JP7120657B2 - SERVER, SERVER SYSTEM, TIME SYNCHRONIZATION METHOD AND PROGRAM - Google Patents

Description

The present invention relates to a server, a server system, a time synchronization method and a program.

In Patent Document 1, by copying the time of the primary BMC to the secondary BMC when the standby power is turned on, the time indicated by the BMC (Baseboard Management Controller) can be shared among a plurality of modules even before module power is turned on. Techniques for matching are disclosed.

Japanese Patent Laid-Open No. 2002-200000 discloses a technique that enables a slave device to update its own information when information in a master device is updated by a management terminal, thereby enabling information to be updated without using management software or the like.

JP 2013-196272 A JP 2015-069282 A

A technique of acquiring time information from an NPT (Network Time Protocol) server and resetting the BMC time of each server in a server system is known. However, if the BMC cannot access the NPT server, it will be necessary to manually reset the BMC time of each server.
An object of the present invention is to provide a server, a server system, a time synchronization method, and a program that solve the problems described above.

A server according to the present invention includes receiving means for receiving a standard radio wave, conversion means for converting analog data obtained based on the standard radio wave received by the receiving means into digital data, and analysis means for obtaining time information from the digital data; recording means for recording the time information obtained by the analysis means in a storage device; and recording the time based on the time information recorded in the storage device by the recording means. A reset controller that spontaneously transmits the time information recorded in the storage device by the recording means to one or more servers connected via a local area network when a preset time comes. and a controller for

A server system according to the present invention includes the server described above and one or more servers connected to the server via a local area network .

A time synchronization method according to the present invention is a time synchronization method performed by a server having a controller, which includes receiving a standard radio wave and converting analog data obtained based on the received standard radio wave into digital data. obtaining time information from the digital data; recording the obtained time information in a storage device; resetting the time based on the time information recorded in the storage device; spontaneously transmitting the time information recorded in the storage device to one or more servers connected by an area network when a preset time comes .

A program according to the present invention causes a computer provided in a server having a controller to receive a standard radio wave, convert analog data obtained based on the received standard radio wave into digital data, convert the digital data to time obtaining information; recording the obtained time information in a storage device; resetting the time based on the time information recorded in the storage device; and causing one or more servers to spontaneously transmit the time information recorded in the storage device when a preset time comes .

According to at least one of the above aspects, even if the BMC of each server connected to the server cannot access the NPT server, the time synchronization of the BMC of each server can be performed.

It is a figure which shows the structure of the server system which concerns on one Embodiment. 1 is a schematic block diagram showing the configuration of a radio-controlled clock section according to an embodiment; FIG. 1 is a schematic block diagram showing the configuration of a BMC according to one embodiment; FIG. 4 is a flow chart showing the operation of the radio clock unit according to one embodiment. It is a flow chart which shows operation of a server system concerning one embodiment. 1 is a schematic block diagram showing a configuration of a computer according to at least one embodiment; FIG.

<First embodiment>
《Server system configuration》
Hereinafter, the server system 1 according to the embodiment will be described in detail with reference to the drawings.
The server system 1 resets the time of the BMC 11 of the first server 10 using the time information obtained from the received standard radio wave.

FIG. 1 is a diagram showing the configuration of a server system 1 according to the first embodiment.
The server system 1 includes a client terminal 20, an operator terminal 21, a switch device 30, a local area network 40, and a plurality of servers. The first server 10 and the second server 50 shown in FIG. 1 are examples of servers. Each server provided in the server system 1 has an IP address segmented by subnet.

The client terminal 20 receives an instruction from the client and accesses the server via the switch device 30 . A client is an example of a user.
The operator terminal 21 receives an instruction to execute time synchronization and an instruction to indicate the time for time synchronization from the operator, and accesses the server via the switch device 30 . An operator is an example of a user.
Although FIG. 1 shows one client terminal 20 and one operator terminal 21 , the server system 1 includes multiple client terminals 20 and multiple operator terminals 21 .

The switch device 30 relays communication so that a plurality of devices can communicate with each other. Specifically, the switch device 30 connects to the client terminal 20 by wire or wirelessly, and relays communication with the first server 10 or the second server 50 via the local area network 40 . Also, the switch device 30 is connected to the operator terminal 21 by wire or wirelessly, and relays communication with the first server 10 or the second server 50 via the local area network 40 .

Local area network 40 is a network that allows multiple devices to communicate with each other in a local environment. The local area network 40 allows the servers to communicate with each other and allows the client terminals 20 and operator terminals 21 to communicate with the servers.

