JP2006197123A - Atm device monitoring system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ATM device monitoring system capable of surely detecting the occurrence of abnormality in an ATM device or the like and having high reliability. <P>SOLUTION: A status transmitting means 109 inserts the device status data of its own ATM device into an idle cell, and transmits it. A cell classification detector 101 of a device status storing means 108 transmits the device status data of another ATM device included in the idle cell to a monitor information storing part 102 at the time of detecting that a main signal cell is an idle cell. The monitor information storing part 102 stores the device status data as data for monitor. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an ATM device monitoring system for monitoring the state of an ATM communication device having an ATM (Asynchronous Transfer Mode) interface.

  Conventionally, as a system for monitoring the state of an ATM device, a cell processing device such as a control cell or an idle cell in an ATM cell is used to detect a failure in the cell processing device. (For example, see Patent Document 1). This device overwrites a cell that is not processed by the cell processing device with a monitoring cell having a combination of VPI (Virtual Path Identifier) and VCI (Virtual Channel Identifier) that is not used in the cell processing device. Applied in the previous stage of a certain arithmetic circuit and transferred in the arithmetic circuit, the monitoring information signal CHK representing the operation state of the arithmetic circuit obtained as a result is compared and collated with the expected value E. A circuit failure is detected.

JP 09-214511 A

  However, although the above conventional ATM device monitoring system is composed of an arithmetic circuit and a CHK circuit and performs comparison and collation, there is no provision to notify the result, and the monitoring control function (failure detection → notification) itself is faulty at the time of failure. In such a case, there is a problem that failure detection is delayed or data for identifying the cause of failure cannot be extracted.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to obtain a highly reliable ATM device monitoring system that can reliably detect an abnormality in an ATM device.

  When the ATM device monitoring system according to the present invention receives an idle cell and status sending means for sending the device status data of the own ATM device in an idle cell to the ATM device that performs data transmission using the ATM cell, Device state storage means for storing device state data of other ATM devices included in the idle cell is provided.

  Since the ATM device monitoring system of the present invention uses idle cells to share device status data among each ATM device, it can reliably detect the occurrence of an abnormality in the ATM device and is highly reliable. An ATM device monitoring system can be obtained.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing the main part of an ATM device monitoring system according to Embodiment 1 of the present invention. Prior to this description, the overall configuration will be described.
FIG. 3 is an explanatory diagram showing the overall configuration and operation of the ATM device monitoring system of the present embodiment. The overall configuration of the system will be described first with the aid of this.
As shown in FIG. 3, the ATM device monitoring system includes ATM devices 100 a to 100 c and a monitoring unit 200. In the illustrated example, there are three ATM devices 100a to 100c, but the number is not limited to this.

  The ATM devices 100a to 100c and the monitoring unit 200 are connected to each other for communication. Each of the ATM devices 100a to 100c is a device that transmits a known ATM cell. In the present embodiment, the ATM devices 100a to 100c are configured to notify all other ATM devices of the device status data of the own device. The device A data, the device B data, and the device C data indicate device status data of the ATM devices 100a to 100c, respectively. The monitoring control unit 104 is a control unit for sending device status data of its own device and device status data of another device to the monitoring unit 200. These configurations will be described later in detail. Furthermore, the monitoring unit 200 is a device that monitors each of the ATM devices 100a to 100c based on the device status data from the monitoring control unit 104 of each of the ATM devices 100a to 100c.

FIG. 1 shows an internal configuration of each of the ATM devices 100a to 100c.
As illustrated, the ATM devices 100a to 100c include a cell type detector 101, a monitoring information storage unit 102, a detected bit inversion unit 103, a monitoring control unit 104, an own device monitoring information unit 105, an idle cell detection unit 106, a monitoring An information application unit 107 is provided. In addition, when the cell type detector 101 and the monitoring information storage unit 102 receive an idle cell, the device type storage unit 108 that stores device state data of other devices included in the idle cell is configured to monitor the own device. The information section 105 to the monitoring information applying section 107 constitute a state sending means 109 for sending the apparatus state data of the own apparatus in an idle cell and sending it. Further, the cell type detector 101 to the own device monitoring information unit 105 are configured on the receiving side 110, and the own device monitoring information unit 105 to the monitoring information applying unit 107 are configured on the transmitting side 111. The own device monitoring information unit 105 has a configuration common to both the reception side 110 and the transmission side 111.

