JP3883132B2 - Line format setting method and communication apparatus using the same - Google Patents

Description

  The present invention relates to a line format setting method and a communication apparatus using the same, and more particularly to a line format setting method in a ring network and a communication apparatus using the same.

In recent years, with the demand for expansion of the entrants to the communication service industry and diversification of various services, it is often seen that communication line holders provide lines to non-communication line holders. At that time, it is only necessary to first specify the line provided by the line owner, and then to provide a line (STS bundle line) that automatically recognizes the line format of the main signal without any intervention and automatically sets the format. The demand is growing.
Furthermore, as a protection configuration of a network, a ring network configuration such as UPSR (Uniformal Path Switched Ring) is currently mainstream, and the demand for applying an STS bundle line to a UPSR network is increasing.
The function will be described below by taking a communication line OC-48 (Optical Carrier-48) line in SONET (Synchronous Optical Network) as an example. In the case of the OC-48 line, the STS bundle line can be set with one STS-48c line, four STS-12c lines, 18 STS-3c lines, or a combination of STS-12c and STS-3c. .
STS bundle lines are not allowed to have different format settings in both directions. That is, when one line S1-1 to the other line S2-1 sets the STS-1 format, the lines S2-1 to S1-1 are only allowed to set the STS-1 format. Setting the STS-3c format is not allowed. Therefore, it is necessary to preferentially select concatenation information from one of the lines and set the format.
Here, the concatenation information is information on the line format. For example, OC-48 has STS-1, STS-3c, STS-12c, and STS-48c in the format. Therefore, the STS bundle line has the priority setting (configuration setting) of the reception line of the concatenation information, and the format setting is preferentially executed according to the concatenation information from the configured line.
FIG. 1 is a configuration diagram of an example of a communication apparatus having a conventional STS bundle function, and FIG. 2 is a configuration diagram of a software processing function in FIG. In FIG. 1, the concatenation detection units 12A and 12B of the communication apparatus 10 detect concatenation information from the SOH (Section OverHead) pointers of the input signals of the lines S1-1 and S2-1, and the detection results are obtained. The CPU 14 is notified.
The line alarm detection units 16A and 16B detect line alarms such as LOS (Loss Of Signal), LOF (Loss Of Frame), AIS-L (Alarm Indication Signal-Line), and notify the CPU of the results. To do. When each of the cross-connect units 18A and 18B receives a format setting execution command from the CPU 14, it executes format setting.
In FIG. 2, as software processing in the CPU 14, the concatenation information reception line determination unit 20 compares the line alarm states of the lines S <b> 1-1 and S <b> 2-1, and the selector 22 compares the line alarm state with the higher line quality. Select concatenation information. If there is no line alarm on both lines, or if there is a line alarm on both lines, the concatenation information of the configured line (for example, S1-1) is selected.
The format setting execution processing unit 24 sends a format setting execution command to the cross-connect units 18A and 18B in FIG. 1 based on the selected concatenation information.
However, in the conventional apparatus that selects the reception line for the concatenation information by comparing the line alarm states as described above, the following problem occurs when the STS bundle line is applied to the UPSR network.
FIG. 3 shows a configuration diagram of a UPSR network to which an STS bundle line is applied. In the figure, the underlined lines indicate the configuration settings. Here, in the node that is executing the path switch such as the node A and the node C, the STS bundle line setting is performed for the line S3-1 between the lines S1-1 and S2-1.
In this case, when the configuration setting is set to the lines S1-1 and S2-1 on the UPSR network side, it is necessary to set the priority order between the lines S1-1 and S2-1, and the default side of the path switch is the priority order. have.
Here, when the signal input from the line S3-1 of the node A changes from STS-1 to STS-3c, if there is no failure in the network, the format is changed normally in all nodes. It can be carried out.
However, in the case where a failure occurs in the line between the nodes A and B, the following operation is performed. The format is normally changed in node A and node D. In the node B, since a line alarm has occurred in the line S1-1, the reception line of the concatenation information is switched to the line S2-1. Therefore, the format change cannot be changed until the node C format is changed. In node C, AIS-P (Alarm indication signal-Path) occurs in all paths of line S1-1. However, since no line alarm has occurred, the reception line of concatenation information remains S1-1. Yes, the line format cannot be changed. Therefore, there is a problem that the format cannot be changed in the node B and the node C, the format setting mismatch occurs in the network, and the main signal is disconnected.
