JP4190880B2 - SDH transmission system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an SDH transmission system, and in particular, at the time of failure uninterrupted switching in an SDH transmission system. Flapping prevention technique About.
[0002]
[Prior art]
The SDH (Synchronous Digital Hierarchy) transmission system is an international standard digital transmission multiplexing configuration established by ITU-T (International Telecommunication Union Telecommunication Standardization Sector) in 1988. Based on 156 Mbps, a digital transmission system having a transmission rate of 156 Mbps × N (N is an arbitrary integer) is configured. A conventional technique in such a technical field, in particular, a technique for preventing malfunction of the apparatus at the time of clock disturbance is disclosed (for example, refer to Patent Document 1).
[0003]
[Patent Document 1]
Japanese Patent Laid-Open No. 7-64666 (pages 3 to 4, FIG. 1)
[0004]
FIG. 12 is a block diagram showing the configuration of the uninterruptible switching device in the conventional SDH transmission system. The SDH transmission system 100 has a redundant configuration of an operating system 101A and a standby system (or non-operating system) 101B. At the time of switching between the active system 101A and the standby system 101B, the in-device delays of the active system 101A and the standby system 101B are adjusted by the delay adjusting unit 102 having the delay units 102A and 102B, respectively, so that they match. In other words, the synchronization is realized by switching the switching unit 103 by absorbing the delay difference between the active system 101A and the standby system 101B by synchronizing multi-frames using the J1 byte of POH (overhead). Automatic switching when an error occurs is realized without instantaneous interruption by error detection by B3 byte on POH and P-AIS (Alarm Indication Signal) detection.
[0005]
Next, FIG. 13 illustrates a specific example of a switching control unit that performs switching control of the switching unit 103 illustrated in FIG. That is, the state transition (switching determination) unit 110 outputs the switching instruction control signal 113 to perform switching control of the switching unit 103. The state transition unit 110 receives the alarm information 111 on the active system 101A side, the alarm information 112 on the standby system 101B side, and a feedback signal 114 indicating the previous state.
[0006]
Next, FIG. 14 is a timing chart for explaining the operation of the conventional SDH system 100. This shows the relationship between actual switching and notification in the case where the monitoring of the upper monitoring system collects the state at a constant cycle by polling and has protection several times (for example, three times). In FIG. 14, (a) shows a polling cycle performed at a constant cycle. (B) and (c) show the error occurrence states of the active system 101A and the standby system 101B, respectively, where “1” is an error occurrence state and “0” is no error occurrence (normal). (D) shows the actual switching operation, and (e) shows the active system selection or standby system selection notification from the actual host monitoring apparatus.
[0007]
When this method is used, in order to generate synchronization timing to the J1 byte for multi-frame synchronization, regarding the B3 error that occurred before the insertion point of the J1 byte and the failure that occurred outside the device, there is a frame in which an error exists. Since switching points are input at the same timing, switching does not occur. However, with regard to P-AIS, there is a difference in timing depending on the number of pointer ends and insertion points in the system from the J1 insertion point to the phase adjustment unit. As a result, unnecessary switching within the apparatus occurs for a failure that occurs outside the apparatus. In addition, when an error repeatedly occurs and recovers under the same conditions, notifications for switching up to the monitoring system occur frequently, and important alarms cannot be monitored.
[0008]
In order to cope with such a situation, the following two methods have been proposed.
(1) The monitoring system is collected in a polling format to prevent frequent notifications.
(2) Provide protection for switching and suppress switching itself.
In the former case, it may not be possible to monitor the case where the switching occurs instantaneously, and an important fault that needs to be dealt with may be overlooked. In addition, in the failure timing and the alarm input state, the selection system differs depending on the switching state before error input and the switching state after error input, and as a result, switching may be notified.
[0009]
Specific examples showing the eight states shown in FIGS. 2B to 9B will be described. In each of these drawings, (a) shows alarm information 111 of the active system 101A, (b) shows alarm information 112 of the standby system 101B, and (c) shows a switching state signal 113 which is an output from the state transition unit 110. In the alarm information 111 and 112, the presence / absence of an alarm is indicated by “1” and “0”, respectively. Further, in the switching state signal 113, the active system 101A selection is indicated as “0”, the standby system selection is indicated as “1”, and the active system 101A is selected in advance.
