JP3896660B2 - Network monitoring system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a network monitoring system in which a child transmission device having a parent transmission device, a control unit, and a child transmission device not having a control unit are connected by a transmission path.
[0002]
With the progress of the information society, high-speed communication of large amounts of data has become necessary, and the network has been expanded more and more. A transmission apparatus connected to such a large-scale network includes, for example, a microprocessor, which is used as a control unit, and performs various setting control and monitoring by the control unit, thereby enabling a flexible network construction. On the other hand, it is also necessary to construct a network economically. For this purpose, a child transmission device with a small number of accommodating terminals does not have a control unit and detects its own failure in hardware. Information is held in a register, and the failure information is collected and monitored by accessing the register from the control unit of the parent transmission apparatus.
[0003]
In such a network, when the entire network is monitored by the parent transmission device, if the network becomes larger, the number of devices to be monitored increases, the monitoring items are diversified, and the amount of failure information processed by the parent transmission device increases. In some cases, the load on the control unit increases, the processing takes a long time, and failure information cannot be collected quickly.
[0004]
Therefore, there is a demand for a monitoring method for a transmission apparatus that can efficiently perform monitoring control even in a large-scale network.
[0005]
[Prior art]
FIG. 9 is a diagram for explaining a conventional example. Reference numeral 100 in the figure denotes a parent transmission apparatus, a control unit 110 that performs monitoring control of the own apparatus and network monitoring control, a storage apparatus 130 that accumulates the own apparatus and collected fault information, and various control information, Registers 141 to 143 for storing individual failure information in the own apparatus are provided.
[0006]
Reference numerals 201A and 202A denote a control unit 210 that performs monitoring control of the own device, a storage device 230 that stores failure information of the own device, and various control information, and registers 241 to which failure information in the own device is written. This is a child transmission device I having 242.
[0007]
Further, 301A and 302A are child transmission apparatuses II that do not have a control unit, and are provided with a register 341 in which failure information in the own apparatus is written.
In the configuration shown in the figure, the parent transmission device 100 includes three registers 141 to 143, the child transmission devices I201A and 202A include two registers 241 and 242, and the child transmission devices II301A and 302A include only one register 341. However, the number of registers is not limited to this number, and can be increased or decreased depending on the scale of the transmission apparatus.
[0008]
Reference numeral 400 denotes a network monitoring device connected to the parent transmission device 100.
In such a configuration, the slave transmission apparatuses I201A and 202A perform monitoring control of the own apparatus by the control unit 210. Since the detected individual failure information is written in the registers 241 and 242, the control unit 210 reads out the failure information from the registers 241 and 242 and stores it in the designated area of the storage device 230.
[0009]
On the other hand, the child transmission devices II 301 A and 302 A monitor their own devices, and when a failure is detected, the failure information is held in the register 341.
In this state, the control unit 110 of the parent transmission device 100 collects the failure information written in the storage device 230 via the control unit 210 of the child transmission devices I201A and 202A. For the child transmission devices II 301 A and 302 A, the failure information is collected by directly accessing the register 341, written into the storage device 130, the failure information is processed, and the result is displayed on the display of the network monitoring device 400.
[0010]
[Problems to be solved by the invention]
In such network monitoring control, when a plurality of failures occur, the failures are often causally related. For example, when a failure occurs in a transmission line connecting between transmission devices and the signal level is lowered, the failure is detected as a failure, such as a signal level drop or a clock signal loss of synchronization. From the point of network monitoring, it is not necessary to output the two faults individually. If only the “signal level drop” that is the cause of these faults is output, It is enough for disaster countermeasures. Such basic failure causes primary failure, information related to primary failure is called primary alarm, failure caused by primary failure is secondary failure, information related to secondary failure is secondary This is called an alarm.
[0011]
The present invention provides a network capable of reducing the load on the parent transmission device and efficiently performing monitoring control by suppressing secondary alarms related to secondary failures caused by primary failures in network monitoring. To implement the monitoring method.