《Server configuration》
The configurations of the first server 10 and the second server 50 will be described below.
The first server 10 has a BMC 11 and a radio clock section 12 . The second server 50 has a BMC 51 . The BMC 11 and BMC 51 have similar configurations and perform similar operations.

FIG. 2 is a schematic block diagram showing the configuration of the radio clock section 12. As shown in FIG.
The radio clock unit 12 includes an antenna 121 , a conversion unit 122 , a CPU 123 , a time recording unit 124 and a time storage unit 125 . The radio clock unit 12 is provided in a PCI card (not shown) provided in the first server 10 .

The antenna 121 receives a standard radio wave (time code) transmitted from a standard radio wave receiving station. The antenna 121 is an example of receiving means.
The converter 122 converts analog data obtained based on the standard radio wave received by the antenna 121 into digital data. The conversion unit 122 transmits the converted digital data to the CPU 123 . The conversion unit 122 is an example of conversion means.

The CPU 123 obtains time information from the digital data converted by the converter 122 .
The time recording unit 124 records the time information obtained by the CPU 123 in the time storage unit 125 .
The time storage unit 125 stores time information recorded by the time recording unit 124 .

FIG. 3 is a schematic block diagram showing the configuration of the BMC 11. As shown in FIG.
The BMC 11 is a server management controller that monitors server hardware (CPU, memory, temperature, etc.), performs remote control, records hardware events, and manages firmware.
The BMC 11 includes a detection unit 111 , a storage unit 112 , a reception unit 113 , a time acquisition unit 114 , a time communication unit 115 and a time synchronization unit 116 .

The detection unit 111 transmits a predetermined command to the local area network 40 and detects one or more servers connected to the local area network 40 based on the response to the predetermined command. Further, the detection unit 111 records information indicating the detected server in the storage unit 112 .
For example, the detection unit 111 periodically transmits a PING command to the local area network 40 and detects the server by specifying the IP address of the server that responded. A PING command is an example of a predetermined command. An IP address is an example of a server. This allows the detection unit 111 to detect servers connected to the local area network 40 .

Storage unit 112 stores information indicating one or more servers connected to the same local area network as the server. The storage unit 112 is an example of storage means.
For example, the storage unit 112 stores information indicating the server recorded by the detection unit 111 .
The storage unit 112 also stores information (hereinafter referred to as rule information) indicating a time set in advance by the operator.

The accepting unit 113 accepts an instruction to execute time synchronization and an instruction to indicate the time for time synchronization from the operator terminal 21 . The instruction indicating execution of time synchronization and the instruction indicating time for time synchronization are examples of user instructions regarding time synchronization.
The receiving unit 113 records the rule information in the storage unit 112 based on the received instruction indicating the time of time synchronization.

The time acquisition unit 114 acquires time information from the time storage unit 125 of the radio clock unit 12 . Also, the time acquisition unit 114 converts the acquired time information into POSIX time. Poxix time is an example of time information.

The time communication unit 115 transmits the POSIX time converted by the time acquisition unit 114 based on the rule information and the information indicating the server stored in the storage unit 112 . That is, the time communication unit 115 transmits the POSIX time to the server indicated by the IP address stored in the storage unit 112 at preset time intervals.
Further, when the reception unit 113 receives an instruction indicating execution of time synchronization, the time communication unit 115 converts the Poxx time converted by the time acquisition unit 114 based on the information indicating the server stored in the storage unit 112 . to send. That is, when the time communication unit 115 receives an instruction to execute time synchronization from the operator, the time communication unit 115 transmits the POSIX time to the server indicated by the IP address stored in the storage unit 112 .
Also, the time communication unit 115 receives the transmitted POSIX time. For example, the time communication unit included in the BMC 51 of the second server 50 receives the POSIX time transmitted by the time communication unit 115 of the BMC 11 of the first server 10 .
The time communication unit 115 is an example of transmission means.

The time synchronization unit 116 synchronizes the time by resetting the time based on the POSIX time converted by the time acquisition unit 114 or the POSIX time received by the time communication unit 115 . The time synchronization unit 116 is an example of time setting means.
The BMC time of each server in the server system 1 is synchronized by the time synchronization unit 116 .

《Operation of the server system》
The operation of the server system 1 will be described below.
FIG. 4 is a flow chart showing the operation of the radio clock unit 12 acquiring time information.

The antenna 121 receives a standard radio wave (time code) transmitted from a standard radio wave receiving station (step S1).
The conversion unit 122 converts analog data obtained based on the standard radio wave received in step S1 into digital data. The conversion unit 122 transmits the converted digital data to the CPU 123 (step S2).

