JP2004072271A - Apparatus management system and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus management system and method for suppressing congestion in traffic required for apparatus management and reducing a time required to acquire management information. <P>SOLUTION: The method allows a management apparatus to separately manage operating states of one or a plurality of apparatuses to be managed, sets in advance an operating identification code denoting each operating state to the operating states of a plurality of kinds with respect to the apparatus to be managed, the operating identification codes are set so that the operating identification codes being elements of a composite code can be classified when the operating identification codes are subjected to composite coding according to a prescribed computing equation, and the management apparatus grasps the operating state of each kind with respect to the apparatus to be managed by acquiring the composite code from the apparatus to be managed. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a device management system and method.
[0002]
[Prior art]
For example, in the management of a communication network, the management device grasps the operation state of the managed device by communicating with the managed device (communication device) using SNMP (Simple Network Management Protocol). The managed device sequentially detects its own operation state and registers it as management information in a MIB (Management Information Base). Upon receiving a transmission request of the operation state from the management device, the managed device manages the management information registered in the MIB. Send to device.
[0003]
A frame provided between the wide area LAN (Local Area Network) and the dedicated communication line when the wide area LAN (Local Area Network) and the user LAN (Local Area Network) are interconnected by the dedicated communication line. The conversion device is configured to register a plurality of types of management information (that is, operation states) in the MIB and transmit an operation state corresponding to the request to the management device in response to a request from the management device. Further, such a frame conversion device is composed of a plurality of line boards provided for each line and a management board for collectively managing the respective line boards, and a storage device in the management board stores each of the line boards. Is set to collectively register the management information of the management information. That is, the management board sequentially acquires a plurality of types of information (operation state information) on the operation state from each line board, and registers the information in the MIB for each line board.
[0004]
[Problems to be solved by the invention]
By the way, the management device performs a polling process based on SNMP when acquiring various kinds of operation state information on each line board from the frame conversion device (more precisely, the management board). That is, the management device transmits an acquisition request specifying a specific line board and a specific type of operation state information to the frame conversion device, and transmits a specific line board and a specific type of operation state information as a response to the acquisition request. get. Therefore, in order to obtain all types of operation state information for all the line boards, the management device must perform polling processing the number of times that the number of line boards is multiplied by the number of types of operation state information, There is a problem that traffic between the management device and the frame conversion device is congested, and it takes time to acquire operation state information.
[0005]
The present invention has been made in view of the above problems, and has as its object to suppress traffic congestion required for device management and to shorten the time required for acquiring management information.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, according to the present invention, as a first means related to a device management method, a management device (9) separately manages an operation state of one or a plurality of managed devices (5). In addition, for a plurality of types of operation states related to the managed device (5), an operation identification code indicating each operation state is set in advance, and the operation identification code is synthesized and encoded by a predetermined arithmetic expression. The operation identification code, which is an element of the composite code, is set so as to be separable, and the management device (9) obtains the composite code from the managed device (5) to thereby control the managed device (5). A configuration is adopted in which each type of operation state is grasped.
[0007]
Also, as a second means relating to the device management method, in the first means, the managed device (5) is composed of a plurality of functional units (C1 to Cn) having a plurality of types of operation states. Is a unit identification set to identify each of the functional units (C1 to Cn) and to be able to discriminate a unit identification code which is an element of the composite code when the composite code is performed by a predetermined arithmetic expression. The code is set in advance, and the management device (9) obtains the composite code composed of the unit identification code from the managed device (5) before acquiring the composite code composed of the operation identification code, so that the functional unit in the abnormal operation state is obtained. (C1 to Cn), and by acquiring a composite code including an operation identification code from the functional unit (C1 to Cn) in the abnormal operation state, the operation state of each type can be changed. To adopt a configuration that grip.
[0008]
As a third means relating to the device management method, in the second means, the unit identification code is set to 2 for each of the n functional units (C1 to Cn) provided in the managed device (5). ^(N-1) And the arithmetic expression is an addition expression for adding the numerical value.
