JP2013210796A - System and program for constructing redundancy - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce workload for installation of OS and an application in a server configuring a cluster and network setting.SOLUTION: The present invention is a redundancy construction system to construct redundancy by mounting a server to a mounting part of backboard control means. Respective servers are connected via a network for mutually transferring information. A server newly mounted detects a location of a mounting part on which the server is mounted, assigns address information according to the detected location of the mounting part, and obtains data necessary to operate a server via the network from another server.

Description

  The present invention relates to a redundancy construction system and a redundancy construction program, and can be applied to, for example, a redundancy construction system and a redundancy construction program for constructing a redundancy system in an IP-PBX system.

  Generally, a computer server performs main processing such as telephone exchange in the IP-PBX system. Therefore, computer servers may be clustered to ensure high availability.

  Here, clustering means that one system is constructed using two or more servers, and if one server fails, such as a failure, other servers can continue the service. It is a system.

  For example, Patent Document 1 describes a redundant system constructed with two servers. When a failure occurs in the active server, the logical address information of the active server is released and the logical address information is released. After the server is set as a standby server, the system switching process is shown.

JP 2009-118063 A

  By the way, in order to construct a clustering system, it is necessary to install an OS, an application such as clustering or telephone exchange, etc. on each server constituting the system, and further, according to the use environment of the system. Therefore, it is necessary to perform network settings such as TCP / IP. This is the same not only when building a clustering system but also when replacing a failed server. In other words, when a failed server is replaced, it is necessary to install an OS, an application, etc., network settings, etc. on the new server.

  However, the operation of building a server generally takes time and labor, and there may be many items to be set depending on the network and system operating environment. The server construction work takes about one to several days including the operation check.

  Therefore, there is a need for a redundancy construction system and a redundancy construction program that can reduce the burden of installing OS and applications on a server and network setting.

  In order to solve such a problem, the first aspect of the present invention is a redundancy construction system in which a server is attached to any of a plurality of attachment units included in a backboard control unit to construct redundancy having a plurality of servers. The server includes network interface means for exchanging information with other servers through the network, and storage means for storing at least information necessary for server operation, and the new server is attached to any of the attachment portions. In this case, the new server includes a mounting position detection unit that detects the position of the mounting unit to be mounted, and an address that provides address information to the network interface unit according to the position of the mounting unit detected by the mounting position detection unit. The other server mounted on the mounting unit has an information setting unit and duplicates the information stored in the storage unit. And an information acquisition means for storing the information acquired from the other server in the storage means, the data transfer means for transferring the information copied by the copying means to a new server through the network. It is the redundant construction system characterized by having.

  According to a second aspect of the present invention, there is provided a redundancy construction program for constructing redundancy having a plurality of servers by attaching a server to any of the plurality of attachment units of the backboard control means. A computer equipped with network interface means for exchanging information and at least storage means for storing information necessary for server operation is mounted by a mounting position detecting means and a mounting position detecting means for detecting the position of the mounting portion to be mounted. Address information setting means for assigning address information to the network interface means according to the detected position of the mounting portion, information stored in the storage means by another server mounted on the mounting portion, and the acquired information Is made to function as an information acquisition means for storing the information in the storage means of its own server. Is a program.

  According to the present invention, it is possible to reduce the work load of OS and application installation and network setting on the server.

It is a block diagram which shows the structure of the server apparatus of embodiment. It is explanatory drawing explaining the connection structure between the backboard part and each blade apparatus in the server apparatus of embodiment. It is a block diagram which shows the whole structure of the voice communication network of embodiment, and the internal structure of an IP-PBX server blade apparatus. It is an internal block diagram which shows the internal structure of the IP-PBX server blade apparatus of embodiment. It is a block diagram which shows the structure of the server specific data of embodiment. It is a flowchart which shows the operation | movement in the case of exchanging the IP-PBX server blade apparatus in the server apparatus of embodiment.