[0012]
[Means for Solving the Problems]
FIG. 1 is a diagram for explaining the principle of the present invention. In the figure, a parent transmission device 100, one or a plurality of first child transmission devices 201 and 202 having a control unit, and a predetermined number of second child transmission devices 301 and 302 having no control unit are connected by a transmission line. Network Here, the predetermined number of second child transmission devices 301 and 302 indicates that any number including 0 is possible.
[0013]
In the figure, a parent transmission device 100 controls a control unit 110 that collects failure information from a predetermined number of second child transmission devices 301 and 302 that do not have a control unit with itself, and a primary alarm in the failure information. A primary alarm notification unit 120 for sending to one or a plurality of first child transmission devices 201 and 202 having a unit.
[0014]
In addition, the one or more first child transmission devices 201 and 202 having a control unit include a control unit 210 that collects failure information of the own device, a primary alarm received from the parent transmission device 100, and a primary in the own device. A secondary alarm suppression unit 220 that suppresses secondary alarms related to the alarm is provided.
[0015]
Reference numerals 301 and 302 denote second child transmission devices that do not have a control unit, and include a register 341 that holds failure information.
The master transmission device 100 suppresses the secondary alarm in the failure information collected from the failure information of the own device and the predetermined number of second child transmission devices 301 and 302 that do not have a control unit, and the primary in the failure information. The first child transmission devices 201 and 202 having the control unit are notified of the alarm, and the first child transmission devices 201 and 202 having received the notification receive the primary alarm received from the parent transmission device and the primary alarm in the own device. The related secondary alarm is suppressed, and the failure information in which the secondary alarm is suppressed is sent to the parent transmission device 100.
[0016]
In the figure, two each of the first slave transmission device and the second slave transmission device are shown. However, the number is not limited to two, and can be increased or decreased depending on the scale of the network. A plurality of master transmission devices 100, at least one first child transmission device 20i (i = arbitrary number), and zero or more second child transmission devices 30j (j = arbitrary number). Is possible.
[0017]
The network is illustrated as a ring network, but is not limited to a ring network.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 2 is a diagram for explaining the embodiment (1) of the present invention. The figure shows a network in which a parent transmission device 100 and child transmission devices I201A and 202A as first child transmission devices 20i and child transmission devices II301A and 302A as second child transmission devices 30j are connected by a transmission line. It is.
[0019]
The parent transmission device 100 includes a control unit 110, a primary alarm notification unit 120, a storage device 130, and registers 141 to 143, to which a network monitoring device (shown as a monitoring device in the figure) 400 is connected, and the child transmission devices I201A and 202A. Includes a control unit 210, a secondary alarm suppression unit 220, a storage device 230, and registers 241 and 242, and the child transmission devices II301A and 302A include a register 341.
[0020]
Further, the child transmission devices II 301A and 302A are provided with a register 341 for holding a failure state, and the control unit 110 of the parent transmission device 100 accesses the register 341 to display the stored alarm information. Collected and stored in the storage device 130. In addition, since the failure information of the own device of the parent transmission device 100 is held in the registers 141 to 143, the failure information is collected by accessing it from the control unit 110.
[0021]
Further, the failure information of the own device in the child transmission devices I201A and 202A is held in the registers 241 and 242, and the control unit 210 accesses them to collect the failure information and store it in the storage device 230.
[0022]
The failure information collected by the parent transmission device 100 is referred to an alarm table T (not shown, which will be described with reference to FIG. 3) to determine whether or not there is a primary alarm. When there is a primary alarm, the primary alarm is notified to all the child transmission devices I201A and 202A. The child transmission devices I201A and 202A that have received the primary alarm also have an alarm table T (not shown), and read the primary alarm received from the failure information collected by reading the registers 241 and 242 of the own device, and Suppress the secondary alarm corresponding to the primary alarm in the device itself. The collected failure information is sent to the network monitoring device 400, and designated statistical processing is performed. The result is displayed on the display of the network monitoring device 400. As described above, the child transmission devices I201A and 202A send the failure information after the secondary alarm is suppressed to the parent transmission device 100, so that the amount of failure information processed by the parent transmission device 100 can be reduced. Monitoring control can be performed.
