JP2015159454A - Network device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve such a problem of a method which allows a management terminal to be connected with an object device by using a device name, by inquiring a network device, and holding the information associating the device name and the IP address in the management terminal, that when the IP address of the object device is changed, the correspondence information of the device name and IP address is brought into a state different from the actual situation, until the information is collected again from the management terminal, and the management terminal requires a function for inquiring the network device.SOLUTION: A network device is provided with the information for associating the device name and the IP address, and the information of the device name and IP address is updated every time when the IP address of the network device is changed.

Description

  The present invention relates to an IP network device that can be managed from a management terminal via a network.

In a conventional network device, it is necessary to connect by specifying an IP (Internet Protocol) address of a target device when performing management communication from a management terminal. Since this IP address is a numerical value, it is difficult to distinguish the installation location and type of the apparatus, and there is a high possibility that a connection error will occur.
As a means for solving such a problem, there is a method of introducing a DNS (Domain Name System) server in a network.
However, the introduction of a DNS server complicates network management. For this reason, means for solving the problem without using a DNS server has been proposed (see, for example, Patent Document 1). According to this prior art, information that associates a device name with an IP address is held in a terminal, and a connection destination can be determined from the terminal using the device name. The information held by the terminal is created by the terminal making simultaneous inquiries to the target device and collecting the responses.

JP 2007-019614 A

  As described above, in the conventional method, the terminal needs to collect device name information from the target device. The information that associates the device name with the IP address is information on the timing of information collection. When the IP address of the target device is changed, the device name and the IP address are collected until the information is collected again from the terminal. There was a problem that the correspondence information of the address became different from the actual situation. In addition, the terminal has a problem that a function for collecting information from the apparatus is required.

  The present invention has been made to solve the above-described problems, and provides a network device that can connect to a target device using a device name instead of an IP address even if the terminal does not have a special function. Objective. It is another object of the present invention to obtain a network device that can always hold information associating a device name with an IP address in the latest state.

The network device according to the present invention provides:
An address storage unit having an address table in which a device name of one network device is associated with an IP address;
An address change processing unit for notifying and processing the setting information of the IP address as the IP address change information to the address storage unit or another network device in the device of the one network device;
When receiving a name resolution request for requesting the IP address to correspond to the device names of the other network device and the one network device from the management terminal of the one network device, when searching for the device names A name resolution processing unit that searches the address table as a keyword and returns the searched IP address to another network device and the management terminal,
Management communication is performed from the management terminal to the other network device and each device of the one network device for the purpose of setting change and status check management.

  According to the present invention, it is possible to connect from a management terminal to all devices using device names instead of IP addresses. In addition, it is possible to always keep the information associating the device name with the IP address in the latest state. Furthermore, the network topology is not limited to a ring shape, and the present invention can be applied to a star shape.

It is a figure which shows the ring type network comprised using the apparatus carrying this invention. It is a figure which shows the star type network comprised using the apparatus carrying this invention. It is an apparatus block diagram which shows Embodiment 1 of this invention. It is a flowchart which shows Embodiment 1 of this invention, and is a figure regarding an address memory | storage part. It is a flowchart which shows Embodiment 1 of this invention, and is a figure regarding an address change process part. It is a flowchart which shows Embodiment 1 of this invention, and is a figure regarding a name resolution process part. It is a flowchart which shows Embodiment 1 of this invention, and is a figure regarding a packet transmission / reception part. It is a sequence diagram which shows Embodiment 1 of this invention. It is an apparatus block diagram which shows Embodiment 2 of this invention. It is a flowchart which shows Embodiment 2 of this invention, and is a figure regarding an SNMP communication part. It is a flowchart which shows Embodiment 2 of this invention, and is a figure regarding a packet transmission / reception part. It is a sequence diagram which shows Embodiment 2 of this invention. It is an apparatus block diagram which shows Embodiment 3 of this invention. It is a flowchart which shows Embodiment 3 of this invention, and is a figure regarding a survival monitoring part. It is a flowchart which shows Embodiment 3 of this invention, and is a figure regarding an address memory | storage part. It is a flowchart (first half part) which shows Embodiment 3 of this invention, and is a figure regarding a packet transmission / reception part. It is a flowchart (latter half part) which shows Embodiment 3 of this invention, and is a figure regarding a packet transmission / reception part. It is a sequence diagram (first half part) which shows Embodiment 3 of this invention. It is a sequence diagram (latter half part) which shows Embodiment 3 of this invention. It is an apparatus block diagram which shows Embodiment 4 of this invention. It is a flowchart which shows Embodiment 4 of this invention, and is a figure regarding a survival monitoring part. It is a flowchart (first half part) which shows Embodiment 4 of this invention, and is a figure regarding a packet transmission / reception part. It is a flowchart (latter half part) which shows Embodiment 4 of this invention, and is a figure regarding a packet transmission / reception part. It is a sequence diagram (first half part) which shows Embodiment 4 of this invention. It is a sequence diagram (latter half part) which shows Embodiment 4 of this invention. It is an apparatus block diagram which shows Embodiment 5 of this invention. It is a flowchart which shows Embodiment 5 of this invention, and is a figure regarding an address change process part. It is a flowchart which shows Embodiment 5 of this invention, and is a figure regarding an address memory | storage part. It is a sequence diagram which shows Embodiment 5 of this invention. It is an apparatus block diagram which shows Embodiment 6 of this invention. It is a flowchart which shows Embodiment 6 of this invention, and is a figure regarding an SNMP communication part. It is a sequence diagram (first half part) which shows Embodiment 6 of this invention. It is a sequence diagram (latter half part) which shows Embodiment 6 of this invention.