[0010]
Example 1 shown in FIG. 2 (B) is a case where an alarm is detected first on the operating system 101A side from no alarm in both systems. The switching state signal 113 becomes the standby system selection state “1” at the time of this alarm occurrence. Example 2 shown in FIG. 3B is a case where an alarm is first detected in the standby system 101B from an alarm-free state in both systems. The switching state signal 113 remains the active system selection “0” and does not change. Example 3 shown in FIG. 4B is a case in which an instantaneous alarm is detected in the active system 101A first from an alarm-free state in both systems, and then an instantaneous alarm is also detected in the standby system 101B. The switching state signal 113 is in the standby system selection state “1” only between these two alarms. Example 4 shown in FIG. 5B is a case in which an instantaneous alarm is generated in the standby system from an alarm-free state in both systems, and then an instantaneous alarm is also generated in the operational system. The switching state signal 113 is set to the standby system selection state when an instantaneous alarm occurs in the operation system.
[0011]
On the other hand, Example 5 shown in FIG. 6B is a case where both systems are in an alarmed state, the operating system first has no alarm (recovery), and the standby system also has no alarm. The switching state signal 113 remains the active system selection state “0” and does not change. Example 6 shown in FIG. 7B shows that both systems With alarm This is a case where the standby system has no alarm first, and then the active system has no alarm. The switching state signal 113 becomes the standby system selection state “1” when the standby system has no alarm. Example 7 shown in FIG. 8B is a case in which both systems are in an alarmed state, and the operational alarm recovers instantaneously first, and then the operational alarm recovers instantaneously. The switching state signal 113 enters the standby system selection state when the standby system is instantaneously restored. Finally, Example 8 shown in FIG. 9B is a case where the standby system is instantaneously recovered first from the alarm state in both systems, and then the operational system is instantaneously recovered. The switching state signal 113 is in the standby system selection state from the instantaneous recovery of the standby system to the instantaneous recovery of the active system.
[0012]
As described above, in the case of Example 1, Example 4, Example 6 and Example 7, although the alarm is detected in both the active system and the standby system, the final switching direction is an event (alarm). Different from before the outbreak. Therefore, there exists a state where the switching can be seen.
[0013]
On the other hand, in the latter case, since switching is prohibited without instantaneous interruption, the uninterruptible function that improves the quality of the transmission line system is hindered, resulting in deterioration of transmission line quality. there is a possibility. In this case, a switching permission bit is provided, and once switching occurs, the switching permission bit is set to “switching prohibited”, and a switchover occurs from a higher-level monitoring and control system device within a certain period of time. When such a situation occurs, it has a function of switching back from the host control system and masking the switching operation itself. With this function, the flutter of the switching notification itself is suppressed, but error recovery at the time of switching (switching back) is impossible, and a frame including an error is sent to the downstream device. In addition, since switching is performed when switching back in case of flapping, no warning is given to the upper level monitoring device regarding the SD level (error of 10 −6 or less). , Do not notify the inherent failure.
[0014]
[Problems to be solved by the invention]
The first problem is that unnecessary switching notifications frequently occur in the apparatus for instantaneous failures outside the apparatus. That is, due to failures outside the device, switching within the device occurs frequently, and it takes time to check other alarms in the monitoring system, and it takes effort to identify the failure location. The second problem is that when notification is suppressed (that is, switching itself is suppressed), an error that can be relieved without protection cannot be relieved by switching protection, which is an advantage of non-instantaneous switching. The road quality is deteriorated.
[0015]
OBJECT OF THE INVENTION
The present invention has been made in view of the above-described problems of the prior art.When monitoring a switching state from a higher-level monitoring device by polling, the occurrence of unnecessary alarms is suppressed without degrading the quality of the transmission line, An object of the present invention is to provide an SDH transmission system that facilitates monitoring.