(A) Main Embodiment Hereinafter, a main embodiment of the redundancy construction system and the redundancy construction program of the present invention will be described in detail with reference to the drawings.

  In this embodiment, a case where the present invention is applied to a system in which a plurality of IP-PBX servers for controlling voice communication are provided to construct clustering is illustrated.

(A-1) Configuration of Embodiment FIG. 1 is a configuration diagram showing the configuration of the server device of this embodiment. 1, the server apparatus 5 of this embodiment includes a plurality (two in FIG. 1) of IP-PBX server blade apparatuses 1-1 and 1-2, and a plurality (two in FIG. 2) of L2 (layer 2). The switch blade devices 2-1 and 2-2, a plurality (two in FIG. 2) of telephone accommodating blade devices 3-1 and 3-2, and a backboard unit 4 are configured.

  The IP-PBX server blade apparatuses 1-1 and 1-2 perform voice communication control for the accommodated telephones. The voice communication function by the IP-PBX server blade apparatuses 1-1 and 1-2 is not particularly limited, and an existing voice communication function can be applied. For example, voice communication using SIP (Session Initiation Protocol) Take control.

  The L2 switch blade devices 2-1 and 2-2 perform layer 2 switch processing.

  The telephone accommodating blade devices 3-1 and 3-2 perform line processing with the accommodated telephone.

  The server device 5 takes the form of a so-called board computer, and is a unit device on which a plurality of blade devices serving as a base (so-called card board) can be mounted.

  In the example of FIG. 1, the IP-PBX server blade devices 1-1 and 1-2, the L2 switch blade devices 2-1 and 2-2, and the telephone accommodating blade devices 3-1 and 3-2 are the blade devices. The server device 5 is equipped with these blade devices.

  As long as a plurality of blade devices can be mounted on the server device 5, the structure thereof is not particularly limited and can take various structures. For example, in this embodiment, the case where the server apparatus 5 is a shelf structure is illustrated. Further, the server device 5 having the shelf structure is assumed to adopt a hardware specification defined in, for example, ATCA (Advanced Telecom Computing Architecture).

  The server device 5 includes a plurality of IP-PBX server blade devices 1-1 and 1-2, and constructs clustering between the IP-PBX server blade devices 1-1 and 1-2. Furthermore, the server device 5 is also equipped with L2 switch blade devices 2-1 and 2-2 that constitute a voice communication network, and telephone housing base blade devices 3-1 and 3-2 that house telephones.

  FIG. 2 is an explanatory diagram illustrating a connection configuration between the backboard unit 4 and each blade device in the server device 5 of this embodiment. As shown in FIG. 2, the server device 5 is controlled so that information can be exchanged between the slot unit 41 in which each blade device, which is a card board, is mounted, and the blade device connected to the slot unit 41. The control part 42 which has.

  As shown in FIG. 2, the blade device to be mounted is completed by inserting the blade device mounting portion into the slot portion 41 of the backboard portion 4.

  Here, it is assumed that the server apparatus 5 has a fixed position for mounting the IP-PBX server blade apparatus 1-1 and the IP-PBX server blade apparatus 1-2 for constructing the clustering.

  That is, the mounting position of the server blade device constituting the clustering is determined in advance. For example, in the case of FIG. 1, the first and second positions from the left side of FIG. 1 are the mounting positions of the IP-PBX server blade device. The mounting positions need not be adjacent. For example, in the example of FIG. 1, the first position on the left side and the first position on the right side in FIG.

  Further, the number of server blade devices constituting the clustering may be three or more. In this case, the mounting position of the server blade device corresponding to the number of clustering is determined in advance.

  The L2 switch blade devices 2-1 and 2-2 and the telephone housing base blade devices 3-1 and 3-2 are other than the mounting positions of the IP-PBX server blade devices 1-1 and 1-2 for constructing the clustering. Mounted in position.

