JP5775497B2 - Network control system and network device operation system - Google Patents

Description

  The present invention relates to a network device that is installed on a network and includes a plurality of different systems, a network control system that integrally manages these network devices, and an operation system of the network device.

  In recent years, network operation systems (hereinafter referred to as OpS) that collectively manage NEs (Network Elements), which are devices on an IP (Internet Protocol) network composed of a plurality of different vendors and a plurality of different devices. In some cases, the operating rate is improved by judging whether the system of the apparatus is alive or not, and changing the control execution destination to a system in a living state. In addition, a TCP (Transmission Control Protocol) session (Non-Patent Document 1), a Ping response, a DNS (Domain Name System) response, and the like are widely used for determining whether a device is active or dead on an IP network.

The life and death judgment by the TCP session is to judge whether the target device is alive or not by determining whether or not a session with the target device is established.
The life and death judgment by the Ping response refers to sending an ICMP (Internet Control Message Protocol) “echo request” packet to the target device and judging whether or not an “echo reply” packet is returned from the target device. Is used to determine the life and death of the target device.
The life and death judgment by the DNS response is to judge the life and death of the target device by judging whether or not the address of the target device exists in the DNS response.

  However, in these life / death determination methods, it is not possible to perform life / life determination of an application program that operates on a network device and performs a service unique to the device. For this reason, when the network and the hardware of the network device are operating normally and the service provided by the application program is out of order, it is impossible to make a life / death judgment correctly.

FIG. 8 is a schematic configuration diagram showing a network control system in a comparative example.
In the network control system 10 </ b> C, a network device (NE) 50 and an operation system (OpS) 30 </ b> C that comprehensively manages the network device (NE) 50 are connected by a network 100 so that they can communicate with each other. Furthermore, an operation system (OpS) terminal 20 which is an operation terminal is connected to the operation system (OpS) 30C.

The network device (NE) 50 is a redundantly configured device including two element management systems of NE-EMS (Element Management System) (0 system) 51-0 and NE-EMS (1 system) 51-1. . Hereinafter, when NE-EMS (0 system) 51-0, NE-EMS (1 system) 51-1 and the like are not particularly distinguished, they may be simply described as NE-EMS 51.
Since the network device (NE) 50 is a redundant device having a multiplexed element management system, one of the NE-EMS (0 system) 51-0 and the NE-EMS (1 system) 51-1 has failed. Even in such a case, it is possible to continue the operation by switching to a system that has not failed.

  The NE-EMS (system 0) 51-0 and the NE-EMS (system 1) 51-1 each transmit and receive a packet to and from other devices connected to the network 100 (NIC). 55, an operating system (OS) 54 that provides an application interface for controlling the network interface (NIC) 55, a communication middleware (MW) 53 that calls the application interface to perform IP communication, and a communication middleware (MW) And an application program (APP) 52 that provides a service specific to the apparatus via the network 53.

  The operation system (OpS) 30C provides a network interface (NIC) 34 that transmits and receives packets to and from other devices connected to the network 100, and an application interface for controlling the network interface (NIC) 34. The operating system (OS) 33, the communication middleware (MW) 32 that calls the application interface to perform IP communication, the NE control interface unit 40C that controls the network device (NE) 50, and the operation system (OpS) terminal 20 from the operator And an operator interface unit 31 for receiving the instruction.

  The operator uses the operation system (OpS) terminal 20 to control the network device (NE) 50. In the initial state, the operation system (OpS) 30C acquires the operation information of the operator through the operator interface unit 31, and then the NE-EMS (0 system) 51-0 is connected to the ACT system (from the NE control interface unit 40C. = Neutral state) or NE-EMS (1 system) 51-1 is not determined whether it is an ACT system, and one of the NE-EMSs 51 is selected and controlled.

In the operating state of the comparative example of FIG. 8, the following situation is assumed.
The network 100 between the network device (NE) 50 and the operation system (OpS) 30C operates normally, and the network interface (NIC) 55, the operating system (OS) 54, and the communication middleware (MW) of the network device (NE) 50 53 is operating normally, and only the service of the application program (APP) 52 of the NE-EMS (system 0) 51-0 is out of order.

  In this situation, since the network interface (NIC) 55, the operating system (OS) 54, and the communication middleware (MW) 53 are operating normally, the TCP session remains established and the Ping response and DNS response are normal. Returns an unchanging response. As a result, the operation system (OpS) 30C determines that the NE-EMS (0 system) 51-0 is an ACT system, and performs control with the NE-EMS (1 system) 51-1 which is the correct ACT system. I can't.