Embodiment 1 FIG.
A first embodiment of the present invention will be described below with reference to FIG.
FIG. 1 is a diagram showing a network composed of a network device and one management terminal. The devices 101, 102, and 103 are network devices according to the present invention (hereinafter, these devices 101 to 103 are referred to as corresponding devices). The non-corresponding device 104 is a device not related to the present invention. The management terminal 100 is a PC or the like, and performs management communication by connecting to the devices 101, 102, and 103. All the corresponding devices and management terminals are connected by an IP network 121 (the non-compatible device 104 is also included in the IP network 121). In the above, the management communication means communication performed for the purpose of changing the setting of the network device and checking the state. Specifically, TELNET (Telecommunication network)
Change of network device settings by means of communication, acquisition of network device operation status by SNMP (Simple Network Management Protocol), which is communication for monitoring and controlling communication devices via the network, survival by Ping (Ping: Packet Internet Groper) Monitoring, etc.

According to the present invention, a management communication connection using a device name instead of an IP address (hereinafter referred to as an address) from the management terminal 100 to all the devices 101, 102, and 103 (in this case, management communication is executed between the management terminal and the network device). Specifically, when the management terminal is a PC (personal computer), a process of making a TELNET connection from the PC to the network device (the same applies hereinafter) is possible.
In FIG. 1, the network topology connecting the devices 101, 102, and 103 is a ring shape. However, in the present invention, the network topology is not limited to a ring shape (ring type network). As shown in FIG. 2, a star topology (star network) may be used.

FIG. 3 is a block diagram showing the components of the apparatuses 101, 102, and 103.
The apparatus 101 includes an address storage unit C1A, an address change processing unit C2, a name resolution processing unit C3, and a packet transmission / reception unit C4A. The address storage unit C1 holds an address table D1 therein. The address table D1 stores device names and address information corresponding to the devices.
The devices 102 and 103 do not have the name resolution processing unit C3, but include an address change processing unit C2 and a packet transmission / reception unit C4A.

Next, the role of each component in the apparatus will be described.
The address storage unit C1A manages device names and addresses (IP addresses) of a plurality of devices using the address table D1. Information registration in the address table D1 is performed by a notification from another function unit (meaning another component, the same applies hereinafter). When an address of a certain device is requested from another function unit, the address table D1 is searched using the device name as a keyword, and the found address is returned.
The address change processing unit C2 refers to an own device (where the own device refers to a device having the component inside when the component (function unit) is viewed. The own device for the address change processing unit C2 is 101. Further, the own device for C2 of the device 102 is 102. Furthermore, the own device for C2 of the device 103 is 103. The same applies hereinafter). When the address is changed, the address after the change is stored in the address storage unit C1A or another device that holds the address storage unit C1A (here, the other device is, for example, from the devices 101, 102, and 103 in FIG. Specifically, the other devices for the device 101 are the devices 102 and 103, and the other devices for the device 102 are the devices 101 and 103. Other apparatus I is an apparatus 101, 102. Performs change processing to notify the same) or less.
The name resolution processing unit C3 is a functional unit that processes a name resolution request from the management terminal 100 (the functional unit has the same meaning as the component. The same applies hereinafter). Upon receiving the name resolution request, the name resolution processing unit C3 An address corresponding to the device name is requested (in the above, “name” is an identification number). Then, the acquired address is returned to the management terminal 100 as a response. Here, the name resolution request and the response transmitted from the management terminal 100 are not in a format specially defined in the present invention, but based on the DNS standard.
The packet transmission / reception unit C4A performs packet communication with another device or the management terminal 100 via the IP network 121. A notification or request received from another device or the management terminal 100 is transmitted to each functional unit. And the response from each function part is transmitted to another apparatus or the management terminal 100.

Next, the operation of each component (functional unit) will be described with reference to a flowchart.
FIG. 4 shows a flowchart of the address storage unit C1A. When this component starts its operation, it waits for reception of a notification or request from another component (F102). When an address change notification is received (F103), the device name and address are registered in the address table D1 (F105), and the process returns to waiting for notification or request reception (F110).
When the name resolution request is received (F104), the address table D1 is searched using the device name as a key (F106), and when the search is hit (F107), the device name and address are transmitted to the name resolution processing unit C3 ( F108). If the search does not hit, a name resolution failure notification is transmitted to the name resolution processing unit C3 (F109).

