JPH11317745A - Network system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a network system which can back up and restore setting data even if a backup memory of its own transmitting device is abnormal. SOLUTION: Each of network constitution device has a backup storage means 44 which is connected to the network constitution device by a transmission line and holds setting data of mutually opposite network constitution devices. The setting data of the network constitution device are held in the backup storage means 44 of the opposite network constitution device, so even if hardware such as the backup memory and access circuit of the network constitution device is abnormal, its setting data can be backed up.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a network system, and more particularly to a network system in which a plurality of network components are connected by a transmission line.

[0002]

2. Description of the Related Art FIG. 1 is a block diagram showing an example of a conventional network system. In FIG. 1, each of the transmission devices 11 to 15 is connected by a transmission line 16 to form a network system. Each of the transmission devices 11 to 15 is connected to an upper control monitoring device (OPS) 18 via a LAN (local area network) 20. In such a network system, data necessary for starting up each of the transmission devices 11 to 15 in terms of reliability and security,
In other words, setting and status data of a built-in hardware package and the like are backed up as backup data.

Conventionally, as shown in FIG.
To 15 each have a CPU 21 for controlling their own transmission device.
A RAM 22 storing data of setting and status of a built-in hardware package and the like; and a backup memory (non-volatile memory) for backing up data of setting and status of a built-in hardware package and the like necessary for starting up the transmission device. Memory 23). Further, the upper-level control monitoring device 18 also includes hard disk devices (HD) 25 _{1 to} 25 ₅ for backing up the setting and status data of the built-in hardware package necessary for starting up the transmission devices 11 to 15, respectively. Is provided.

[0004] The backup to the own transmission device is performed by the maintenance person by the operation of the host control and monitoring device 18.
Data necessary to start up the own transmission device is copied from the AM 22 to the backup memory 23 of the own transmission device. In addition, the backup to the higher-level control monitoring device 18 is performed by a maintenance person operating the higher-level control monitoring device 18 from the backup memory 23 of the own transmission device via the LAN 20 via the hard disk device corresponding to the own transmission device in the higher level control monitoring device 18 21i (i is 1 to 5).

[0005]

Conventionally, when a failure occurs in a transmission apparatus, data stored in the backup memory 23 of the transmission apparatus is transferred to the RAM 22 for restoration.
For this reason, when there is an abnormality in the hardware such as the backup memory 23 and its access circuit, there is a problem that the backed up data cannot be read and restored.

The backup to the higher-level control and monitoring device 18 is performed by the maintenance person by operating the higher-level control and monitoring device 18. Therefore, the backup is held in the hard disk device corresponding to its own transmission device in the higher-level control and monitoring device 18. In some cases, the data that is stored may be different from the latest data in the RAM 22, and in that case, there is a problem that the data cannot be restored to the latest state.

[0007] The present invention has been made in view of the above points,
It is an object of the present invention to provide a network system capable of backing up and restoring setting data even if there is an abnormality in a backup memory of its own transmission device.

[0008]

According to a first aspect of the present invention, there is provided a network system in which a plurality of network components are connected by a transmission line, wherein each of the plurality of network components is provided with its own network component. And backup storage means for storing setting data of network components connected to each other via the transmission path and facing each other.

As described above, since the setting data of the own network component device is stored in the backup storage means of the opposing network component device, when there is an abnormality in the hardware such as the backup memory of the own network component device and its access circuit. Also, the setting data can be backed up. According to a second aspect of the present invention, in the network system according to the first aspect, a higher-level control / monitoring device that controls and monitors the network is configured to hold a setting history of setting data for each of the plurality of network components. It has history holding means.

As described above, since the setting history of the setting data for each of the plurality of network components is held in the host control monitoring device, it is necessary to transmit the setting data from each network component to the host control monitoring device for backup. The setting data of each network component device can be restored from the setting history of the setting data.

According to a third aspect of the present invention, in the network system according to the first or second aspect, the transmission of the setting data between the own network configuration device and the network configuration devices connected to each other by the transmission path and facing each other is performed by transmitting This is performed using predetermined bits in the header part of the frame.