  FIG. 3 is a configuration diagram showing the overall configuration of the voice communication network of this embodiment and the internal configurations of the IP-PBX server blade apparatuses 1-1 and 1-2.

  In FIG. 3, the IP-PBX server blade apparatuses 1-1 and 1-2 have a dedicated network interface unit 11, an external network interface unit 12, and a control unit 13.

  As shown in FIG. 3, the IP-PBX server blade apparatuses 1-1 and 1-2 include a dedicated network interface unit 11 and an external network interface unit 12 as two types of network interface units.

  The dedicated network interface unit 11 is connected to a dedicated network directly connected to another IP-PBX server blade device that constructs clustering. The dedicated network interface unit 11 is not connected to an external network, and exchanges information only with other IP-PBX server blade devices.

  Here, since the dedicated network does not depend on the external network, a fixed IP address is assigned to the dedicated network interface unit 11.

  The external network interface unit 12 is connected to an external network via the L2 switch blade devices 2-1 and 2-2 and accommodates the telephones 6-1 to 6-3. This external network is also called a service network.

  The external network interface unit 12 is assigned a unique physical IP address to each of the IP-PBX server blade apparatuses 1-1 and 1-2.

  The external network interface unit 12 is given a logical logical IP address. This logical IP address is set only for the IP-PBX server blade apparatuses 1-1 and 1-2 that operate as the active system. Accordingly, the telephones 6-1 to 6-3 to be accommodated, the intervening switch blade apparatuses 2-1 and 2-2, and the like use the logical logical IP address, and the IP-PBX server blade apparatus 1-1. And 1-2.

  The control unit 13 performs the function of the IP-PBX server blade device 1. The control unit 13 includes, for example, a CPU, a ROM, a RAM, an EEPROM, an input / output interface, and the like, and functions as the IP-PBX server blade device 1 when the CPU executes a processing program stored in the ROM. Realized.

  The control unit 13 performs voice communication control processing as an IP-PBX server, server construction processing when a new IP-PBX server blade device 1 is mounted on the server device 5, and the like.

  FIG. 4 is an internal configuration diagram showing an internal configuration of the IP-PBX server blade device 1.

  Note that the IP-PBX server blade apparatuses 1-1 and 1-2 perform the same function, but depending on whether they are newly installed in the server apparatus 5 this time or not, as will be described later. The operations performed by the IP-PBX server blade device are different. Therefore, in FIG. 4, for convenience of explanation, it is assumed that the IP-PBX server blade device 1-1 is already installed in the server device 5, and the IP-PBX server blade device 1-2 is newly installed in the server device 5 this time. It will be described as a thing.

  As shown in FIG. 4, the IP-PBX server blade devices 1-1 and 1-2 include a slot position detection unit 111, an own device operation setting unit 112, an already mounted operation unit 113, a mounting operation unit 114, and voice communication control. Part 115 and storage part 116.

  The slot position detection unit 111 detects the position of the slot 41 of the server apparatus 5 in which the IP-PBX server blade apparatus itself is mounted.

  Here, the own device (IP-PBX server blade device) 1 does not recognize which slot 41 of the server device 5 is installed. Therefore, when the device 1 is installed in the slot 41, the slot position detection unit 111 detects which slot 41 is installed based on a signal from the backboard unit 4.

  Here, as a method of detecting the position of the slot 41 by the slot position detection unit 111, the following method can be applied.

  For example, it is assumed that two clusters are constructed, and the server apparatus 5 has two slots for mounting the slot 41 IP-PBX server blade apparatuses 1-1 and 1-2 for constructing the clustering.

  Here, the slot in which the already-installed IP-PBX server blade device is installed is referred to as “slot # 0”, and the slot in which the new IP-PBX server blade device is replaced and installed is referred to as slot # 1.

  When the IP-PBX server blade device 1 is installed in the slot 41, the slot position detection unit 111 makes a determination based on a signal to the pin inserted into the slot 41.

