JP4642996B2 - Optical multi-branch communication system and transmission path switching recovery control method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
In the present invention, a master station device and a plurality of slave station devices are connected by an optical splitter, at least a trunk transmission line between the master station device and the optical splitter is configured redundantly, and the plurality of slave station devices transmit Sharing the medium and the transmission band, the master station device controls the allocation of the used transmission band of each slave station device, and each slave station device is based on the allocation of the used transmission band by the master station device. In particular, an optical multi-branch communication system and a transmission path switching recovery control method thereof for transmitting transmission information, and in particular, an optical multi-branch communication system capable of recovering from a momentary interruption associated with switching of the main transmission line in a short time, and The present invention relates to the transmission path switching recovery control method.
[0002]
[Prior art]
Conventionally, as a method in which a plurality of slave station devices share a transmission medium and a transmission band and each slave station device performs data transmission to the master station device by bandwidth control of the master station device, for example, ITU-T Recommendation G. N ONUs (Optical Network Units) shown in Figure 5 / G.983.1-Generic physical configuration of the Optical Distribution Network of 983.1 (Broadband optical access systems based on Passive Optical Network (PON) 1998/10) An optical network having one OLT (Optical Distribution Termination) is known.
[0003]
This optical network uses a frame format (ITU-T recommendation G.983.1 (Figure 11 / G.983.1-Frame format for 155.52 / 155.52 Mbit / s PON)) from the master station to each slave station. (Downward) or data is transmitted from each slave station device to the master station device (upstream direction). In this frame format, the downstream direction is transmitted by a 53-byte fixed-length cell (ATM cell), and the upstream direction is transmitted by a 56-byte fixed-length cell in which a 3-byte overhead is added to a 53-byte ATM cell. It is assumed that.
[0004]
The downlink frame has 54 ATM cells and two supervisory control (PLOAM: Physical Layer Operations Administration and Maintenance) cells, and PLOAM cells are inserted in a cycle of 28 cells. The PLOAM cell is an ITU-T Recommendation G. As shown in 983.1 (Table 8 / G.983.1-Payload content of downstream PLOAM cell), “GRANT1” to “GRANT27” are inserted into the first PLOAM cell as the bandwidth allocation information, and the second “GRANT28” to “GRANT54” are inserted into the PLOAM cells.
[0005]
  The upstream frame has 53 ATM cells, each of which forms a time slot. “GRANT1” to “GRANT53” described in the above-described PLOAM cell correspond to each time slot. The “GRANT” value is identification information associated with each slave station device.IsThe associated identification information is held in advance. Therefore, by inserting the “GRANT” value of each slave station device as “GRANT1” to “GRANT53”, each slave station device recognizes the time slot position of the ATM cell to be transmitted by the slave station device. As a result, band assignment control of each slave station device is performed.
[0006]
Here, the line between the master station apparatus and the slave station apparatus may be momentarily interrupted due to a line failure between the master station apparatus and the slave station apparatus. When such a momentary interruption occurs, the slave station device has “LOS (Loss Of Signal)” which is an optical signal input interruption, “LCD (Loss of Cell Delineation)” which is out of cell synchronization, and PLOAM cell loss. Alarms such as “OAML (PLOAM cell loss)” and “FRML (FRML Loss of downstream frame)”, which is out of frame synchronization, are detected. When this alarm is detected, the operation state transits to the POPUP (pop-up) state, and then the pop-up message from the master station device is received, and the slave station device transits to the startup standby state. Wait for startup control.
[0007]
  FIG. 11 is a block diagram showing a configuration of a conventional optical multi-branch communication system, in which a master station device 1 and a plurality of slave station devices 5 (5-1 to 5-n) are connected via an optical splitter 4. In addition, the trunk line between the master station device 1 and the optical splitter 4 is configured redundantly. In this redundant configuration, one optical switch 3a, 3b is interposed between the master station device 1 and the optical splitter 4, and the optical switches 3a, 3b are connected by two optical fibers L2a, L2b. The switching instruction unit 6 performs switching control of the optical switches 3a and 3b. As a result, the optical transmission line between the master station device 1 and the optical splitter 4 is connected to the optical fibers L1, L.2a, path L3 and optical fiber L1,L2The redundant configuration forms two paths, b and L3. On the other hand, the optical splitter 4 and each slave station device 5 are connected by optical fibers L4 (L4-1 to L4-n) of branch lines, respectively.
[0008]
The master station device 1 includes a registration management unit 17 that performs registration management of each slave station device 5 and a communication interface unit 2. The communication interface unit 2 performs optical signal transmission / reception processing and optical signal / electrical signal conversion processing with each slave station device 5 via the optical fiber L1.