Marina del Rey, “RFC 793 TRANSMISSION CONTROL PROTOCOL DARPA INTERNET PROGRAM PROTOCOL SPECIFICATION”, Information Sciences Institute University of Southern California, September 1981

  Thus, in general network responses such as a TCP session, a Ping response, and a DNS response, responses are returned by the network, hardware, OS, and middleware. Therefore, in a situation where the network, hardware, OS, and middleware are operating normally and the service provided by the application program is broken, the system to be controlled may not be determined correctly.

  Therefore, the present invention detects a failure of the system of the network device even when only the application program that provides the service of the network device fails and the network, hardware, OS, and middleware are operating normally. It is an object to provide a network control system and an operation system for a network device.

In order to solve the above-described problem, according to the first aspect of the present invention, there is provided a network control system including a network device and an operation system for controlling the network device, wherein the network device includes a plurality of element managements. The multiple element management system has a redundant configuration, and each of the plurality of element management systems is operated by an application program that performs a service, and the operation system performs life and death judgment by a response message generated by the application program. a determination unit, when the element management system of the control target by the life-and-death determination unit determines that a fault condition, and a control interface unit for the element management system other than the control target as a new control object, the elementary of the plurality based A combination of a message transmission / reception unit that transmits / receives a message to / from any one of the management systems, a message analysis unit that extracts a message from a message received by the message transmission / reception unit, and a next state of the message and the corresponding element management system And a storage unit that includes a state determination pattern list that is recorded, and a state list that stores the state of each of the plurality of element management systems. The life and death judgment unit receives a message from the element management system to be controlled by the message transmission / reception unit, extracts the message from the message by the message analysis unit, and performs life and death judgment according to the next state of the state determination pattern list In addition, the state of the element management system to be controlled in the state list is updated, and the control interface unit newly inputs one of the element management systems in the living state based on the state list. A featured network control system was adopted.

The invention according to claim 6 is an operation system for controlling a network device having a redundant configuration including a plurality of element management systems, wherein each of the plurality of element management systems operates an application program for performing a service. The operation system is configured to determine whether the life / non-life determination unit performs life / non-life determination based on a response message generated in the application program, and when the element management system to be controlled is determined to be in a failure state by the life / non-life determination unit. Received by the control interface unit to be a new control target by introducing an element management system other than the target, the message transmission / reception unit that transmits / receives a message between any of the plurality of element management systems, and the message transmission / reception unit Extract messages from messages A message analysis unit, a state determination pattern list in which a combination of the message, the state of the element management system corresponding to the message, and the next state is recorded, and the state of each of the plurality of element management systems are stored A storage unit including a state list. The life and death judgment unit receives a message from the element management system to be controlled by the message transmission / reception unit, extracts the message from the message by the message analysis unit, and performs life and death judgment according to the next state of the state determination pattern list And updating the state of the element management system to be controlled in the state list, and the control interface unit newly inputs an element management system in the living state based on the state list. The operation system of the apparatus was used.

In this way, even when only an application program that provides a service specific to the network device is out of order, the failure can be detected. Furthermore, when it is determined that the element management system to be controlled is in a failure state, an element management system other than the control target can be input and set as a new control target. That is, it is possible to automatically switch to the normal element management system. Further, since the operation system is provided with the NE state list, it is possible to easily select the NE-EMS in the living state and to control the NE-EMS.

In the invention according to claim 2 , the state determination pattern list records the message, the state of the element management system, and a combination of the next states corresponding thereto, and the life and death determination unit performs the message analysis. And acquiring the next state of the state determination pattern list based on the message extracted by the unit and the next state of the element management system to be controlled recorded in the state list, and determining whether the state is active or not. It updates the state of the element management system in the controlled object, and a network control system according to claim 1, characterized in that.

  By doing in this way, since the operation system is equipped with the NE state determination pattern list, it is possible to determine NE failure by combining a plurality of messages.

According to a third aspect of the present invention, the control interface unit stores the load of the element management system of the plurality of systems, and newly inputs the one with the lowest load among the element management systems in the living state. The network control system according to claim 1 or claim 2 is characterized.

  By doing so, the operation system has the least load on the element management system and can be put into a living state, so that the operation rate of the network device can be improved.

In the invention according to claim 4 , the control interface unit stores the number of inputs of the element management system of the plurality of systems, and newly inputs the one with the smallest number of inputs among the element management systems in the living state. A network control system according to claim 1 or claim 2 is provided.

  By doing in this way, the operation system can input the element management system of the plural systems with the smallest number of inputs and the living state, so the number of inputs of the element management system is leveled, The operating rate of the network device can be improved.

