KR100796445B1 - Duplex system - Google Patents

Abstract

A duplex system is provided to minimize time needed for switching a blade of a standby state to an active state when malfunction occurs in the active blade or switching is needed. Two blades(20,30) are mounted for executing a predetermined application, one blade is operated in the active state, and another one is operated in the standby state. Each attachment detecting sensor(41,42) detects attachment of the blade. A manager(50) transmits an activation control signal for switching the standby blade to the active state. Each blade includes a latch detecting sensor(23) detecting a state of a latch(24) installed to fix the blade, and a sensor module(21) transmitting a state signal to the manager when an abnormal state not normally executing the application is detected or a detection signal is received from the latch detecting sensor by detecting the state of an executing module(22) for executing the application. The abnormal state of the executing module includes a reset state or an OS(Operating System)-down state of the executing module.

Description

Redundancy System {Duplex system}

1 is a view showing a conventional redundancy system,

2 is a view showing a redundancy system according to the present invention,

3 is a view showing an example of the overall control flow of the redundancy system according to the present invention,

4 is a view showing another example of the overall control flow of the redundancy system according to the present invention,

5 is a view showing the control flow of the standby blade of the redundancy system according to the present invention.

* Explanation of symbols for the main parts of the drawings

20,30: blade 21,31: sensor module

22,32: execution module 23,33: latch detection sensor

24,34: Latch 25,35: Interface

26,36: high availability execution unit 27,37: application execution unit

41,42: Detachable sensor

The present invention relates to a redundancy system, and more particularly, to a redundancy system for redundancy of a device driving a specific application by mounting a removable blade.

With the development of high-speed Internet and intranet technology, server technology that can process a large amount of data at high speed has evolved from a cluster server to a blade-type server with low power consumption, efficient management, and easy system scalability. Blade-type servers have a minimum number of systems on each blade that can run server programs, and power or other I / O equipment can be shared by multiple blades and easily removable from the chassis on which each blade is mounted. Refers to the server you created.

Enterprises provide various services using a blade-type server as described above. With the development of the Internet, users can handle various tasks such as internet banking, electronic payment, e-commerce, home shopping, stock trading, and civil affairs through the Internet. .

As the Internet penetrates deep into life and users of such services rapidly increase, the demand for uninterrupted services is increasing. In other words, the effort is steadily increasing along with the need to maximize business continuity and availability.

In other words, as the downtime of server system is down and the service function is not provided, the downtime can be greatly damaged with the trust of the company that provides the service. Therefore, the company needs a configuration to minimize downtime in various ways. It became.

Therefore, when providing various services using a blade server, one of the two blades is kept in the active state and the other is in the standby state, and the standby blade provides the corresponding service when a malfunction occurs in the active blade. A redundancy system has been proposed for this purpose.

The redundant system 1 of the conventional blade server will be described with reference to FIG. 1 as follows. Herein, it is assumed that the first blade 2 is in an active state and the second blade 3 is in a standby state.

The first blade 2 periodically maintains a predetermined communication channel with the second blade 3 and continuously transmits to the second blade 3 a status maintenance signal, for example, a heartbeat. For example, transmit once every 0.1 seconds. Here, the state maintaining signal (ie, heartbeat signal) is a signal provided to inform the blade that is in the active state from the blade in the active state that it is currently operating in the active state.

The second blade 3 determines whether a heartbeat signal is received from the first blade 2 in the standby state, and if it is received, continuously maintains the standby state. Perform the function provided by (2).

However, this conventional technology has the following disadvantages.

The heatbeat signal may be delayed in transmission due to a system load of the first blade 2, or a part of the signal may disappear. Therefore, when the heartbeat signal is not received from the first blade 2, the second blade 3 in the stand-by state does not immediately switch, but determines whether to switch after a predetermined time passes. This is because if the heartbeat signal is not immediately received, the switchover occurs even when a malfunction does not occur in the first blade 2.

Therefore, even though an error or the like occurs in the system of the first blade 2 and the second blade 3 should be immediately switched from the standby state to the active state, the second blade 3 may have a predetermined time (eg, For example, after 5 seconds to 10 seconds), the transfer is not performed, and thus the system is not immediately switched, and thus the service provision is interrupted during the period.