[0009]
The bandwidth control unit 10 performs allocation control of the used transmission bandwidth for each slave station device 5. The upstream alarm monitoring unit 12 monitors the upstream signal 15 sent from each slave station device 5, detects the upstream alarm, and sends the detected information to the start / stop control unit 13. The activation / deactivation control unit 13 controls activation and deactivation of each slave station device 5 based on an instruction from the registration management unit 17 and an alarm notification from the uplink alarm monitoring unit 12. The management signal sending unit 14 adds the band information from the band control unit 10 and the start / stop instruction from the start / stop control unit 13 to the downlink signal 16 and sends it to each slave station device 5.
[0010]
Here, with reference to a flowchart shown in FIG. 12, a conventional transmission path restoration processing procedure associated with switching of the trunk line will be described. In FIG. 12, first, when the optical switches 3a and 3b are switched based on the switching instruction of the switching instruction unit 6 and connection switching of the optical fibers L2a and L2b is executed (step S400), each slave station device 5 As a result of this switching, a momentary interruption occurs and a down alarm is detected (step S411). Thereafter, each slave station device 5 performs a process of stopping transmission of uplink data to the master station device 1 (step S412).
[0011]
On the other hand, the uplink warning monitoring unit 12 of the master station device 1 detects an uplink warning due to a momentary interruption accompanying execution of switching of the main line (step S401), and the start / stop control unit 13 transmits a transmission stop signal to the slave station device 5 The slave station is stopped and transmitted (step S402). Here, depending on the upstream band of the slave station device 5, there may be a case where the uplink alarm is not detected only by momentary interruption, but because the slave station device 5 stops the transmission of the uplink data by detecting the downlink alarm, As a result, an up alarm is detected. Thereafter, the start / stop control unit 13 starts a built-in slave station stop timer (not shown) (step S403). The timer time set in the slave station stop timer is a time obtained by adding a predetermined margin to the time when the switching of the main line is completed.
[0012]
Thereafter, the start / stop control unit 13 determines whether or not the timer time counted by the slave station stop timer has expired (step S404). The start / stop control unit 13 performs slave station start control for restarting the slave station device 5 when the timer time has expired (YES in step S404) (step S405), and the slave station start control performs slave station start control. The device 5 restarts (step S413).
[0013]
[Problems to be solved by the invention]
By the way, in the conventional optical multi-branch communication system described above, the used transmission band is allocated to each slave station device 5, but this allocated amount is different for each slave station device 5, and it is possible to protect the uplink warning. Therefore, the upstream warning monitoring unit 12 outputs the upstream warning to the start / stop control unit 13 only when the upstream warning is detected a predetermined number of times, for example, 8 times or more, and performs stop control on the slave station device 5. . Therefore, in accordance with the allocated amount of the transmission band used, the time taken from the main line switching to the detection of the uplink alarm is increased or decreased. In particular, when the allocated amount of the used transmission band is small, there is a problem that it takes a long time from the switching of the trunk line to the detection of the uplink alarm and the restart of the slave station device 5.
[0014]
For example, in a small bandwidth allocation of 64 kbps for voice information or the like, the interval between the uplink time slots is about 6.6 ms, and it takes about 53 ms at maximum from switching the main line to detecting the uplink alarm. On the other hand, the instantaneous interruption time due to switching of a normal optical switch is about 10 to 20 ms.
[0015]
  FIG. 13 is a timing chart showing processing for the slave station device 5-1 to which the small band is allocated and the slave station device 5-2 to which the large band is allocated until the slave station activation control is started after the main line switching is executed. It is. In the case of the slave station device 5-1, since a small band is allocated, the time slot period Tc1 of the slave station device 5-1 becomes long. On the other hand, in the case of the slave station device 5-2, since a large band is allocated, the time slot period Tc2 of the slave station device 5-2 is determined.Is shortBecome.
[0016]
As a result, for the slave station device 5-1, the time Tu1 required from the momentary disconnection due to the trunk line switching execution tx to the detection of the eighth uplink warning is compared with the time Tu2 for the slave station device 5-2. Become bigger. Here, since the time set in the slave station stop timer is constant, it takes from the detection of the eighth uplink warning (t41, t51) to the start of slave station activation control (t44, t54). The time will be the same. As a result, in the slave station device 5-1, which has a small bandwidth allocation amount, a large amount of time is spent before restarting from the switching execution tx.
[0017]
The present invention has been made in view of the above, and reduces the time during which communication is interrupted due to a momentary interruption, in particular due to a momentary interruption accompanying switching of a trunk line, regardless of the amount of bandwidth allocated to each slave station device. It is an object of the present invention to obtain an optical multi-branch communication system and a transmission path switching recovery processing method thereof.