[0009]
As a fourth means relating to the device management method, in any one of the first to third means, the operation identification code is set to 2 for m kinds of operation states. ^(M-1) And the arithmetic expression is an addition expression for adding the numerical value.
[0010]
As a fifth means relating to the device management method, in any one of the above first to fourth means, the managed device (5) stores management information registered in a MIB (Management Information Base) in an SNMP (Simple Network Management Protocol). Is adopted as a communication device for transmitting to the management device (9) by using the communication device.
[0011]
As a sixth means relating to the device management method, in the fifth means, the communication device interconnects a wide area LAN (Local Area Network) of a communication carrier and a user LAN (Local Area Network) by a dedicated communication line. In such a case, a configuration is adopted in which a frame conversion device is provided between a wide area LAN (Local Area Network) and a dedicated communication line.
[0012]
On the other hand, in the present invention, as a first means related to the device management system, a management device (9) separately manages the operation state of one or a plurality of managed devices (5). ) Indicates a plurality of types of operation states, and stores in advance an operation identification code that is set so that the operation identification code, which is an element of the composite code, can be discriminated when the encoding is performed by a predetermined arithmetic expression. When an operation state transmission request is input from the management device (9), the composite code is output to the management device (9), and the management device (9) acquires the composite code from the managed device (5). By doing so, a configuration of grasping each type of operation state regarding the managed device (5) is adopted.
[0013]
Further, as a second means relating to the device management system, in the first means, the managed device (5) is composed of a plurality of functional units (C1 to Cn) having a plurality of types of operation states, and A unit identification code, which is set so that the unit identification code, which is an element of the composite code, when it is composite-encoded by an arithmetic expression, is also stored in advance, and the functional unit (C1 to Cn) is transmitted from the management device (9). When a transmission request for the operation state for each operation is input, the composite code composed of the unit identification code is output to the management device (9), and the management device (9) outputs the composite code composed of the operation identification code before acquiring the composite code composed of the operation identification code. By acquiring the composite code composed of the unit identification code from the managed device (5), the functional unit (C1 to Cn) in the abnormal operation state is grasped, and the functional unit in the abnormal operation state is obtained. A construction is adopted to determine the operating status of each type by a composite code consisting operation identification code related (C1 to Cn) acquired from the managed device (5).
[0014]
As a third means relating to the device management system, in the second means, the unit identification code is set to 2 for each of the functional units (C1 to Cn) provided in the managed device (5). ^(N-1) And the arithmetic expression is an addition expression for adding the numerical value.
[0015]
As a fourth means relating to the device management system, in the above first to third means, the operation identification code is set to 2 for m kinds of operation states. ^(M-1) And the arithmetic expression is an addition expression for adding the numerical value.
[0016]
As a fifth means relating to the device management system, in the first to fourth means, the managed device (5) uses SNMP (Simple Network Management Protocol) for management information registered in MIB (Management Information Base). The communication device transmits the data to the management device (9).
[0017]
As a sixth means relating to the device management system, in the fifth means, the communication device interconnects a wide area LAN (Local Area Network) of a communication carrier and a user LAN (Local Area Network) with a dedicated communication line. In this case, a configuration is adopted in which a frame conversion device is provided between a wide area LAN (Local Area Network) and a dedicated communication line.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of a device management system and method according to the present invention will be described with reference to the drawings.
[0019]
FIG. 1 is a system configuration diagram of a device management system according to the present embodiment. In this figure, reference numeral 1 denotes a user LAN, 2 and 6 denote routers, 3 and 5 denote frame converters, 4 denotes an HSD (High Super Digital) network, 7 denotes a carrier wide area LAN, 8 denotes a management LAN, and 9 denotes a management LAN. It is a management device. Among these components, the device management system A includes a frame converter 5 (managed device), a management LAN 8, and a management device 9.
[0020]
The user LAN 1 is a local area network operated by a general user such as a company, and is connected to the frame converter 3 via the router 2. The router 2 has a known routing function, and relays TCP / IP-based communication between the user LAN 1 and the frame converter 3. The frame converter 3 converts a LAN frame and an HSD frame into each other, converts a LAN frame input from the user LAN 1 through the router 2 into an HSD frame, and sends the HSD frame to the HSD network 4. The HSD frame input from the network 4 is converted into a LAN frame and transmitted to the router 2.