  FIG. 5 shows a flowchart of the address change processing unit C2. When this component starts its operation, it waits for the address of its own device to be changed (F202). If the address has been changed, it is determined whether or not the address storage unit C1A is in its own device (F203). Then, if the address storage unit C1A is in its own device, an address change notification is transmitted to the address storage unit C1A (F204). If it is not present, the address change notification is transmitted to the packet transmitting / receiving unit C4A (F205). Thereafter, it waits for an address change again (F206).

  A flowchart of the name resolution processing unit C3 is shown in FIG. When this component starts operation, it waits for reception of a request from another component (F302). When the name resolution request is received (F303), the name resolution request is transmitted to the address storage unit C1A (F304). Then, it waits for a name resolution response from the address storage unit C1A (F305). When the response is received, the name resolution result is transmitted to the packet transmitting / receiving unit C4A (F306). Thereafter, it waits for receiving the request again (F307).

A flowchart of the packet transmitting / receiving unit C4A is shown in FIG. When this component starts its operation, it waits for reception of a notification, request, or result from another component (F402A). The address change notification is received (F403), and if the own device has the address storage unit C1A, the address change notification is transmitted to the address storage unit C1A. If the own device does not have the address storage unit C1A, an address change notification is transmitted to the other device (see F406).
When the name resolution request is received (F404), the name resolution request is transmitted to the name resolution processing unit C3 (F407). When the name resolution result is received (F405), the name resolution result is transmitted to the management terminal that has sent the name resolution request (F408). After the processing of the notification, request, and result is completed, it waits for reception again (F409).

Next, the operation of each device in the network shown in FIG. 1 or 2 will be described with reference to the sequence diagram shown in FIG.
A case will be described in which an address change operation is performed in the device 103 and then management communication is connected from the management terminal 100 to the device 103 using the device name. When an address change operation S301 is performed in the device 103, an address change notification S302 is transmitted from the device 103. In the address change notification S302, information on the device name and address of the device 103 is stored. When the device 101 receives the notification, the device name and address information of the device 103 is registered in the address table D1 in the device 101 (S101). Through these processes, new address information is registered in the address table D1 in the apparatus 101 immediately after the address of the apparatus 103 is changed.

Next, it is assumed that management communication with the device 103 is started in the management terminal 100. When management communication is started, connection processing S001 with the apparatus 103 is first performed. In order to connect to the device 103 from the management terminal 100, the address of the device 103 is required, but the management terminal 100 knows the device name of the device 103 but does not know the address.
In that case, the management terminal 100 makes an inquiry to the device 101 in order to obtain an address from the device name of the device 103. This inquiry is called a name resolution request S002 here. When the device 101 receives the name resolution request S002, the device 101 searches the address table D1 held by itself (S102), and acquires an address corresponding to the device name. Then, the acquisition result is transmitted to the management terminal 100 as a name resolution response S103. With these processes, the management terminal 100 can acquire an address from the device name of the device 103, and the connection S003 from the management terminal 100 to the device 103 becomes possible.

Embodiment 2. FIG.
In the first embodiment, any device that can be connected from the management terminal 100 using the device name has any one of the constituent elements C1A, C2, C3, and C4A. In the first embodiment, a device that does not have any of the constituent elements C1A, C2, C3, and C4A (non-compatible device 104) cannot be connected using the device name.

  In the second embodiment, a method for enabling connection to the non-compliant device 104 using the device name from the management terminal will be described. In this method, a device that implements the present invention acquires the address and device name of the non-compliant device 104 using SNMP (Simple Network Management Protocol) communication. SNMP communication is a communication protocol used to acquire the operating state of a network device. By using SNMP communication, the device name of a network device can be acquired. Then, by registering the acquired information in the aforementioned address table, the non-compatible device 104 can be connected using the device name.

FIG. 9 shows a block diagram of the apparatuses 101, 102, and 103. The apparatus 101 includes an address storage unit C1B, an address change processing unit C2, a name resolution processing unit C3, and a packet transmission / reception unit C4B. The devices 102 and 103 include an address storage unit C1B, an address change processing unit C2, a packet transmission / reception unit C4B, and an SNMP communication unit C5.
Among these, the address storage unit C1B, address change processing unit C2, and name resolution processing unit C3 have the same functions as the address storage unit C1A, address change processing unit C2, and name resolution processing unit C3 of the first embodiment. Here, the same function means a function that operates according to the same flowchart. Components having the same function are indicated by a one-dot chain line surrounded by a frame in FIG.

Next, the role of each component in the apparatus will be described. The description of the same components as those in Embodiment 1 is omitted.
The SNMP communication unit C5 acquires the device name of the non-compliant device 104 by performing SNMP communication with the non-compliant device 104. In the SNMP communication, the SNMP communication unit C5 operates as an SNMP manager, and the incompatible device 104 operates as an SNMP agent.