The CPU 123 obtains time information from the digital data converted by the converter 122 (step S3).
The time recording unit 124 records the time information obtained by the CPU 123 in the time storage unit 125 (step S4). The time storage unit 125 stores time information recorded by the time recording unit 124 .

FIG. 5 is a flow chart showing an operation related to time synchronization in the server system 1. As shown in FIG.
The detection unit 111 periodically transmits a PING command to the local area network 40 and detects the server by specifying the IP address of the server that responded. Further, the detection unit 111 records information indicating the detected server in the storage unit 112 (step S11).
For example, the detection unit 111 detects an IP address indicating the second server 50 and records it in the storage unit 112 .

The time acquisition unit 114 acquires time information from the time storage unit 125 of the radio clock unit 12 . Also, the time acquisition unit 114 converts the acquired time information into POSIX time (step S12).
The time synchronization unit 116 performs time synchronization by resetting the time of the first server 10 using the POSIX time converted in step S12 (step S13).

When the preset time comes, or when the reception unit 113 receives an instruction to execute time synchronization, the time communication unit 115 sends a message to the server indicated by the IP address stored in the storage unit 112 in step S12. Transmits converted Poxx time. That is, the time communication unit 115 transmits the POSIX time to the second server 50 (step S14).

The time communication unit included in the BMC 51 of the second server 50 receives the POSIX time transmitted in step S13 (step S15).
The time synchronization unit 116 performs time synchronization by resetting the time of the second server 50 using the Poxx time received in step S15 (step S16).

With this operation, even if the BMC of each server cannot access the NPT server, the server system 1 can transmit the time information acquired by the radio clock unit 12 to the BMC of each server. BMC time synchronization can be performed.

《Action and effect》
A server according to the present invention includes receiving means for receiving a standard radio wave, converting means for converting analog data obtained based on the standard radio wave received by the receiving means into digital data, and converting the digital data converted by the converting means into An analysis means for obtaining time information, a time setting means for resetting the time based on the time information obtained by the analysis means, and a transmission means for transmitting the time information obtained by the analysis means to the outside.

The server resets the time based on the time information received by the receiving means, and transmits the time information to the outside. As a result, the external device that receives the time information from the server can synchronize the time with the time of the server.

In addition, the server further comprises storage means for storing information indicating one or more servers connected to the same local area network 40 as the server, and the transmission means transmits information to the one or more servers based on the information stored in the storage means. Send time information to

The server transmits the time information to the outside based on the information stored in the storage means. As a result, the device indicated by the above information can perform time synchronization with the time of the server.

Further, the server further comprises detection means for transmitting a predetermined command to the local area network 40 to which the server is connected and detecting one or more servers connected to the local area network 40 based on the response to the predetermined command, The transmitting means transmits the time information to one or more servers detected by the detecting means.

The server transmits the time information to the outside based on the response to the predetermined command. As a result, the device related to the response can perform time synchronization with the time of the server.

Further, the transmitting means of the server transmits the time information to the outside at preset time intervals.
The server transmits the time information to the outside at preset times. As a result, the external device that has received the time information from the server can synchronize the time with the time of the server every preset time.

The server further includes receiving means for receiving a user's instruction regarding time synchronization, and the transmitting means transmits the time information to the outside when the receiving means receives a user's instruction regarding time synchronization.

The server accepts the user's instruction and transmits the time information to the outside. This allows the user of the server to synchronize the time of the external device and the time of the server.

A server system 1 according to the present invention includes a first server 10 and a second server 50 connected to the first server 10 via a local area network 40. The first server 10 receives standard radio waves. means, converting means for converting analog data obtained based on the standard radio wave received by the receiving means into digital data, analyzing means for obtaining time information from the digital data converted by the converting means, and obtained by the analyzing means The second server 50 has time setting means for resetting the time used in the first server 10 based on the time information obtained, and transmission means for transmitting the time information obtained by the analysis means to the second server. It has time setting means for resetting the time used by the second server 50 based on the time information received from the first server 10 .

The server system 1 includes a first server 10 that resets the time based on the time information received by the receiving means and transmits the time information to the outside. Thereby, the second server 50 that has received the time information from the first server 10 can perform time synchronization with the time of the first server 10 .

The time synchronization method according to the present invention includes: receiving a standard radio wave; converting analog data obtained based on the received standard radio wave into digital data; obtaining time information from the digital data; resetting the time based on the time, and transmitting the time information to the outside.