[0021]
The HSD network 4 is a form of a dedicated line network that realizes a line speed of up to 6 Mbps by using a frame multiplexing technology with a basic line speed of 64 kbps of the ISDN network, as is well known. In the HSD network 4, communication is performed by transmitting and receiving an HSD frame defined exclusively. The frame converter 5 is interposed between the HSD network 4 and the carrier wide area LAN 7 (more precisely, the router 6), and converts between a LAN frame and an HSD frame. The frame converter 5 converts the HSD frame input from the HSD network 4 into a LAN frame and sends the LAN frame to the router 6, and converts the LAN frame input from the carrier wide area LAN 7 through the router 6 into an HSD frame. And sends it to the HSD network 4.
[0022]
As shown in FIG. 2, the frame converter 5, which is a managed device, includes one management board M and a plurality of (n) line boards C1 to Cn (functional units). The line boards C1 to Cn are provided for each line between the carrier wide area LAN 7 and the HSD network 4, and perform mutual frame conversion between a LAN frame and an HSD frame on each line.
[0023]
The management board M includes a storage unit m1, a MIB (Management Information Base) m2, an arithmetic control unit m3, and a communication unit m4, and communicates with each of the line boards C1 to Cn via the communication unit m4. The operation state of C1 to Cn (that is, the communication state of each line handled by the line boards C1 to Cn) is acquired and registered as management information in the MIB m2 provided in the storage unit m1.
[0024]
In the case of the present embodiment, the management information includes the following four items related to alarms in order to facilitate understanding. That is, the management information includes “alarmLineRecState” indicating the input disconnection and the out-of-synchronization state of the HSD frame, “alarmLineAisState” indicating the detection of the all (all) 1 signal in the HSD frame, “AlarmLineErrorMortState” indicating detection, and “alarmLineErrorMonState” indicating detection of a bit error equal to or less than the threshold value of the HSD frame. Here, in the management information of the above four items, “1” is set as a value when indicating the occurrence of an alarm, and “0” is set as a value when indicating a normal state in which an alarm is not generated. Is done.
[0025]
The communication unit m4 of the management board M is configured to communicate with the management device 9 based on SNMP (Simple Network Management Protocol) defined as a management technology of the TCP / IP standard. In response to a management information acquisition request input from the management server 9, the operation state of each of the line boards C1 to Cn, that is, management information registered in the MIBm2 is transmitted to the management device 9.
[0026]
As shown in FIG. 3A, the management board M identifies each of the line boards C1 to Cn based on the board numbers # 1 to #n, communicates with each of the line boards C1 to Cn, and The management information of the line boards C1 to Cn is classified for each of the board numbers # 1 to #n and registered in the MIBm2. Then, the management board M separates the board numbers # 1 to #n from the identification numbers "1" and "2" of the line boards C1 to Cn used when providing the management information to the management device 9. , "4", ..., "2 ^(N-1) Is previously stored in the storage unit m1. Such identification values “1”, “2”, “4”,. ^(N-1) Is a unit identification code in the present embodiment.
[0027]
Further, as shown in FIG. 3B, the management board M also identifies the management information over the above four items with identification numbers “1”, “2”, “4” and “4” based on the same idea as the unit identification code. “8” is stored in the storage unit m1 in advance. That is, the identification number “1” is assigned to “almLineRecState”, the identification number “2” is assigned to “almLineAisState”, the identification number “4” is assigned to “almLineErrorMajState”, and the identification number “8” is assigned to “almLineErrorMonState”. Have been assigned. The identification numbers “1”, “2”, “4”, and “8” assigned to each piece of such management information are operation identification codes in the present embodiment.
[0028]
If m types of management information are registered in the MIBm2 for each of the line boards C1 to Cn, the identification numbers “1”, “2”, “4”,. "2 ^(M-1) Is assigned as the operation identification code. Such an operation identification code and a unit identification code are used when providing management information registered in MIBm2 to the management device 9, and are characteristic points of the device management system A.