In addition, when LOP-P (Loss of Pointer-path) occurs in the path in the STS bundle line, normal concatenation information cannot be detected, so the format setting cannot be performed, or an error occurs. There is a problem that there is a danger of performing the format setting.

The present invention is capable of surely automatically setting a format in a UPSR network when a failure occurs, and capable of recovering a failure when using an STS bundle line in the UPSR network, and a communication apparatus using the same The general purpose is to provide
In order to achieve this object, the present invention provides a line format setting method for setting a line format of an STS bundle line in a communication device constituting a ring network, and detects line alarms for each of a plurality of connected lines. Path alarm information is inserted into all paths of the line where the alarm is detected, path alarm information of all paths of each of the plurality of lines is detected, concatenation information of each of the plurality of connected lines is detected, and the plurality of the plurality of lines are detected. Based on the path alarm information of all the paths of each line, a reception line of concatenation information is selected, and the line format of the STS bundle line is set using the concatenation information of the selected reception line.
According to such a line format setting method, the automatic setting of the format can be surely performed in the UPSR network when a failure occurs, and the failure can be recovered when the STS bundle line is used in the UPSR network.

FIG. 1 is a configuration diagram of an example of a communication apparatus having a conventional STS bundle function.
FIG. 2 is a block diagram of the software processing function in FIG.
FIG. 3 is a configuration diagram of a UPSR network to which an STS bundle line is applied.
FIG. 4 is a block diagram of a first embodiment of a communication apparatus having an STS bundle function to which the present invention is applied.
FIG. 5 is a block diagram of the software processing function in FIG.
FIG. 6 is a configuration diagram of a second embodiment of a communication apparatus having an STS bundle function to which the present invention is applied.
FIG. 7 is a block diagram of the software processing function in FIG.
FIG. 8 is a configuration diagram of a third embodiment of the device to which the present invention is applied when the slot used for the UPSR network is fixed.
FIG. 9 is a configuration diagram of a fourth embodiment of the device to which the present invention is applied when the slot used for the UPSR network is not specified.
FIG. 10 is a configuration diagram of an embodiment of a ring partner line information recognition circuit unit.
FIG. 11 is a timing chart for explaining automatic detection of ring partner channel information.
FIG. 12 is a configuration diagram of a fifth embodiment of a communication apparatus having an STS bundle function to which the present invention is applied.
FIG. 13 is a block diagram of the software processing function in FIG.
FIG. 14 is a configuration diagram of an embodiment of a UPSR network using the communication device of the fifth embodiment as a node.
FIG. 15 is a block diagram of a sixth embodiment of a communication apparatus having an STS bundle function to which the present invention is applied.
FIG. 16 is a block diagram of the software processing function in FIG.
FIG. 17 is a configuration diagram of an embodiment of a UPSR network using the communication device of the sixth embodiment as a node.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 4 is a configuration diagram of a first embodiment of a communication apparatus having an STS bundle function to which the present invention is applied, and FIG. 5 is a configuration diagram of a software processing function in FIG.
In FIG. 4, the concatenation detection units 32A and 32B detect concatenation information from the H1 and H2 bytes that are pointers in the SOH in the input signals of the lines S1-1 and S2-1, and the detection result is sent to the CPU 34. Notice.
The line alarm detectors 36A and 36B detect each line alarm (LOS, LOF, AIS-L) of each of the lines S1-1 and S2-1. When a line alarm is detected, the AIS- Insert P (Alarm Indication Signal-Path).
The AIS-P detection units 38A and 38B detect AIS-P for each line and notify the CPU 34 of the detection result. When the cross-connect unit 40 receives the format setting execution command from the CPU 34, it executes the line format setting.
In FIG. 5, a concatenation information reception line determination unit 42 determines a line for receiving concatenation information using the AIS-P in the STS bundle of both lines S1-1 and S2-1, and selects a selector (SEL). ) 46 is switched.