In particular, when the first blade 2 is detached from a chassis (not shown) or the like, the second blade 3 does not receive a heartbeat signal from the first blade 2 but is immediately active for the reasons mentioned above. There is a problem in that a system provision delay occurs by waiting for a predetermined time without being switched to.

Accordingly, an object of the present invention is to solve the above problems, when the blade in the active state when the malfunction or when there is a need for other transfer, the standby state of the blade in the active state It is to provide a redundancy system that minimizes the switching time.

In order to achieve the above object, a redundancy system according to the present invention includes a redundancy system, which is mounted to execute a specific application, two blades, one operating in an active state and the other operating in a standby state; Detachable detection sensor for detecting the detachment of the blade; And a management device for transmitting an activation control signal for causing the blade in the standby state to operate in the active state based on the detachment detection signal from the detachable detection sensor and the state signal from the blade in the active state. Achieved by a redundancy device.

Here, the blade and the latch detection sensor for detecting the state of the latch installed for fixed mounting of the blade; A sensor module that detects a state of an execution module for executing a specific application and detects an abnormal state in which the application cannot be normally executed or receives a detection signal from the latch sensor, and transmits the state signal to the management device; It may include.

The abnormal state of the execution module may include a reset state of the execution module and an operating system down state.

Here, the management device is a detachable detection signal indicating that the blade in the active state is detached from the detachable detection sensor, the latch is open from the sensor module of the blade in the active state (OPEN), the execution module is reset or the operating system When one of the status signals indicating that the down is input, the activation control signal can be transmitted to the blade in the standby state.

The execution module may include a high availability execution unit configured to exchange a state signal with an execution module of another blade and to receive the activation control signal from the management device; It may include an application execution unit for executing a specific application program under the control of the high availability execution unit.

The status signal transmitted / received between execution modules of the blade may be a signal periodically transmitted from the blade in the active state to the blade in the standby state.

Here, when the sensor module of the blade in the active state receives the detection signal from the latch sensor, the execution module is characterized in that to perform the normal termination process of the program being driven in accordance with the control signal of the sensor module. Can be.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2, the redundancy system 10 according to the present invention includes two blades 20 and 30, a detachable detection sensor 41 and 42, and a management device 50.

The blades 20 and 30 are mounted to execute a specific application, one operating in an active state and the other operating in a standby state. Here, the specific application may be a program such as a web server, a mail server, a file server, etc. provided to a general user, and may be a module that performs a specific operation.

 Here, the active state and the standby state mean a state in which a predetermined function is performed at the present time or waiting to be performed in the future, and the active state is a case of providing a predetermined service such as a web server. By running an application such as a web server, it means that the user can access the network using the current network. The standby state is changed to an active state when the predetermined condition is satisfied, and the user can access it. Means inaccessible state.

2, the first blade 20 is in an active state, and the second blade 30 is in a standby state, as an example.

Meanwhile, the blades 20 and 30 may include latches 24 and 34, latch detection sensors 23 and 33, execution modules 22 and 32, and sensor modules 21, for fixed mounting of the blades 20 and 30. 31).

Here, the latch detection sensors 23 and 33 detect the state of the latches 24 and 34 of the corresponding blades 20 and 30. That is, it is possible to detect whether the latches 24 and 34 are open or closed, and also detect whether the latches 24 and 34 are in contact with an external object.

The execution modules 22 and 32 are modules for executing a specific application and may include high availability execution units 26 and 36 and application execution units 27 and 37.

The high availability execution unit 26, 36 receives an activation control signal from the management device 50 to be described later, and the application so that the corresponding blades 20, 30 are switched from the standby state to the active state according to the received activation control signal. The execution units 27 and 37 are controlled. The application execution units 27 and 37 drive a specific program in an active state. Here, the communication method between the high availability execution unit 26 and 36 and the application execution unit 27 and 37 may use any one of UDP (User Datagram Protocol) socket communication or a message queue method.

Also, the high availability execution units 26 and 36 maintain communication channels with the high availability execution units 26 and 36 of the other blades 20 and 30 and transmit status signals to each other. For example, the heartbeat signal is periodically sent to the other blades 20 and 30 so as to know the state of the blades 20 and 30.

The execution modules 22 and 32 may include a central processing unit (CPU) and a random access memory (RAM) in which a predetermined program is stored.

