CN113949722A - Emergent all-in-one of AODB - Google Patents

Abstract

The invention discloses an AODB emergency all-in-one machine, which belongs to the field of airport flight production and operation and comprises a hardware system, an operation management system based on the hardware system and a monitoring system for monitoring the operation management system and the hardware system, wherein the hardware management system comprises a bearing unit, a power supply unit, a calculation storage unit, a network safety unit and a utility unit, the bearing unit comprises a cabinet, the power supply unit comprises a plurality of rack-type UPSs and a plurality of rack-type PDUs (Power distribution units), the power supply unit comprises a plurality of servers and a plurality of storage devices matched with the servers, the network safety unit comprises a plurality of network switches and a plurality of firewalls, and the utility unit comprises a plurality of KVM switches, terminal equipment and an acousto-optic alarm. The connection is simple, the whole integrated machine can be regarded as a terminal device, and emergency networking can be completed by one network cable; the networking mode is flexible, a one-to-many emergency backup mode can be formed, and a plurality of sets of all-in-one machines can be connected in series to realize a plurality of sets of emergency or test modes.

Description

Emergent all-in-one of AODB

Technical Field

The invention relates to the technical field of airport flight production and operation, in particular to an AODB emergency all-in-one machine.

Background

The scale of a modern airport has greater and greater dependence on an information system, the function of the information system in the operation process of the airport is less and less replaceable, and in addition to the popularization of various mobile terminals at present, any airport guarantee abnormality or fault influence which can be perceived by passengers can be quickly propagated and diffused by a network, great negative influence is brought to the airport, and new challenges are brought to the operation safety of each information system of the airport.

The flight production operation management system of the airport is one of the most important production systems of the airport, bears important production services such as airport flight information management, resource allocation, operation command and the like, and has irreplaceable functions in the production operation process of the airport. If the device fails to operate, command is not smooth, command failure and confusion are caused, and even serious safety production accidents are caused.

At present, although most airports have high availability schemes of all systems, the systems can be automatically switched to standby operation when partial equipment fails and cannot provide service. Although each airport has an emergency plan of each system, the system of the modern airport is complicated from the past operation experience. The system failure of the airport often has certain unpredictability, the failure cause can not be determined in a short time, some failures can cause global influence, such as network, machine room, cloud platform, storage, physical link, power supply and the like, or the original backup system of the flight production operation management system can not take over the operation normally due to special reasons.

When serious faults occur, an airport technical department is busy with troubleshooting and recovery, a business department starts various emergency plan guarantee production, and no effective support of an information system exists in the process, so that the efficiency of operation guarantee is reduced, and potential safety production hazards exist. Therefore, a set of real-time emergency backup system of the flight production operation management system is needed, which can depend on external conditions as little as possible, can operate independently under the condition of the most serious fault, seamlessly take over the production guarantee service and real-time operation data of the airport, and guarantee the orderly operation of the airport production command service.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides the method.

In order to achieve the purpose, the invention adopts the following technical scheme:

according to one aspect of the invention, an AODB emergency all-in-one machine is provided.

An AODB emergency all-in-one machine comprises a hardware system, an operation management system based on the hardware system and a monitoring system for monitoring the operation management system and the hardware system, the hardware management system comprises a bearing unit, a power supply unit, a calculation storage unit, a network security unit and a utility unit, the bearing unit comprises a cabinet, the power supply unit comprises a plurality of rack-type UPSs and a plurality of rack-type PDUs, the rack-type UPSs and the rack-type PDUs are used for supplying power to all parts of equipment, the computing storage unit comprises a plurality of servers and a plurality of storages matched with the servers, the network security unit includes a plurality of network switches and a plurality of hot wall that prevents, utility unit includes a plurality of KVM switchers, terminal equipment and audible-visual annunciator, every the switch all connects gradually a plurality of protective wall, a plurality of server and a plurality of storage, the switch with the antenna is connected.

Further, the number of the rack-mounted PDUs is 4, the number of the servers is 3, the number of the network switches is 2, and the number of the firewalls is 2.

Further, the rack is 24U high strength server rack, the front back of rack all is equipped with the net door, the inside of rack is equipped with the rack drawer.

Further, the terminal device is a notebook computer provided with a control system, wherein the notebook computer is an association computer, and the notebook computer is placed inside the cabinet drawer.

Further, the audible and visual alarm and the cabinet are installed in a magnetic type mode, and the working voltage of the audible and visual alarm is DC24V and AC 200V.