AIS-P of all paths of the STS bundle of line S1-1 is ANDed by AND circuit 43A, and AIS-P of all paths of the STS bundle of line S2-1 is ANDed by AND circuit 43B. The concatenation information reception line determination unit 44 is supplied. The concatenation information reception line determination unit 44 switches the concatenation information reception line when an AIS-P has occurred in all the paths in the STS bundle. Even if there is one path in the STS bundle, the AIS-P If not, no switching is performed. When all paths of both lines are AIS-P, or when all paths of both lines are not AIS-P, priority is given to the concatenation information of the configuration setting line.
The format setting execution processing unit 48 notifies the cross-connect unit 40 of a format setting execution command according to the concatenation information selected by the selector 46.
In this embodiment, by selecting the concatenation information reception line by using the AIS-P information of all paths in the STS bundle, the conventional concatenation information reception line selection by line alarm comparison can be remedied. Even in the case where a failure has occurred in the line between nodes A and B shown in FIG. 3, since all paths in the STS STS bundle of node C1-1 are AIS-P, the concatenation information The reception line can be switched to the line S2-1, and an accurate line format can be automatically set even in the UPSR network when a failure occurs.
FIG. 6 is a block diagram of a second embodiment of the communication apparatus having the STS bundle function to which the present invention is applied, and FIG. 7 is a block diagram of the software processing function in FIG. 6 and 7, the same parts as those in FIGS. 4 and 5 are denoted by the same reference numerals.
In FIG. 6, the line alarm detectors 36A and 36B detect line alarms (LOS, LOF, AIS-L) of the lines S1-1 and S2-1. Insert -P. The AIS-P detection units 38A and 38B detect AIS-P and notify the CPU 34 of the detection result.
The concatenation detection units 32A and 32B in the PTR processing units 50A and 50B detect the concatenation information from the H1 and H2 bytes that are pointers in the SOH of the input signals of the lines S1-1 and S2-1, and LOP-P The detection units 51A and 51B detect HOP1 and H2 byte LOP-P information, and notify the CPU 34 of the detection results. When the cross-connect unit 40 receives the format setting execution command from the CPU 34, it executes the line format setting.
In FIG. 7, the concatenation information reception line determination unit 52 obtains a logical product of the AIS-P information of all paths in the STS bundle in the lines S1-1 and S2-1 by the AND circuits 53A and 53B, and performs an OR circuit 54A. , 54B obtain the logical sum of LOP-P in each STS bundle, and the OR circuits 54A, 54B take the logical sum of the logical product and the logical sum and supply the logical sum to the concatenation information reception line determination unit 56. The concatenation information reception line determination unit 56 determines the concatenation information reception line using this information, and switches the selector 46.
When an LOP-P alarm is generated on any path in the STS bundle or an AIS-P alarm is generated on all paths, concatenation information is selected from a line where no alarm is generated. If there is no alarm on both lines, or if both lines have an alarm, priority is given to the concatenation information on the configuration line.
The state continuation monitoring timer 57 monitors the continuation of the alarm state, and starts the timer triggered by the occurrence of the alarm, and restarts the timer when the alarm is cleared during the timer period. If the alarm is not cleared until the timer period ends, the selector 46 is switched according to the determination result. The monitoring time can be changed by setting the timer time.
The format setting execution processing unit 48 notifies the cross-connect unit 40 of a format setting execution command according to the concatenation information selected by the selector 46.
In the present embodiment, by using the LOP-P information in the STS bundle to determine the reception line of the concatenation information, it is possible to prevent incomplete format setting when the LOP-P occurs.
Further, by monitoring the concatenation information selection line determination result by the state continuation monitoring timer 57, the concatenation information selection line can be switched only by the LOP-P due to a failure, except for the LOP-P that occurs when the line format setting is changed. Can be done. As a result, an accurate line format can be automatically set.
By the way, the concatenation information reception line determination and the format setting can be performed by hardware. FIG. 8 shows a configuration diagram of a third embodiment of the device to which the present invention is applied when the slot used for the UPSR network is fixed. FIG. 8 shows a configuration for performing add / drop.
In FIG. 8, all of the STS bundles in the own line (for example, line S1-1), the ring partner line (for example, line S2-1), and the cross-connect destination line (for example, line S3-1) are AND circuits 60A to 60C. The logical product of the AIS-P information of the path is obtained, the logical sum of the LOP-P in each STS bundle is obtained by the OR circuits 61A to 61C, and the logical product and the logical sum are taken by the OR circuits 62A to 62C. Is supplied to the ALM comparison unit 63 as alarm information.