  For example, if the pin signal is “H”, the slot position detection unit 111 determines that the installed slot 41 is “slot # 0”, and if it is “L”, the installed slot 41 is “slot # 1”. It is judged that.

  Here, as a setting method of the pin signal of the backboard unit 4, the control unit 42 of the backboard unit 4 sets the pin signal of the slot 41 into which the IP-PBX server blade device 1 is inserted / removed to “H” or “L”. May be set in advance.

  Based on the detection result of the slot position detection unit 111, the own device operation setting unit 112 determines whether the own device 1 is a newly attached device or an already attached device. Set the operation mode.

  For example, if the own device operation setting unit 112 determines that the slot position detection unit 111 determines that it is slot # 0, the own device operation setting unit 112 recognizes that the own device is the already installed IP-PBX server blade device 1-1, and If it is determined that the IP-PBX server blade apparatus 1-2 is newly installed, the local apparatus recognizes that the own apparatus is newly installed.

  The already-installed operation unit 113 is an operation function performed by the already installed IP-PBX server blade apparatus 1-1. For example, when it receives a command input by an operation of a user or the like, it operates as a start-up operation unit 113.

  The mounting operation unit 114 is an operation function performed by the IP-PBX server blade device 1-2 newly mounted this time.

  Note that the IP-PBX server blade apparatuses 1-1 and 1-2 have both functions of the already-installed operation unit 113 and the mounted operation unit 114, and operate by switching any operation mode.

  The already mounted operation unit 113 transfers the data copied by the data copy unit 71 to the other IP-PBX server blade device 1 through the dedicated network. And a transfer unit 72.

  The mounting operation unit 114 acquires data received through the dedicated network, stores the acquired data in the storage unit 116, and an activation unit 75 that is activated based on the data stored in the storage unit 116. And have.

  The storage unit 116 stores, for example, data such as OS, application data, telephone terminal information (station data), server-specific data of the IP-PBX server blade apparatuses 1-1 and 1-2, and the like. The storage unit 116 holds data as common data in the IP-PBX server blade apparatuses 1-1 and 1-2.

  Here, the server specific data is data specific to the IP-PBX server blade apparatuses 1-1 and 1-2 mounted on the server apparatus 5. That is, the data is specific to the server that constructs the clustering.

  Specifically, the server-specific data is, for example, the IP address, subnet mask, and default gateway of each network interface unit. Further, a host name, OS serial number (PID: product number), and the like may be included.

  Here, each network interface unit described above is a network interface unit included in the IP-PBX server blade apparatuses 1-1 and 1-2, and includes at least address information of the external network interface unit 12. Since the subnet mask and the default gateway are common to both the IP-PBX server blade apparatuses 1-1 and 1-2, the server-specific data substantially indicates an IP address.

  FIG. 5 is a configuration diagram showing a configuration of server-specific data. As shown in FIG. 5, the server unique data is unique data of both the IP-PBX server blade apparatuses 1-1 and 1-2.

  FIG. 5A shows server-specific data of the IP-PBX server blade device 1-1, and FIG. 5B shows server-specific data of the IP-PBX server blade device 1-2.

  “TYPE” is a data identification field. “TYPE” is a unique data identifier, and the IP-PBX server blade device 1 identifies which server is unique data based on the unique data identifier.

  “I / F1” is an interface data field. This is data related to the dedicated network interface unit 11 of the IP-PBX server blade device 1.

  “I / F2” is an interface data field. This is data related to the physical IP address of the external network interface unit 12 of the IP-PBX server blade device 1.

  “I / F2: 0” is an interface data field. This data is related to the logical IP address of the external network interface unit 12 of the IP-PBX server blade device 1. “I / F2: 0” is a setting clause relating to an interface that is physically the same as “I / F2”. “I / F2: 0” is set as an alias.

  “HOSTNAME” is a host name field. This is data relating to the host name of the IP-PBX server blade device 1.