[0018]
[Means for Solving the Problems]
  In order to achieve the above object, an optical multi-branch communication system according to the present invention includes:A master station device and a plurality of slave station devices are connected by an optical splitter, and at least a trunk transmission line between the master station device and the optical splitter has a redundant configuration by a signal route switching means capable of switching the transmission line. The master station device controls the allocation of the used transmission band of each slave station device, and each slave station device transmits transmission information to the master station device based on the allocation of the used transmission band by the master station device. In the optical multi-branch communication system, the master station device counts a slave station start / stop control unit that controls start and stop of the slave station device, and a predetermined time corresponding to a non-communication time associated with switching of the main transmission line. A switching instruction transmitting means for receiving a switching start notification for the signal route switching means, which is a switching instruction for switching the trunk transmission line, and the slave station start / stop control means includes the switching instruction When the reaching means receives the switching start notification, it performs stop control for each slave station device regardless of the presence or absence of an uplink alarm that can be detected by monitoring an uplink signal, and further starts time counting by the timer, The start control of each slave station device is started after the time measured by the timer has expired.
[0019]
According to the present invention, when the switching instruction transmission means accepts the notice of switching start of the main transmission line, and the slave station start / stop control means accepts the notice of switching start, the time measurement by the timer is started and the time measurement by the timer is started. After the time expires, start control of each slave station device is started.
[0030]
DETAILED DESCRIPTION OF THE INVENTION
Preferred embodiments of an optical multi-branch communication system and its transmission path switching recovery processing method according to the present invention will be described below with reference to the accompanying drawings.
[0031]
Embodiment 1 FIG.
First, a first embodiment of the present invention will be described. FIG. 1 is a diagram showing a schematic configuration of an optical multi-branch communication system according to Embodiment 1 of the present invention. In FIG. 1, this optical multi-branch communication system is similar to the conventional optical multi-branch communication system shown in FIG. 11, in which a master station device 1 and a plurality of slave station devices 5 are connected via an optical splitter 4, The trunk line between the master station device 1 and the optical splitter 4 is redundantly configured.
[0032]
The master station device 1 includes a switching instruction transmission unit 31. The switching instruction unit 6 issues a switching instruction to the optical switches 3 a and 3 b for switching the transmission line of the trunk line using the optical fibers L <b> 2 a and L <b> 2 b, and this switching instruction is also input to the switching instruction transmission unit 31. When the switching instruction from the switching instruction unit 6 is input, the switching instruction transmission unit 31 outputs to the start / stop control unit 13 that the switching instruction has been received. Other configurations are the same as those of the conventional optical multi-branch communication system shown in FIG. 11, and the same components are denoted by the same reference numerals. However, the start / stop control unit 13 illustrated in FIG. 1 performs control processing different from that of the start / stop control unit 13 illustrated in FIG.
[0033]
FIG. 2 is a block diagram showing a detailed configuration of the slave station device 5 shown in FIG. In FIG. 2, the optical transceiver 21 performs transmission / reception processing of an optical signal transmitted / received to / from the master station device 1, conversion processing between an optical signal and an electric signal, and the like. The downlink alarm monitoring unit 22 monitors the downlink alarm from the downlink signal output from the optical transceiver 21 and outputs the monitoring result to the uplink data transmission control unit 28. The uplink data transmission control unit 28 performs control to stop transmission of uplink data transmitted from the optical transceiver 21 to the master station device 1 when the downlink alarm monitoring unit 22 detects a downlink alarm.
[0034]
The allocation identifying unit 23 acquires information related to band allocation from the downlink signal output from the optical transceiver 21, and controls data reading by the data reading units 24a and 24b based on the information related to band allocation. The buffer memories 25 a and 25 b temporarily store data input from a terminal device connected to the slave station device 5. The data reading units 24 a and 24 b read the data from the buffer memories 25 a and 25 b at the timing output to the own time slot based on the control by the assignment identifying unit 23 and output the data to the multiplexing unit 27. The multiplexing unit 27 multiplexes the data output from the data reading units 24 a and 24 b, and the optical transceiver 21 outputs the multiplexed data to the master station device 1 as an optical signal.
[0035]
Here, with reference to the flowchart shown in FIG. 3, the transmission path restoration processing procedure when the switching of the trunk line by the switching instruction unit 6 occurs will be described. In FIG. 3, first, the optical switches 3a and 3b are switched based on the switching instruction of the switching instruction unit 6, and the connection switching of the optical fibers L2a and L2b is executed (step S100). The switching instruction is notified, and the switching instruction transmission unit 31 notifies the start / stop control unit 13 that the main line switching has been executed (step S101).