The ALM comparison unit 63 determines the reception line of concatenation information from the alarm information of the own line, the ring partner line, and the cross-connect destination line for each path, and notifies the selector control unit 64 of the received line. Here, when an LOP-P alarm is generated in any path in the STS bundle or an AIS-P alarm is generated in all paths, concatenation information is selected from a line in which no alarm is generated. If there is no alarm on all lines, or there is an alarm on all lines, priority is given to the concatenation information on the configuration line.
The timer unit 65 starts the timer with the occurrence of an alarm as a trigger, and stops the timer when the alarm is cleared during the timer period. When the alarm continues during the timer period, the output of the selector control unit 64 is validated, and the selector control unit 64 receives it and switches the selector 66 for selecting the concatenation information reception line for each path. .
The format setting unit 67 performs format setting in a cross-connect unit (not shown) according to the concatenation information for each path selected by the selector 66. The concatenation information for each path selected by the selector 66 is stored in the hard register 68. The software can receive information from the hardware register 68 and recognize that the hardware has changed the format setting.
In this embodiment, by providing a hardware configuration for determining and switching the reception line of concatenation information in a slot-supported UPSR network compatible device, it is possible to reduce the time required for switching the line format in the UPSR network in a short time. It becomes possible to recover.
FIG. 9 shows a configuration diagram of a fourth embodiment of the device to which the present invention is applied when the slot used for the UPSR network is not specified. The apparatus configuration shown in FIG. 9 is provided for each path.
If the slot to be used for the UPSR network is not specified, it is necessary to first set the ring partner line of the UPSR in the hard register 71. Each of the selectors 70A, 70B, and 70C selects ring partner line concatenation information from concatenation information of all paths based on ring partner line information set in the hard register 71.
Each of the selectors 72A, 72B, 72C selects path alarm information in the ring partner line from the alarm information of all paths based on the ring partner line information set in the hard register 71. For the alarm information of each path, the AND circuit 77 calculates the logical product of the AIS-P information of all paths in each bundle, and the OR circuit 78 calculates the logical sum of the LOP-P of all paths in each bundle. The OR circuit 79 obtains the logical sum of the logical product and the logical sum.
The selector control units 74A, 74B, and 74C have their own path alarm information, path alarm information in the ring partner line selected by the selectors 76A, 76B, and 76C, alarm information of the cross-connect destination path that has been cross-connected, and Based on the configuration setting information, the reception line of the concatenation information is determined, and the selectors 72A, 72B, and 72C are switched.
Based on the concatenation information selected by the selectors 72A, 72B, 72C, the format setting of the own path is executed and the hard register 71 is notified.
By the way, in the apparatus configuration for the UPSR drop line, since there is no ring partner line, each of the selectors 76A, 76B, and 76C outputs a high level (with an alarm), and the selector control units 74A, 74B, and 74C The reception line of the concatenation information is determined from the alarm information of the cross-connect destination path that has been cross-connected, and the configuration setting information, and the selectors 72A, 72B, and 72C are switched based on the determination result. Note that since there are two cross-connect destination paths in the drop side path, a logical product of the alarm information of the two paths in the AND circuit 80 is used as alarm information of the cross-connect destination path.
At this time, the drop-side path selector 72C selects either the concatenation information of the own path or the concatenation information obtained by switching the concatenation information of the two paths at the cross-connect destination by the path switch (PSW) 81. The
In this embodiment, the ring alarm line path alarm information set in the hard register 71, the cross-connected line path alarm information, and the configuration setting information are used to determine and switch the concatenation information reception line. By executing the above, even in a device in which the slot used for the UPSR is not specified, it is possible to determine the reception line of concatenation information and switch by hardware, and at the time of switching the line format in the UPSR network. It is possible to recover from a failure in a short time.
FIG. 10 shows a configuration diagram of an embodiment of a ring partner line information recognition circuit unit. In the figure, an ACME 90 and an ACMW 92 are memories having slot and path number information that are cross-connected to each path. ACME 90 corresponds to the UPSR east pass, and ACMW 92 corresponds to the UPSR west pass. The ACM information is serial data transferred to the path switch (PSW) 94 at the same timing as the east and west information of each path. The path switch 94 selects one of the pieces of information, and the cross-connect unit 73 (same as the cross-connect unit shown in FIG. 9) performs line setting based on the information. This is a configuration of a conventional UPSR compatible cross-connect device.
