the specific pattern in the ODU overhead detected by the detection unit 13 and the identifier detection unit 15, and the time accumulated in the memory unit 16 and the memory unit 17 is adjusted based on the phase difference. By doing so, the memory that matches the read phase of the ODU signal from the memory unit 16 and the memory unit 17 The switching unit 18 switches between the active system and the standby system by reading the ODU signal from the memory unit 16 or the memory unit 17, and the original signal restoring unit 19 includes the switching unit 18. To restore the ODU signal read out to the original signal format.
[0029]
The identifier assigning unit 2 is configured to transmit the ITU-T G. The RES byte described in the 709 optical transport network is used as the phase adjustment identifier as the insertion position of the specific pattern, or the ITU-T G.709 The EXP byte described in the optical transport network 709 is used as a phase adjustment identifier and used as an insertion position of the specific pattern. The MFAS byte described in the 709 optical transport network is used as a phase adjustment identifier and used as the insertion position of the specific pattern.
[0030]
The ODU signal is a G.264 signal. G.709 optical transport network. 707 is a new transmission signal format suitable for large-capacity transmission. FIG. 2 shows an ODU structure diagram. G. FIG. In 709, a 4 × 2 byte OPU overhead is added to a 4 × 3808 byte client signal, and a 3 × 14 byte ODU overhead is further added. Incidentally, each of the abbreviations in Figure 2, PM: Path Monitoring, TCM: Tandem Connection Monitoring, SAPI: Source Access Point Identifier, DAPI: Destination Access Point Identifier, RES: Reserved for future international standardisation, ACT: Activation / deactivation control channel, FTFL: Fault Type & Fault Location reporting channel, EXP: Experimental, GCC: General Communication Channel, AP : Automatic Protection Switching coordination channel, PCC: Pretection Communication Control channel, TTI: Trail Trace Identifier, BIP8: Bit Interleaved Parity-level 8, BIE: Backward Error Indication, BDI: Backward Defect Indication, STAT: Status, PSI: Payload Structure Identifier , PT: Payload Type, MFAS: Multi Frame Alignment Signal. Further, before the signal is transmitted to the transmission medium, the OTU overhead and the FEC are added, and the signal is transmitted as a 4 × 4080-byte OTU frame.
[0031]
G. FIG. The payload of the ODU1 frame and the ODU2 frame regulated by Since it has a capacity capable of transmitting all bit rates of the STM16 frame and the STM64 frame specified by 707, conversion to the ODU signal format does not cause bit loss of the STM-N signal. The payload portion of the ODU signal format includes not only STM-N signals but also ATM cells and ITU-TG. A GFP frame defined by 7041 can also be transmitted. Also, in the block configuration of FIG. Although the ODU signal format has been converted into the ODU signal format conforming to 709, another signal conversion means may be used as the signal format conversion means if the client signal is stored.
[0032]
Further, claim 3, claim 4, claim 5, claim 8, claim 9, and claim 10 all apply to G.264. This is a non-instantaneous interruption switching system that performs phase adjustment using an overhead byte defined by an H.709. Claims 3 and 8 use the RES byte shown in FIG. 2 as a phase adjustment identifier. Claims 4 and 9 use the EXP byte shown in FIG. 2 as a phase adjustment identifier. Claims 5 and 10 use the MFAS byte shown in FIG. 2 as a phase adjustment identifier.
[0033]
As described above, in the hitless switching system of the present embodiment, by using a part of the overhead of the ODU signal for inserting a specific pattern for phase recognition, for example, an STM frame in which a client signal is multiplexed with a plurality of VC paths is provided. Is realized in the payload portion of the ODU signal, thereby realizing instantaneous interruption switching for all multiplexed lines, there is no need to independently install a plurality of switching circuits for each VC path, and the STM-N frame This can be realized by mounting only one switching circuit for each ODU having the payload as a payload. This can solve the first problem.
[0034]
Further, before the insertion of the specific pattern for phase recognition, the STM-N frame is converted into an ODU frame having a different signal format, and the ODU signal format is converted from the ODU signal format into the STM signal format after the switching unit 18 so that the original signal can be converted. Signal transmission and switching control can be performed while maintaining the transparency of the STM-N frame without changing the overhead byte of a certain STM-N frame. Thereby, the second problem can be solved.
[0035]
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0036]
(First embodiment)
FIG. 3 shows a form in which the present invention is applied to an optical ADM ring system to realize a highly reliable network system having an instantaneous interruption switching function. The optical ADM ring system converts a plurality of signals received from a plurality of client interfaces into wavelengths, and multiplexes the signals onto a single optical fiber for transmission. This is a system that realizes large-capacity communication in the optical layer between them.
[0037]
The optical ADM ring system includes a client interface (IF, shown) 21 connected to a client device, a wavelength dropping / inserting unit 22 for dropping, inserting, and passing a signal from each client interface 21 into a multiplexed signal, It comprises a WDM interface unit 23 having a function of wavelength-multiplexing each optical signal routed by the add / drop unit 22 and transmitting it to another node.