[0036]
Thereafter, the start / stop control unit 13 performs slave station stop control such as sending a transmission stop signal to the slave station device 5 regardless of the uplink alarm result monitored by the uplink alarm monitoring unit 12 (step S102). . Furthermore, the start / stop control unit 13 starts a built-in slave station stop timer (not shown) (step S103). The timer time set in the slave station stop timer is a time obtained by adding a predetermined margin to the time when the switching of the main line is completed.
[0037]
Thereafter, the start / stop control unit 13 determines whether or not the timer time counted by the slave station stop timer has expired (step S104). When the timer time has expired (YES in step S104), the start / stop control unit 13 performs slave station start control for restarting the slave station device 5 (step S105), and the slave station start control performs slave station start control. The device 5 restarts (step S113).
[0038]
On the other hand, each slave station device 5 detects a down alarm due to a momentary interruption that occurs with the execution of switching of the trunk line (step S111). Thereafter, each slave station device 5 performs processing for stopping transmission of uplink data to the master station device 1 (step S112). Thereafter, each slave station device 5 is restarted by the slave station activation control from the master station device 1 (step S113).
[0039]
Here, based on the timing chart shown in FIG. 4, a specific transmission path recovery process when the switching of the trunk line by the switching instruction unit 6 occurs will be described. FIG. 4A shows the flow of uplink data of the slave station device 5-1 with a small allocated band, and FIG. 4B shows the uplink data flow of the slave station device 5-2 with a large allocated bandwidth. The flow is shown.
[0040]
When the optical switches 3a and 3b execute switching of the optical fibers L2a and L2b at the time point tx according to the switching instruction by the switching instruction unit 6, a momentary interruption occurs. The start / stop control unit 13 starts the slave station stop timer at time t1 according to the switching instruction notified from the switching instruction transmission unit 31. The slave station stop timer times out at time t2, and at time t3 after this timeout, the start / stop control unit 13 starts slave station start control. In this case, the slave station stop control and the slave station start control are performed based on the switching instruction sent from the switching instruction unit 6 regardless of the presence or absence of the upstream alarm, in particular, the number of counts of the upstream alarm.
[0041]
In the first embodiment, each slave station device 5 is compulsory based on the switching instruction input from the switching instruction unit 6 regardless of the bandwidth allocation amount and the uplink warning assigned to each slave station device 5. Therefore, each slave station device 5 is controlled to stop at approximately the same time, and is further controlled to restart, so that quick restart control is executed. Is done.
[0042]
Embodiment 2. FIG.
Next, a second embodiment of the present invention will be described. In the first embodiment described above, the master station device 1 forcibly performs stop control and start control of the slave station device 5 based on the switching instruction from the switching instruction unit 6. In this case, when one or more uplink alarms are detected from all the slave station devices 5, it is recognized that the main line has been switched, and then the stop control and start control for the slave station device 5 are performed.
[0043]
FIG. 5 is a diagram showing a schematic configuration of an optical multi-branch communication system according to Embodiment 2 of the present invention. 5, this optical multi-branch communication system is similar to the conventional optical multi-branch communication system shown in FIG. 11, in which a master station device 1 and a plurality of slave station devices 5 are connected via an optical splitter 4, The trunk line between the master station device 1 and the optical splitter 4 is redundantly configured.
[0044]
When the upstream alarm detected by the upstream alarm monitoring unit 12 is detected at least once from all the slave station devices 5, the master station device 1 determines that the main line switching has occurred, and starts and stops the determination result. It has a trunk instantaneous disconnection determination unit 19 that outputs to the control unit 13. Other configurations are the same as those of the conventional optical multi-branch communication system shown in FIG. 11, and the same components are denoted by the same reference numerals. The output of the up warning monitoring unit 12 is output to the main line instantaneous interruption determination unit 19 and is not output to the start / stop control unit 13.
[0045]
Here, with reference to the flowchart shown in FIG. 6, a transmission path restoration processing procedure by the master station device 1 when the switching of the main line by the switching instruction unit 6 occurs will be described. In FIG. 6, first, when the optical switches 3a and 3b are switched based on the switching instruction of the switching instruction unit 6 and the connection switching of the optical fibers L2a and L2b is executed (step S200), the upstream alarm monitoring unit 12 The up alarm, that is, the instantaneous interruption of the up signal is detected (step S201).