  The cell type detector 101 detects whether or not the cell is an idle cell based on the ATM header of the ATM cell. If the cell type detector 101 is an idle cell, the cell type detector 101 extracts the monitoring information and transmits the monitoring information to the monitoring information storage unit 102. Have. At this time, the cell type detector 101 has a function of sending a storage instruction signal to the monitoring information storage unit 102 and the detected bit inversion unit 103. The monitoring information storage unit 102 is a functional unit that stores monitoring information based on a storage instruction signal from the cell type detector 101. That is, the device status data of other devices is stored. The detected bit inversion unit 103 is a functional unit that detects a detected bit from the monitoring information cell based on the storage instruction signal from the cell type detector 101 (= 0) and sends it as a main signal cell. The monitoring control unit 104 is a control unit that periodically transmits the device status data of the own device to the monitoring unit 200 and notifies the abnormality when the abnormality occurs in the own device.

  The own device monitoring information unit 105 is a functional unit for storing the monitoring information of the own device. When the output instruction signal from the idle cell detection unit 106 is input, the own device monitoring information unit 105 and the monitoring information applying unit 107 Has a function of outputting device status data as monitoring information. The idle cell detection unit 106 has a function of detecting an idle cell from the received main signal cell and sending an output instruction signal to the own device monitoring information unit 105 and the monitoring information application unit 107. When the monitoring information application unit 107 receives the output instruction signal from the idle cell detection unit 106, the monitoring information application unit 107 stores the device state data of the own device sent from the own device monitoring information unit 105 in the idle cell and transmits it as the main signal cell. It has a function to do.

Next, the operation of the ATM device monitoring system configured as described above will be described.
FIG. 2 is an explanatory diagram showing the format of the ATM cell.
As shown, the ATM cell 10 is a 53-byte cell comprising a 5-byte ATM header 11 and a 48-byte information field 12. The information field includes a monitoring information cell ID 12a, a device ID 12b, a detected bit 12c, and monitoring information 12d. The ATM header 11 includes information indicating the type of ATM cell such as an idle cell. Further, the monitoring information cell ID 12a in the information field 12 is information indicating whether or not the information is monitoring information, and the device ID 12b is an ID for identifying which ATM device 100a to 100c is the device state data. Further, the detected bit 12c is a bit indicating whether or not it has been detected, and is set to a value such as “0” if it has been detected and “1” if it has not been detected. The monitoring information 12d is an area including device status data for each monitoring item of the ATM device. Note that the number of monitoring items is appropriately determined according to the operating conditions and the like. The time information is also subject to the monitoring information 12d.

Next, the operation of the receiving side 110 in each of the ATM devices 100a to 100c will be described.
When the receiving side 110 receives an ATM cell as shown in FIG. 2, the cell type detector 101 determines that the ATM cell 10 is an idle cell (determined by the value of the ATM header 11).
The monitoring information cell ID 12a is a specified value (a value indicating a predetermined monitoring information cell). It is determined whether the cell satisfies all of the detected bits 12c = “1” (not detected). To do. If so, the cell type detector 101 sends the monitoring information 12d of the information field 12 of the ATM cell 10 to the monitoring information storage unit 102, and also inverts the storage instruction signal from the monitoring information storage unit 102 and the detected bit inversion. Output to the unit 103.

  When the monitoring information storage unit 102 receives the monitoring information 12d and the storage instruction signal from the cell type detector 101, the monitoring information storage unit 102 stores the monitoring information 12d in a storage area corresponding to the device ID provided in advance. Further, the detected bit inversion unit 103 inverts the value of the detected bit 12c of the ATM cell 10 from “1” to “0” based on the storage instruction signal from the cell type detector 101 to change the main signal cell. Send it out.

Next, the operation of the transmission side 111 will be described.
When the idle cell detection unit 106 on the transmission side 111 detects that the main signal cell is an idle cell based on the value of the ATM header 11, an output instruction is given to the own device monitoring information unit 105 and the monitoring information application unit 107. Send a signal. When receiving the output instruction signal, the own device monitoring information unit 105 outputs monitoring information of the own device such as a memory state to the monitoring control unit 104 and the monitoring information applying unit 107, for example. The monitoring information application unit 107 captures the monitoring information from the own device monitoring information unit 105 at the timing of the output instruction signal from the idle cell detection unit 106, and the monitoring information cell ID 12a, device ID 12b, The detected bit 12c = “1” and the monitoring information 12d are written and sent as a main signal cell to other devices (ATM devices 100a to 100c other than the own device storing the monitoring information) and subsequent devices.

By such processing, as shown in FIG. 3, the device A data 20a, the device B data 20b, and the device C data 20c are stored in each of the ATM devices 100a to 100c.
Further, the monitoring control unit 104 periodically outputs the device status data from the own device monitoring information unit 105 to the monitoring unit 200 as monitoring information.