In the present invention, ring partner line information is automatically detected by hardware from this ACM information. The timing chart shown in FIG. 11 shows an example of detecting the ring counterpart of the slot 1 path 1 in the case of the east slot 1, the west slot 2, and the drop slot 3.
The comparison unit (COMPE) 97 and the comparison unit (COMPW) 98 compare the own slot and the path number (slot 1, path 1) with the information of the ACME 90 and the ACMW 92, and generate a trigger pulse if they match. A logical sum of the ACME information and the output of the comparator 98 and the logical product of the ACMW information and the output of the comparator 97 are input to the flip-flop 99 as a hard register and latched by the trigger pulse. The Information stored in the flip-flop 99 is supplied to the selectors 70A to 70C and 76A to 76 shown in FIG. 9 as ring partner line information.
Here, since slot 1 path 1 is set in ACME 90 of slot 3 path 1, slot 2 path 1 set in ACMW 92 is output as ring partner line information.
According to this embodiment, in FIG. 9, the ring partner line information preset in the hardware register 71 can be automatically detected from the ACM information by hardware. As a result, setting of ring partner line information for all paths becomes unnecessary, and the scale of the hard register can be reduced.
Further, the STS bundle function can be realized by hardware only by performing the conventional cross-connect setting first, and it is possible to recover from a failure at the time of switching the line format in the UPSR network in a short time.
FIG. 12 is a block diagram of a fifth embodiment of a communication apparatus having an STS bundle function to which the present invention is applied, and FIG. 13 is a block diagram of the software processing function in FIG. 12 and 13, the same parts as those in FIGS. 6 and 7 are denoted by the same reference numerals.
In FIG. 12, the concatenation detection unit 32A detects concatenation information from the H1 and H2 bytes that are pointers in the SOH of the input signal of the line S1-1, and notifies the CPU 100 of the detection result. The line alarm detection unit 36A detects a line alarm (LOS, LOF, AIS-L) of the line S1-1 and notifies the CPU 100 of the detection result.
The POH detection unit 102 extracts the remote line alarm information from, for example, the G1 byte of the POH (Pht OverHead) of the input signal of the line S1-1 and notifies the CPU 100 of it. Here, the POH is not terminated and is sent to the next node as it is. When the cross-connect unit 104 receives a format setting execution command from the CPU 100, the cross-connect unit 104 executes line format setting.
When receiving the notification of the remote line alarm from the CPU 100, the POH inserting unit 106 inserts the remote line alarm information into the G1 byte of the POH of the output signal of the line S2-1. Similarly, the same configuration is provided in both directions with respect to the direction from the line S2-1 to the line S1-1.
In FIG. 13, the AND circuit 105 takes the logical product of the line alarms LOS, LOF, AIS-L of the line S1-1, and the AND circuit 106 takes the logic of the line alarms LOS, LOF, AIS-L of the line S2-1. The product is taken and supplied to the POH processing unit 107.
The POH processing unit 107 generates remote line alarm information for the line S2-1 when the logical product of the line alarms LOS, LOF, and AIS-L of the line S1-1 is at a high level, and transmits the remote path alarm information for the path that has been cross-connected. When the logical product of the line alarms LOS, LOF, and AIS-L of the line S2-1 is high level, the remote line alarm information for the line S1-1 is generated and the cross-connected destination is notified. Notify the POH insertion part of the path.
The concatenation information reception line determination unit 108 is based on the remote line alarm information of both lines S1-1 and S2-1 from the POH detection unit 102, the logical product of each line alarm from the AND circuits 105 and 106, and the configuration setting information. The reception line of concatenation information is determined and the selector 46 is switched.
Here, when a remote line alarm or a line alarm occurs in one line, concatenation information is received from a line in which no alarm has occurred. If a remote line alarm or line alarm occurs on both lines, or if both line alarms do not occur, the configuration setting line has priority.
The format setting execution processing unit 48 notifies the cross connection unit 104 and the like of a format setting execution command according to the concatenation information selected by the selector 46.
FIG. 14 shows a configuration diagram of an embodiment of a UPSR network using the communication device of the fifth embodiment as a node. In the figure, the underlined lines indicate the configuration settings. The numbers with circles in the figure correspond to step numbers.