[0046]
After that, the main line instantaneous interruption determination unit 19 determines whether or not an uplink alarm is detected for all of the slave station devices 5 that are currently connected to the master station device 1 and are activated (step S202). When an upstream alarm is detected for all active slave station devices 5 (YES in step S202), the start / stop control unit 13 sends a transmission stop signal to the slave station device 5 or the like. Stop control is performed (step S203). Furthermore, the start / stop control unit 13 starts a built-in slave station stop timer (not shown) (step S204). The timer time set in the slave station stop timer is a time obtained by adding a predetermined margin to the time when the switching of the main line is completed.
[0047]
Thereafter, the start / stop control unit 13 determines whether or not the timer time counted by the slave station stop timer has expired (step S205). When the timer time has expired (YES in step S205), the activation / stop control unit 13 performs slave station activation control for restarting the slave station device 5 (step S206), and the slave station activation control performs slave station activation control. The apparatus 5 is restarted.
[0048]
Here, based on the timing chart shown in FIG. 7, a specific transmission path restoration process when the switching of the trunk line by the switching instruction unit 6 occurs will be described. FIG. 7 shows the flow of uplink data of each slave station apparatus 5 to which various bandwidth allocation amounts are allocated.
[0049]
When the optical switches 3a and 3b perform switching of the optical fibers L2a and L2b at the time tx according to the switching instruction by the switching instruction unit 6, a momentary interruption occurs, and an uplink alarm is detected for each slave station device 5. In this case, the timing at which the uplink warning is detected first differs depending on the bandwidth allocation amount allocated to each slave station device 5. For example, for the slave station devices 5-1, 5-2, and 5 -n, an upstream alarm is detected at timings tx 1, tx 2, and txn, respectively. However, this timing difference is small compared to the time difference in which the upstream alarm is detected eight times or more for each slave station device 5.
[0050]
Here, as described above, when the main line instantaneous interruption determining unit 19 detects one or more up alarms for all the slave station devices 5, at the time point ty, an up instantaneous interruption occurs due to the main line switching. The slave station stop timer is started at time t11. This slave station stop timer times out at time t12, and at time t13 after this timeout, the start / stop control unit 13 starts slave station start control. That is, in order to protect the uplink alarm, the slave station stop control and slave station activation control are performed only by detecting one or more uplink alarms without detecting eight or more uplink alarms. In addition, although it is determined that the uplink alarm for each slave station device 5 has occurred only once, an instantaneous uplink interruption has occurred. However, in the case of a momentary disconnection of the main line, not the number of uplink alarms but all the slave station devices 5 On the other hand, it is important whether or not an up alarm is generated. On the other hand, when only one slave station device 5 has not received an up warning, it cannot be determined that there is an instantaneous interruption due to trunk line switching.
[0051]
In this second embodiment, it is determined that there is an instantaneous interruption due to switching of the trunk line at the time when the uplink warning for all the slave station devices 5 occurs one or more times, and thereafter, each slave station device 5 is controlled to stop, and further activation control is performed. Therefore, each slave station device 5 is controlled to stop at approximately the same time, and is further controlled to be restarted to execute quick restart control.
[0052]
Embodiment 3 FIG.
Next, a third embodiment of the present invention will be described. In the first and second embodiments described above, the slave station stop control and the slave station start control are performed for each slave station device 5 using one slave station stop timer. In the third embodiment, each slave station stop control is performed. A plurality of slave station stop timers corresponding to each slave station device 5 are provided, an appropriate timer setting time corresponding to the bandwidth allocation amount is set for each slave station stop timer, and slave station stop control is performed for each slave station device 5 And slave station activation control.
[0053]
FIG. 8 is a diagram showing a schematic configuration of an optical multi-branch communication system according to the third embodiment of the present invention. 8, this optical multi-branch communication system is similar to the conventional optical multi-branch communication system shown in FIG. 11, in which a master station device 1 and a plurality of slave station devices 5 are connected via an optical splitter 4, The trunk line between the master station device 1 and the optical splitter 4 is redundantly configured.
[0054]
  The bandwidth control unit 10 of the master station device 1 outputs the bandwidth information 20 that is information relating to bandwidth allocation to each slave station device 5 to the start / stop control unit 13. The start / stop control unit 13 includes a plurality of slave station stop timers (not shown) corresponding to the slave station devices 5. In addition, the start / stop control unit 13The timer setting unit 13a includes the timer setting unit 13a.Predetermined time corresponding to the switching time from the start of trunk line switching to the completion of switching"Depending on the amount of bandwidth allocation"From the switchover of the trunk lineConcernedSlave station device 5Corresponded toUpward alarm 8Round tripUntil it comes outIs timeelapsed time"Is calculated, and the corresponding remaining time is set in the slave station stop timer corresponding to each slave station device 5..The start / stop control unit 13 starts counting the timer time set in the slave station stop timer for the slave station device that has detected the uplink alarm when the uplink alarm is detected for each slave station device 5. After the time counted by the slave station stop timer expires, the slave station apparatus is activated. Other configurations are the same as those of the conventional optical multi-branch communication system shown in FIG. 11, and the same components are denoted by the same reference numerals.