On the other hand, the sensor module (21, 31) detects the state of the blades (20, 30) and transmits the state signal to the management device 50 to be described later. For example, when the first latch 24 of the first blade 30 in the active state is opened, or when the first execution modules 22 and 32 are reset or the operating system is down. The first sensor module 21 detects the state of the first blade 20 and transmits the state signal to the management device 50. The first sensor module 21 may be configured independently of the first execution module 22 and include a microprocessor.

In addition, the blades 20 and 30 may further include interface units 25 and 35. The interface unit may be configured as a LAN card to provide communication with an external network based on various protocols such as TCP / IP. Can be.

Desorption detection sensor (41, 42) detects the detachment state of the blades (20, 30) and transmits the detachment detection signal to the management device 50 to be described later. Desorption detection sensor may be provided in a structure for forming / blocking a predetermined electrical closed loop in accordance with the attachment or detachment of the blade (20,30). That is, when the blades 20 and 30 are mounted, an electric closed loop is formed so that the current flows while the blades 20 and 30 are separated, so that the closed loop is blocked so that the current does not flow. .

The flow / block of current generated by the formation / blocking of the closed loop may be directly transmitted to the management device 50 using an internal bus or the like.

The detachable detection sensors 41 and 42 may also be provided with various contact sensors and optical sensors. Here, the detachable detection sensors 41 and 42 detect a detachable state of the first detachable detection sensor 41 and the second blade 30 that detect a detachable state of the first blade 20 as shown in FIG. 2. The second detachable detection sensor 42 may be provided independently.

Meanwhile, the management device 50 maintains a communication channel with each of the blades 20 and 30 and the detachable detection sensors 41 and 42, and from the detachable detection sensors 41 and 42 received through the communication channel. On the basis of the detachable detection signal and the state signals from the blades 20 and 30 in the active state, the activation control signal for causing the blade 30 in the standby state to operate in the active state is transmitted.

In this case, the communication channel may be configured by an IPMI (Inteligent Platform Management Interface) method and may be provided by a simple configuration using only a current interruption. When the IPMI method is configured, the transmission channel may be an IPMB (Inteligent Platform Management Bus) or a general cable. Can be used.

Hereinafter, an embodiment of the overall operating flow of the redundancy system 10 according to the present invention will be described in detail with reference to FIGS. 2 and 3.

Here, the functions of the blades 20 and 30 will be described as an example of a web server.

Initially, the first blade 20 is driven in an active state, and the second blade 30 is driven in a standby state. Therefore, when a user inputs an IP (INTERNET PROTOCOL) address in a web browser address bar to access a web page, the first blade 20 in an active state provides a page requested by the user (S1). At this time, the first blade 20 is set to an IP (INTERNET PROTOCOL) address requested by the user.

The first detachable detection sensor 41 detects a detached state of the first blade 20 in an active state. If the detached state of the first blade 20 is detected (S2), the first detachable detection sensor 41 ) Transmits the detachment detection signal to the management device 50 (S3).

In response to the detachable monitoring signal, the management device 50 transmits an activation control signal for switching the second blade 30 in the standby state to the active state (S4).

After receiving the activation control signal, the second high availability execution unit 36 sets an IP (INTERNET PROTOCOL) address for providing a web service and mounts a necessary file system for storage, and then performs a web service. The second application execution unit 37 is controlled to execute a program providing the program (S5). Accordingly, the second application execution unit 37 drives a web server program to provide a web page requested by the user by inputting it into the address bar (S6).

Hereinafter, another embodiment of the overall operating flow of the redundancy system 10 according to the present invention will be described with reference to FIGS. 2 and 4. In the description of the present embodiment, portions overlapping with the above-described embodiment with reference to FIGS. 2 and 4 may be omitted.

When the first latch 24 is opened to separate the first blade 20, the first sensor module 21 detects this (S12) and the status signal of the blade 20 is transmitted to the management device 50. Send (S13). Here, the first sensor module 21 may perform normal termination of a program, etc. that was operating in the first blade after transmitting the status signal.

In addition, when a software error occurs, for example, even when an OS (Operating System) down or reset occurs, the first sensor module 21 detects this (S12) and the corresponding blade 20 to the management device 50. Transmit the status signal of (S13).