[0016]
[Means for Solving the Problems]
In order to solve the above-described problems, the SDH transmission system according to the present invention has the following characteristic configuration.
[0017]
(1) Operational system and standby system A feedback signal based on the alarm information on the active system side, the alarm information on the standby system side, and the switching instruction signal output from the state transition unit is input to the state transition unit that performs the switching determination. In the SDH transmission system configured to switch without interruption from the active system to the standby system or vice versa,
A multi-bit status signal indicating the previous state is input to the state transition unit, and the new selection direction is switched by the status signal in addition to the alarm information on the active system side, the alarm information from the standby system, and the feedback signal. SDH transmission system.
[0018]
(2) The above A timer to which one bit of a multi-bit status signal is input, and a time-out output from the timer is input to the state transition unit The SDH transmission system according to (1) above.
[0019]
(3) The above The set time of the timer is the monitoring section corresponding to the flutter protection period the above (2) SDH transmission system.
[0020]
(4) The plurality Bit Status signal Is a status 0 indicating whether the previous state is an abnormal state of both the active system and the standby system, status 1 indicating a time-out state corresponding to the monitoring section, and the active system and the standby in the monitoring section Status 2 indicating which of the systems is to be monitored, Status 3 indicating whether the alarm timer is activated in response to the occurrence of an alarm in the monitoring section, or recovery by alarm recovery, and the monitoring target is in the monitoring section It includes status 4 indicating that it has occurred and status 5 indicating the direction of selection when the timer is started (the previous state if switching has occurred) the above (2) Or the SDH transmission system of (3).
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the configuration and operation of a preferred embodiment of the SDH transmission system according to the present invention will be described in detail with reference to the accompanying drawings.
[0024]
FIG. 1 is an explanatory diagram of a control unit that controls a switching unit of a preferred embodiment of the SDH transmission system according to the present invention. The control unit of the switching unit includes a state transition unit (switch determination unit) 10. The state transition unit 10 includes the alarm information 11 on the operating system side and the alarm information 12 on the standby system side as in the conventional technology described above. A feedback signal 14 indicating the previous control state is input, and a switching instruction (control) signal 13 is output. That is, the state transition unit 10 includes (1) a selection direction and a switching state at the current stage, (2) a new operation standby state, and (3) as signals necessary for the existing uninterrupted switching. A new switching direction and switching state are input.
[0025]
Further, in the SDH transmission system according to the present invention shown in FIG. 1, the state transition unit 10 is fed back from the above-described alarm information 11 on the operating system side, alarm information 12 on the standby system side, and the switching instruction signal 13. In addition to the feedback 14 as the current state, a 6-bit status signal (or status bit) 15 of status 0 to status 5 is output. These status bits 15 are processed and input. That is, a 6-bit status signal 15 is further added to the prior art shown in FIG. 13, and the new state and the selection direction are added to the output. These status signals 15 are configured to switch the new selection direction. Further, the timer 16 is started using one bit of the status (for example, status 1), and the timeout of the timer 16 is input to the state transition unit 10.
[0026]
With the configuration shown in FIG. 1, switching is performed based on the error state (alarm information) of the main signal system. When switching is performed with this configuration, a 6-bit status signal 15, that is, status 0 to status 5 is output. This status signal 15 is processed, and is composed of a register indicating a previous state as a 6-bit input. Here, status 0 to status 5 are as follows.
Status 0: Information indicating whether the previous state is an abnormal state of both systems.
Status 1: A start signal for the timer 16 that determines whether or not the flicker occurs or may occur in the future, so that it is within the monitoring section (time). At the time of input to the state transition unit 10, a timer timeout state is indicated.
Status 2: Signal indicating which selection is monitored within the monitoring section.
Status 3: A signal indicating which alarm is monitored in the monitoring section.
Status 4: A signal indicating that a monitoring target has occurred in the monitoring section.
Status 5: A signal indicating the selection direction at the time of timer activation (the previous state when switching has occurred).