  “SERIAL_NUMBER” is a serial number field. This is data related to the OS serial number.

  In other words, the IP-PBX server blade device 1 determines whether the own device operation setting unit 112 is the IP-PBX server blade device 1-1 or the IP-PBX server based on the detection of the slot position by the slot position detection unit 111. It is determined whether the blade device is 1-2.

  Then, the own device operation setting unit 112 identifies the unique data corresponding to the own device 1 with “TYPE”, and if there is a match, sets the server itself with the contents of each data field.

  The voice communication control unit 115 performs voice communication control using SIP, for example.

(A-2) Operation | movement of embodiment Next, operation | movement in the server apparatus 5 of this embodiment is demonstrated, referring drawings.

  FIG. 6 is a flowchart showing an operation when the IP-PBX server blade device 1 is replaced in the server device 5.

  The server device 5 constructs clustering using two IP-PBX server blade devices 1-1 and 1-2. There are slot # 0 and slot # 1 as slots 41 in which servers for constructing the cluster are installed.

  An IP-PBX server blade device 1-1 is installed in the slot # 0, and an IP-PBX server blade device 1-2 is installed in the slot # 0.

  In the following, an example will be described in which the IP-PBX server blade device 1-2 installed in the slot # 1 fails and is newly replaced with another IP-PBX server blade device 1-2.

  A new IP-PBX server blade device 1-2 is installed in slot # 1 of the server device 5 (S101). At this time, the new IP-PBX server blade device 1-2 is not activated only by being installed in the slot 41.

  Note that the IP-PBX server blade device 1-1 installed in the slot # 0 receives, for example, a built-in operation such as inputting a command indicating that it operates as an already installed device. As a result, the IP-PBX server blade apparatus 1-1 can perform the operation of the already mounted operation unit 13.

  When the IP-PBX server blade device 1-2 is installed in the slot # 1, in the IP-PBX server blade device 1-2, the slot position detection unit 111 detects a pin signal from the backboard unit 4 (S102). ), Which slot 41 is installed is detected (S103).

  For example, if the pin signal is “H” and the slot is # 0, and the pin signal is “L” and the slot is # 1, the control unit 42 of the backboard unit 4 is connected to the slot # 1. A pin signal of “L” is given to. When the slot position detection unit 111 of the IP-PBX server blade apparatus 1-2 installed in the slot # 1 detects the pin signal “L”, the slot 41 in which the apparatus is installed is “slot # 1”. Recognize

  In the IP-PBX server blade device 1-2, the own device operation setting unit 112 determines the IP-PBX server blade device 1-2 installed in the slot # 1 based on the slot position detected by the slot position detection unit 111. (S104).

  Then, the own device operation setting unit 112 gives the IP address of the IP-PBX server blade device 1-2 to the dedicated network interface unit 11 (S105).

  For example, in the case of the example of FIG. 3, the IP-PBX server blade device 1-2 is assigned “I / F1: ip3” as the IP address of the dedicated network.

  As for the IP address of the dedicated network, for example, both the IP addresses of the dedicated network interface units 11 of the IP-PBX server blade apparatuses 1-1 and 1-2 are stored in advance in the storage unit 116, and the slot position detection is performed. The own device operation setting unit 112 may set the IP address of any dedicated network interface unit 11 according to the slot position detected by the unit 111.

  Next, the IP-PBX server blade device 1-1 performs the operation of the already mounted operation unit 113.

  That is, in the IP-PBX server blade device 1-1, the already-installed operation unit 113 includes the OS, application data, station data, server-specific data of the IP-PBX server blade device 1-1, IP stored in the storage unit 116. -The server specific data of the PBX server blade device 1-2 is copied (S106).

  Then, the already mounted operation unit 113 transmits the copied data to the dedicated network with the IP address of the other IP-PBX server blade device 1-2 as the destination (S107). That is, the IP-PBX server blade device 1-1 transfers the copied data with “I / F1: ip3” as the destination.