[0038]
In FIG. 3, a four-node optical ADM ring system is configured by the optical ADM node devices 30, 40, 50, and 60, and a clockwise route A is provided between the optical ADM node device 30 and the optical ADM node device 40. , The signal path of the counterclockwise path B is set.
[0039]
By applying the hitless switching units 24 and 28 having the hitless switching function of this embodiment to the client interface units 21 and 27 of the optical ADM node devices 30 and 40, the route A and the route B can be changed as follows. It is possible to realize instantaneous interruption switching between switches.
[0040]
The phase recognition pattern is inserted into the client signal input from the client interface unit 21 of the optical ADM node device 30 by the hitless switching unit 24 equipped with the transmission side subsystem 10 of the hitless switching system of the present embodiment. The divided ODU signal is transmitted by branching through paths A and B. These ODU signals are phase-adjusted by different paths by the non-interruptible switching unit 28 equipped with the receiving-side subsystem 20 of the non-interruptible switching system of the optical ADM node device 40 according to the present embodiment. The ODU signal is read, and the ODU signal is output from the client interface unit 27 after the original signal is restored from the ODU signal.
[0041]
Thus, for example, when the optical ADM node device 40 detects a failure in the path A, it switches the selection system for reading the ODU signal from the path A to the path B within one bit, so that when the transmission path failure occurs, It is possible to automatically rescue a client signal without an instantaneous interruption.
[0042]
(Second embodiment)
FIG. 4 shows a form in which a highly reliable network system having an instantaneous interruption switching function is realized by applying the instantaneous interruption switching system of the present embodiment to an optical-cross-connect (OXC) system. is there.
[0043]
The optical cross-connect system is a system that realizes a large-capacity mesh network in an optical layer between a plurality of sites by interconnecting a plurality of OXC nodes 81 to 89. Each of the OXC nodes 81 to 89 transmits a signal received from a plurality of interface units through another interface unit after setting a route. In FIG. 4, the OXC nodes 81 to 89 implement a nine-point mesh network.
[0044]
In the network shown in FIG. 4, it is assumed that routes A and B by optical paths are set from the OXC node 81 to the OXC node 89. In this case, similarly to the first embodiment, the transmitting subsystem 10 of the present embodiment shown in FIG. 1 is connected to the IF unit 70 of the OXC node 81, and the receiving subsystem is connected to the IF unit 71 of the OXC node 89. By applying 20, the optical path can be switched between the paths A and B without any instantaneous interruption.
[0045]
【The invention's effect】
As described above, according to the present invention, on the transmitting side, a client signal is transmitted according to ITU-TG. The ODU signal is converted into an ODU signal specified in 709, a specific phase recognition multi-frame (identifier) is inserted into a part of the overhead byte of the ODU signal, and transmitted to two different paths. Detecting a specific multi-frame for phase recognition from the above, detecting the difference between the arrival times of the signals transmitted through different paths, and controlling the memory to absorb the difference between the arrival times, as described above, , The instantaneous interruption switching can be realized while preserving, and further, it is possible to avoid complication of the device configuration.
[Brief description of the drawings]
FIG. 1 is a block diagram of a hitless switching system according to an embodiment.
FIG. 2 is an ODU structure diagram.
FIG. 3 is a diagram for explaining the first embodiment.
FIG. 4 is a diagram illustrating a second embodiment.
FIG. 5 is a block diagram of a conventional hitless switching system (transmitting side).
FIG. 6 is a block diagram of a conventional hitless switching system (receiving side).
[Explanation of symbols]
1 ODU converter
2 Identifier giving unit
3 branch
4, 5 signal transmission unit
10 Sender subsystem
11, 12 signal receiving unit
13, 15 identifier detection unit
14 Memory controller
16, 17 memory section
18 Switching unit
19 original signal restoration unit
20 Receiver subsystem
21, 27 Client interface unit
22, 26 wavelength add / drop unit
23, 25 WDM interface
24, 28 Instantaneous interruption switching unit
30, 40, 50, 60 optical ADM node device
70, 71 Interface section
81-89 OXC nodes

Claims (12)

A transmitting subsystem for transmitting the original signal to two paths different from the working and protection paths; and a receiving subsystem for receiving the original signal from the two paths, wherein the transmitting subsystem performs phase adjustment together with the original signal. Means for branching and transmitting an identifier for use in a different path, wherein the receiving subsystem measures the phase difference between the identifiers for phase adjustment received from two different paths together with the same original signal and absorbs the phase difference. Instantaneous interruption switching system including a phase difference absorbing means, and a switching means for switching the signal having the phase difference absorbed between the working and the standby,
In the transmitting subsystem,
Signal format conversion means for performing a process of newly adding a control byte without changing the original signal before branching the original signal into two different paths;
A part of the control byte added by the signal format conversion means, an identifier providing means for providing a specific pattern as the identifier,
The reception-side subsystem further includes a signal restoration unit that restores the signal format converted by the signal format conversion unit to an original signal format after the switching of the signal selection system by the switching unit. Instantaneous interruption switching system. The signal format converting means converts the original signal to be switched to the uninterruptible power supply to the ITU-TG. 709, comprising an ODU conversion means for converting into an ODU signal format defined by the optical transport network,
The identifier assigning means includes means for assigning the specific pattern as an identifier for phase adjustment to a part of an overhead byte of an ODU signal,
The phase difference absorbing means,
Working identifier detecting means for detecting an identifier represented by the specific pattern from overhead bytes in the ODU signal received from the working transmission path;