When the time synchronization method is used, the time can be reset based on the time information received by the receiving means, and the time information can be transmitted to the outside. As a result, the external device that receives the time information can perform time synchronization.

The program according to the present invention causes a computer to receive a standard radio wave, convert analog data obtained based on the received standard radio wave into digital data, obtain time information from the digital data, and time information and transmit the time information to the outside.

When the program is executed, the time can be reset according to the time information received by the receiving means, and the time information can be transmitted to the outside. As a result, the external device that receives the time information can perform time synchronization.

<Computer configuration>
FIG. 6 is a schematic block diagram showing the configuration of a computer according to at least one embodiment.
Computer 1100 comprises processor 1110 , main memory 1120 , storage 1130 and interface 1140 .
The BMC11 and BMC51 described above are implemented in the computer 1100 . The operation of each processing unit described above is stored in the storage 1130 in the form of a program. The processor 1110 reads a program from the storage 1130, develops it in the main memory 1120, and executes the above processing according to the program. Further, the processor 1110 secures storage areas corresponding to the storage units described above in the main memory 1120 according to the program.

The program may be for realizing part of the functions that the computer 1100 is caused to exhibit. For example, the program may function in combination with another program already stored in storage 1130 or in combination with another program installed in another device. In another embodiment, the computer 1100 may include a custom LSI (Large Scale Integrated Circuit) such as a PLD (Programmable Logic Device) in addition to or instead of the above configuration. Examples of PLD include PAL (Programmable Array Logic), GAL (Generic Array Logic), CPLD (Complex Programmable Logic Device), and FPGA (Field Programmable Gate Array). In this case, part or all of the functions implemented by processor 1110 may be implemented by the integrated circuit.

Examples of the storage 1130 include magnetic disks, magneto-optical disks, semiconductor memories, and the like. The storage 1130 may be an internal medium directly connected to the bus of the computer 1100, or an external medium connected to the computer via the interface 1140 or communication line. Moreover, when this program is delivered to the computer 1100 via a communication line, the computer 1100 receiving the delivery may develop the program in the main memory 1120 and execute the above process. In at least one embodiment, storage 1130 is a non-transitory, tangible storage medium.

Also, the program may be for realizing part of the functions described above. Furthermore, the program may be a so-called difference file (difference program) that implements the above-described functions in combination with another program already stored in the storage 1130 .

1 Server System 10 First Server 11 BMC
REFERENCE SIGNS LIST 12 radio clock unit 20 client terminal 21 operator terminal 30 switch device 40 local area network 50 second server 51 BMC
111 detection unit 112 storage unit 113 reception unit 114 time acquisition unit 115 time communication unit 116 time synchronization unit 121 antenna 122 conversion unit 123 CPU
124 time recording unit 125 time storage unit 1100 computer 1110 processor 1120 main memory 1130 storage 1140 interface

Claims (6)

a receiving means for receiving standard radio waves;
a converting means for converting analog data obtained based on the standard radio wave received by the receiving means into digital data;
analysis means for obtaining time information from the digital data converted by the conversion means;
a recording means for recording the time information obtained by the analysis means in a storage device;
A controller for resetting the time based on the time information recorded in the storage device by the recording means, wherein the time information recorded in the storage device by the recording means when a preset time comes. to one or more servers connected by a local area network; and
A server with The controller is
storing information indicating the one or more servers, and transmitting the time information to the one or more servers based on the stored information;
A server according to claim 1 . The controller is
transmitting a predetermined command to the local area network, detecting the one or more servers based on a response to the predetermined command, and transmitting the time information to the detected one or more servers;
A server according to claim 1 or claim 2. a server according to any one of claims 1 to 3 ;
one or more servers connected to the server by a local area network;
A server system with A time synchronization method performed by a server having a controller,
Receiving standard radio waves,
converting analog data obtained based on the received standard radio wave into digital data;
obtaining time information from the digital data;
recording the obtained time information in a storage device;
resetting the time based on the time information recorded in the storage device;
voluntarily transmitting the time information recorded in the storage device to one or more servers connected to the server via a local area network when a preset time comes;
Time synchronization methods, including In a computer provided in a server having a controller,
Receiving standard radio waves,
converting analog data obtained based on the received standard radio wave into digital data;
obtaining time information from the digital data;
recording the obtained time information in a storage device;
resetting the time based on the time information recorded in the storage device;
voluntarily transmitting the time information recorded in the storage device to one or more servers connected to the server via a local area network when a preset time comes;
program to run.

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