Next, an operation when an abnormality occurs in any of the ATM devices 100a to 100c will be described.
The monitoring control unit 104 performs abnormality monitoring based on the monitoring information of the own device sent from the own device monitoring information unit 105.
FIG. 4 is an explanatory diagram of abnormality determination.
As shown in the figure, the monitoring information 12d has a plurality of monitoring items. These monitoring items are items indicating the presence or absence of abnormality such as memory abnormality, main signal abnormality or clock abnormality. The bit values of these items are set to, for example, “0” in the normal state and “1” in the case of an abnormality. The monitoring control unit 104 performs bit comparison for each monitoring item, recognizes that a monitoring item changed from “0” to “1” is abnormal, and notifies the monitoring unit 200 of it. For example, in the state shown in FIG. 4, when the state (a) (no abnormality) is changed to the state (b), the monitoring item m and the monitoring item n are recognized as abnormal as shown in (b). This is notified to the monitoring unit 200.

Further, when an abnormality occurs in the monitoring control unit 104 of any of the ATM devices 100a to 100c and the apparatus state data and abnormality occurrence information cannot be notified to the monitoring unit 200, the operation is performed as follows.
Now, as shown in FIG. 3, it is assumed that an abnormality has occurred in the monitoring control unit 104 of the ATM device 100b and data cannot be transmitted to the monitoring unit 200. Since the monitoring unit 200 cannot receive the device status data from the ATM device 100b, the monitoring unit 200 makes an acquisition request for the device status data of the ATM device 100b to the other ATM devices 100a and 100c. Thereby, the monitoring control unit 104 of the ATM device 100 a and the ATM device 100 c transmits the device B data stored in the monitoring information storage unit 102 to the monitoring unit 200. Here, the device B data transmitted from the monitoring control unit 104 of each ATM device 100a, 100c is a device ID 12b and monitoring information 12d.

  The monitoring unit 200 that has received the device B data from the ATM devices 100a and 100c determines whether an abnormality has occurred by bit comparison for each monitoring item. If there is no bit indicating abnormality in each monitoring item in the apparatus B data of both apparatuses, it is determined that only the monitoring control unit 104 is abnormal. On the other hand, if the device B data is in the state shown in FIG. 4B and the data of both devices match, it is determined that an abnormality has occurred in the monitoring items m and n. .

  As described above, according to the ATM device monitoring system of the first embodiment, status transmission is provided in an ATM device that performs data transmission using an ATM cell, and transmits device status data of the own ATM device in an idle cell. Means and device state storage means for storing device state data of other ATM devices included in the idle cell when an idle cell is received, since each ATM device can share the same device state data, It is possible to reliably detect the occurrence of an abnormality in the ATM device and obtain a highly reliable ATM device monitoring system.

  In addition, in this embodiment, since the device state data is transmitted using the idle cell, the idle cell is not processed as data, so that even if it is transmitted to a device that does not have the configuration of the present embodiment, it is affected. There is an effect of not giving. Also, in ATM communication devices, since there are generally few states in which valid cells are transmitted over the entire band, it is possible to secure a certain amount of idle cell transmission, and therefore transmission of device status data in each device is reliable. Can be done.

  In addition, according to the ATM device monitoring system of the first embodiment, when device state data of another ATM device is stored, the device state is provided with a detected bit inversion unit for adding detected information to an idle cell. The storage means stores the device state data of another ATM device when the detected information is not included in the idle cell, and therefore receives the idle cell from a device that does not have the configuration of the present embodiment. However, it is possible to prevent unnecessary information from being stored, and to transmit such an idle cell to a device that does not have the configuration of the present embodiment has no effect on the device.

  In addition, according to the ATM device monitoring system of the first embodiment, since the device controller includes a monitoring control unit that sends device state data of other ATM devices stored in the device state storage unit to a monitoring unit that monitors the ATM device. The monitoring unit has an effect that device status data other than the ATM device can be acquired from each ATM device.

  In addition, according to the ATM device monitoring system of the first embodiment, when the monitoring unit cannot receive the device status data from any ATM device, the monitoring status is based on the device status data from another ATM device. Since the status of the ATM device that could not receive the data is recognized, the monitoring unit can acquire the device status data of the ATM device even if the device status data cannot be acquired from a certain ATM device for some reason. Therefore, there is an effect that the reliability as the ATM device monitoring system can be improved.

  In addition, according to the ATM device monitoring system of the first embodiment, when the monitoring unit matches the abnormal part included in the device status data of the ATM device that is acquired from a plurality of ATM devices and the device status data cannot be received. Since the matched abnormal part is identified as the abnormal part of the ATM device in which the device status data could not be received, the abnormal part of the ATM device in which the abnormality occurred can be reliably identified, and the ATM device monitoring system The reliability can be further improved.

Embodiment 2. FIG.
In the second embodiment, load monitoring control of each of the ATM devices 100a to 100c is performed.