(1) A failure occurs on the line between nodes A and B.
(2) A line alarm LOS occurs on the line S1-1 of the node B.
(3) The node B that has detected the line alarm in the line S1-1 transmits the line alarm information using the POH in the STS bundle of the line S2-1.
(4) The node C switches the concatenation information reception line from the configured line S1-1 to the line S2-1 based on the line alarm information of the POH from the direction of the line S1-1, and formats based on the information. Make a change.
(5) The node C transmits the line alarm information on the POH in the STS bundle of the line S3-1.
FIG. 15 is a block diagram of a sixth embodiment of a communication apparatus having an STS bundle function to which the present invention is applied, and FIG. 16 is a block diagram of the software processing function in FIG. 15 and 16, the same parts as those in FIGS. 12 and 13 are denoted by the same reference numerals.
In FIG. 15, the concatenation detection unit 32A detects concatenation information from the H1 and H2 bytes that are pointers in the SOH of the input signal of the line S1-1, and notifies the CPU 110 of the detection result. The line alarm detection unit 36A detects a line alarm (LOS, LOF, AIS-L) of the line S1-1 and notifies the CPU 110 of the detection result.
The POH detection unit 112 extracts concatenation change information from, for example, the G1 byte of the POH of the input signal of the line S1-1 and notifies the CPU 110 of it. Here, the POH is not terminated and is sent to the next node as it is. When the cross-connect unit 114 receives a format setting execution command from the CPU 110, it performs line format setting.
When receiving the notification of the concatenation change information from the CPU 110, the POH insertion unit 116 inserts the concatenation change information into the G1 byte of the POH. Similarly, the same configuration is provided in both directions with respect to the direction from the line S2-1 to the line S1-1.
In FIG. 16, the concatenation information reception line determination unit 117 determines the reception line of concatenation information from the concatenation change information, line alarm, and configuration setting information of both lines, and switches the selector 46. In this case, preferential concatenation information is received from the line that has received the concatenation change information. However, if the concatenation change information is received from both lines, the config setting line has priority.
When a line alarm occurs, the concatenation information reception line determination unit 117 receives concatenation information from a line where no alarm has occurred. If a line alarm occurs on both lines, or if both line alarms are not present, the config setting line has priority.
The format setting execution processing unit 48 notifies the format setting execution command to the cross-connect unit 116 according to the concatenation information selected by the selector 46, and also notifies the POH insertion unit 116 of the path in the STS bundle where the format setting has been changed. Notification of concatenation change information.
FIG. 17 shows a configuration diagram of an embodiment of a UPSR network using the communication device of the sixth embodiment as a node. In the figure, the underlined lines indicate the configuration settings. The numbers with circles in the figure correspond to step numbers.
(1) A failure occurs on the line between nodes A and B.
(2) The input signal format of the line 3-1 of the node A changes from STS-1 to STS-3c.
(3) The node A changes its own line format, and the concatenation change information indicating that the concatenation information has changed in the STS bundle is sent to the POH in the STS bundle of the lines S1-1 and S2-1. Put it on and send it.
(4) Since the configuration of the node D is originally the line S2-1, the format is changed as it is from the concatenation information of the line S2-1, and the POH concatenation change information is overwritten and transmitted to the line S1-1. To do.
(5) Since node C receives concatenation change information from line S2-1, node C switches the concatenation information reception line to line S2-1 and changes the format based on the concatenation information.
(6) Here, node B does not receive the concatenation change information because the line on the receiving side is disconnected, and the line format is not changed, so that node C remains in STS-1 without changing the line format of node B. The line format cannot be changed with the concatenation information from the line S1-1 configured. However, since the concatenation change information is received from the line S2-1, the node C can switch the concatenation information reception line to S2-1 and change the line format to STS-3c based on the information. Can do. Further, the node C overwrites the POH concatenation change information and transmits it to the line S3-1.
In this way, the node that has changed the line format transmits the concatenation change information using POH, and the line format is changed by preferentially using the concatenation information of the line that has received the concatenation change information. By doing so, it is possible to automatically set the correct line format even in the UPSR network at the time of failure.