[0055]
Here, with reference to the flowchart shown in FIG. 9, a description will be given of a transmission path restoration processing procedure in the case where switching of the main line by the switching instruction unit 6 occurs. In FIG. 9, first, when the optical switches 3a and 3b are switched based on the switching instruction of the switching instruction unit 6 and the connection switching of the optical fibers L2a and L2b is executed (step S300), the upstream alarm monitoring unit 12 Then, an up alarm is detected (step S301). In this case, the upstream warning monitoring unit 12 outputs the upstream warning to the start / stop control unit 13 for the first time when the upstream warning is detected eight times.
[0056]
Thereafter, when the main line instantaneous interruption determining unit 19 is notified from the up alarm monitoring unit 12 that the up alarm has been detected, it sends a transmission stop signal to the slave station device 5 in which the up alarm has been detected, etc. The slave station stop control is performed (step S302). Furthermore, the start / stop control unit 13 acquires the band information 20 output from the band control unit 10 (step S303), and sets the timer value, which is the remaining time described above, to the slave station stop timer corresponding to this uplink alarm. (Step S304).
[0057]
Thereafter, the start / stop control unit 13 starts the slave station stop timer (step S305). Furthermore, the start / stop control unit 13 determines whether or not the timer time counted by the slave station stop timer has expired (step S306). The start / stop control unit 13 performs slave station start control for restarting the slave station device 5 (step S307) when the timer time has expired (step S306, YES), and the slave station start control performs slave station start control. The apparatus 5 is restarted.
[0058]
Here, based on the timing chart shown in FIG. 10, a specific transmission path restoration process in the case where switching of the main line by the switching instruction unit 6 occurs will be described. FIG. 10 shows a flow of uplink data of the slave station device 5-1 having a small allocated bandwidth allocation amount and a flow of uplink data of the slave station device 5-2 having a large allocated bandwidth allocation amount.
[0059]
When the optical switches 3a and 3b perform switching of the optical fibers L2a and L2b at the time tx according to the switching instruction by the switching instruction unit 6, a momentary interruption occurs, and an uplink alarm is detected for each slave station device 5. From the time when this up alarm is detected, the timer setting unit 13 calculates the remaining time of the slave station stop timer corresponding to the slave station device 5 in which this up alarm is detected, and sets this to the slave station stop timer. Alternatively, the remaining time is periodically calculated based on the band information 20 for each slave station stop timer, and this remaining time is set in each slave station stop timer.
[0060]
Since the bandwidth allocation amount allocated to the slave station device 5-1 is small, the time slot period Tc1 of the slave station device 5-1 is long. The timer setting unit 13a calculates the time slot period Tc1 from the band information 20 and calculates a time Tu1 until counting eight up alarms. A predetermined margin is set in the time from the start of main line switching to the completion of switching. The remaining time (t23-t22) obtained by subtracting the time obtained by adding the predetermined time (t22-t21) to the time Tu1 is calculated from the time (t23-tx) added, and the remaining time is calculated as the slave station device 5-1. Set to the slave station stop timer corresponding to. On the other hand, since the bandwidth allocation amount allocated to the slave station device 5-2 is large, the time slot period Tc2 of the slave station device 5-2 is short. Similarly, the timer setting unit 13a calculates a long remaining time (t33-t32) for the slave station device 5-2 and stops the slave station corresponding to the slave station device 5-2. Set to timer. In other words, if the time required for uplink alarm detection corresponding to the bandwidth allocation amount is long, a short timer time is set, and if the time required for uplink alarm detection corresponding to the bandwidth allocation amount is short, a long timer time is set. Thus, the times t23 and t33 when the slave station stop timer expires are made substantially the same.
[0061]
In the third embodiment, the timer time of each slave station stop timer is set corresponding to the length of time until the up warning detection is performed eight times so that the timeout time of each slave station stop timer becomes substantially constant. Therefore, the stop control and restart control of each slave station device 5 can be performed without being affected by the bandwidth allocation amount assigned to each slave station device 5, and quick restart control is executed. Will be.