[0023]
FIG. 3 is a diagram for explaining an alarm table according to the present invention. The alarm table T is a table in which correspondence between primary alarms and secondary alarms is summarized in the table. In the figure, secondary alarms a1 to ai for the primary alarm A and secondary alarms b1 to b1 for the primary alarm B are shown. For bj, secondary alarms n1 to nk are registered for the primary alarm N.
[0024]
FIG. 4 is a flowchart (part 1) of the embodiment (1) of the present invention. The operation of the present invention will be described in detail with reference to FIG.
Step (hereinafter referred to as S) 1; The parent transmission apparatus 100 repeats an operation of collecting failure information every time a predetermined time elapses by a timer not shown. Here, first, the registers 141 to 143 of the parent transmission apparatus 100 are read to detect fault information.
[0025]
S2; Next, the child transmission devices are sequentially accessed, and it is determined whether or not all the child transmission devices have been accessed.
S3: It is determined whether or not the accessed child transmission device is the child transmission device II. If the accessed child transmission device is not the child transmission device II, the process returns to S2 to access the next child transmission device.
[0026]
S4; When the child transmission apparatus accessed in S3 is the child transmission apparatus II, the failure information is detected by reading the register 341.
S5: When access of all the child transmission devices is completed in S2, it is determined whether or not there is a primary alarm in the failure information collected with reference to the alarm table T.
[0027]
S6: When there is a primary alarm in the collected failure information, the secondary alarm corresponding to the primary alarm is suppressed with reference to the alarm table T.
S7; Next, only the child transmission device I is sequentially accessed, and it is determined whether or not all the child transmission devices I have been accessed.
[0028]
S8: Only the primary alarm as a result of suppressing the secondary alarm in S6 is notified to all the child transmission devices I.
In S5, if the collected failure information does not include the primary alarm, the process ends as it is.
[0029]
FIG. 5 is a flowchart (part 2) of the embodiment (1) of the present invention. In FIG. 4, the failure information is collected by the parent transmission device 100, and when the primary alarm is not included in the failure information, the processing is terminated as it is. However, even when the primary alarm is not included, the child transmission devices I201A and 202A By receiving primary alarm no-information indicating that there is no primary alarm from the parent transmission device 100, the normal operation of the parent transmission device 100 is confirmed. Only the parts of the flowchart that are different from FIG. 4 will be described.
[0030]
S1 to S8 are the same as in FIG.
S9: Even if there is no primary alarm in the failure information collected in S5, the child transmission device I20iA is sequentially accessed, and it is determined whether or not all the child transmission devices I have been accessed.
[0031]
S10: Notify the accessed child transmission apparatus I20iA that there is no primary alarm.
FIG. 6 is a flowchart (part 3) of the embodiment (1) of the present invention. The figure is a flowchart for explaining the operation of the child transmission device I20iA that has been notified of the primary alarm by the processing of the flowcharts of FIGS.
[0032]
(A) is an example in which an operation for processing fault information is repeated every time a predetermined time elapses by a timer not shown.
S1; When a predetermined time elapses due to the timer, the control unit 210 is activated, reads the registers 241 and 242 in its own device, and writes the failure information in the storage device 230.
[0033]
S2: It is determined whether there is a primary alarm in the own apparatus or a primary alarm received from the parent transmission apparatus 100.
S3: The secondary alarm corresponding to the primary alarm is suppressed with reference to the alarm table T.
[0034]
S4: Notify the parent transmission device 100 of the failure information for which the secondary alarm is suppressed.