In the invention according to claim 5 , the control interface unit stores the cumulative operation time of the element management systems of the plurality of systems, and newly selects the one with the smallest cumulative operation time among the element management systems in the living state. The network control system according to claim 1 or 2 , wherein the network control system is provided.

  By doing in this way, the operation system can throw in the element system that has the least accumulated operating time and the surviving state among the multiple element management systems. Therefore, the operation rate of the network device can be improved.

  According to the present invention, even when only an application program that provides a service of a network device fails and the network, hardware, OS, and middleware are operating normally, the failure of the network device system is detected. It is possible to provide a network control system and an operation system for a network device.

It is a schematic block diagram which shows the network control system in 1st Embodiment. It is a flowchart which shows the process of the NE control interface part in 1st Embodiment. It is a schematic block diagram which shows the network control system in 2nd Embodiment. It is a figure which shows the NE state list | wrist and NE state determination pattern list | wrist in 2nd Embodiment. It is a flowchart which shows the process of the NE control interface part in 2nd Embodiment. It is a figure which shows the NE state list | wrist in 3rd Embodiment. It is a flowchart which shows the process of the NE control interface part in 3rd Embodiment. It is a schematic block diagram which shows the network control system in a comparative example.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

(Configuration of the first embodiment)

FIG. 1 is a schematic configuration diagram showing a network control system in the first embodiment.
The network control system 10 includes a network device (NE) 50 that is, for example, a server device or a router device, and an operation system (OpS) 30 that comprehensively manages the network device (NE) 50. It is connected so that it can communicate. Furthermore, an operation system (OpS) terminal 20 that is an operation terminal is connected to the operation system (OpS) 30.

The network device (NE) 50 is a redundantly configured device including two element management systems of NE-EMS (Element Management System) (0 system) 51-0 and NE-EMS (1 system) 51-1. . Hereinafter, when NE-EMS (0 system) 51-0, NE-EMS (1 system) 51-1 and the like are not particularly distinguished, they may be simply described as NE-EMS 51.
Since the network device (NE) 50 is a redundant device, even if one of the NE-EMS (0 system) 51-0 and the NE-EMS (1 system) 51-1 fails, the network device (NE) 50 fails. It is possible to continue operation by switching to a system that is not.

  The NE-EMS (system 0) 51-0 and the NE-EMS (system 1) 51-1 each have a network interface (NIC) 55 for transmitting and receiving packets to and from other devices connected to the network 100. An operating system (OS) 54 that provides an application interface for controlling the network interface (NIC) 55, a communication middleware (MW) 53 that calls the application interface to perform IP communication, and a communication middleware (MW) 53 And an application program (APP) 52 that provides services specific to the apparatus. The service unique to the device is, for example, a database search function of a server device storing a database, a terminal accommodation function of a router device accommodating a terminal, or the like.

  The operation system (OpS) 30 provides a network interface (NIC) 34 that transmits and receives packets to and from other devices connected to the network 100, and an application interface for controlling the network interface (NIC) 34. An operator from the operating system (OS) 33, a communication middleware (MW) 32 that calls an application interface to perform IP communication, a NE control interface unit 40 that controls the network device (NE) 50, and an operation system (OpS) terminal 20 And an operator interface unit 31 for receiving the instruction. The NE control interface unit 40 includes an NE life / non-life determination unit 41 that makes a life / non-life determination of the network device (NE) 50.

(Operation of the first embodiment)
As shown in FIG. 1, the operator uses the operation system (OpS) terminal 20 to control the NE-EMS 51. In the initial state, the operation system (OpS) 30 receives an operator operation at the operator interface unit 31, and then receives the NE operation / determination unit 41 in the NE control interface unit 40, and then the NE-EMS ( Whether the 0 system) 51-0 is an ACT system or the NE-EMS (1 system) 51-1 is an ACT system is determined from the result of communication to both sides.
The NE life and death determination unit 41 controls the NE-EMS 51 that is determined to be an ACT system.

In the operating state of the first embodiment in FIG. 1, the following situation is assumed.
The network 100 between the network device (NE) 50 and the operation system (OpS) 30 operates normally, and the network interface (NIC) 55, operating system (OS) 54, and communication middleware ( MW) 53 is operating normally. At this time, only the service of the application program (APP) 52 of the NE-EMS (0 system) 51-0 has failed.