  Here, the IP-PBX server blade device 1-1 may include a communication confirmation unit not shown in FIG. With such a configuration, the communication confirmation unit of the IP-PBX server blade apparatus 1-1 confirms communication with “I / F1: ip3”, and if the communication can be confirmed, “I / F1: ip3” is sent to the destination. As described above, the copied data is transferred. Similarly, the IP-PBX server blade device 1-2 may include a communication confirmation unit. The communication confirmation unit activates a function on the side of the IP-PBX server blade device that operates as an already-installed device and starts communication confirmation. In other words, the IP-PBX server blade that has received an installation operation such as a command input indicating that it operates as an already-installed device starts communication confirmation.

  In the IP-PBX server blade device 1-2, the mounting operation unit 114 acquires data received through the dedicated network, and stores the acquired data in the storage unit 116 (S107).

  Then, the wearing operation unit 114 is activated using the data stored in the storage unit 116 (S108). That is, the IP-PBX server blade device 1-2 is activated based on the copy data acquired from the IP-PBX server blade device 1-1.

  For example, in FIG. 3, since the IP-PBX server blade device 1-2 recognizes that its own device is a device installed in slot # 1, it uses the server fixed data in FIG. 5B. The address of the external network interface unit 12 is set.

  Here, the activation unit 75 of the mounting operation unit 114 has a data setting function for setting server-fixed data in its own device. This data setting function is demonstrated when the operation flowchart of FIG. 6 is activated (S108). Specifically, the activation unit 75 of the IP-PBX server blade apparatus 1-2 sets the OS based on the server 1-2 unique data (FIG. 5B) in the storage unit 116 by the data setting function. First, the activation unit 75 sets “SERIAL_NUMBER: ddd-eeee-fff” in FIG. 5B in the OS. Subsequently, the activation unit 75 sets “HOSTNAME: hogehoge2” in FIG. 5B in the OS. Subsequently, the activation unit 75 sets “I / F1: ip3” in FIG. 5B in the OS. Subsequently, the activation unit 75 sets “I / F2: ip4” in FIG. 5B in the OS. Subsequently, the activation unit 75 sets “I / F2: 0: ip5” in FIG. 5B to the OS. Therefore, the data setting function of the activation unit 75 has a license setting function, a host name setting function, and a network I / F setting function.

  The IP-PBX server blade apparatus 1-2 also acquires copy data of the OS and application data from the IP-PBX server blade apparatus 1-1. That is, since the data stored in the IP-PBX server blade device 1-2 is the same as the data stored in the IP-PBX server blade device 1-1, a new OS or application data is transferred to the IP-PBX server. No time and effort is required for installation in the blade device 1-2.

(A-3) Effects of Embodiment As described above, according to this embodiment, the IP-PBX server blade device is mounted in the slot, and the slot is mounted only by a simple operation such as inputting a built-in command. The construction of the IP-PBX server blade device is completed. As a result, it is possible to significantly reduce man-hours and eliminate work mistakes.

(B) Other Embodiments Although various modified embodiments have been described in the above-described embodiments, the following modified embodiments may be applied.

(B-1) The method of detecting the slot position in the above-described embodiment has exemplified the case of detecting the “H” or “L” pin signal from the backboard unit. In the above-described embodiment, the case where the pin signal is “H” is slot # 0 and when the pin signal is “L”, the slot # 1 is illustrated. However, when the pin signal is “H”, the slot # 1 is “ When it is “L”, it may be slot # 0.

  Further, the control unit 42 of the backboard unit 4 may be set to “H” or “L” under the control of the pin signal from the IP-PBX server blade device 1.