Further, the operation management system comprises an AODB server with an AODB database, a FOMS main application server for deploying a main application process of flight production operation, a FOMS data synchronization server for deploying FOMS data special synchronization application service, an Apache middleware server for deploying Apache and Active MQ services and an MQ middleware server for deploying WebSphere MQ service and AODB ADP service, wherein the AODB server is connected with the FOMS data synchronization server through the FOMS main application server, and the AODB server is connected with the FOMS main application server.

Further, the FOMS main application server is connected with an IMF database, the IMF database comprises a system interface module, and the system interface module is used for providing a plurality of system standby interfaces such as IMG, FIDS, PA and the like.

According to another aspect of the invention, the invention further provides a synchronization method of the AODB emergency all-in-one machine.

The application message synchronization method of the AODB emergency all-in-one machine comprises the following steps:

in an emergency test environment, establishing an application message synchronous environment which is twin in a production environment;

the data received in the production environment is checked and analyzed by the database;

rolling back if the verification fails, and generating different types of execution data if the data verification succeeds;

and generating a communication message of different ports by the execution data and sending the communication message to the client or the ESB, and distributing the execution result to the twin environment.

Further, the auxiliary data synchronization method of the AODB emergency all-in-one machine comprises the following steps:

the method comprises the following steps: preparing all-in-one equipment for running an application test environment;

step two: after the data change is input into a database of a production environment operation system, the data change is input into a data change monitor of the operation system;

step three: in the data change monitor, an execution script or a database log is generated through an ETL tool;

step four: sending the data obtained in the step to a database of an application test environment operation system;

step five: and the database of the application test environment operation system inputs data into the data change monitor of the operation system to complete synchronization.

Furthermore, two all-in-one machines can be connected in series or in parallel, and the same operation management system is arranged between the two all-in-one machines.

Compared with the prior art, the invention has the beneficial effects that: the production and emergency test system operates in a double-active mode, and the emergency system can be operated at any time by a non-traditional third standby machine or cold standby scheme; the production and emergency systems are loosely coupled, the emergency system can be temporarily removed for other use, and can also be connected to a network at any time, and the data can be immediately restored to be synchronous; the automatic recovery cleaning of data garbage, automatic cleaning of garbage data generated during testing or during data interruption, and high efficiency and reliability of a system in an emergency state are guaranteed; the system is highly integrated, does not depend on external environmental conditions, is provided with professional equipment and software such as a wired network, a wireless network, a firewall, terminal equipment, a UPS and the like, can quickly recover the operation and control command function in emergency, and can quickly rebuild a small emergency command center; all important equipment adopts high-reliability redundancy configuration, so that the operation risk caused by equipment failure is avoided, and the system operation is ensured to be reliable; the system is provided with a self-monitoring evaluation system, and under a daily state, the state of the self-monitoring equipment, the running state of the system and the data synchronization state are detected to be abnormal, and an alarm is given immediately; the power consumption is small, the integral working power does not exceed 2KW, and the daily commercial power 10A socket can be used in a plug-and-play mode; the connection is simple, the whole integrated machine can be regarded as a terminal device, and emergency networking can be completed by one network cable; the networking mode is flexible, a one-to-many emergency backup mode can be formed, and a plurality of sets of all-in-one machines can be connected in series to realize a plurality of sets of emergency or test modes.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

Fig. 1 is a schematic diagram of a hardware system of an AODB emergency all-in-one machine according to the present invention;

FIG. 2 is a connection diagram of internal components of a hardware system of the AODB emergency all-in-one machine provided by the invention;

fig. 3 is a schematic diagram of an operation management system of the AODB emergency all-in-one machine according to the present invention;

FIG. 4 is a schematic diagram of an auxiliary data synchronization method of the AODB emergency all-in-one machine according to the present invention;

FIG. 5 is a logic diagram of an application message synchronization method of the AODB emergency all-in-one machine according to the present invention;

FIG. 6 is a flowchart illustrating the steps of an auxiliary data synchronization method of the AODB emergency all-in-one machine according to the present invention;

fig. 7 is one of schematic operation connection diagrams of the AODB emergency all-in-one machine according to the present invention;

fig. 8 is a second schematic diagram of the operation connection of the AODB emergency all-in-one machine according to the present invention.

In the figure: 1. a cabinet; 2. a rack-mounted UPS; 3. a rack PDU; 4. an audible and visual alarm; 5. storing; 6. a network switch; 7. a firewall; 8. a KVM switch.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

According to the embodiment of the invention, an AODB emergency all-in-one machine is provided.