As described above, the setting data is transmitted between the network components by using the predetermined bits of the header of the transmission frame, so that the backup can be performed without affecting the normal data transmission between the network components. it can. According to a fourth aspect of the present invention, in the network system according to the third aspect, the higher-level control / monitoring device is configured such that when a holding amount of a setting history of setting data for each of the plurality of network constituent devices exceeds a predetermined threshold. Then, the corresponding network component device holds the setting data, and deletes the setting history of the corresponding setting data.

As described above, when the holding amount of the setting history of the setting data for each of the plurality of network constituent devices exceeds a predetermined threshold value, the corresponding network constituent device holds the setting data, and the corresponding setting data is stored. By deleting the setting history, it is possible to limit the holding amount of the setting history of the setting data in the higher-level control monitoring device.

According to a fifth aspect of the present invention, in the network system according to the second aspect, the setting history holding means holds an address in each network component device and time information together with the setting data. In this way, by holding the setting data together with the address in each network component device and the time information, it is possible to restore the backup up to the time specified.

[0015] The invention according to claim 6 is the invention according to claims 2 to 5.
In the network system according to any one of the above, after the setting data stored in the backup storage unit of the opposite network configuration device is transmitted and restored to the own network configuration device, the setting stored in the configuration history storage unit is restored. Based on the data setting history, the higher-level control monitoring device sets the setting data in the own network configuration device and performs backup restoration.

As described above, after restoring the backed up configuration data from the opposing network component,
Since the backup is restored by setting the setting data based on the setting history, even if the setting is made from the higher-level control monitoring device until the next backup after the backup to the opposite network component, the setting is also included. Complete restoration is possible.

[0017]

FIG. 3 is a block diagram showing one embodiment of a network system according to the present invention. In the figure, transmission devices 31 to 35 are connected by a transmission line 36 to form a network system. Each of the transmission devices 31 to 35 as the above-mentioned network components is connected to an upper control monitoring device (OPS) 38 via a LAN (local area network) 40. In such a network system, data necessary for starting up each of the transmission devices 31 to 35, that is, data of setting and status of a built-in hardware package and the like is backed up as backup data in terms of reliability and security. Do that.

In the present invention, as shown in FIG. 4, each of the transmission devices 31 to 35 has a CPU 4 for controlling its own transmission device.
1, a RAM 42 storing setting and status data of a built-in hardware package and the like, and a non-volatile memory for backing up setting and status data of a built-in hardware package and the like necessary for starting up the transmission device. And a backup memory 44, which is a non-volatile memory for backing up data of setting and status of a built-in hardware package and the like necessary for starting up a transmission device that is adjacent to the BUM. Have been. Also, the higher-level control monitoring device 38 holds the hard disk devices (HD) 41 _{1 to} 41 _{5 which} are retained when the setting and status data of the built-in hardware packages of the transmission devices 31 to 35 are updated.
Is provided.

[0019] In this configuration, when the upper control monitoring device 38 for changing the setting of the transmission device 31 for example, it holds the changes to the hard disk device 41 _1, transmitter 3
1 is rewritten. Further, at a predetermined timing, a command is issued to the transmission device 31 and the RAM 42 of the transmission device 31
Is stored in the backup memory 43 of the transmission device 31 to perform backup. If the backup of the transmission device 31 to the backup memory 43 is abnormal,
The contents of the RAM 42 of the transmission device 31 are held in the backup memory 44 of the transmission device 32 that is opposed via the transmission line 36 to perform backup. The same applies to the other transmission devices 32, and the backup memory 43 of the transmission device 32
When the backup to the transmission device 32 is abnormal,
The backup is performed by holding the contents of the AM 42 in the backup memory 44 of the transmission device 31 opposed thereto via the transmission line 36.

Further, as shown in FIG.
In the case where a repeater 37 as a network component device is connected between the two by a transmission line 36 and the transmission devices 31 and 32 are not connected to another transmission device via the transmission line, the repeater 3
7, a CPU 41 for controlling its own transmission device, and an R for storing setting and status data of a built-in hardware package and the like.
The AM 42, a backup memory (BUM) 43 which is a non-volatile memory for backing up data of setting and status of a built-in hardware package and the like necessary for starting the own transmission device, and a transmission device that is adjacent to the transmission device. Backup memories 44 and 45, which are non-volatile memories for backing up data of setting and status of a built-in hardware package and the like necessary for raising the size, are provided. The backup memories 44 and 45 are for backing up the data of the transmission devices 31 and 32, respectively.