[0027]
Next, the operation of the SDH transmission system of the present invention will be described based on the eight states of Examples 1 to 8, with reference to the timing charts of FIGS. Examples 1 to 8 are the same as FIGS. 2B to 9B. That is, Example 1 shown in FIG. 2A is a case where an alarm is detected first on the operating system side and an alarm is also detected on the standby system within the flutter protection time in a state where there is no both-system alarm. Example 2 shown in FIG. 3A is a case where, in the absence of both system alarms, an alarm is detected first in the standby system, and an alarm is also detected in the active system within the flutter protection time. Example 3 shown in FIG. 4A is a case where an instantaneous alarm is detected first in the active system and an instantaneous alarm is also detected in the standby system within the flutter protection time in a state where there is no both-system alarm. Example 4 shown in FIG. 5A is a case where an instantaneous alarm is detected first in the standby system and an instantaneous alarm is also detected in the operational system within the flutter protection time in a state where there is no both-system alarm. Example 5 shown in FIG. 6A is a case in which the alarm is recovered first in the active system and the alarm is recovered in the standby system within the flicker protection time in both system alarm states. Example 6 shown in FIG. 7A is a case where, in both system alarm states, the standby system recovers from the alarm first, and the operating system also recovers within the flutter protection time. Example 7 shown in FIG. 8A is a case where, in both system alarm states, the operating system alarm is instantaneously recovered first, and the standby system alarm is also instantaneously recovered within the flutter protection time. Further, Example 8 shown in FIG. 9A is a case in which the standby system alarm is instantaneously recovered and the operational system alarm is instantaneously recovered within the flicker protection time in both system alarm states.
[0028]
2A to 9A, (a) is the active alarm information, (b) is the standby alarm information, (c) is the switching state of the switching unit, and (d) is the switching state of the switching unit. Status 0, (e) is status 1 output, (f) is status 1 input (timeout output from timer 16), (g) is status 2, (h) is status 3, (i) is status 4 and (J) is status 5. The overall time of the timing charts shown in FIGS. 2 (A) to 9 (A) is the same as in the case of the conventional switching inhibition operation (the time T shown in FIG. 14 (a), which is the minimum detection time by polling). The operation within a sufficiently short time) is shown.
[0029]
(In the case of Example 1)
As shown in FIG. 2A, when an alarm occurs in the active system, as the output of the state transition unit 10, switching to the standby system occurs and the bit of the anti-flicker timer (status 1) 16 is “1”. ”And the timer is being activated. In this case, the flutter protection monitoring target (status 2 and status 3) is an alarm on the standby side, and status 2 = “1” and status 3 = “1 (1 at alarm)” are output. When the status 1 to the status 3 are input to the state transition unit 10 as the previous state, the value is retained until the timeout (until the status 1 = “1”). During the continuation, if an alarm occurs on the standby system side (in the pre-switching stage), it is an error in both systems, so the switchback action to the active system side is not executed, and the alarm to be monitored is As detected, status 4 is output from the state transition as “1”. This state is also input to the state transition unit 10 as a previous state like the other statuses, and the input is output as it is within the flutter protection time. In this state, when a timeout occurs (see (f) in FIG. 2A), since the status 4 is “1”, the previous status flag of the status 5 (in this case, the active system) Refer to and switch to the active side.
[0030]
(In the case of Example 2)
As shown in FIG. 3A, when an alarm occurs in the standby system, the output of the state transition unit 10 is not switched and the flutter prevention timer (status 1) bit becomes “1”, and the timer is started. . In this case, the monitoring targets (status 2 and status 3) within the flutter protection time are in the alarm state on the operation side, and status 2 = “0” and status 3 = “1” are output. When Status 1, Status 2 and Status 3 are input to the state transition unit 10 as previous states, the values are maintained until a timeout (status = “1”) is maintained. During the continuation, if an alarm is generated on the active system side, both systems become abnormal, so the standby system is not switched, and the status transition unit 10 is detected by detecting the active system alarm to be monitored. Outputs status 4 = “1”. This state is also input to the state transition unit 10 as a previous state in the same manner as other statuses, and it is determined that there is a monitoring target of status 4 at the time of timeout (status 1 = “1”). While referring to (in this case, the active system), an attempt is made to switch to the active system side, but since the active system side has already been selected, no switching occurs at this point.