In this situation, the NE control interface unit 40 of the operation system (OpS) 30 establishes a session with, for example, the NE-EMS (0 system) 51-0 and the NE-EMS (1 system) 51-1 and uses the TCP session. Conduct life and death monitoring. Since the TCP session cannot be disconnected in the situation of the first embodiment, it is initially determined that the NE-EMS (0 system) 51-0 is the ACT system, and the NE-EMS (0 system) 51-0 is controlled. To do.
Specifically, the NE control interface unit 40 transmits a message to the NE-EMS (0 system) 51-0 to be controlled. The transmitted message is received by the network interface (NIC) 55 of the NE-EMS (0 system) 51-0, and the application program (the communication middleware (MW) 53) and the application program ( APP) 52 is reached.

Here, the application program (APP) 52 of the NE-EMS (system 0) 51-0 generates a message including a service failure error indicating that a failure has occurred, and outputs the message to the communication middleware (MW) 53. This electronic message is output to the network interface (NIC) 55 via the communication middleware (MW) 53 and the application interface of the operating system (OS) 54 and transmitted to the operation system (OpS) 30.
In another situation, the service of the application program (APP) 52 of the NE-EMS (system 0) 51-0 may fail to generate a response message. In this case, the response message does not reach the operation system (OpS) 30 within a predetermined time, and the operation system (OpS) 30 detects a communication timeout.
That is, because of a failure of the NE-EMS (0 system) 51-0, the NE alive determination unit 41 receives a message including an error message indicating that the service is disabled from the NE-EMS (0 system) 51-0, or Communication times out. Thereby, the NE life and death determination unit 41 can determine that the NE-EMS (0 system) 51-0 is incapable of service, and changes the control execution destination to the NE-EMS (1 system) 51-1. Thereafter, the NE control interface unit 40 controls the NE-EMS (1 system) 51-1.

FIG. 2 is a flowchart showing processing of the NE control interface unit in the first embodiment.
When the processing is started, in step S10, the NE control interface unit 40 establishes a session with the NE-EMS (0 system) 51-0 and the NE-EMS (1 system) 51-1.
In step S11, the NE control interface unit 40 performs life / death monitoring of the NE-EMS (0 system) 51-0 and the NE-EMS (1 system) 51-1. Here, the NE control interface unit 40 performs alive monitoring by, for example, a TCP session.
In step S12, the NE control interface unit 40 controls the NE-EMS (0 system) 51-0. The NE control interface unit 40 controls the NE-EMS (0 system) 51-0 by transmitting a message to the NE-EMS (0 system) 51-0 and receiving a response message, for example.
In step S13, the NE life / death determination unit 41 determines whether a message including a service inability error is received from the NE-EMS (0 system) 51-0 or a communication timeout is detected. The NE life / death determination unit 41 returns to the process of step S12 if the determination condition is not satisfied (No), and performs the process of step S14 if the determination condition is satisfied (Yes).

In step S14, the NE control interface unit 40 changes the control execution destination to the NE-EMS (1 system) 51-1. As a result, the operator can repair the NE-EMS (0 system) 51-0 that is no longer being controlled.
In step S15, the NE control interface unit 40 controls the NE-EMS (1 system) 51-1. The NE control interface unit 40 controls the NE-EMS (1 system) 51-1 by transmitting a message to the NE-EMS (1 system) 51-1 and receiving a response message, for example.
In step S <b> 16, the NE life / death determination unit 41 determines whether a message including a service inability error is received from the NE-EMS (system 1) 51-1 or a communication timeout is detected. The NE life / death determination unit 41 returns to the process of step S15 if the determination condition is not satisfied (No), and performs the process of step S17 if the determination condition is satisfied (Yes).
In step S17, the NE control interface unit 40 changes the control execution destination to NE-EMS (0 system) 51-0, and returns to the process of step S12. As a result, the operator can repair the NE-EMS (1 system) 51-1 that is no longer being controlled.

(Effects of the first embodiment)
The first embodiment described above has the following effects (A) and (B).

(A) Even when only the application program (APP) 52 that provides the service of the network device (NE) 50 has failed, the failure can be detected.

(B) When a failure of the NE-EMS (system 0) 51-0 is detected, the NE-EMS (system 1) 51-1 is controlled to detect a failure of the NE-EMS (system 1) 51-1. When this occurs, the NE-EMS (0 system) 51-0 is being controlled. Thereby, when one NE-EMS 51 is out of order, the control can be automatically switched to the normal NE-EMS 51. Furthermore, the NE-EMS 51 that has failed can be repaired.