  For example, the case where the IP-PBX server blade device 1-2 installed in the slot # 1 fails and is replaced is illustrated. The pin signal “H” is slot # 0, and when the pin signal is “L”, slot # 1 is set. The IP-PBX server blade device 1-1 is inserted into slot # 0, and no blade device is installed in slot # 1. In this case, the IP-PBX server blade device 1-1 requests the control unit 42 of the backboard unit 4 to change the pin signal. In response to this, the control unit 42 sets the pin signal. That is, the control unit 42 changes the slot # 1 from the pin signal “L” to “H”, and changes another slot # 1 from the pin signal “H” to “L”. After that, the IP-PBX server blade apparatus 1-1 sets the server fixed data (FIG. 5B) of the server 1-2, functions as the IP-PBX server blade apparatus 1-2, and the IP-PBX server The blade device 1-2 sets server fixed data (FIG. 5A) of the server 1-1 and functions as the IP-PBX server blade device 1-1.

(B-2) When the IP-PBX server blade device 1-2 newly installed in the slot assigns the IP address of the dedicated network in S105 of FIG. Become.

  When acquiring copy data, the new IP-PBX server blade device 1-2 makes a data copy start request, a copy data transfer request, etc. to the IP-PBX server blade device 1-1. It may be. As a result, data copying and the like can be started without inputting a command to the IP-PBX server blade apparatus 1-1.

(B-3) In the above-described embodiment, the storage unit stores server specific data of all servers. Furthermore, in the storage unit, server data for maintenance setting is stored, and when the server cannot find matching server-specific data even though the server has determined the slot to be installed and its own device, The server may apply server data for maintenance setting.

(B-4) In the above-described embodiment, the case where the server for constructing the clustering is an IP-PBX server has been exemplified. However, the service provided by the server that constructs the clustering is not limited to IP-PBX, and can be widely applied.

1-1 and 1-2 ... IP-PBX server blade device,
11 ... Dedicated network interface unit,
12 ... External network interface unit,
13 ... control unit,
111 ... Slot position detection unit, 112 ... Self-device operation setting unit,
113 ... Existing mounting operation unit, 71 ... Data copy unit, 72 ... Transfer unit,
114... Operation unit when mounted, 74... Copy data acquisition unit, 75.
116: Storage unit,
4 ... Backboard part, 41 ... Slot, 42 ... Control part,

Claims (4)

In a redundancy construction system for constructing redundancy having a plurality of servers by attaching the server to any of the plurality of attachment parts of the backboard control means,
The server
Network interface means for exchanging information with other servers via the network;
And at least storage means for storing information necessary for server operation,
When a new server is mounted on any of the mounting sections, the new server is
A mounting position detecting means for detecting the position of the mounting portion to be mounted;
Address information setting means for assigning address information to the network interface means according to the position of the mounting portion detected by the mounting position detection means;
Other servers attached to the mounting part
Duplication means for duplicating the information stored in the storage means;
Data transfer means for transferring the information copied by the copy means to the new server through the network;
The redundancy construction system, wherein the new server has information acquisition means for storing the information acquired from the other server in the storage means. Information necessary for the server operation includes operating system, application data, and server-specific data of all servers,
The new server
External network interface means for communicating with the user terminal through an external network;
2. The redundancy according to claim 1, further comprising: an operation setting unit that activates an operation by assigning corresponding address information to the external network interface unit based on server-specific data acquired from the other server. Construction system.   2. The redundant construction according to claim 1, wherein the mounting position detection unit detects the position of the mounting unit based on a signal indicating the position of the mounting unit from the backboard control unit. system. In the redundancy construction program for constructing redundancy having a plurality of servers by attaching the server to any of the plurality of attachment parts of the backboard control means,
Network interface means for exchanging information with other servers via the network;
A computer comprising at least storage means for storing information necessary for server operation,
Mounting position detecting means for detecting the position of the mounting portion to be mounted;
Address information setting means for assigning address information to the network interface means according to the position of the mounting portion detected by the mounting position detection means;
Redundancy characterized in that another server mounted on the mounting unit acquires information stored in the storage unit, and functions as information acquisition unit that stores the acquired information in the storage unit of its own server Construction program.

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