[0021] In this configuration, when the upper control monitoring device 38 for example to change the setting of the transmission apparatus 31 (or 32), which holds the changes to the hard disk device 41 _1, 41 _2, the transmission apparatus 31 (or 32) RAM4
Rewrite 2. Further, at a predetermined timing, a command is issued to the transmission device 31 (or 32) to transmit the command to the transmission device 31 (or 3).
2) The contents of the RAM 42 are transferred to the transmission device 31 (or 32).
The backup is performed by being held in the backup memory 43. If the backup of the transmission device 31 (or 32) to the backup memory 43 is abnormal, the contents of the RAM 42 of the transmission device 31 (or 32) are transferred to the transmission line 36.
Backup memory 44 of the repeater 37 which is opposed via
(Or 45) for backup.

Here, the data format of the data flowing on the transmission path 36 is an SDH (Synchronized Digital Hierarchy) transmission frame as shown in FIG. In the figure, the SDH transmission frame includes a header section 50 and a communication actual data section 51. DCC (data communication channel) bytes used for transfer of supervisory control data and the like are defined in the header section 50, and the transmission device is formed by LAP-D (message format protocol) using the DCC bytes of a plurality of SDH transmission frames. Between the backup data. As described above, by using the predetermined bits of the header part of the transmission frame for the transmission of the setting data between the transmission devices 31 and 32, backup can be performed without affecting the normal data transmission between the network components. .

FIG. 7 shows a backup processing sequence executed by the host control monitoring device 38. This process is executed, for example, when the setting of the transmission device 31 shown in FIG. 4 is changed. In the figure, the host control monitoring device 38 is a LAN4
0, a setting command is transmitted to the transmission device 31 through
In step S10, the transmission device 3
1 is converted from the setting command in the RAM 42 and the hard disk drive 4 corresponding to the transmission device 31 is converted.
1 Stored in ₁ . Thus, as shown in FIG. 8, the date and time (time information), and sets the address of the RAM 42, and the setting data are stored in the hard disk device 41 ₁ as setting history. In this manner, by storing the setting data together with the address and the time information, it is possible to perform backup restoration up to the time specified.

Next, the amount of data stored in the hard disk device 41 ₁ in step S12 it is determined whether or not exceeding the threshold value. Here, the threshold is 50% of the threshold A for the entire memory capacity of the hard disk device 41 _1.
Further, as shown in FIG. 9, the thresholds used for the above determination may be changed to a threshold A (50%), a threshold B (75%), and a threshold C (88%) according to the number of backups. If the storage data amount does not exceed the threshold value in step S12, the process ends, and if the storage data amount exceeds the threshold value, the process proceeds to step S14.

In step S14, the hard disk drive 4
That store data amount of one ₁ exceeds the threshold value and notifies the maintenance person, and then initiates a backup request to the transmission apparatus 31 at step S16. In this way, the host control monitoring device 38 checks whether the data link by the LAN 40 is normal or abnormal to the transmission device 31, and obtains a response from the transmission device 31.

Thereafter, it is checked in step S18 whether the data link is normal or abnormal based on the above response. If the data link is abnormal, the data link alarm is notified to the maintenance person in step S20, and the process is terminated. If it is normal, a command is sent from the RAM 42 to the transmission device 31 to request backup to the backup memory 43 of the own transmission device, and a response from the transmission device 31 is obtained. Then, in step S22, it is determined whether the backup has been completed normally or abnormally.

At the time of this backup, the data to be backed up is added, for example, in byte units, and a SUM value which becomes 0 when added to the sum thereof is calculated and added to the backup data. It can be checked whether or not the backup has been normally performed based on whether or not the total sum becomes 0 when the addition is performed.