[0031]
(In the case of Example 3)
When an alarm is generated on the active system side as shown in FIG. 4 (A), switching to the standby system occurs as an output of the state transition unit 10 and the flutter prevention timer (status 1) bit becomes “1”. The timer 16 is started. In this case, the monitoring target (status 2 and status 3) within the flutter protection time is an alarm state on the standby side, and status 2 = “1”, status 3 = “1” (alarm “1”). Output. When status 1, status 2, and status 3 are input to the state transition unit 10 as previous states, the values are maintained until timeout (status 1 = “1”). During the continuation, if an alarm occurs on the standby side (in the stage before switching), a switchback action to the active side is executed.
[0032]
Further, assuming that an alarm to be monitored is detected, the status transition unit 10 outputs the status 4 = “1”. This state is also input to the state transition unit 10 as a previous state like other statuses, and the input is output as it is within the flutter protection time. In this state, if a timeout occurs, status 4 is “1”, so it is determined that the switching that has occurred this time is unnecessary, and the previous state (status 5) is determined to be the active system. Thus, switching (switching back) to the active system side is performed (at the stage before switching occurs). Thereby, the switching action is not detected in the host monitoring system.
[0033]
(In the case of Example 4)
When an alarm occurs in the standby system as shown in FIG. 5A, the output of the state transition unit 10 does not execute switching and the flutter prevention timer (status 1) bit becomes “1”, and the timer 16 is to start. In this case, the monitoring targets (status 2 and status 3) within the flutter protection time are in the alarm state on the operation side, and status 2 = “0” and status 3 = “1” are output. When status 1, status 2 and status 3 are input to the state transition unit 10 as previous states, the values are maintained until timeout (status = “1”). During the continuation, when an alarm occurs on the active system side, the standby system is switched and the status transition unit 10 detects status 4 = “1” by detecting the active system alarm to be monitored. Is output. This state is also input to the state transition unit 10 as a previous state in the same manner as other statuses, and it is determined that there is a monitoring target of status 4 at the time of timeout (status 1 = “1”). Referring to (in this case, the active system), switch to the active system side.
[0034]
(In the case of Example 5)
As shown in FIG. 6 (A), when the active system is recovered first in the both-system alarm state, only the timer activation (status 1) is activated. In this case, the monitoring target (status 2 and status 3) is a normal state of the standby system (status 2 = “1”, status 3 = “0”). If the alarm is restored on the standby side while the timer is activated, the status 4 is set to “1” due to the occurrence of the monitoring target. In this case as well, switching is not executed because both systems are normal. If a timeout (status 1 = “1”) occurs in this state, the monitoring target is detected (status 4 = “1”), so the previous state flag (status 5) is referred to return to the previous state. However, although switching on the active side is performed, since the active side has already been selected, switching does not occur here.
[0035]
(In the case of Example 6)
As shown in FIG. 7A, in the both-system alarm state, when the standby system is restored first, switching to the standby system is executed and the timer is activated (status 1). In this case, the monitoring target is in the normal state on the active side (status 2 = “0”, status 3 = “0”. If the active side also recovers while the timer is running, the monitoring target is detected. Status 4 = “1”, but switching is not executed because both systems are in a normal state, and a monitoring target is detected (status 4 = “1”) in a time-out state (status 1 = “1”). Therefore, referring to the previous state flag (status 5 = “0”), the operation side is switched to.
[0036]
(In the case of Example 7)
As shown in FIG. 8A, when the active system is instantaneously recovered first in the both-system alarm state, the switching prevention is not performed and the flutter prevention timer is being activated (status 1 = “1”). The monitoring targets (status 2 and status 3) at this time are in the normal state (status 2 = “1”, status 3 = “0”) on the standby side. When instantaneous recovery is performed on the standby side while the timer is activated, the operation side is switched to and the monitoring target is detected (status 4 = “1”). Since the monitoring target is detected (status 4 = “1”) at time-out (status 1 = “1”), refer to the previous state (status 5) and switch to the active system because it is “0” However, switching has not occurred because the active system has already been selected.