[0029]
The router 6 has a well-known routing function like the router 2, and relays TCP / IP-based communication between the carrier wide area LAN 7 and the frame converter 5. The communication carrier wide area LAN 7 is provided for interconnecting the user LAN 1 and another user LAN different from the user LAN 1, and is operated by the communication carrier. The management LAN 8 is a local area network interconnecting the frame converter 5 and the management device 9 provided on the communication carrier wide area LAN 7 side, and is operated by the communication carrier.
[0030]
The management device 9 is a computer that remotely manages the operation state of the frame converter 5 as a managed device by performing communication based on the above-described SNMP with the frame converter 5 via the management LAN 8 and is operated by a communication carrier. Have been. Although not shown, other managed devices are also connected to the management LAN 8, and the management device 9 constantly monitors the operation states of a plurality of managed devices including the frame converter 5, and if the managed devices are abnormal, etc. Is issued, the operating status information such as the occurrence of the abnormality and the content of the abnormality is notified to the communication carrier.
[0031]
Next, the operation (management operation) of the device management system A thus configured will be described in detail with reference to the flowchart shown in FIG. This flowchart shows the operation of the management device 9.
[0032]
When ascertaining the operation state of the frame converter 5, the management device 9 first checks which of the line boards C1 to Cn (that is, which line) has issued the alarm. A request to acquire management information on Cn is transmitted to the frame converter 5 (more precisely, the management board M) (step S1). The communication unit m4 of the management board M receives such a management information acquisition request, and notifies the arithmetic control unit m3 of the received content. As a result, the arithmetic control unit m3 searches the management information of each of the line boards C1 to Cn registered in the MIB m2, and thereby obtains the composite code CDu indicating the alarm generation status of each of the line boards C1 to Cn as follows. The images are combined and transmitted to the management device 9 via the communication unit m4.
[0033]
That is, the arithmetic control unit m3 calculates the logical sum of the values set in “almLineRecState”, “almLineAisState”, “almLineErrorMajState”, and “almLineErrorMonState” for each of the n line boards C1 to Cn. The issuing line board (alarm generating line board) is specified, and all the unit identification codes of the alarm generating line board are added by an addition formula to generate a composite code CDu. Then, the composite code CDu is transmitted to the management device 9 as a response to the acquisition request of the management information regarding the line boards C1 to Cn. When all the line boards C1 to Cn do not issue an alarm, the arithmetic control unit m3 transmits “0” as a numerical value to the management device 9 as a composite code CDu.
[0034]
For example, when the line board C2 and the board C4 generate an alarm in any one of the above four items, the logical sum regarding the line boards C2 and C4 is “1”. The arithmetic control unit m3 adds the identification value "2" which is the unit identification code of the circuit board C2 whose logical sum is "1" and the identification value "8" which is the unit identification code of the circuit board C4. Calculates the numerical value “10” as the composite code CDu, and transmits it to the management device 9.
[0035]
When receiving such a composite code CDu from the management board M, the management device 9 determines whether or not the composite code CDu is “0” (Step S2). If the determination is "Yes", that is, if all the line boards C1 to Cn have not issued a warning, the process is terminated. If the determination is "No", a warning is issued based on the composite code CDu. (For example, the line board C2 and the board C4) (step S3).
[0036]
Here, the numerical value “10” as the composite code CDu indicates that the line boards C2 and C4 have issued an alarm, and does not indicate that other line boards have issued an alarm. Absent. In other words, the management device 9 indicates that the numerical value “10” as the composite code CDu indicates that one or a plurality of line boards are giving an alarm, and the unit identification code of the line board giving the alarm is Since the sum of all values is the numerical value “10”, the unit identification code that configures the numerical value “10” based on the addition formula is only a combination of “2” and “8”. Even if another unit identification code other than this is added, it cannot be "10".