Referring to fig. 1, 2, 7 and 8, an AODB emergency all-in-one machine includes a hardware system, an operation management system based on the hardware system and a monitoring system for monitoring the operation management system and the hardware system, where the hardware management system includes a carrying unit, a power supply unit, a computing storage unit, a network security unit and a utility unit, the carrying unit includes a cabinet 1, the power supply unit includes a plurality of rack UPS2 and a plurality of rack PDU3 for supplying power to each component of the device, the computing storage unit includes a plurality of servers, a plurality of storages 5 matched with the servers, the network security unit includes a plurality of network switches 6 and a plurality of firewalls 7, the utility unit includes a plurality of KVM switches 8, a terminal device and an acousto-optic alarm 9, each switch sequentially connects a plurality of protection walls, a plurality of servers and a plurality of storages 5, the switch is connected with the antenna.

In one embodiment, the rack-mounted PDUs 3 number 4, the servers number 3, the network switch 6 number 2, and the firewall 7 number 2.

In one embodiment, the cabinet 1 is a 24U high-strength server cabinet 1, the front and the back of the cabinet 1 are both provided with a mesh door, and a cabinet drawer is arranged inside the cabinet 1.

In one embodiment, the terminal device is a notebook computer with a control system installed therein, wherein the notebook computer is an associative computer, and the notebook computer is disposed inside the cabinet drawer.

In one embodiment, the audible and visual alarm 9 is magnetically mounted with the cabinet 1, and the operating voltage of the audible and visual alarm 9 is DC24V, AC 200V.

Referring to fig. 3, in one embodiment, the operation management system includes an AODB server having an AODB database, a FOMS master application server for deploying a primary application process of a flight production operation, a FOMS data sync server for deploying a FOMS data-specific sync application service, an Apache middleware server for deploying Apache and Active MQ services, and an MQ middleware server for deploying a WebSphere MQ service and an AODB ADP service, wherein the AODB server is connected with the FOMS data sync server through the FOMS master application server, wherein the AODB server is connected with the FOMS master application server.

Furthermore, the operation management system also provides a configuration mode of an operation data source of the flight information service bus, and the configuration mode comprises the following components:

the system comprises a Message Borker, IMF application software, a Mysql database and a system interface, wherein the Message Borker is used for providing an interface Message processing platform, the system interface is used for providing a plurality of system standby interfaces such as IMG, FIDS and PA, and the Mysql database is used for the configuration of the IMF and a log database.

In one embodiment, the FOMS master application server is connected to an IMF database, which includes a system interface module for providing a number of system standby interfaces such as IMG, FIDS, PA, etc.

Specifically, access to emergency and temporary clients can be performed, and wired and wireless access is supported.

In the embodiment of the invention, the invention further provides a synchronization method of the AODB emergency all-in-one machine.

Specifically, the method comprises an application message synchronization method for an operation management system of the AODB emergency all-in-one machine and an auxiliary data synchronization method for the operation management system of the AODB emergency all-in-one machine.

Further, the application message data synchronization method for the operation management system of the AODB emergency all-in-one machine can ensure that the emergency environment or the test environment can keep a multi-active state together with the production environment through application-level message data synchronization, all the applications, the clients and the message interface buses can synchronously generate and receive messages, so that real-time online and effectiveness of the emergency all-in-one machine can be ensured in real time, and when the emergency condition is sent, seamless switching and real-time online can be realized, so that the application message data synchronization method is used for core system application message data synchronization.

Furthermore, the auxiliary data synchronization method for the operation management system of the AODB emergency all-in-one machine adopts the traditional ETL mode to periodically synchronize data, ensures that various configurations and production environments of other application databases of the emergency all-in-one machine are kept consistent, and is used for synchronizing auxiliary application data outside a core system.

Referring to fig. 5, the application message data synchronization method for the operation management system of the AODB emergency all-in-one machine includes the following steps:

step S201: in an emergency test environment, establishing an application message synchronous environment which is twin in a production environment;

step S203: the data received in the production environment is checked and analyzed by the database;

step S205: rolling back if the verification fails, and generating different types of execution data if the data verification succeeds;

step S207: and generating a communication message of different ports by the execution data and sending the communication message to the client or the ESB, and distributing the execution result to the twin environment.

Referring to fig. 4 and 6, the auxiliary data synchronization method for the operation management system of the AODB emergency all-in-one machine includes the following steps:

step S101: preparing all-in-one equipment for running an application test environment;

step S103: after the data change is input into a database of a production environment operation system, the data change is input into a data change monitor of the operation system;

step S105: in the data change monitor, an execution script or a database log is generated through an ETL tool;

step S107: sending the data obtained in the step to a database of an application test environment operation system;

step S109: and the database of the application test environment operation system inputs data into the data change monitor of the operation system to complete synchronization.