As described above, in the present invention, the line alarm information of each line, the LOP-P of all paths in the STS bundle, and the AIS-P states of all paths are compared, and the reception line of the concatenation information is selected. As a result, it becomes possible to perform the automatic setting of the format reliably in the UPSR network at the time of failure occurrence, and it becomes possible to recover from the failure when using the STS bundle line in the UPSR network.
In addition, the remote line alarm information or the concatenation change information is transmitted using the POH in the STS bundle line, and the reception line of the concatenation information is selected using the information. The format can be surely automatically set, and the failure can be recovered when the STS bundle line is used in the UPSR network.
In addition, by providing a circuit configuration that implements the determination and switching processing of concatenation information reception lines in hardware, the time required to automatically set the format of the entire network is shortened, and it is possible to reduce the trouble caused by line format changes in the UPSR network. It will be possible to recover in time.
From the above, it is possible to provide an STS bundle line that can be reliably and quickly recovered from a failure at the time of changing the line format in the UPSR network, and an STS bundle line compatible device having a highly reliable failure recovery function is provided. It becomes possible to provide.
By the way, in the through station such as the nodes B and D in FIG. 14, one configuration setting is made for one cross-connect. In addition, in an add / drop station such as nodes A and C, one configuration setting is made for two cross-connects (between lines S1-1 and S3-1 and between S2-1 and S3-1). Therefore, the same configuration is simultaneously set for S1-1, S2-1, and S3-1.
In the configurations shown in FIG. 4 and FIG. 6, in the through stations such as nodes B and D, the alarm information of the lines S1-1 and S2-1 is compared and the configuration is switched. It is possible to cope with the fact that it is set between −1 and S2-1. In the configuration shown in FIGS. 12 and 15, the through station has the configuration shown in FIGS. 12 and 15 in both directions of lines S1-1 and S2-1 and compares the alarm information in both directions to switch the configuration. I do.
The present invention is not limited to SONET, and can be applied to SDH (Synchronous Digital Hierarchy).
The line alarm detection units 36A and 36B correspond to the line alarm detection unit described in the claims, the AIS-P detection units 38A and 38B correspond to the path alarm detection unit, and the concatenation detection units 32A and 32B include the concatenation information. Corresponding to the detecting means, the concatenation information receiving line determining sections 42, 52, 108, 117, the selector 46 and FIGS. 8 and 9 correspond to the concatenation information receiving line selecting means, and the LOP-P detecting sections 51A, 51B Corresponding to pointer loss detection means, state continuation monitoring timer 57 and timer 65 correspond to timer means, ACME 90 and ACMW 92 correspond to storage means, POH insertion section 106 corresponds to remote alarm information insertion means, POH detection section 102 corresponds to remote alarm information detection means, POH insertion 116 corresponds to the concatenation change information insertion means, POH detector 112 corresponds to the concatenation change information detecting means.

Claims (12)

In a line format setting method for setting a line format of an STS bundle line in a communication device constituting a ring network,
Detects line alarms for each of multiple connected lines, inserts path alarm information into all paths of the line where the line alarm was detected,
Detect path alarm information of all paths of each of multiple lines,
Detect concatenation information for each of multiple connected lines,
Based on the path alarm information of all paths of each of the plurality of lines, select a reception line for concatenation information,
A line format setting method for setting a line format of the STS bundle line using concatenation information of a selected reception line. In a line format setting method for setting a line format of an STS bundle line in a communication device constituting a ring network,
Detects line alarms for each of multiple connected lines, inserts path alarm information into all paths of the line where the line alarm was detected,
Detect path alarm information of all paths of each of multiple lines,
Detect pointer loss on each path of multiple lines,
Detect concatenation information for each of multiple connected lines,
Based on the path alarm information of all paths of each of the plurality of lines and the pointer disappearance information of each path, a reception line for concatenation information is selected,
A line format setting method for setting a line format of the STS bundle line using concatenation information of a selected reception line. In a line format setting method for setting a line format of an STS bundle line in a communication device constituting a ring network,
Detects line alarms for each of multiple connected lines, inserts path alarm information into all paths of the line where the line alarm was detected,
When detecting the line alarm, remote alarm information is inserted into overhead information and sent to the connected line,
Detects remote alarm information for each connected line,
Detect concatenation information for each of multiple connected lines,
Based on the path alarm information of all the paths of each of the plurality of lines and the remote alarm information of each of the plurality of lines, select a reception line for concatenation information,
A line format setting method for setting a line format of the STS bundle line using concatenation information of a selected reception line. In a line format setting method for setting a line format of an STS bundle line in a communication device constituting a ring network,