[0037]
FIG. 5 is an explanatory diagram showing the properties of such a unit identification code. In the present embodiment, the identification numbers “1”, “2”, “4”,. ^(N-1) Is assigned. That is, the identification numbers “1”, “2”, “4”,. ^(N-1) ", As shown in the figure, only a specific digit in a binary number is" 1 ", and all digits other than the specific digit are" 0 ".
[0038]
For example, as for the identification value “1” assigned to the first line board C1, only the least significant digit of the binary number is “1”, and all other digits are “0”. As for the identification value "2" assigned to the second circuit board C2, only the second digit of the binary number is "1", and all other digits are "0". Further, the identification value “2” assigned to the n-th line board Cn ^(N-1) ", Only the n-th digit of the binary number is" 1 ", and all other digits are" 0 ".
[0039]
Therefore, each of the identification numbers “1”, “2”, “4”,. ^(N-1) Since the digits of "1" are all different, no carry occurs even if any value is added. That is, each identification value "1", "2", "4", ..., "2" ^(N-1) Is added based on the addition formula to generate the composite code CDu, the identification numerical value forming the composite code CDu is specified based on which digit value of the composite code CDu is “1”. be able to.
[0040]
For example, when a synthetic code CDu is generated by adding all three identification numbers “1”, “2”, and “4”, no carry occurs in all digits, and the least significant digit of the binary number, The values of the second and third digits are “1”, and the values of the other digits are all “0”. Therefore, it can be easily determined that such a composite code CDu is formed by adding all the identification values “1”, “2”, and “4”.
[0041]
The management device 9 uses the characteristics of the composite code CDu and the unit identification code that configures the composite code CDu based on the addition formula to generate a line board that issues an alarm, that is, the line board C2 and the board. Specify C4. Then, the management device 9 determines which of the four items of management information registered in the MIBm2 the alarm contents of the line board C2 and the board C4 correspond to, that is, the line that issues the alarm in order to confirm the alarm contents. A request for acquiring management information of the boards, that is, the line boards C2 and C4, is transmitted to the management board M (step S4).
[0042]
The communication unit m4 of the management board M, upon receiving such a management information acquisition request regarding the line board C2 and the board C4, notifies the arithmetic control unit m3 of the received content. Then, the arithmetic control unit m3 searches and acquires the management information of the line board C2 and the line board C4 registered in the MIB m2, and synthesizes the synthesis code CD2 indicating the alarm content of the line board C2 and the alarm content of the line board C4. The code CD4 is synthesized as follows, and transmitted to the management device 9 through the communication unit m4.
[0043]
That is, in the line board C2, for example, the value of "alarmLineRecState" indicating the input disconnection and the out-of-synchronization state of the HSD frame and the value of "alarmLineErrorMajState" indicating the detection of the bit error exceeding the threshold of the HSD frame are set to "1", respectively. If the alarms are performed (that is, the two persons have generated alarms), the arithmetic and control unit m3 sets the operation identification code of the “alarmLineRecState” to “1” and the operation identification code to the “almLineErrorMajState” to “4”. Are added based on the addition formula to calculate the value “5” of the composite code CD2.
[0044]
On the other hand, regarding the line board C4, for example, “alarmLineRecState” indicating the input disconnection and the out-of-synchronization state of the HSD frame, “alarmLineAisState” indicating the detection of the all (all) 1 signal in the HSD frame, and the threshold value of the HSD frame are exceeded. If the value of “almLineErrorMajState” indicating the detection of the bit error is set to “1” (that is, the three persons have issued alarms), the arithmetic control unit m3 performs the operation of the “almLineRecState”. Based on the addition formula, all of the identification code “1”, the operation identification code “2” of the “almLineAisState”, and the operation identification code “4” of the “almLineErrorMajState” are added. To calculate the value "7" of the composite code CD4 by.
[0045]
Then, the arithmetic control unit m3 transmits the composite codes CD2 and CD4 to the management device 9 via the communication unit m4 as a response to the acquisition request for the management information on the line board C2 and the board C4. When receiving such composite codes CD2 and CD4 from the management board M, the management device 9 specifies the alarm contents of the line boards C2 and C4 based on the composite codes CD2 and CD4 (step S5). The reason why the operation identification codes constituting the composite codes CD2 and CD4 can be separated based on the composite codes CD2 and CD4 is exactly the same as the case of the composite code CDu based on the unit identification code described above. The description is omitted.