  In addition to the functions described in the first embodiment, the packet transmission / reception unit C4B has a function of performing SNMP communication with a non-compliant device in response to a request from the SNMP communication unit C5. In C4A of Embodiment 1 (see FIG. 7) and C4B of Embodiment 2 (see FIG. 11), the name is the same in the packet transmitting / receiving unit, but there are functionally different parts. There is a difference between whether an SNMP packet is not transmitted / received (Embodiment 1) or whether an SNMP packet is transmitted / received (Embodiment 2). The difference in effect due to this difference is whether or not SNMP communication can be executed. Since the C4B can recognize that the received packet is an SNMP packet as described in FIGS. 11, F411, and F412, an apparatus including the C4B can perform SNMP communication. On the other hand, since C4A cannot recognize that it is an SNMP packet, a device including C4A cannot perform SNMP communication).

  Next, the operation of each component will be described with reference to a flowchart. The description of the same components as those in Embodiment 1 is omitted.

A flowchart of the SNMP communication unit C5 is shown in FIG. When the operation starts, this component waits for a notification from another component (F502). When the SNMP reception notification is received (F503), it is determined whether the SNMP reception is a response to the device name request transmitted by the own device (F504).
In the case of a response to the device name request transmitted by the own device, the address change notification of the target device is transmitted to the address storage unit C1B (F506), and further the address change notification is transmitted to the packet transmitting / receiving unit C4B (F508).
When an SNMP reception notification is received (F503) and it is not a response to the device name request transmitted by the device itself (F504), a name resolution request is transmitted to the address storage unit C1B (F505). As a result, if the name resolution is not successful (F507), an SNMP device name request is transmitted to the packet transmitting / receiving unit C4B (F509).

  A flowchart of the packet transmitting / receiving unit C4B is shown in FIG. When starting operation, this component waits for reception of any of notifications, requests, results, and packets from other components (F402B). When the address change notification is received (F403), the address change notification is transmitted to the address storage unit C1 (F410). When the name resolution request is received (F404), the name resolution request is transmitted to the name resolution processing unit (F407). When the name resolution result is received (F405), the name resolution result is transmitted to the management terminal 100 that has sent the name resolution request (F408). When an SNMP packet is received (F411), an SNMP reception notification is transmitted to the SNMP communication unit (F413). When an SNMP device name request is received (F412), a device name is requested by SNMP communication to the target device (in this case, the non-compliant device 104 is applicable) (F414).

  Next, the operation of each device in the network shown in FIG. 1 or 2 will be described with reference to the sequence diagram shown in FIG. Here, a case will be described in which management communication is performed using the device name from the management terminal 100 to the non-compliant device 104 performing SNMP communication.

  When the non-compliant device 104 performs the SNMP communication S401, the SNMP packet S402 reaches the device 103. When the device 103 detects SNMP communication (S303), it confirms whether or not the source address of the SNMP communication packet is registered in the address table D2 held by the own device. If it is not registered in the address table D2 as a result of the confirmation, it is determined that a device that the device itself does not recognize has appeared, and tries to acquire the device name. The device name is acquired by acquiring MIB (Management Information Base) information of the non-compatible device 104 by SNMP communication. The device 103 makes a device name request S305 to the incompatible device 104 by SNMP communication. Then, the device name of the incompatible device 104 is acquired by the response S403. The acquired device name is registered in the address table D2 held by the device 103 together with the address (S306). Furthermore, the device 103 notifies the device 101 of the device name and address information of the incompatible device 104 to the device 101 as an address registration notification (S307).

  In response to the address registration notification from the device 103, the device 101 registers the device name and address of the incompatible device 104 in the address table D2 held by the device 101 (S104). By these processes, the device name and address of the non-compliant device 104 are registered in the address table D2 of the devices 101 and 103.

  When the management terminal 100 connects management communication to the non-compliant device 104, the management terminal 100 transmits the name resolution request S005 of the non-compliant device 104 to be connected to the device 101 as in the first embodiment. As a response, the management terminal 100 acquires the address of the non-compatible device 104 (S105). Through these processes, the management terminal 100 can be connected to the incompatible device 104 by the device name (S006).

Embodiment 3 FIG.
In the first embodiment, the information registered in the address table D1 continues to remain without being deleted even when the registered device is removed or communication is disabled.
In the third embodiment, a method of detecting a device that has become unable to communicate and deleting registration information of the device from the address table D1 will be described. In this embodiment, communication for survival monitoring is periodically performed for each device registered in the address table D1. The communication is, for example, Ping using ICMP (Internet Control Message Protocol). In this communication, if there is a response from the corresponding device, it is determined that communication is possible, and if there is no response, it is determined that communication is not possible. If a device in a communication disabled state is detected, the corresponding device is registered from the address table D1. Delete information.