Spare identifier detecting means for detecting an identifier represented by the specific pattern from overhead bytes in the ODU signal received from the spare transmission line;
Working memory means for temporarily storing the ODU signal received from the working transmission path;
Spare memory means for temporarily storing the ODU signal received from the spare transmission path;
A phase difference is detected from a difference between arrival times of the specific pattern in the ODU overhead detected by the working identifier detecting means and the spare identifier detecting means, and stored in the working memory means and the spare memory means based on the phase difference. Memory control means for matching the read phase of the ODU signal from the working memory means and the spare memory means by adjusting the time taken,
The switching means includes means for switching between a working system and a standby system by reading an ODU signal from the working memory means or the spare memory means, and the signal restoring means reads the ODU signal from the working memory means or the spare memory means. 2. The system according to claim 1, further comprising means for restoring the ODU signal to the original signal format. The means for giving the specific pattern is defined in ITU-T G. The instantaneous uninterruptible switching system according to claim 2, further comprising means for using a RES byte described in the 709 optical transport network as a phase adjustment identifier as an insertion position of the specific pattern. The means for giving the specific pattern is defined in ITU-T G. 3. The non-stop switching system according to claim 2, further comprising means for using an EXP byte described in the optical transport network as an identifier for phase adjustment as an insertion position of the specific pattern. The means for giving the specific pattern is defined in ITU-T G. The instantaneous interruption switching system according to claim 2, further comprising means for using an MFAS byte described in the 709 optical transport network as a phase adjustment identifier as an insertion position of the specific pattern. A transmitting subsystem including means for branching and transmitting an identifier for phase adjustment to a different path together with an original signal,
Signal format conversion means for performing a process of newly adding a control byte without changing the original signal before branching the original signal into two different paths;
A transmitting-side subsystem comprising: an identifier assigning unit that assigns a specific pattern as the identifier to a part of the control byte added by the signal format converting unit. The signal format converting means converts the original signal to be switched to the uninterruptible power supply to the ITU-TG. 709, comprising an ODU conversion means for converting into an ODU signal format defined by the optical transport network,
7. The transmission-side subsystem according to claim 6, wherein said identifier assigning means includes means for assigning the specific pattern as an identifier for phase adjustment to a part of an overhead byte of an ODU signal. The means for giving the specific pattern is defined in ITU-T G. The transmission-side subsystem according to claim 7, further comprising means for using a RES byte described in the 709 optical transport network as a phase adjustment identifier as an insertion position of the specific pattern. The means for giving the specific pattern is defined in ITU-T G. The transmission-side subsystem according to claim 7, further comprising means for using an EXP byte described in the 709 optical transport network as an identifier for phase adjustment as an insertion position of the specific pattern. The means for giving the specific pattern is defined in ITU-T G. The transmission-side subsystem according to claim 7, further comprising means for using an MFAS byte described in the 709 optical transport network as a phase adjustment identifier as an insertion position of the specific pattern. Phase difference absorbing means for measuring the phase difference of the phase adjustment identifiers received from the two different paths of the working and protection together with the same original signal and absorbing the phase difference; A receiving subsystem including switching means for switching between a standby mode and a standby mode,
Before branching out the original signal to two different paths, the transmitting side performs processing to newly add a control byte without changing the original signal, and the control byte added by this signal format conversion. Is given a specific pattern as the identifier,
A receiving-side subsystem, comprising: signal restoration means for restoring a signal format converted by the signal format conversion to an original signal format after switching of a signal selection system by the switching means. In the signal format conversion, the original signal to be switched without interruption is defined as ITU-TG. 709 is converted into an ODU signal format defined by the optical transport network, and the specific pattern is added to a part of overhead bytes of the ODU signal as an identifier for phase adjustment,
The phase difference absorbing means,
Working identifier detecting means for detecting an identifier represented by the specific pattern from overhead bytes in the ODU signal received from the working transmission path;
Spare identifier detecting means for detecting an identifier represented by the specific pattern from overhead bytes in the ODU signal received from the spare transmission line;
Working memory means for temporarily storing the ODU signal received from the working transmission path;
Spare memory means for temporarily storing the ODU signal received from the spare transmission path;
A phase difference is detected from a difference between arrival times of the specific pattern in the ODU overhead detected by the working identifier detecting means and the spare identifier detecting means, and stored in the working memory means and the spare memory means based on the phase difference. Memory control means for matching the read phase of the ODU signal from the working memory means and the spare memory means by adjusting the time taken,
The switching means includes means for switching between a working system and a standby system by reading an ODU signal from the working memory means or the spare memory means, and the signal restoring means reads the ODU signal from the working memory means or the spare memory means. The receiving-side subsystem according to claim 11, further comprising means for restoring the ODU signal to the original signal format.

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