[0046]
According to the present embodiment, by using the composite code CDu based on the unit identification code, the management device 9 can use any one of the line boards C1 to Cn constituting the frame converter 5 to perform an alarm by one polling process. Can be confirmed. Then, when any of the line boards (for example, the line boards C2 and C4) issues an alarm, the management device 9 converts the composite codes CD2 and CD4 based on the operation identification code into a frame converter by the second polling process. 5, the management information registered in MIBm2 for each of the line boards C2 and C4, that is, any one of "almLineRecState", "almLineAisState", "almLineErrorMajState", and "almLineErrorMonState" which issues an alarm is issued. It is possible that you can.
[0047]
That is, according to the present embodiment, the management device 9 does not need to perform the polling process the number of times that the number of line boards is multiplied by the number of types of operation state information as in the related art. Since the line board issuing the alarm and the contents of the alarm can be confirmed, it is possible to eliminate the traffic congestion between the frame converter 5 and the operation state information of the frame converter 5, that is, It is possible to acquire management information registered in MIBm2 in a short time.
[0048]
Note that the present invention is not limited to the above-described embodiment, and for example, the following modified examples can be considered.
(1) In the above embodiment, the communication device of the communication network connecting the user LAN 1 and the carrier wide area LAN 7 by the HSD network 4 is the managed device. The present invention is not limited to communication devices, and can be applied to management of various devices.
[0049]
(2) In the above embodiment, the frame converter 5 provided on the communication carrier wide area LAN 7 side is a managed device, but the managed device may be another device. For example, the frame converter 3 provided on the user LAN 1 side may be used as a managed device. (3) In the above embodiment, the operation state of the frame converter 5 as the managed device is managed by acquiring the management information of each of the line boards C1 to Cn registered in the MIBm2. Of the frame converter 5 may be managed by acquiring the information of the frame converter 5 from the frame converter 5.
[0050]
【The invention's effect】
As described above, according to the present invention, there is provided a method for separately managing the operation state of one or a plurality of managed devices by a management device. The operation identification code indicating the state is set in advance, and the operation identification code is set such that, when synthesized and encoded by a predetermined arithmetic expression, the operation identification code that is an element of the synthesized code can be distinguished. Since the management device obtains the composite code from the managed device to grasp the various types of operation states of the managed device, the management device suppresses traffic congestion required for device management and the time required for acquiring management information. Can be shortened.
[Brief description of the drawings]
FIG. 1 is a system configuration diagram of a device management system according to an embodiment of the present invention.
FIG. 2 is a configuration diagram of a frame converter 5 (managed device) in one embodiment of the present invention.
FIG. 3 is an explanatory diagram showing a method of assigning an identification code according to an embodiment of the present invention.
FIG. 4 is a flowchart illustrating a procedure for acquiring device status information according to an embodiment of the present invention.
FIG. 5 is an explanatory diagram showing properties of a unit identification code (and an operation identification code) according to an embodiment of the present invention.