  FIG. 13 shows a block diagram of the apparatuses 101, 102, and 103. The apparatus 101 includes an address storage unit C1C, an address change processing unit C2, a name resolution processing unit C3, a packet transmission / reception unit C4C, and a survival monitoring unit C6. The devices 102 and 103 include an address change processing unit C2 and a packet transmission / reception unit C4C. Among these, the address change processing unit C2 and the name resolution processing unit C3 have the same functions as those in the first embodiment. Constituent elements having the same function are indicated by a one-dot chain line surrounded by a frame in FIG.

Next, the role of each component in the apparatus will be described. The description of the same components as those in Embodiment 1 is omitted. The survival monitoring unit C6 periodically communicates with the monitoring target device for survival monitoring. In addition to the functions described in the first embodiment, the packet transmission / reception unit C4C has a function of transmitting / receiving a life monitoring packet to / from a monitoring corresponding device in response to a request from the life monitoring unit C6.
In addition to the function described in the first embodiment, the address storage unit C1C has a function of deleting registration of a corresponding device when the address monitoring deletion of a device is notified from the survival monitoring unit C6.

  Next, the operation of each component will be described with reference to a flowchart. The description of the same components as those in Embodiment 1 is omitted.

A flowchart of the survival monitoring unit C6 is shown in FIG.
When this component starts its operation, it waits for a notification from another component (F602).
When the survival monitoring start notification is received (F603), the survival monitoring of the target device is started (F605). The content is to transmit a survival monitoring request to the packet transmitting / receiving unit at a constant cycle (F605). When a survival monitoring timeout notification is received (F604), an address registration deletion notification is transmitted to the address storage unit C1 (F606).

FIG. 15 shows a flowchart of the address storage unit C1C.
When this component starts its operation, it waits for reception of a notification or request from another component (F102). When an address change notification is received (F103), the device name and address are registered in the address table D1 (F105), and a survival monitoring start notification is transmitted to the survival monitoring unit (F113).
When the name resolution request is received (F104), the address table D1 is searched using the device name as a key (F106), and when the search is hit (F107), the device name and address are transmitted to the name resolution processing unit C3 ( F108). If the search does not hit, a name resolution failure notification is transmitted to the name resolution processing unit C3 (F109). When the address registration deletion notification is received (F111), the registration of the corresponding device is deleted from the address table D1 (F112).

The flowcharts of the packet transmitting / receiving unit C4C are shown in FIGS.
When this component starts its operation, it waits for reception of a notification, request, or result from another component (F402). The address change notification is received (F403), and if the own device has the address storage unit C1C, the address change notification is transmitted to the address storage unit C1C. If the own device does not have the address storage unit C1C, an address change notification is transmitted to the other device (F406).
When the name resolution request is received (F404), the name resolution request is transmitted to the name resolution processing unit C3 (F407). When the name resolution result is received (F405), the name resolution result is transmitted to the management terminal that has sent the name resolution request (F408).

  When a survival monitoring request is received (F415), a survival monitoring packet is transmitted to the target device (F416). If there is no response to the packet transmission within a certain time (F417), a survival monitoring timeout notification is transmitted to the survival monitoring unit C6 (F418).

Next, the operation of each device in the network shown in FIG. 1 or 2 will be described with reference to sequence diagrams shown in FIGS.
An address change operation is performed in the device 103, and the address information of the device 103 is registered in the device 101. After that, the communication of the device 103 is described. In the example shown here, the device 101 detects that the communication of the device 103 has been stopped by viability monitoring, and deletes it from its own address table D1.
When the address change operation S301 is performed in the device 103, an address change notification S302 is transmitted from the device 103, and the device name and address information of the device 103 is registered in the device 101 (S101). The processing so far is the same as in the first embodiment.

  In the third embodiment, the device 101 starts alive monitoring of the device 103 after executing the address registration S101 (S106). As the liveness monitoring, the device 101 transmits a liveness monitoring request to the device 103 at regular intervals (S107). Upon receiving the survival monitoring request S107, the device 103 transmits a survival monitoring response S308. By these processes, the apparatus 101 continues to monitor that the apparatus 103 is in a communicable state.

  Next, it is assumed that management communication with the device 103 is started in the management terminal 100. When management communication is started, connection processing S001 with the apparatus 103 is first performed. From here, the processing until the management terminal 100 connects to the device 103 at S003 is the same as that described in the first embodiment.

  Assume that the communication of the device 103 is stopped after the management communication between the management terminal 100 and the device 103 is completed (S309). Then, the survival monitoring response S308 from the device 103 is not returned in response to the survival monitoring request S107 of the device 101 (S108). Accordingly, the apparatus 101 detects that the apparatus 103 has become unable to communicate. Then, the device 101 deletes the registration information of the device 103 from the address table D1 in the device 101 (S109).