(Configuration of Second Embodiment)

FIG. 3 is a schematic configuration diagram showing a network control system according to the second embodiment.
The network control system 10A of the second embodiment includes a network device (NE) 50A and an operation system (OpS) 30A that are different from those of the first embodiment (FIG. 1).
Unlike the first embodiment, the network device (NE) 50A of the second embodiment includes an NE-EMS 51, which is an (n + 1) redundant element management system (n is 2 or more). Natural number). Each NE-EMS 51 of the second embodiment is configured similarly to the NE-EMS 51 of the first embodiment.
The operation system (OpS) 30A of the second embodiment includes an NE control interface unit 40A and a storage unit 44, which are different from those of the first embodiment. In addition to the configuration of the first embodiment, the NE control interface unit 40A of the second embodiment analyzes an electronic message and an NE message transmission / reception unit 42 that transmits and receives a message to and from the network device (NE) 50A. NE message analysis unit 43 that extracts a message. The storage unit 44 of the second embodiment is, for example, a RAM (Random Access Memory) or the like. The NE state list 45 that stores the state of each NE-EMS 51, the current state of the message and the NE-EMS 51, and the corresponding state The NE state determination pattern list 46 in which the correspondence with the next state 46c and the next action 46d (FIG. 4B) of the NE-EMS 51 to be recorded is recorded.

  FIGS. 4A and 4B are diagrams showing an NE state list and an NE state determination pattern list in the second embodiment.

FIG. 4A is a diagram illustrating an example of the NE state list 45.
The NE state list 45 is a table that stores the life and death states of the NE-EMS (0 system) 51-0 to NE-EMS (n system) 51-n. FIG. 4 shows a state in which a failure of NE-EMS (system 0) 51-0 is detected and control is changed to NE-EMS (system 1) 51-1.
The NE state list 45 holds a correspondence relationship between each NE-EMS 51 and its state. Here, the state of each NE-EMS 51 includes a busy state or other states in addition to the failure state / survival state. Here, the busy state refers to a state in which a failure is suspected by the NE control interface unit 40A, and refers to a state in which processing capability is reduced due to a hardware failure or the like, and a state in which incorrect responses are frequently generated. . Here, the reduction in processing capacity is, for example, a state where the CPU (Central Processing Unit) is overloaded, a communication band of the network interface (NIC) 55 is overloaded, and a read / write band of a storage unit (not shown) is overloaded. And so on.

FIG. 4B is a diagram illustrating an example of the NE state determination pattern list 46.
The NE state determination pattern list 46 records correspondences between the NE-EMS message 46a, the NE-EMS state 46b, the next state 46c, and the next action 46d.
Based on the NE state list 45 and the NE state determination pattern list 46, the NE life / death determination unit 41 determines the next state 46c and the next action 46d based on the message received from the NE-EMS 51.

The NE-EMS message 46a is a message extracted by the NE message analysis unit 43.
The NE-EMS state 46b refers to the current state of the NE-EMS 51 related to the message.
The next state 46c refers to a next state in which the NE-EMS 51 related to the message transitions.
The next action 46d refers to the next action of the NE life and death judgment unit 41. In the present embodiment, the next state 46c and the next action 46d correspond to each other.

In FIG. 4B, if the NE-EMS 51 message is “Error A” and its state is “Surviving” or “Busy”, then the next state 46c is “NE failure” and the next action 46d is “Re-injection into another system”.
If the NE-EMS 51 message is “error AA” and the state is “survival” or “busy”, the next state 46c is “busy” and the next action 46d is “control continuation”.
If the NE-EMS 51 message is “error B” and the state is “survival”, the next state 46 c is “survival” and the next action 46 d is “control continuation”.
If the NE-EMS 51 message is “Error B” and its state is “Busy”, then the next state 46c is “NE failure”, and the next action 46d is “Re-injection into another system”.
In this case, if the “error AA” message is received from the NE-EMS 51 and then the “error B” message is received, the next state 46c becomes “NE failure”, and the next action 46d is “re-enter to another system”. "

(Operation of Second Embodiment)

FIG. 5 is a flowchart showing processing of the NE control interface unit in the second embodiment.
The operation system (OpS) 30A receives the operator operation at the operator interface unit 31 and then passes it to the NE control interface unit 40A to start the processing of FIG.
In step S20, the NE control interface unit 40A requests the NE alive determination unit 41 to determine the system to which the network device (NE) 50A is input.

In step S21, the NE life / death determination unit 41 selects one live NE-EMS 51 from the NE state list 45 and returns it to the NE control interface unit 40A. In the present embodiment, in the initial state, the NE state list 45 records that all NE-EMSs 51 are alive. When there are a plurality of NE-EMSs 51 in a living state, a method of selecting one is a method of selecting 0 system → 1 system →... → n system → 0 system →. Therefore, the NE life and death determination unit 41 selects NE-EMS (0 system) 51-0 at the beginning of the processing.
In step S <b> 22, the NE message transmission / reception unit 42 transmits a message to the NE-EMS 51 selected by the NE life / death determination unit 41. The selected NE-EMS 51 receives a message from the operation system (OpS) 30A, performs processing based on this message, and returns a response message to the operation system (OpS) 30A.