Detects line alarms for each of multiple connected lines, inserts path alarm information into all paths of the line where the line alarm was detected,
Detects concatenation change information for each of multiple connected lines,
Detect concatenation information for each of multiple connected lines,
Based on the path alarm information of all the paths of each of the plurality of lines and the concatenation change information of each of the plurality of lines, select a reception line of concatenation information,
A line format setting method of inserting concatenation change information into overhead information and sending it to a connected line when the line format of the STS bundle line is set using concatenation information of a selected reception line. In a communication device that configures a ring network and sets the line format of an STS bundle line,
Line alarm detection means for detecting a line alarm for each of a plurality of connected lines and inserting path alarm information into all paths of the line where the line alarm is detected;
Path alarm detection means for detecting path alarm information of all paths of each of a plurality of lines;
A concatenation information detecting means for detecting concatenation information of each of a plurality of connected lines;
Concatenation information reception line selection means for selecting a reception line of concatenation information based on path alarm information of all paths of each of the plurality of lines,
A communication apparatus for setting a line format of the STS bundle line using concatenation information of a selected reception line. In a communication device that configures a ring network and sets the line format of an STS bundle line,
Line alarm detection means for detecting a line alarm for each of a plurality of connected lines and inserting path alarm information into all paths of the line where the line alarm is detected;
Path alarm detection means for detecting path alarm information of all paths of each of a plurality of lines;
Pointer loss detection means for detecting pointer loss of each path of each of a plurality of lines;
A concatenation information detecting means for detecting concatenation information of each of a plurality of connected lines;
Concatenation information reception line selection means for selecting a reception line of concatenation information based on path alarm information of all paths of each of the plurality of lines and pointer loss information of each path,
A communication apparatus for setting a line format of the STS bundle line using concatenation information of a selected reception line. The communication device according to claim 6.
Timer means for selecting a reception line for concatenation information by the concatenation information reception line selecting means when the pointer loss period of each path of each of the plurality of lines is counted and the pointer loss period exceeds a predetermined value. Communication device having. The communication device according to claim 6 or 7,
A communication device in which a slot used for a one-way path switching ring is fixed among slots of the plurality of lines. The communication device according to claim 6.
The slot used for the one-way path switching ring among the slots of the plurality of lines is not specified,
Storing means for storing ring partner line information of each of the plurality of lines;
The concatenation information reception line selection means selects a reception line for concatenation information based on path alarm information of all paths of a plurality of lines selected based on the ring partner line information and pointer loss information of each path. apparatus. The communication device according to claim 9, wherein
A communication device that generates ring partner line information for each of the plurality of lines using memory information used for cross-connect setting. In a communication device that configures a ring network and sets the line format of an STS bundle line,
Line alarm detection means for detecting a line alarm for each of a plurality of connected lines and inserting path alarm information into all paths of the line where the line alarm is detected;
Remote alarm information insertion means for inserting remote alarm information into overhead information and sending it to a connected line when a line alarm is detected by the line alarm detection means;
Remote alarm information detecting means for detecting remote alarm information of each of a plurality of connected lines;
A concatenation information detecting means for detecting concatenation information of each of a plurality of connected lines;
Concatenation information reception line selection means for selecting a reception line of concatenation information based on path alarm information of all paths of each of the plurality of lines and remote alarm information of each of the plurality of lines,
A communication apparatus for setting a line format of the STS bundle line using concatenation information of a selected reception line. In a communication device that configures a ring network and sets the line format of an STS bundle line,
Line alarm detection means for detecting a line alarm for each of a plurality of connected lines and inserting path alarm information into all paths of the line where the line alarm is detected;
A concatenation change information detecting means for detecting concatenation change information of each of a plurality of connected lines;
A concatenation information detecting means for detecting concatenation information of each of a plurality of connected lines;
Concatenation information reception line selection means for selecting a reception line of concatenation information based on path alarm information of all paths of each of the plurality of lines and concatenation change information of each of the plurality of lines;
Concatenation change information insertion means for inserting concatenation change information into overhead information and sending it to the connected line when the line format of the STS bundle line is set using the concatenation information of the selected reception line. Communication device.

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