FIG. 5 is an explanatory diagram showing an ATM device monitoring system according to the second embodiment.
In the figure, the internal configuration of each of the ATM devices 100a to 100c is the same as that of the first embodiment. That is, each of the ATM devices 100a to 100c has the same configuration as that shown in FIG. The monitoring unit 200 includes a load monitoring control unit 201. When there is an ATM device 100a to 100c having a load greater than or equal to a predetermined value among the plurality of ATM devices 100a to 100c, the load monitoring control unit 201 acquires device status data of the ATM device from another ATM device. It has the function to do.

Next, the operation of the second embodiment configured as described above will be described.
The load monitoring control unit 201 of the monitoring unit 200 periodically monitors the load status of each ATM device 100a to 100c. That is, it is monitored whether there are ATM devices 100a to 100c whose loads exceed a predetermined threshold. When there is an ATM device 100a to 100c whose load exceeds a threshold value (this is referred to as an ATM device 100b), the load monitoring control unit 201 selects one of the ATM devices other than the ATM device 100b (this is the ATM device 100b). , The ATM device 100a) is requested to obtain the device status data of the ATM device 100b. Thereby, the monitoring control unit 104 of the ATM device 100 a transmits the device B data stored in the monitoring information storage unit 102 to the monitoring unit 200. The device B data transmitted from the ATM device 100a is data including a device ID and monitoring information, as in the case of the first embodiment.

With the above operation, even when the load is concentrated on the ATM device 100b, the ATM device 100b can omit the process of notifying the monitoring unit 200 of the device status data of the own device, and as a result, the load can be reduced. .
In the second embodiment, the ATM device that acquires the device state data instead of the ATM device whose load exceeds the threshold value is any ATM device other than the ATM device whose load exceeds the threshold value. The ATM device having the lightest load among the ATM devices may be selected, or the priority order of data acquisition may be given in advance.

  As described above, according to the ATM device monitoring system of the second embodiment, when there is an ATM device having a load of a predetermined value or more among a plurality of ATM devices, the device status data of the ATM device is The load monitoring control means for acquiring from the ATM device is provided, so even if the load is concentrated on any one of the plurality of ATM devices, the load on the ATM device can be reduced, and the plurality of ATM devices can be reduced. It is possible to achieve load distribution in a system composed of devices.

  In each of the above-described embodiments, the case where there are three ATM devices 100a to 100c has been described. However, the present invention is not limited to this, and can be similarly applied to a system including a plurality of ATM devices. .

It is a block diagram which shows the principal part of the ATM apparatus monitoring system by Embodiment 1 of this invention. It is explanatory drawing which shows the format of the ATM cell in the ATM apparatus monitoring system by Embodiment 1 of this invention. It is explanatory drawing which shows the whole structure and operation | movement of the ATM apparatus monitoring system by Embodiment 1 of this invention. It is explanatory drawing of abnormality determination of the ATM apparatus monitoring system by Embodiment 1 of this invention. It is explanatory drawing which shows the ATM apparatus monitoring system by Embodiment 2 of this invention.

Explanation of symbols

  10 ATM cell, 12a monitoring information cell ID, 12b device ID, 12c detected bit, 12d monitoring information, 20a device A data, 20b device B data, 20c device C data, 100a to 100c ATM device, 103 detected bit reversing unit , 104 Monitoring control unit, 108 Device state storing means, 109 Status sending means.

Claims (6)

It is provided in an ATM device that performs data transmission using ATM cells,
Status sending means for sending device status data of the own ATM device in an idle cell;
An ATM device monitoring system comprising device state storage means for storing device state data of another ATM device included in the idle cell when the idle cell is received. When the device status data of another ATM device is stored, the detected bit inversion unit for adding the detected information to the idle cell is provided.
2. The ATM apparatus monitoring system according to claim 1, wherein the apparatus state storing means stores apparatus state data of another ATM apparatus when the detected information is not included in the idle cell.   3. An ATM device monitor according to claim 1, further comprising a monitoring control unit for sending device status data of another ATM device stored in the device status storage means to a monitoring unit for monitoring the ATM device. system.   The monitoring unit recognizes the state of the ATM device that could not receive the device state data based on the device state data from another ATM device when the device state data could not be received from any ATM device. The ATM device monitoring system according to claim 3.   When the abnormal part included in the apparatus status data of the ATM apparatus acquired from a plurality of ATM apparatuses and the apparatus state data cannot be received is matched, the monitoring unit cannot receive the matched abnormal part. 5. The ATM device monitoring system according to claim 4, wherein the ATM device is identified as an abnormal portion.   When there is an ATM device having a load greater than or equal to a predetermined value among a plurality of ATM devices, load monitoring control means for acquiring device status data of the ATM device from another ATM device is provided. The ATM device monitoring system according to any one of claims 1 to 5.

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