[0028] Here, if the backup is successful the process proceeds to step S30, and ends the process to delete the stored data to threshold of the hard disk device 41 _1. If the backup has ended abnormally, step S24 is executed.
To notify the maintenance person of the backup abnormality alarm in the own transmission device 31. Thereafter, a command is sent to the transmission device 31 requesting backup to the backup memory 44 of the opposing transmission device 32, and the data is transferred from the RAM 42 of the transmission device 31 to the backup memory 44 of the opposing transmission device 32. A completion notification is sent from the device 32 to the transmission device 31, and a completion notification is sent from the transmission device 31 to the host control monitoring device 38. In step S26, the host control monitoring device 38 determines whether the backup has been completed normally or abnormally based on the completion notification.

According to this determination, if the backup in the opposite transmission device 32 ends abnormally, step S2
At 8, an alarm of a backup error in the opposite transmission device 32 is notified to the maintenance person, and the process ends. Also, if the backup in the transmission device 32 facing was successful, the process ends by deleting the stored data to threshold of the hard disk device 41 ₁ in step S30.

[0030] That is, if the data stored in the hard disk device 41 ₁ has exceeded the threshold value as shown in FIG. 10 (A), by the execution of step S30, stores the data until the threshold value is deleted, and FIG. 10 (B) As shown in ( ₁₎ , storage data exceeding the threshold value of the hard disk device 41 ₁ is left in the hard disk device 41 ₁ . In this way, when the retention amount of the setting history of the setting data for each of the transmission devices 31 and 32 as the plurality of network components exceeds a predetermined threshold, the corresponding network component device holds the setting data, By deleting the setting history of the corresponding setting data, it is possible to limit the holding amount of the setting history of the setting data in the higher-level control monitoring device.

As described above, since the setting data of the transmission devices 31 and 32 are held in the backup memory 44 of the transmission devices 32 and 31 facing each other, the backup memory 43 of the transmission devices 31 and 32 and hardware such as an access circuit thereof are provided. The setting data can be backed up even when there is an abnormality in the wear. Further, in order to store the setting history of the setting data for each of the transmission devices 31 and 32, which are a plurality of network components, in the higher-level control and monitoring device 38, the transmission from each of the transmission devices 31 and 32 to the higher-level control and monitoring device 38 for backup. There is no need to transmit the setting data, and the setting data of each network component device can be restored from the setting history of the setting data.

The host control and monitoring device 38 manages whether the data in the RAM 42 of the transmission device 31 is backed up in the backup memory 43 of the transmission device 31 itself or in the backup memory 44 of the transmission device 32 opposite thereto. , A failure occurs in the transmission device 31,
Upon recovery from the failure, the transmission device 31 is restored and started up.

FIG. 11 shows a restoration processing sequence by the backup memory of the own transmission device, which is executed by the higher-level control monitoring device 38. This process is executed by a manual instruction from a maintenance person. In FIG.
8 confirms to the transmission device 31 whether the data link by the LAN 40 is normal or abnormal, and obtains a response from the transmission device 31.

Thereafter, in step S40, whether the data link is normal or abnormal is checked based on the response. If the data link is abnormal, the data link alarm is notified to the maintenance person in step S42, and the process is terminated. If the transmission is normal, a command for a backup restoration request is transmitted to the transmission device 31 to instruct the transmission device 31 to transfer the backup data from the backup memory 43 of the transmission device 31 to the RAM 42, and a response from the transmission device 31 is obtained. Then, in step S44, it is determined from the SUM value whether the backup has been completed normally or abnormally.

If the backup has been abnormally terminated, the flow advances to step S46 to notify an alarm of a backup restoration abnormality in the transmission device 31 to a maintenance person. If the backup has been completed normally, the maintenance person is notified in step S48 that the backup restoration is normal. After this,
State maintenance personnel for storing data as shown in FIG. 8 remaining in the hard disk device 41 _1, when whether the time specified to select up to any point in time, the upper control monitoring device 38 corresponding to each stored data selected A setting request command is transmitted to the transmission device 31 through the LAN 40. If the above time designation is not performed, the hard disk drive 41
All stored data remaining in ₁ are selected.

Thus, the data is set in the RAM 42 of the transmission device 31 after the backup. Then, a completion notification is sent from the transmission device 31 to the higher-level control monitoring device 38. The host control monitoring device 38 determines in step S50 whether the backup restoration has been completed normally or abnormally from the above completion notification, and only when the backup restoration in the transmission device 31 has been abnormally terminated, the transmission device 31 in step S52. Notify the maintenance person of the backup restoration error alarm and terminate the process.