[0037]
(In the case of Example 8)
Finally, as shown in FIG. 9A, in the both-system alarm state, when the backup system is instantaneously restored first, switching to the backup system side is executed, and the flicker prevention timer (status 1) is started. The monitoring target (status 2 and status 3) at this time is a normal state on the operating system side, and status 2 = “0” and status 3 = “0”. When the operational system instantaneously recovers while the timer is running, switching to the operational system occurs, and the monitoring target is detected (status 4 = “1”). Since the monitoring target is detected at the time-out (stator 4 = “1”), the previous state (status 5) is referred to and switching to the active system side is executed.
[0038]
Note that all the eight examples described above start from the state where the active system side is selected, but the same operation is performed even if it starts from the standby system selection state. Furthermore, in order to specifically explain the difference from the prior art, the specific operations of the above-described Example 3 and Example 4 will be described with reference to FIGS. 10 and 11.
[0039]
10, (a) is an error on the active system side, (b) is an error on the standby system side, (c) is a notification from the host monitoring device, (d) to (g) are operations of the prior art, (h ) To (k) show operations according to the present invention. (D) and (h) are actual switching operations, (e) and (i) are switching prohibited states, (f) and (j) are switchback triggers, and (g) and (k) are errors that exit downstream. Show. When an instantaneous error is detected in the standby system after the instantaneous error is detected in the operational system according to Example 3, since there is F / W read protection, no switching notification is issued to the host monitoring device side. However, there is a difference in the actual switching operation and switching back timing. In this operation example, the timer activation timing and operation are the same, and an error in the active system is detected and the operation is switched to the standby system.
[0040]
In the conventional technology, switching is prohibited while the timer is running after switching, so if an error occurs on the standby side next time, switching is executed even though the active side is in an error-free state. Therefore, data including an error is sent downstream.
[0041]
On the other hand, in the present invention, even when the timer is running, switching is not prohibited, so when an error is detected in the standby system, switching is performed to the active system side. Thereby, it is possible to send data without error to the downstream. Note that switching is prohibited in the prior art because the state before switching is not maintained when the timer is started as in the present invention, so the judgment at the time of timeout is switched back or nothing is controlled. This is because it cannot be done.
[0042]
On the other hand, in the case of Example 4 shown in FIG. 11, (a) is an error on the active system side, (b) is an error on the standby system side, (c) to (f) are operations of the prior art, and (g) to ( j) illustrates the operation of the present invention. (C) and (g) are actual switching operations, (d) and (h) are in a switching prohibition state, (e) and (i) are switchback triggers, and (f) and (j) are from the host monitoring device. Indicates a notification. If an instantaneous error is detected on the active system side after an instantaneous error is detected on the standby system side in Example 4, in the conventional technology, switching occurs after an error occurs on the active system side, and at the same timing as that Since the timer is activated, an error in the standby system is not detected after switching. Therefore, the backup system is not selected and the standby system remains selected. However, according to the present invention, since the timer start condition is not a change but a state change, the timer starts when an error is detected on the standby side, and the active side that is the trigger source during the timer startup In order to detect an error, it is possible to mask the switching by executing switching to the active system before the timer activation at the time of timeout.
[0043]
The configuration and operation of the preferred embodiment of the SDH transmission system have been described above in detail. However, such embodiments are merely examples of the present invention and do not limit the present invention. Those skilled in the art will readily understand that various modifications and changes can be made according to a specific application without departing from the gist of the present invention.
[0044]
【The invention's effect】
As understood from the above description, according to the SDH transmission system of the present invention, the following significant effects can be obtained. First, it is possible to suppress an increase in notifications to the host monitoring device. The reason for this is that the non-instantaneous switching function switches the transmission line quality to the first and only the B3 error is generated by 1 bit. This is because switching notification occurs frequently, but by switching back in hardware (H / W), it has a function of suppressing switching notification within a range that can be monitored from the host monitoring device.