In this way, by suppressing the primary alarm in the own device and the secondary alarm corresponding to the primary alarm received from the parent transmission device 100, the amount of information to be transmitted is reduced, and the load on the control unit 110 is reduced. Is possible.
[0035]
(B) The parent transmission device 100 collects the failure information, and if there is a primary alarm in the failure information, sends the primary alarm to the child transmission device I20iA. Here, when a primary alarm is received from the parent transmission device 100, the control unit 210 of the child transmission device I20iA is activated to collect failure information and send it to the parent transmission device 100. This is an example in which step S1A for determining whether or not a primary alarm has been received is added to the flowchart.
[0036]
FIG. 7 is a diagram for explaining the embodiment (2) of the present invention. In the embodiment (1) described with reference to FIG. 2, one master transmission device 100 is provided on the network. However, in the embodiment (2), in order to increase the reliability of network monitoring, a plurality of master transmission devices 100 are provided. In this example, two parent transmission apparatuses 101 and 102 are provided.
[0037]
In the child transmission devices I201A and 202A and the child transmission devices II301A and 302A of the embodiment (2), the active registration unit in which information specifying the device to be monitored as the active system among the parent transmission devices 101 and 102 is written. As the memories 251 and 351.
[0038]
In the configuration of the figure, the control unit 110 of the parent transmission devices 101 and 102 accesses the memories 251 and 351 of the child transmission devices I201A and 202A and the child transmission devices II301A and 302A, and determines the active device from the registration information. Then, the parent transmission device 10i (i = 1OR2) designated as the active system performs the same processing as described in the embodiment (1) and collects fault information.
[0039]
With this configuration, the reliability of the network can be increased.
FIG. 8 is a diagram for explaining an embodiment (3) of the present invention. The embodiments (1) and (2) described in FIGS. 2 and 3 are networks composed of one ring, but in FIG. 8, the network is composed of a sub-ring and a main ring. In this example, the failure information collected by the parent transmission device 100 is sent to the main ring transmission device 100A.
[0040]
In the figure, the sub-ring is composed of a parent transmission device 100, child transmission devices I201A and 202A, and child transmission devices II301A and 302A, and the main ring is composed of transmission devices 100A, 100B, and 100C and the parent transmission device 100. Here, the parent transmission device 100 serves as a parent ring transmission device for the sub-ring and operates as a transmission device constituting the main ring.
[0041]
In the embodiment (3), the sub-ring parent transmission device 100 is provided with a main ring interface (interface shown as INF in the figure) 160 that interfaces with the main ring. The failure information of the sub ring is sent to the main ring via the main ring interface 160, and the failure information is displayed on the display of the network monitoring device 400 connected to the transmission device 100A of the main ring.
[0042]
Here, in the sub-ring failure information collection processing, the operation of suppressing the secondary alarm is the same as described in the embodiment (1).
With such a configuration, network monitoring can be efficiently performed even in a network composed of a sub-ring and a main ring.
[0043]
【The invention's effect】
According to the present invention, the secondary alarm related to the notified primary alarm is notified in the slave transmission device by notifying the primary transmission device in the failure information collected by the master transmission device to the slave transmission device provided with the control unit. Can be reliably deterred.
[0044]
In addition, this suppression operation can reduce network failure information, reduce the load on the control unit, and enable efficient network monitoring.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining the principle of the present invention. FIG. 2 is a diagram for explaining an embodiment (1) of the present invention. FIG. 3 is a diagram for explaining an alarm table according to the present invention. (1) Flowchart of form (1)
FIG. 5 is a flowchart (part 2) of the embodiment (1) of the present invention.
FIG. 6 is a flowchart (part 3) of the embodiment (1) of the present invention.
FIG. 7 is a diagram for explaining embodiment (2) of the present invention. FIG. 8 is a diagram for explaining embodiment (3) of the present invention. FIG. 9 is a diagram for explaining a conventional example.