[0062]
In addition, since the third embodiment detects an upstream alarm for each slave station device 5 and performs stop control and start control for each slave station device 5, only the momentary interruption associated with the switching of the trunk line can be performed. In addition, it is possible to individually cope with an instantaneous interruption of the optical fiber L4, which is a branch line connecting the optical splitter 4 and each slave station device 5, and a quick line restoration process is realized.
[0063]
【The invention's effect】
As described above, according to the present invention, when the switching instruction transmission unit accepts the switching start notification of the main transmission line and the slave station start / stop control unit receives the switching start notification, the timer counts the time. Since the start-up control of each slave station device is started after the time counted by the timer expires, the main transmission line can be switched regardless of the detection of the uplink alarm accompanying the main transmission line switching. There is an effect that it is possible to grasp the instantaneous interruption and to reliably perform stop control and start control of the slave station device.
[0064]
According to the next invention, the trunk line switching determination means determines whether or not an uplink warning has been detected for all active slave station devices, the slave station activation stop control means, the trunk line switching determination means, When an upstream alarm is detected for all the slave station devices that are active, the timer starts timing, and after the time counted by the timer expires, the startup control of each slave station device is started. Apart from the protection of the alarm, there is an effect that the instantaneous interruption associated with the switching of the main transmission line can be reliably identified and the stop control and the start control of the slave station apparatus can be performed quickly.
[0065]
  According to the next invention, the timer setting means comprises:For each slave station device,Predetermined time corresponding to the switching time from the start of switching the trunk line to the completion of switching"Depending on the size of the used transmission band indicated by the band information"From the occurrence of switching of the trunk transmission lineConcernedSlave station deviceCorresponded toUntil the up alarm is detectedIs timeelapsed time"Is calculated by subtracting the remaining time, and the corresponding remaining time is set in the timer corresponding to each slave station device. Since the time measurement by the timer corresponding to the station device is started and the start control of the slave station device is started after the time measured by the timer has expired, it is related to the size of the bandwidth allocated to the slave station device. In addition, it is possible to always perform stop control and start control of the slave station device within a certain time, and not only instantaneous interruption due to main line switching, but also stop control and start for each slave station device due to branch line failure There exists an effect that it can apply also to control.
[0066]
According to the next invention, when the notification of the start of switching of the main transmission line is received by the switching notification receiving step, and when the notification of the start of switching of the main transmission line is received by the timing start step, the switching of the main transmission line is performed. Since the timing by the timer that counts the predetermined time corresponding to the accompanying non-communication time is started, the start control of each slave station device is started by the start control process after the time of the predetermined time by the timer has expired. Regardless of the detection of the uplink alarm accompanying the switching of the main transmission line, it is possible to grasp the instantaneous interruption accompanying the switching of the main transmission line and to reliably perform the stop control and start control of the slave station device. .
[0067]
According to the next invention, the trunk line switching determination step detects whether or not an uplink warning for each slave station device associated with the switching of the trunk transmission line has been detected for all active slave station devices. In the time measurement start step, when an upstream alarm is detected for all active slave station devices, the time is controlled by a timer that measures a predetermined time corresponding to the disconnection time associated with the switching of the main transmission line, and the start control step Therefore, the start control of each slave station device is started after the timing of the predetermined time by the timer expires, so that an instantaneous interruption associated with switching of the main transmission line can be ensured separately from the protection of the upstream alarm. It is possible to identify and quickly perform stop control and start control of the slave station device.
[0068]
  According to the next invention, the band information holding step holds the band information that is information on the used transmission band assigned to each slave station device, and the timer setting stepFor each slave station device,A predetermined time corresponding to the switching time from the start of switching of the trunk line to the completion of switching"From the size of the used transmission band indicated by the band information"From the occurrence of switching of the trunk transmission lineConcernedSlave station deviceCorresponded toUntil the up alarm is detectedIs timeelapsed time"The remaining time is calculated by subtracting, and the corresponding remaining time is set in the timer corresponding to each slave station device, and when the uplink alarm from the slave station device is detected by the activation control step, the uplink alarm is Since the time measurement by the timer corresponding to the issued slave station device is started and the start control of the slave station device is started after the time measured by the timer has expired, the bandwidth allocated to the slave station device is Regardless of the size, it is possible to always perform stop control and start control of the slave station device within a certain time, and not only instantaneous interruption due to main line switching but also stop for each slave station device due to branch line failure There is an effect that it can also be applied to control and activation control.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of an optical multi-branch communication system according to a first embodiment of the present invention.
2 is a diagram showing a detailed configuration of a slave station apparatus of the optical multi-branch communication system shown in FIG.
3 is a flowchart showing a transmission path switching recovery control processing procedure by the optical multi-branch communication system shown in FIG. 1;
4 is a timing chart showing an example of transmission path switching recovery control processing by the optical multi-branch communication system shown in FIG. 1. FIG.