[0045]
Second, high quality transmission lines can be maintained even when the switching notification is suppressed. The reason is that the conventional switching inhibition function was realized by prohibiting actual switching, so that switching due to detection of B3 error was prohibited, so that an error passed to the downstream device, which deteriorated the quality of the transmission path. However, in the present invention, since the function is finally restored, the quality of the transmission line is not deteriorated.
[0046]
Third, even if a signal containing an error from outside the device is received, switching within the device does not occur. The reason for this is that by preventing fluttering, switching back can be realized even when a failure occurs from the outside of the apparatus, and switching within the apparatus can be performed without causing external factors.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a switching control unit which is a main part of a preferred embodiment of an SDH transmission system according to the present invention.
2A and 2B are switching operation timing charts in a switching unit example 1. FIG. 2A shows the present invention, and FIG. 2B shows a conventional case.
FIGS. 3A and 3B are switching operation timing charts in Example 2 of the switching unit, where FIG. 3A shows the present invention, and FIG. 3B shows a conventional case.
4A and 4B are switching operation timing charts in a switching unit example 3. FIG. 4A shows the present invention, and FIG. 4B shows a conventional case.
FIGS. 5A and 5B are switching operation timing charts in Example 4 of the switching unit, in which FIG. 5A shows the present invention, and FIG. 5B shows a conventional case.
6A and 6B are switching operation timing charts in Example 5 of the switching unit, where FIG. 6A shows the present invention, and FIG. 6B shows a conventional case.
7A and 7B are switching operation timing charts in Example 6 of the switching unit, where FIG. 7A shows the present invention, and FIG. 7B shows a conventional case.
FIGS. 8A and 8B are switching operation timing charts in Example 7 of the switching unit, where FIG. 8A shows the present invention, and FIG. 8B shows a conventional case.
9A and 9B are switching operation timing charts in an example 8 of the switching unit, where FIG. 9A shows the present invention, and FIG. 9B shows a conventional case.
FIG. 10 is a comparative explanatory view of the switching operation of the prior art and the present invention in Example 3.
FIG. 11 is a comparative explanatory diagram of the switching operation of the prior art in Example 4 and the present invention.
FIG. 12 is a block diagram showing a configuration of a typical uninterruptible switching circuit.
13 is a configuration diagram of a control unit of the switching unit in FIG. 12;
FIG. 14 is an explanatory diagram of an operation of notification by three-time matching polling in the prior art.
[Explanation of symbols]
10 State transition part
11 Alarm information on the active side
12 Alarm information on the standby side
13 Switching control signal
14 Feedback signal (previous state)
15 Status signal
16 timer

Claims (4)

Input the operational system side alarm information, the standby system side alarm information, and the feedback signal based on the switching instruction signal output from the state transition unit to the state transition unit that performs switching determination between the active system and the standby system , and the operational system In the SDH transmission system configured to switch from the standby system to the standby system or vice versa without interruption,
A status signal of a plurality of bits indicating a previous state is input to the state transition unit, and the new selection direction is switched by the status signal in addition to the alarm information on the active system side, the alarm information from the standby system, and the feedback signal. SDH transmission system characterized by this. 2. The SDH transmission system according to claim 1, further comprising a timer to which one bit of the multiple-bit status signal is input, and a time-out output from the timer is input to the state transition unit . The SDH transmission system according to claim 2 , wherein the set time of the timer is a monitoring section corresponding to a flutter protection period . The multi- bit status signal includes status 0 indicating whether the previous state is an abnormal state of both the active system and the standby system, status 1 indicating a timeout state corresponding to the monitoring section, and within the monitoring section. Status 2 indicating which of the active system and the standby system is to be monitored, Status 3 indicating whether an alarm timer is activated in response to the occurrence of an alarm within the monitoring section, or activated by alarm recovery, and the monitoring when the status 4 and the timer is started indicating that monitored within interval occurs (if the switching occurs, the previous state) according to claim 2 or 3, characterized in that it comprises a status 5 indicating the selected direction of The SDH transmission system described in 1.

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