Embodiment 4 FIG.
In the third embodiment, the device 101 that performs the life monitoring transmits the communication for the life monitoring at a constant cycle. In the fourth embodiment, the device 101 performs the life monitoring without transmitting the communication for the life monitoring. How to do. When the number of devices to be monitored increases, the communication for survival monitoring transmitted by the monitoring device (device 101) increases in the third embodiment, but the communication for survival monitoring increases in the fourth embodiment. A large number of devices can be monitored without causing them to occur.

FIG. 20 shows a block diagram of the apparatuses 101, 102, and 103.
The apparatus 101 includes an address storage unit C1A, an address change processing unit C2, a name resolution processing unit C3, a packet transmission / reception unit C4D, and a survival monitoring unit C6.
The devices 102 and 103 include an address change processing unit C2 and a packet transmission / reception unit C4D. Among these, the address change processing unit C2 and the name resolution processing unit C3 have the same functions as those in the first embodiment. Components having the same function are indicated by a one-dot chain line surrounded by a frame in FIG.

  Next, the role of each component in the apparatus will be described. The description of the same components as those in Embodiment 1 is omitted. The survival monitoring unit C6 snoops and monitors the packet transmitted by the device to be monitored. Then, when the device to be monitored transmits a packet, it is determined that the target device is in a communicable state. In addition to the functions described in the first embodiment, the packet transmitting / receiving unit C4D has a function of snooping the communication of the monitoring compatible device in response to a request from the survival monitoring unit C6 (here, snooping is “ To peek ").

Next, the operation of each component will be described with reference to a flowchart. The description of the same components as those in Embodiment 1 is omitted. A flowchart of the survival monitoring unit C6 is shown in FIG.
When this component starts its operation, it waits for a notification from another component (F602). When the survival monitoring start notification is received (F603), the target device snooping start notification is transmitted to the packet transmitting / receiving unit C4D (F608). When the survival monitoring timeout notification is received (F604), an address registration deletion notification is transmitted to the address storage unit C1A (F606).

The flowcharts of the packet transmitting / receiving unit C4D are shown in FIGS.
When the operation starts, this component determines whether or not snooping is being executed (F421). If snooping is being performed, if the source IP address is snooping, it is determined whether a certain time has elapsed since the last packet whose source IP address is the snooping target device is received ( F422). If the predetermined time has elapsed, a survival monitoring timeout notification is transmitted to the survival monitoring unit (F424). If the predetermined time has not elapsed or if snooping is not executed, it is determined whether any notification, request, or result has been received from another component (F423).

The address change notification is received (F403), and if the own device has the address storage unit C1A, the address change notification is transmitted to the address storage unit C1A. If the own device does not have the address storage unit C1A, an address change notification is transmitted to the other device (F406).
When the name resolution request is received (F404), the name resolution request is transmitted to the name resolution processing unit C3 (F407). When the name resolution result is received (F405), the name resolution result is transmitted to the management terminal that has sent the name resolution request (F408).

  When the snooping start notification is received (F419), the snooping of communication transmitted by the target device is performed. If the target device does not receive the transmission source packet even after a predetermined time has elapsed, a survival monitoring timeout notification is transmitted to the survival monitoring unit C6 (F420).

  Next, the operation of each device in the network shown in FIG. 1 or 2 will be described with reference to the sequence diagrams shown in FIGS.

  An address change operation is performed in the device 103, and the address information of the device 103 is registered in the device 101. After that, the communication of the device 103 is described. In the example shown here, the device 101 detects that the communication of the device 103 has been stopped by viability monitoring, and deletes it from its own address table D1.

  When the address change operation S301 is performed in the device 103, an address change notification S302 is transmitted from the device 103, and the device name and address information of the device 103 is registered in the device 101 (S101). The processing so far is the same as in the first embodiment.

  In the third embodiment, after the device 101 executes the address registration S101, the survival monitoring of the device 103 is started (S106). As alive monitoring, the device 101 performs snooping of communication performed by the device 103. The communication monitored at this time is communication performed by the device 103 with respect to the device 101 or communication with another device or another management terminal. When the device 103 receives the source packet S310 by the device 101, the device 101 determines that the device 103 is in a communicable state. If the device 101 does not receive a packet from the device 103 even after a predetermined time has elapsed, it is determined that the device 103 cannot communicate.

  Next, it is assumed that management communication with the device 103 is started in the management terminal 100. When management communication is started, connection processing S001 with the apparatus 103 is first performed. From here, the processing until the management terminal 100 connects to the device 103 at S003 is the same as that described in the first embodiment.

  Assume that after the management communication between the management terminal 100 and the device 103 is completed, the device 103 is in a communication stop state (S309). Then, the device 101 does not receive a packet from the device 103 even after a predetermined time elapses, and detects that the device 103 has become unable to communicate (S108). Then, the device 101 deletes the registration information of the device 103 from the address table D1 in the device 101 (S109).