In step S23, the NE telegram transmitting / receiving unit 42 of the operation system (OpS) 30A receives a response telegram from the NE-EMS 51.
In step S <b> 24, the NE message analysis unit 43 extracts the NE-EMS 51 message from the received response message, and acquires the NE-EMS 51 state from the NE state list 45.

In step S25, the NE life and death determination unit 41 matches the NE-EMS 51 message and state with the NE state determination pattern list 46, and acquires the next state 46c and the next action 46d.
In step S26, the NE life / death determination unit 41 writes the next state in the NE state list 45 based on the contents of the next state 46c. In the present embodiment, the NE alive determination unit 41 writes “failure” in the NE state list 45 if the next state 46 c is “NE failure”, and the NE state list 45 if the next state 46 c is “busy”. “Busy” is written to “N”, and “Surviving” is written to the NE state list 45 if the next state 46c is “Surviving”.
In step S27, the NE life and death determination unit 41 determines the next action 46d. If the next action 46d is “continue control”, the NE life / death determination unit 41 returns to the process of step S22, and if the next action 46d is “re-injection into another system”, the process returns to step S21.
In the present embodiment, when the next state 46c is “NE failure”, all the next actions 46d are “re-enter into another system”. Therefore, in step S27, the NE life and death determination unit 41 may determine whether or not the next state 46c is “NE failure”. Further, the NE alive determination unit 41 may return to the process of step S22 if the determination condition is not satisfied, and return to the process of step S21 if the determination condition is satisfied.

<Example of re-input operation to another system>
Here, for explanation, in step S21, the NE life / death determination unit 41 selects NE-EMS (0 system) 51-0, and in step S24, the NE message extracted by the NE message analysis unit 43 is “error”. Consider the case of A ”.
In step S25, the NE life / death determination unit 41 matches the NE-EMS (0 system) 51-0 message “error A” with the state “survival” with the NE state determination pattern list 46, and the next state 46c. “NE failure” and the next action 46d “re-injection into another system” are acquired.

In step S <b> 26, the NE life / death determination unit 41 writes “failure” in the NE state list 45 because the next state 46 c is “NE failure”.
In step S27, the NE life and death determination unit 41 returns to the process of step S21 because the next action 46d is “re-injection into another system”.
In step S <b> 21, the NE life / death determination unit 41 replies to the NE control interface unit 40 that the NE-EMS 51 in the living state is the NE-EMS (1 system) 51-1 based on the NE state list 45. When there are a plurality of NE-EMSs 51 in a living state, the method of selecting one unit is a method of selecting 0 system → 1 system →... → n system → 0 system →..., NE-EMS (0 system) 51- When the zero failure is detected, the NE alive determination unit 41 selects the NE-EMS (1 system) 51-1 and returns it to the NE control interface unit 40.
In step S22, the NE message transmission / reception unit 42 transmits a message to the NE-EMS (1 system) 51-1 selected by the NE life / death determination unit 41.

  Here, for example, consider a case where “NE failure” is acquired as the next state 46c as the matching result, and “re-injection into another system” is acquired as the next action 46d. The NE control interface unit 40A that has received the matching result writes “failure” in the NE state list 45 because the next state 46c is “NE failure”. Further, the NE control interface unit 40A returns to the process of step S21 because the next action 46d is “re-injection into another system”. At this time, if the NE-EMS (0 system) 51-0 has returned to the living state, the NE telegram transmitting / receiving unit 42 transmits the message again to the NE-EMS (0 system) 51-0.

  The NE state determination pattern list 46 may be a pattern for determining the next state 46c and the next action 46d by a plurality of NE messages. For example, when the NE message transmission / reception unit 42 receives the “error AA” of the NE message and then receives the “error B” of the NE message, it determines that the next state 46c is “NE failure” and the next action 46d. Can be considered as “re-injection into another system”.

(Effect of 2nd Embodiment)
The second embodiment described above has the following effects (C) and (D).

(C) Since the NE control interface unit 40A includes the NE state list 45, even if it has three or more NE-EMSs 51, the NE-EMS 51 in the living state can be easily selected and controlled. can do.

(D) Since the NE control interface unit 40A includes the NE state determination pattern list 46, an NE failure can be determined by a combination of a plurality of messages.

(Configuration of Third Embodiment)
The network control system 10B according to the third embodiment includes a NE state list 45B different from the network control system 10A (FIG. 3) according to the second embodiment in the storage unit 44 of the operation system (OpS) 30A. Others are configured similarly to the network control system 10A of the second embodiment.