FIG. 5 is a diagram showing a configuration of an optical multi-branch communication system according to a second embodiment of the present invention.
6 is a flowchart showing a transmission path switching recovery control processing procedure by the optical multi-branch communication system shown in FIG.
7 is a timing chart showing an example of transmission path switching recovery control processing by the optical multi-branch communication system shown in FIG.
FIG. 8 is a diagram showing a configuration of an optical multi-branch communication system according to a third embodiment of the present invention.
9 is a flowchart showing a transmission path switching recovery control processing procedure by the optical multi-branch communication system shown in FIG.
10 is a timing chart showing an example of transmission path switching recovery control processing by the optical multi-branch communication system shown in FIG.
FIG. 11 is a diagram showing a configuration of a conventional optical multi-branch communication system.
12 is a flowchart showing a transmission path switching recovery control processing procedure by the optical multi-branch communication system shown in FIG.
13 is a timing chart illustrating an example of transmission path switching recovery control processing by the optical multi-branch communication system illustrated in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Master station apparatus, 2 Communication interface part, 3a, 3b Optical switch, 4 Optical splitter, 5,5-1 to 5-n Slave station apparatus, 6 Switching instruction | indication part 10 Band control part, 11, 21 Optical transmitter-receiver, 12 Upward alarm monitoring unit, 13 Start / stop control unit, 13a Timer setting unit, 14 Management signal sending unit, 15 Up signal, 16 Down signal, 17 Registration management unit, 19 Trunk disconnection judgment unit, 22 Down alarm monitoring unit 23 Assignment identification Unit, 24a, 24b data reading unit, 25a, 25b buffer memory, 26a, 26b uplink data, 27 multiplexing unit, 28 uplink data transmission control unit, 31 switching instruction transmission unit L1, L2a, L2b, L3, L4, L4- 1-L4-n optical fiber.

Claims (2)

A master station device and a plurality of slave station devices are connected by an optical splitter, and at least a trunk transmission line between the master station device and the optical splitter has a redundant configuration by a signal route switching means capable of switching the transmission line. The master station device controls the allocation of the used transmission band of each slave station device, and each slave station device transmits transmission information to the master station device based on the allocation of the used transmission band by the master station device. In an optical multi-branch communication system,
The master station device is
Slave station start / stop control means for controlling start and stop of the slave station device;
An upstream alarm monitoring means for detecting an upstream alarm of each slave station device by monitoring the upstream signal;
Band information holding means for holding band information, which is information related to the used transmission band assigned to each slave station device,
A plurality of timers corresponding to each slave station device;
For each slave station device, from “a predetermined time corresponding to a switching time from the start of switching of the trunk transmission line to the completion of switching”, “switching of the trunk transmission line” according to the size of the used transmission band indicated by the band information. Timer that calculates the remaining time by subtracting the “elapsed time that is the time from occurrence to detection of the uplink alarm corresponding to the slave station device”, and sets the corresponding remaining time in the timer corresponding to each slave station device Setting means;
With
The slave station start / stop control means, when detecting an uplink alarm, performs stop control on the slave station apparatus that is generating the uplink alarm, and further counts time by a timer corresponding to the slave station apparatus that is generating the uplink alarm And the start-up control of the slave station apparatus is started after the time counted by the timer has expired. A master station device and a plurality of slave station devices are connected by an optical splitter, and at least a trunk transmission line between the master station device and the optical splitter has a redundant configuration by a signal route switching means capable of switching the transmission line. The master station device controls the allocation of the used transmission band of each slave station device, and each slave station device transmits transmission information to the master station device based on the allocation of the used transmission band by the master station device. In the optical multi-branch communication system, in the transmission path switching recovery control method by the master station device,
A band information holding step for holding band information that is information about the used transmission band assigned to each slave station device;
For each slave station device, from “a predetermined time corresponding to a switching time from the start of switching of the trunk transmission line to the completion of switching”, “switching of the trunk transmission line is determined according to the size of the used transmission band indicated by the band information”. Timer that calculates the remaining time by subtracting the “elapsed time that is the time from occurrence to detection of the uplink alarm corresponding to the slave station device”, and sets the corresponding remaining time in the timer corresponding to each slave station device A setting process;
When detecting the up alarm from the slave station device by the monitoring of the uplink signal, performs stop control to the slave station apparatus said uplink in alarm, further corresponds to the slave station apparatus said uplink in alarm A start control step of starting the time measurement by the timer, and starting the start control of the slave station device after the time measured by the timer has expired;
Including a transmission path switching recovery control method.

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