Embodiment 5 FIG.
In the fourth embodiment, the amount of communication transmitted by the monitoring device (device 101) can be reduced compared to the third embodiment, but monitoring is performed by snooping packets transmitted by the monitoring target device. When the frequency of communication performed by the monitored device is low, there is a problem that it is difficult to determine whether the monitored device is in a communication disabled state or whether it is in a communication enabled state but not communicating is there. In order to solve this problem, the fifth embodiment notifies that the device itself is in a communicable state by periodically communicating from the device to be monitored.

  FIG. 26 shows a block diagram of the apparatuses 101, 102, and 103. The apparatus 101 includes an address storage unit C1A, an address change processing unit C2, a name resolution processing unit C3, and a packet transmission / reception unit C4E. The devices 102 and 103 include an address change processing unit C2 and a packet transmission / reception unit C4E. Among these, the name resolution processing unit C3 and the packet transmitting / receiving unit C4E have the same functions as the packet transmitting / receiving unit C4A of the first embodiment. Components having the same functions as those of the first embodiment are indicated by a one-dot chain line surrounded by a frame in FIG.

  Next, the role of each component in the apparatus will be described. The description of the same components as those in Embodiment 1 is omitted.

  The address change processing unit C2 notifies the address of the own device to the address storage unit C1 or another device holding the address storage unit C1 at regular intervals. In addition to the functions described in the first embodiment, the address storage unit C1 determines that the corresponding device has become incapable of communication unless an address is notified within a certain time from the device registered in the address table D1. It has a function of deleting registration from the address table D1.

Next, the operation of each component will be described with reference to a flowchart.
FIG. 27 shows a flowchart of the address change processing unit C2. When this component starts operating, it determines whether the address storage unit C1A is in its own device (F203). Then, if the address storage unit C1A is in its own device, an address change notification is transmitted to the address storage unit C1A (F204). If it is not present, the address change notification is transmitted to the packet transmitting / receiving unit C4E (F205). After a predetermined time has elapsed, the process returns to the start of the flowchart (F201) (F206), and the above-described processing is repeated.

FIG. 28 shows a flowchart of the address storage unit C1A.
When this component starts its operation, it waits for reception of a notification or request from another component (F102). When the address change notification is received (F103), the device name and address are registered in the address table D1 (F105). When the name resolution request is received (F104), the address table D1 is searched using the device name as a key (F106), and when the search is hit (F107), the device name and address are transmitted to the name resolution processing unit C3 ( F108). If the search does not hit, a name resolution failure notification is transmitted to the name resolution processing unit C3 (F109). If the address change notification is not received within a certain time (F114), the registration of the target device is deleted from the address table (F115).

  Next, the operation of each device in the network shown in FIG. 1 or 2 will be described with reference to the sequence diagram shown in FIG.

  A case where the address information of the device 103 is registered in the device 101 and then the communication of the device 103 is stopped will be described. In the example shown here, the device 101 detects that the communication of the device 103 has been stopped by viability monitoring, and deletes it from its own address table D1. Unlike the first embodiment, the device 103 continues to transmit the address change notification S302 at a constant cycle without performing an address change operation. By receiving the notification, the device 101 registers the device name and address information of the device 103 (S101).

Next, it is assumed that management communication with the device 103 is started in the management terminal 100. When management communication is started, connection processing S001 with the apparatus 103 is first performed. From here, the processing until the management terminal 100 connects to the device 103 at S003 is the same as that described in the first embodiment.

  Assume that the communication of the device 103 is stopped after the management communication between the management terminal 100 and the device 103 is completed (S309). Then, the apparatus 101 does not receive the address change notification S302 from the apparatus 103 even after a predetermined time has elapsed, and detects that the apparatus 103 has become unable to communicate. Then, the device 101 deletes the registration information of the device 103 from the address table D1 in the device 101 (S109).

Embodiment 6 FIG.
In the above-described fifth embodiment, the device that can monitor the communication state is only a device equipped with a function for realizing the present invention, and the communication state of the incompatible device 104 cannot be monitored. In the sixth embodiment, a method for monitoring the communication state of the incompatible device 104 will be described.

  FIG. 30 shows a block diagram of the apparatuses 101, 102, and 103. The apparatus 101 includes an address storage unit C1D, an address change processing unit C2, a name resolution processing unit C3, and a packet transmission / reception unit C4F. The devices 102 and 103 include an address storage unit C1D, an address change processing unit C2, a packet transmission / reception unit C4F, and an SNMP communication unit C5. Among these, the address change processing unit C2, the name resolution processing unit C3, and the packet transmitting / receiving unit C4F have the same functions as those in the second embodiment. Components having the same function are indicated by a one-dot chain line surrounded by a frame in FIG.

  Next, the role of each component in the apparatus will be described. Description of the same components as those in Embodiment 2 is omitted. In addition to the functions described in the second embodiment, the address storage unit C1D is in a state where the corresponding device cannot communicate unless an address is notified within a predetermined time from the address registration notification for the device registered in the address table D2. And has a function to delete the registration from the address table D2. The SNMP communication unit C5 acquires the device name of the non-compliant device 104 by performing SNMP communication with the non-compliant device 104.