Specifically, two all-in-one machines can be connected in series or in parallel, and the same operation management system is arranged between the two all-in-one machines.

In the embodiment of the invention, a zabbix system is adopted for monitoring the system monitoring of the software and the hardware of the equipment and is used for monitoring the running state of the software and the hardware of the equipment, and the running platform of the equipment is formed by an X86 server, shared storage and VMware computing virtualization and is based on the elasticity and the expandability of a basic framework and application.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. The utility model provides an emergent all-in-one of AODB, includes hardware system, based on hardware system's operation management system and the monitored control system who is used for operation management system and hardware system control, a serial communication port, hardware management system includes load-bearing unit, power supply unit, calculation memory cell, network security unit and utility unit, load-bearing unit includes rack (1), power supply unit includes a plurality of rack UPS (2) and a plurality of rack PDU (3) that are used for each part power supply to equipment, calculation memory cell include a plurality of servers, a plurality of with storage (5) that the server matches, network security unit includes a plurality of network switch (6) and a plurality of hot wall (7), utility unit includes a plurality of KVM switch (8), terminal equipment and audible-visual annunciator (4), every the switch all connects gradually a plurality of protective wall, A plurality of said servers and a plurality of storages (5), said switch being connected to said antennas.

2. The AODB emergency all-in-one machine according to claim 1, wherein the number of rack-mounted PDUs (3) is 4, the number of servers is 3, the number of network switches (6) is 2, and the number of firewalls (7) is 2.

3. The AODB emergency all-in-one machine according to claim 1, wherein the cabinet (1) is a 24U high-strength server cabinet (1), the front and the back of the cabinet (1) are provided with mesh doors, and a cabinet drawer is arranged inside the cabinet (1).

4. The AODB emergency all-in-one machine according to claim 3, wherein the terminal equipment is a notebook computer provided with a control system, wherein the notebook computer is an association computer, and the notebook computer is placed inside the cabinet drawer.

5. The AODB emergency all-in-one machine according to claim 1, wherein the audible and visual alarm (9) and the cabinet (1) are mounted in a magnetic type, and the working voltage of the audible and visual alarm (9) is DC24V and AC 200V.

6. The AODB emergency all-in-one machine according to claim 1, wherein the operation management system comprises an AODB server having an AODB database, a FOMS main application server for deploying a main application process of flight production operation, a FOMS data synchronization server for deploying FOMS data-specific synchronization application services, an Apache middleware server for deploying Apache and Active MQ services, and an MQ middleware server for deploying WebSphere MQ services and AODB ADP services, wherein the AODB server is connected with the FOMS data synchronization server through the FOMS main application server, and wherein the AODB server is connected with the FOMS main application server.

7. The AODB emergency all-in-one machine according to claim 6, wherein the FOMS main application server is connected with an IMF database, the IMF database comprises a system interface module, and the system interface module is used for providing a plurality of system standby interfaces such as IMG, FIDS, PA and the like.

8. A synchronization method of an AODB emergency all-in-one machine is characterized by comprising an application message synchronization method of an operation management system for the AODB emergency all-in-one machine, and the steps are as follows:

in an emergency test environment, establishing an application message synchronous environment which is twin in a production environment;

the data received in the production environment is checked and analyzed by the database;

rolling back if the verification fails, and generating different types of execution data if the data verification succeeds;

and generating a communication message of different ports by the execution data and sending the communication message to the client or the ESB, and distributing the execution result to the twin environment.

9. The synchronization method of the AODB emergency all-in-one machine according to claim 8, further comprising an auxiliary data synchronization method for an operation management system of the AODB emergency all-in-one machine, comprising the following steps:

the method comprises the following steps: preparing all-in-one equipment for running an application test environment;

step two: after the data change is input into a database of a production environment operation system, the data change is input into a data change monitor of the operation system;

step three: in the data change monitor, an execution script or a database log is generated through an ETL tool;

step four: sending the data obtained in the step to a database of an application test environment operation system;

step five: and the database of the application test environment operation system inputs data into the data change monitor of the operation system to complete synchronization.

10. The synchronization method of the AODB emergency all-in-one machine according to any one of claims 8 or 9, wherein two all-in-one machine devices can be connected in series or in parallel, and the same operation management system is arranged between the two all-in-one machine devices.

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