FIG. 6 is a diagram showing an NE state list in the third embodiment.
The NE state list 45B in the third embodiment includes a load and the number of inputs corresponding to each NE-EMS 51 in addition to the NE state list 45 (FIG. 4A) in the second embodiment. It has an item of accumulated operating time.
The load is an operation load of the NE-EMS 51, and is measured by, for example, CPU load, traffic volume, number of calls, current flowing through the NE-EMS 51 power supply, power consumed by the NE-EMS 51 power supply, and the like. Is.
The number of times of insertion is the number of times that the NE-EMS 51 is input to the control.
The cumulative operating time is the cumulative operating time of the NE-EMS 51.

(Operation of Third Embodiment)

FIG. 7 is a flowchart showing processing of the NE control interface unit in the third embodiment.
After starting the processing, the processing in step S20 is the same as the processing in step S20 (FIG. 5) of the second embodiment.
In step S21B, the NE life / death determination unit 41 selects one NE-EMS 51 that is alive and has the smallest load amount from the NE state list 45B, and returns a response to the NE control interface unit 40A.
In step S21C, the NE life / death determination unit 41 adds 1 to the number of times the NE state list 45B is input, and performs the process of step S30.
In step S30, the NE message transmission / reception unit 42 transmits a message for inquiring the load and the accumulated operation time to the NE-EMS 51 selected by the NE life / death determination unit 41. The NE-EMS 51 returns a message that responds with its own load and the accumulated operating time.
In step S31, the NE telegram transmission / reception unit 42 receives the telegram that responds to the load and the cumulative operation time from the NE-EMS 51 selected by the NE life / death determination unit 41, thereby acquiring the load and the cumulative operation time. .
In step S32, the NE life and death determination unit 41 stores the load and cumulative operating time of the NE-EMS 51 in the NE state list 45B, and performs the process of step S22.
The process of steps S22 to S26 is the same as the process of steps S22 to S26 of the second embodiment.
In step S27, the NE life and death determination unit 41 determines the next action 46d. If the next action 46d is “control continuation”, the NE life / death determination unit 41 returns to the process of step S30, and if the next action 46d is “re-injection into another system”, the process returns to step S21B.

(Effect of the third embodiment)
The third embodiment described above has the following effect (E).

(E) Among the NE-EMSs 51 in the living state, the control targets are in order from the lowest load. Thereby, since the load of each NE-EMS 51 can be leveled, the operation rate of the network device (NE) 50A and the network control system 10B can be improved.

(Modification)
The present invention is not limited to the above-described embodiment, and can be modified without departing from the spirit of the present invention. For example, there are the following (a) to (e).

(A) In 2nd Embodiment, the method of selecting one NE-EMS51 of a living state is the method of selecting in order of 0 system-> 1 system -...-> n system. However, the present invention is not limited to this, and the method of selecting one surviving NE-EMS 51 may be a method of generating one random number and randomly selecting one surviving NE-EMS 51. Thereby, the operating state of each NE-EMS 51 can be leveled, and the operating rate of the network device (NE) 50A and the network control system 10A can be improved.

(B) In 3rd Embodiment, it is set as the control object in an order from the thing with the lowest load of NE-EMS51. However, the present invention is not limited to this, and the NE-EMS 51 may be the control target in order from the lowest cumulative load, the NE-EMS 51 may be the control target in order from the lowest number of inputs, and the NE-EMS 51 cumulative operation time. It is good also as a control object in an order from the least. Thereby, the operation state of each NE-EMS 51 can be leveled, and the operation rate of the network device (NE) 50A and the network control system 10B can be improved.

(C) In 3rd Embodiment, it is set as the control object in an order from the lowest load of NE-EMS51. However, the present invention is not limited to this, and the NE-EMS 51 may be controlled in order from the one with the lowest failure rate or the one with the smaller number of failures. As a result, the NE-EMS 51 with the lowest failure rate or the NE-EMS 51 with the least number of failures can be selected and controlled, so that the failure rate of the network device (NE) 50A and the network control system 10B can be reduced. .

(D) In the third embodiment, the NE control interface unit 40A inquires the selected NE-EMS 51 about the load and the accumulated operating time, and further transmits and receives a message to extract a message. However, the present invention is not limited to this, and the NE control interface unit 40A may transmit a message that inquires the selected NE-EMS 51 about the load and the accumulated operation time, and may extract a message included in the message of this response.