FIG. 12 shows a restoration processing sequence by the backup memory of the opposite transmission device, which is executed by the higher-level control monitoring device 38. This process is executed by a manual instruction from a maintenance person. In the figure, the host control monitoring device 38 confirms whether the data link by the LAN 40 is normal or abnormal to the transmission device 32, and obtains a response from the transmission device 32.

Thereafter, in step S60, whether the data link is normal or abnormal is checked from the above response. If the data link is abnormal, in step S62, a data link abnormality alarm is notified to the maintenance person, and the process ends. If normal, a backup restoration request command instructing the opposite transmission device 32 to transfer backup data from the backup memory 44 of the transmission device 32 to the RAM 42 of the transmission device 31 is sent. Get a response. Then, in step S64, it is determined from the SUM value whether the backup has been completed normally or abnormally.

If the backup is abnormally terminated, the flow advances to step S66 to notify the maintenance person of the backup restoration abnormality alarm in the transmission device 31. If the backup has been completed normally, the maintenance person is notified in step S68 that the backup restoration is normal. Thereafter, the maintenance person stored data as shown in FIG. 8 remaining in the hard disk device 41 _1, when the specified whether to select the time up to which point the upper control monitoring device 38 are each stored data selected A corresponding status setting request command is transmitted to the transmission device 31 via the LAN 40. If the above time is not specified, the hard disk device 41 ₁
Is selected.

Thus, the data is set in the RAM 42 of the transmission device 31 after the backup. Then, a completion notification is sent from the transmission device 31 to the higher-level control monitoring device 38. The host control monitoring device 38 determines in step S70 whether the backup restoration has been completed normally or abnormally based on the completion notification, and only when the backup restoration in the transmission device 31 has been terminated abnormally, the transmission device 31 in step S72. Notify the maintenance person of the backup restoration error alarm and terminate the process.

As described above, the transmission devices 31 and 32 facing each other
After restoring the configuration data that has been backed up from the server, the configuration data is set based on the configuration history and the backup is restored. Even if settings are made from the device, complete restoration including the settings is possible.

By the way, in the above embodiment, the own transmission device 3
Although the setting data of the first RAM 42 is directly backed up in the backup memory 43 of the own transmission device 31 and the backup memory 44 of the transmission device 32 opposite thereto, the configuration may be such that the data is compressed at the time of backup and decompressed at the time of backup restoration. However, in order to quickly restore the backup, it is better to back up the setting data as it is, as in this embodiment.

Note that the backup memories 44 and 45 correspond to backup storage means, and the hard disk drive 41
_{1-41 5} corresponds to the setting history holding means.

[0044]

As described above, each of the plurality of network components has the backup storage means for holding the setting data of the network components connected to the own network component by the transmission line and facing each other. As described above, since the setting data of the own network component device is stored in the backup storage unit of the opposing network component device, the setting data can be set even when there is an abnormality in the hardware such as the backup memory of the own network component device and its access circuit. Data can be backed up.

According to a second aspect of the present invention, a higher-level control / monitoring device that controls and monitors a network includes a setting history holding unit that holds a setting history of setting data for each of the plurality of network components. . In this way, since the setting history of the setting data for each of the plurality of network components is held in the higher-level control monitoring device, there is no need to transmit the setting data for backup from each network component to the higher-level control monitoring device, The setting data of each network component device can be restored from the setting history of the setting data.

According to a third aspect of the present invention, the transmission of the setting data between the own network constituting device and the network constituting devices connected to each other via the transmission path is performed by using a predetermined bit of a header portion of a transmission frame. Do. As described above, the transmission of the setting data between the network components is performed by using the predetermined bits of the header portion of the transmission frame.
Backup can be performed without affecting normal data transmission between network components.

[0047] In the invention according to claim 4, the higher-level control / monitoring device, when the holding amount of the setting history of the setting data for each of the plurality of network constituent devices exceeds a predetermined threshold value, sets the corresponding network. The configuration device holds the setting data and deletes the setting history of the corresponding setting data. As described above, when the holding amount of the setting history of the setting data for each of the plurality of network constituent devices exceeds a predetermined threshold, the corresponding network constituent device holds the setting data, and the setting history of the corresponding setting data. Is deleted, it is possible to limit the holding amount of the setting history of the setting data in the host control monitoring device.