The management device 50 receiving the status signal transmits the activation control signal to the second blade 30 as described in the above-described embodiment (S14).

Hereinafter, the function of the blade 30 operating in the standby state in the redundancy system 10 according to the present invention will be described in detail with reference to FIG. 5.

Initially, the second blade 30 operates in a standby state. (S21)

The second high availability execution unit 36 determines whether an activation control signal is received from the management device 50 (S22).

If it is determined that the activation control signal is not received, the second high availability execution unit 36 maintains a standby state (S21) and performs the subsequent steps. When the activation control signal is received as a result of the determination, the second high availability execution unit 36 prepares the activation for the second blade 30 to perform the function of the active state, and performs the function of the active state. 2, the application execution unit 37 is controlled (S27).

Here, the preparation for activation is to set the IP (INTERNET PROTOCOL) address of the blade 30, mount the required file system, and control the required web server program to run, as mentioned in the previous embodiment. And the like.

Under the control of the second high availability execution unit 36, the second application unit execution unit performs a function of an active state (S28) and may provide a web service to a user when the web server program is driven.

Meanwhile, the second high availability execution unit 36 determines whether a heartbeat signal is received from the first high availability execution unit 26 (S23). The heartbeat signal is a signal that is periodically transmitted from the first blade 20 in the active state to the second blade 30 in the standby state, indicating that the first blade 20 is operating.

When the heartbeat signal is received as a result of the determination, the second high availability execution unit 36 maintains the standby state (S21) and performs subsequent steps. However, when the heartbeat signal is not received, the second high availability execution unit 36 initializes the timer (S24) and waits for a predetermined time and then determines again (S26). If the heartbeat signal is not received, as described above, It prepares for activation (S27) and controls the second application execution unit 37 to switch to the active state (S28).

The determination of whether to receive the activation control signal and the reception of the heartbeat signal can be processed in parallel, as well as the determination sequence can be performed serially.

Although some embodiments of the invention have been shown and described, it will be apparent to those skilled in the art that modifications may be made to the embodiment without departing from the spirit or spirit of the invention. . In particular, the embodiment has described a web server as an example, but the Public Switched Telephone Network (PSTN), Sonnet, Multi Service Provisioning Platform (MSPP), VoIP, and the like are on the Advanced Telecom Computing Architecture (ATCA) platform, which is becoming a standard platform in the telecommunications industry. Of course, the redundant system 10 according to the present invention may be applied to a communication equipment such as a Voice over Internet Protocol.

It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.

As described above, according to the present invention, it is possible to minimize the time required for the blade in the standby state to switch to the active state when a malfunction occurs in the active state of the blade or needs to be transferred.

Claims (7)

In a redundant system, Two blades mounted to execute a specific application, one of which operates in an active state and the other in a standby state; Detachable detection sensor for detecting the detachment of the blade; And a management device for transmitting an activation control signal for causing the blade in the standby state to operate in the active state based on the detachment detection signal from the detachable detection sensor and the state signal from the blade in the active state. Redundancy system. The method of claim 1, The blade, A latch detection sensor for detecting a state of the latch installed for fixed mounting of the blade; A sensor module that detects a state of an execution module for executing a specific application and detects an abnormal state in which the application cannot be normally executed or receives a detection signal from the latch sensor, and transmits the state signal to the management device; Redundancy system comprising a. The method of claim 2, The redundant state of the execution module includes a reset state of the execution module and an operating system down state. The method of claim 3, The management device includes a detachment detection signal indicating that the blade in the active state has been detached from the detachment detection sensor, a latch is opened from the sensor module of the blade in the active state, the execution module is reset, or the operating system is down. If any one of the status signal indicating that the input, the redundancy system characterized in that for transmitting the activation control signal to the blade in the standby state. The method of claim 4, wherein The execution module, A high availability execution unit which exchanges a status signal with an execution module of another blade and receives the activation control signal from the management device; Redundancy system comprising an application execution unit for executing a specific application program under the control of the high availability execution unit. The method of claim 5, The status signal transmitted / received between execution modules of the blade is a signal that is periodically transmitted from the blade in the active state to the blade in the standby state. The method of claim 6, When the sensor module of the blade in the active state receives the detection signal from the latch sensor, the execution module performs a normal termination process of the program being driven in accordance with the control signal of the sensor module. .

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