(E) In the third embodiment, the NE telegram transmission / reception unit 42 of the NE control interface unit 40A receives a telegram that responds with the load and the accumulated operation time from the NE-EMS 51 selected by the NE alive determination unit 41. Are stored in the NE state list 45B. However, the present invention is not limited to this, and the NE control interface unit 40A receives the load and the accumulated operation time by transmitting / receiving a message to / from the live NE-EMS 51, and then stores the load and the accumulated operation time in the temporary storage area. You may select the NE-EMS51 with the shortest load and the accumulation operation time. Further, the NE control interface unit 40A monitors the behavior of the NE-EMS 51 in the living state from the outside, acquires the load and the accumulated operating time, stores the load and the accumulated operating time in the temporary storage area, and stores the NE in the living state. -You may select the thing with the fewest load and accumulation operation time among EMS51.

10, 10A, 10B, 10C Network control system 20 Operation system (OpS) terminal 30, 30A, 30C Operation system (OpS)
31 Interface section for operator 32 Communication middleware (MW)
33 Operating System (OS)
34 Network Interface (NIC)
40, 40A, 40C NE control interface unit (control interface unit)
41 NE Life / Life Judgment Unit (Life / Life Judgment Unit)
42 NE message transmission / reception unit (message transmission / reception unit)
43 NE message analysis unit (message analysis unit)
44 storage unit 45 NE state list (state list)
46 NE state judgment pattern list (state judgment pattern list)
50 Network equipment (NE)
51 NE-EMS (Element Management System)
52 Application (APP)
53 Communication middleware (MW)
54 Operating System (OS)
55 Network Interface (NIC)
100 network

Claims (6)

A network control system comprising a network device and an operation system for controlling the network device,
The network device has a redundant configuration including a plurality of element management systems,
In the multiple element management system, application programs for performing services are operating,
The operation system includes:
A life / death determination unit that performs life / death determination by a response message generated by the application program;
When the element management system to be controlled is determined to be in a failure state by the life and death judgment unit, a control interface unit that makes a new control target an element management system other than the control target;
A message transmission / reception unit for transmitting / receiving a message to / from any of the plurality of element management systems;
A message analysis unit that extracts a message from a message received by the message transmission / reception unit;
A state determination pattern list in which a combination of the next state of the message and the corresponding element management system is recorded, and a storage unit including a state list for storing the state of each of the plurality of element management systems. Prepared,
The life and death judgment unit receives a message from the element management system to be controlled by the message transmission / reception unit, extracts the message from the message by the message analysis unit, and performs life and death judgment according to the next state of the state determination pattern list And updating the state of the element management system to be controlled in the state list,
The control interface unit newly inputs one of the element management systems in the living state based on the state list,
A network control system characterized by that. In the state determination pattern list, the message, the state of the element management system, and the combination of the next state corresponding to them are recorded,
The life and death judgment unit obtains the next state of the state judgment pattern list based on the message extracted by the message analysis unit and the next state of the control target element management system recorded in the state list. A life and death judgment is performed, and the state of the element management system to be controlled in the state list is updated.
The network control system according to claim 1 . The control interface unit stores the load of the element management system of the plurality of systems, and newly inputs the one with the least load among the element management systems in the living state.
The network control system according to claim 1 or 2 , characterized in that The control interface unit stores the number of inputs of the element management system of the plurality of systems, and newly inputs the one with the smallest number of inputs among the element management systems in the living state.
The network control system according to claim 1 or 2 , characterized in that The control interface unit stores the cumulative operation time of the multiple element management system, and newly inserts the one that has the least cumulative operation time among the element management systems in the living state.
The network control system according to claim 1 or 2 , characterized in that An operation system for controlling a network device having a redundant configuration including a plurality of element management systems,
In the multiple element management system, application programs for performing services are operating,
The operation system includes:
A life / death determination unit that performs life / death determination by a response message generated in the application program;
When the element management system to be controlled is determined to be in a failure state by the life and death determination unit, a control interface unit that inputs an element management system other than the control target and sets a new control target; and
A message transmission / reception unit for transmitting / receiving a message to / from any of the plurality of element management systems;
A message analysis unit that extracts a message from a message received by the message transmission / reception unit;
A state determination pattern list in which a combination of the message, the state of the element management system corresponding to the message and the next state is recorded, and a state list storing the state of each of the plurality of element management systems And a storage unit
The life and death judgment unit receives a message from the element management system to be controlled by the message transmission / reception unit, extracts the message from the message by the message analysis unit, and performs life and death judgment according to the next state of the state determination pattern list And updating the state of the element management system to be controlled in the state list,
The control interface unit newly inputs an element management system in a living state based on the state list,
An operation system for a network device.

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