In the invention according to claim 5, the setting history holding means holds the address and time information in each network component device together with the setting data.
As described above, by holding the setting data together with the address in each network component device and the time information,
It is possible to restore the backup up to the time specified.

According to a sixth aspect of the present invention, after the setting data held in the backup storage unit of the opposing network constituent device is transmitted and restored to the own network constituent device, the setting data is held in the setting history holding unit. Based on the setting history of the setting data that has been set, the higher-level control / monitoring device sets the setting data in the network device itself and performs backup restoration.

As described above, after restoring the setting data backed up from the opposing network component,
Since the backup is restored by setting the setting data based on the setting history, even if the setting is made from the higher-level control monitoring device until the next backup after the backup to the opposite network component, the setting is also included. Complete restoration is possible.

[Brief description of the drawings]

FIG. 1 is a block diagram of an example of a conventional network system.

FIG. 2 is a block diagram for explaining a backup function of each conventional transmission device.

FIG. 3 is a block diagram of an embodiment of a network system according to the present invention.

FIG. 4 is a block diagram for explaining a backup function of each transmission device of the present invention.

FIG. 5 is a block diagram for explaining a backup function of each transmission device and repeater of the present invention.

FIG. 6 is a diagram showing a format of an SDH transmission frame.

FIG. 7 is a diagram showing a backup processing sequence executed by the higher-level control monitoring device 38 of the present invention.

FIG. 8 is a diagram for explaining setting data stored in a hard disk device.

FIG. 9 is a diagram for explaining a threshold for a memory capacity of a hard disk device.

FIG. 10 is a diagram for explaining a threshold for a memory capacity of a hard disk device.

FIG. 11 is a diagram showing a backup restoration processing sequence executed by the host control monitoring device 38 of the present invention.

FIG. 12 is a diagram showing a backup restoration processing sequence executed by the host control monitoring device 38 of the present invention.

[Explanation of symbols]

31 to 35 transmission device 36 transmission line 38 host control monitoring device (OPS) 40 LAN (local area network) 41 CPU 42 RAM 43, 44, 45 backup memory (BUM) 41 _{1 to} 41 ₅ hard disk device (HD)

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁶ Identification symbol FI H04L 29/14 (72) Inventor Norio Iijima 3-1-1 Hirooka, Kanazawa-shi, Ishikawa Prefecture Inside Fujitsu Hokuriku Communication System Co., Ltd. (72) Inventor Kaoru Kanaya 3-1-1 Hirooka, Kanazawa-shi, Ishikawa Prefecture Inside Fujitsu Hokuriku Communication System Co., Ltd. (72) Inventor Tomozumi Saigo 3-1-1 Hirooka, Kanazawa-shi, Ishikawa Prefecture Inside Fujitsu Hokuriku Communication System Co., Ltd.

Claims (6)

[Claims] 1. A network system in which a plurality of network components are connected by a transmission line, wherein each of the plurality of network components is connected to its own network component by the transmission line and faces each other. A network system having backup storage means for storing the setting data of (1). 2. The network system according to claim 1, wherein a higher-level control monitoring device that controls and monitors the network includes a setting history holding unit that holds a setting history of setting data for each of the plurality of network components. A network system comprising: 3. The network system according to claim 1, wherein the transmission of the setting data between the own network configuration device and the network configuration device connected by the transmission path and facing each other is performed by a predetermined bit of a header portion of a transmission frame. A network system characterized in that the network system is performed using: 4. The network system according to claim 3, wherein the higher-level control monitoring device responds when an amount of setting history of setting data of each of the plurality of network components exceeds a predetermined threshold. A network system in which a network configuration device stores the setting data and deletes a setting history of the corresponding setting data. 5. The network system according to claim 2, wherein the setting history holding unit holds an address in each network component device and time information together with the setting data. 6. The network system according to claim 2, wherein the setting data stored in the backup storage unit of the opposing network configuration device is transmitted and restored to the own network configuration device. A network system, wherein setting data is set in said own network component device from said higher-level control monitoring device based on a setting history of setting data held in a setting history holding means, and backup restoration is performed.