  Next, the operation of each component will be described with reference to a flowchart. Description of the same components as those in Embodiment 2 is omitted. FIG. 31 shows a flowchart of the SNMP communication unit C5. When this component starts its operation, it waits for a notification from another component (F502). When the SNMP reception notification is received (F503), it is determined whether the SNMP reception is a response to the device name request transmitted by the own device (F504). In the case of a response to the device name request transmitted by the own device, an address change notification of the target device is transmitted to the address storage unit C1D (F506), and further an address change notification is transmitted to the packet transmitting / receiving unit C4F (F508). When an SNMP reception notification is received (F503) and it is not a response to the device name request transmitted by the device itself (F504), an SNMP device name request is transmitted to the packet transmitting / receiving unit C4F (F509). The flowchart of the address storage unit C1D is the same as FIG. 28 shown in the fifth embodiment.

  Next, the operation of each device in the network shown in FIG. 1 or FIG. 2 will be described with reference to sequence diagrams shown in FIGS.

A case where the non-compliant device 104 that performs SNMP communication stops communicating will be described.
When the non-compliant device 104 performs the SNMP communication S401, the device name and address of the non-compliant device 104 are registered in the address table D2 of the devices 101 and 103 by the processing described in the second embodiment.

  In the sixth embodiment, when the device 103 receives the SNMP packet S402 from the non-compliant device 104, the device 103 always performs the registration process. If the device 103 does not receive the SNMP packet S402 from the non-compliant device 104 within a certain time, the device 103 determines that the non-compliant device 104 has stopped communicating, and deletes the corresponding address registration.

Management communication connection processing from the management terminal 100 to the non-compliant device 104 is the same as that described in the second embodiment. It is assumed that after the management communication between the management terminal 100 and the non-compliant device 104 is completed, the non-compliant device 104 is in a communication stopped state (S404). Then, the SNMP packet S402 is not received from the non-compliant device 104. Therefore, the device 103 detects that the incompatible device 104 has become unable to communicate, and deletes the registration information of the incompatible device 104 from the address table D2 in the device itself (S311). Furthermore, the device 103 transmits an address registration deletion notification S312 to the device 101. Upon receiving the notification, the device 101 also deletes the registration information of the non-compliant device 104 from the address table D2 (S110).
It should be noted that the present invention can be freely combined with each other within the scope of the invention, and each embodiment can be appropriately modified or omitted.

  100 management terminal, 101, 102, 103 device, 104 non-compliant device, 121 IP network, C1, C1A, C1B, C1C, C1D address storage unit, C2 address change processing unit, C3 name resolution processing unit, C4, C4A, C4B C4C, C4D, C4E, C4F packet transmission / reception unit, C5 SNMP communication unit, C6 survival monitoring unit.

Claims (7)

An address storage unit having an address table in which a device name of one network device is associated with an IP address;
An address change processing unit for notifying and processing the setting information of the IP address as the IP address change information to the address storage unit or another network device in the device of the one network device;
When receiving a name resolution request for requesting the IP address to correspond to the device names of the other network device and the one network device from the management terminal of the one network device, when searching for the device names A name resolution processing unit that searches the address table as a keyword and returns the searched IP address to another network device and the management terminal,
A network device that performs management communication for setting change and status check management from the management terminal to each of the other network device and the one network device.   By acquiring each device name of the other network device by SNMP communication which is a protocol communication for monitoring and controlling the communication device from the other network device, the address table of the one network device, and the one The device name and the IP address of each device of the other network device can be registered in the address table of the network device other than the network device, and the management communication can be executed from the management terminal to the other network device. 2. The network device according to claim 1, wherein a management communication connection, which is a connection to be made in order to achieve a proper state, is performed.   Whether or not a device registered in each address table is in a communicable state is monitored and communicated as a survival state whether or not an IP address corresponding to each device name is registered in each address table. The registration of the registered device is deleted from each of the address tables when the registered device is periodically monitored by alive monitoring communication and the registered device becomes unable to communicate. The network device described.   Whether the registered device in each address table is in a communicable state is monitored by snooping a packet transmitted by the registered device, and the registered device becomes incapable of communication 3. The network device according to claim 2, wherein the registration of the registered device is deleted from each address table.   2. The IP address setting information is periodically transmitted to the other network device to notify the other network device that the network device is in a communicable state. The network device described.   When the notification of the setting information of the IP address is no longer received from the other network device, it is detected that the other network device has become unable to communicate, and the other information registered in the address table is detected. The network device according to claim 1, wherein the registration of the network device is deleted.   By periodically acquiring the device name from the other network device, the communication status of the other network device is monitored, and if communication with the other network device is interrupted, the other network device cannot communicate. 3. The network device according to claim 2, wherein the network device is determined to have entered a state, and the registration of the other network device registered in the address table is deleted.

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