[Explanation of symbols]
A: Equipment management system
1. User LAN
2 ... Router
3. Frame converter
4 HSD network
5 Frame converter
6 ... Router
7 ... Communication carrier wide area LAN
8 Management LAN
9 Management device
M …… Management board
m1 storage unit
m2: MIB (Management Information Base)
m3 ... Calculation control unit
m4: Communication unit
C1 to Cn: Line board (functional unit)

Claims (12)

A method of separately managing an operation state of one or a plurality of managed devices (5) by a management device (9),
For a plurality of types of operation states related to the managed device (5), an operation identification code indicating each operation state is set in advance, and when the operation identification code is synthesized and encoded by a predetermined arithmetic expression, The operation identification code, which is an element of the composite code, is set to be separable,
The management device (9) is a device management method characterized in that the management device (9) obtains the synthesized code from the managed device (5) to thereby grasp each type of operation state of the managed device (5). When the managed device (5) includes a plurality of functional units (C1 to Cn) having a plurality of types of operation states, a predetermined operation is performed to identify each of the functional units (C1 to Cn). A unit identification code that is set so that the unit identification code, which is an element of the composite code, can be discriminated when synthesized by the equation,
The management device (9) obtains the composite code composed of the unit identification code from the managed device (5) before acquiring the composite code composed of the operation identification code, so that the functional units (C1 to Cn) in the abnormal operation state are obtained. 2. The device management system according to claim 1, wherein the operation state of each type is grasped by acquiring the synthesized code including the operation identification code from the functional unit (C1 to Cn) in the abnormal operation state. Method. The unit identification code is a numerical value defined by 2 ^(n-1) for each of the ⁿ functional units (C1 to Cn) provided in the managed device (5), and the arithmetic expression adds the numerical value. 3. The device management method according to claim 2, wherein the device management method is an addition type. The operation identification code is a numerical value defined by 2 ^(m-1) for each of m types of operation states, and the arithmetic expression is an addition expression for adding the numerical value. Device management method described in Crab. 2. The communication device according to claim 1, wherein the managed device (5) is a communication device that transmits management information registered in MIB (Management Information Base) to the management device (9) using SNMP (Simple Network Management Protocol). 5. The device management method according to any one of items 1 to 4. The communication device is provided between the wide area LAN (Local Area Network) and the dedicated communication line when the wide area LAN (Local Area Network) of the communication carrier and the user LAN (Local Area Network) are interconnected by the dedicated communication line. 6. The apparatus management method according to claim 5, wherein the apparatus is a frame conversion apparatus that can be used. A management system (9) for separately managing an operation state of one or a plurality of managed devices (5),
The managed device (5) indicates a plurality of types of operation states, and has an operation identification set so as to be able to discriminate an operation identification code which is an element of the composite code when the encoding is performed by a predetermined arithmetic expression. The code is stored in advance, and when a transmission request of the operation state is input from the management device (9), the composite code is output to the management device (9),
The device management system, wherein the management device (9) obtains the composite code from the device to be managed (5) so as to ascertain various types of operation states of the device to be managed (5). The managed device (5) is composed of a plurality of functional units (C1 to Cn) having a plurality of types of operation states, and when synthesized by a predetermined arithmetic expression, a unit identification code which is an element of the synthesized code is used. A unit identification code set to be separable is also stored in advance, and when a request for transmitting an operation state for each functional unit (C1 to Cn) is input from the management device (9), the unit identification code is used. Outputting the synthesized code to the management device (9),
The management device (9) obtains the composite code composed of the unit identification code from the managed device (5) before acquiring the composite code composed of the operation identification code, so that the functional units (C1 to Cn) in the abnormal operation state are obtained. It is characterized by grasping and acquiring from the managed device (5) a composite code composed of operation identification codes relating to the functional units (C1 to Cn) in the abnormal operation state, thereby grasping the operation state of each type. The device management system according to claim 7. The unit identification code is a numerical value defined by 2 ^(n-1) for each of the ⁿ functional units (C1 to Cn) provided in the managed device (5), and the arithmetic expression adds the numerical value. The device management system according to claim 8, wherein the device management system is an addition type. 10. The operation identification code is a numerical value defined by 2 ^(m-1) for each of m types of operation states, and the arithmetic expression is an addition expression for adding the numerical value. The device management system described in Crab. 8. The communication device according to claim 7, wherein the managed device (5) transmits the management information registered in MIB (Management Information Base) to the management device (9) using SNMP (Simple Network Management Protocol). An apparatus management system according to any one of claims 10 to 10. The communication device is provided between the wide area LAN (Local Area Network) and the dedicated communication line when the wide area LAN (Local Area Network) of the communication carrier and the user LAN (Local Area Network) are interconnected by the dedicated communication line. 12. The device management system according to claim 11, wherein the device conversion system is a frame conversion device.

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