100, 101, 102 Parent transmission device 100A to 100C Transmission device 110, 210 Control unit 120 Primary alarm notification unit 130, 230 Storage devices 141-143, 241, 242, 341 Register 160 Maining interface 201, 202 First child transmission Device 201A, 202A Child transmission device I
220 Secondary alarm suppression unit 251, 351 Memory 301, 302 Second child transmission device 301A, 302A Child transmission device II
400 Network monitoring device T Alarm table

Claims (3)

In a network in which a parent transmission device, one or a plurality of first child transmission devices having a control unit, and a predetermined number of second child transmission devices not having a control unit are connected by a transmission path,
The parent transmission device includes a register that holds failure information of the device itself,
A control unit that collects failure information from a predetermined number of second child transmission devices that do not have its own device and control unit;
A primary alarm notification unit for sending a primary alarm in the failure information to one or a plurality of the first child transmission devices having a control unit;
One or a plurality of first child transmission devices having the control unit, a register that holds the failure information of its own device,
A control unit that collects failure information of the device itself;
A secondary alarm suppression unit that suppresses a primary alarm received from the parent transmission device and a secondary alarm related to the primary alarm in the own device;
The master transmission device suppresses secondary alarms in failure information collected from a predetermined number of second child transmission devices not having failure information and a control unit of the own device, and has a first control unit. child transmission apparatus, a network monitoring system, characterized in that to suppress the secondary alarm associated with primary alarm primary alarms and the own apparatus is received from the main transmission apparatus. In a network in which a plurality of parent transmission devices, one or more first child transmission devices having a control unit, and a predetermined number of second child transmission devices not having a control unit are connected by a transmission path,
The parent transmission device includes a register that holds failure information of the device itself,
A control unit that collects failure information from a predetermined number of second child transmission devices that do not have its own device and control unit;
A primary alarm notification unit for transmitting a primary alarm in the failure information to one or a plurality of first child transmission devices having the control unit;
One or a plurality of first child transmission devices having the control unit, a register that holds the failure information of its own device,
A control unit that collects failure information of the device itself;
A primary alarm received from the parent transmission device, and a secondary alarm suppression unit for suppressing secondary alarms related to the primary alarm in the device itself;
An active registration unit that registers an active parent transmission device among the plurality of parent transmission devices, and a predetermined number of second child transmission devices that do not have the control unit include: It has a working registration unit that registers the parent transmission device that is the working system inside,
The plurality of parent transmission devices access one or a plurality of first child transmission devices having the control unit and a predetermined number of second child transmission devices not having the control unit, and the accessed control unit One or a plurality of first child transmission devices and a predetermined number of second child transmission devices not having the control unit send failure information to the parent transmission device registered in the active registration unit. Network monitoring system characterized by. A sub-ring in which a parent transmission device, one or a plurality of first child transmission devices having a control unit, and a predetermined number of second child transmission devices not having a control unit are connected by a transmission line and a plurality of transmission devices In a network consisting of main rings connected by a transmission line,
The parent transmission device includes a register that holds failure information of the device itself,
A control unit that collects failure information from a predetermined number of second child transmission devices that do not have its own device and control unit;
A primary alarm notification unit for sending a primary alarm in the failure information to one or a plurality of first child transmission devices having the control unit;
It has a main ring interface that transmits and receives control monitoring information to the main ring network.
One or more first child transmission apparatus having the control unit includes a register for holding the failure information of the self apparatus, suppresses secondary alarms associated secondary alarm primary alarm received from the main transmission apparatus With a deterrent section,
The parent transmission device suppresses secondary alarms in the failure information collected from the failure information of the own device and a predetermined number of second child transmission devices not having the control unit, and the collected failure information is main- ringed. The first child transmission device that is sent to the main ring via the interface and has the control unit suppresses the secondary alarm related to the primary alarm received from the parent transmission device and the primary alarm in the own device. Feature network monitoring system .

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