KR20000047234A - Method for restoring abnormal processor in satellite communication system - Google Patents

Abstract

The present invention relates to a method for automatically recovering an abnormal processor in a satellite communication system that checks the operating state of each processor in the central control station, and informs the state when the abnormal processor is generated and automatically recovers.

In the present invention, in the central control station of the satellite communication system having a check processor coupled to the processor of each system for checking the operation state of each processor, and a network management system for managing the overall network of each system, said check The processor sends a check message for checking the processor operation status to the processor of each system, receives the check result data from each processor, analyzes the received check result message, and if there is an abnormal processor, checks for the corresponding processor. It sends out to the network management system, and characterized in that to restore the abnormal processor by restarting the abnormal processor.

Therefore, according to the present invention, by checking the operating state of the processors of each system through the inspection processor, it is possible to immediately recover if an abnormal processor occurs, and also the system is stopped during the operation of the satellite communication system is stopped communication By preventing it, the reliability of satellite communication can be improved.

Description

Automatic recovery method of abnormal processor in satellite communication system

The present invention relates to a method for automatically recovering an abnormal processor in a satellite communication system. In particular, the central control station checks the operation status of each processor to notify the status of an abnormal processor and automatically recover the status when an abnormal processor occurs. Relates to an automatic recovery method of an abnormal processor.

In recent years, as the communication technology is rapidly developed, satellite communication, which enables subscribers located at remote sites to perform mutual communication through satellites, has become increasingly common, and as shown in FIG. Satellite (1) having a communication channel for communication, and a central control station (2) for controlling the entire satellite communication system, data terminals (13A, 13B) such as switchboards (11A, 11B), telephones (12A, 12B), and computers. And base stations 3A and 3B having an interface function for terminals such as facsimile 14A and 14B and providing a call function between various terminals through data transmission and reception with the central control station 2.

That is, in the satellite communication system, packet data for inquiring the status of the central control station 2 or each base station 3 is generated, and for each base station 3 through the service channel S, A polling operation is performed to determine the state of each base station 3 based on the state data transmitted from each base station 3 with respect to the packet data.

If there is a call request for a subscriber coupled to another base station 3 from a predetermined base station 3 during the polling operation, the state of the call requested base station is determined based on the state information obtained in the polling operation. When a call is possible, the traffic channel T is allocated to both base stations 3 so that subscribers connected to both base stations 3 can perform mutual communication.

2 is a configuration diagram showing the configuration of the central control station 2 for controlling the entire satellite system.

In FIG. 2, reference numeral 21 denotes an antenna for transmitting and receiving an uplink signal and a downlink signal with respect to the satellite 1, and 22 denotes an orthogonal mode converter for separating and inputting and receiving signals transmitted and received through the antenna 21; Is a low noise amplifier for low noise amplifying the frequency signal input through the orthogonal mode converter 22, 24 is a frequency down converter for converting the intermediate frequency signal IF applied through the low noise amplifier 23, 25 is this frequency The intermediate frequency signal applied from the down-converter 24 is separated into a plurality of intermediate frequency signals and output, and the intermediate frequency signals applied from the channel modems 28: 28 _{1 to} 28 n to be described later are combined and output. Frequency combination / distribution.

In the drawing, reference numeral 26 denotes a telephone data card for connecting terminals such as the telephone 12, the data terminal 13, the facsimile 14, etc. of FIG. Trunk interface port (28) for connecting, etc., 28 is demodulated and decoded the frequency signal from the base station input through the intermediate frequency combination / distribution unit 25, the trunk interface port (27) Encodes and modulates and outputs the transmission signal from the exchange inputted through the terminal or the transmission signal from the terminal inputted from the telephone data card 26 and control data for another base station output from the network control unit 32 to be described later. It is a channel modem. The channel modems 28:28 _{1 to} 28n are composed of a plurality of processors, and processors are respectively provided therein to perform modulation / demodulation and encoding / decoding respectively under the control of the processor.

In the figure, reference numeral 30 denotes a frequency up-converter for converting the intermediate frequency signal output from the intermediate frequency combination / distributor 25 to generate an uplink frequency signal, and 31 is output from the frequency up-converter 30. A high output amplifier for amplifying an uplink frequency signal, 32 transmits a control message to each base station 3 through a specific channel modem 28, and then each base station 3 based on a response message transmitted from the base station. It performs a polling function to check the status of, and if there is a call request from a specific base station, based on the information obtained in the polling process to determine whether the other base station is available for communication when the available traffic channel of the satellite By assigning (T) to both base stations, the two base stations can directly communicate with each other. Of a network control section for performing system control.

In addition, reference numeral 35 denotes a network management system for managing the overall network of the satellite communication system by the system manager managing the network control unit 32, the network control unit 32, the channel modem 28, the trunk interface port (27), and the telephone data card 26 is coupled via an MPH bus (Main PCM Highway BUS) 33 for transmitting and receiving processing data, such as voice data, and UPH (Utility PCM Highway: 34) for transmitting and receiving predetermined control data. Will be.

That is, when the central control station 2 having the above-described configuration is powered on and system operation starts, the processor of each subsystem, for example, the processor in the channel modem 28 or the processor of the network controller 32, etc., is in order. In this case, a processor communicating with other subsystems is first driven, and then a processor is stored, which stores data in a database of the network management system 35, and then the remaining processors are driven.

Therefore, after the initialization, each processor performs an operation independently. Since each processor does not know an operation state of another processor except for its own operation, during operation of the system in which each processor operates. When one of the processors goes down, the entire system is in a hang-up state, i.e., the processor to be processed is abnormally operated, but a processing request message is continuously received and a system resource is bound, resulting in a system stop or stop. This can cause a drop in reliability.

Accordingly, the present invention has been made in view of the above circumstances, and includes a check processor for checking the operation status of the processors in charge of each system at the central control station of the satellite communication system, so that an abnormal processor is checked while checking each processor. The purpose of the present invention is to provide an automatic recovery method of an abnormal processor in a satellite communication system that can notify its status and recover automatically when it occurs.

1 is a system configuration diagram schematically showing the configuration of a general satellite communication system.

2 is a configuration diagram showing the configuration of a central control station 2 for controlling the entire satellite system.

3 is a block diagram showing an apparatus configuration for explaining an automatic recovery method of an abnormal processor in a satellite communication system according to a first embodiment of the present invention.

4 is an operation flowchart for explaining an automatic recovery method of an abnormal processor in a satellite communication system according to a first embodiment of the present invention.

*** Explanation of symbols for the main parts of the drawing ***

1: satellite 2: central control station

3: base station 21: antenna

22: orthogonal mode converter 23: low noise amplifier

24: frequency down converter 25: intermediate frequency combination / distribution unit

26: Telephony Data Card 27: Trunk Interface Port

28: channel modem 30: frequency up converter

31: high power amplifier 32: network control unit

33: MPH bus 34: UPH bus

35: network management system 301: network control unit processor

302: network management system processor 303 to 305: SCU processor

306: Inspection Processor

The automatic recovery method of the abnormal processor in the satellite communication system according to the present invention for realizing the above object is a check processor coupled to the processor of each system to check the operating state of each processor, and a network for managing the overall network of each system In the central control station of the satellite communication system having a management system, an initialization execution step in which the processor of the main system and the processors of other subsystems are sequentially driven to perform initialization, and an inspection message for checking the operation state of the processor. A check message sending step of transmitting a check result message to a processor of each system, a check result message receiving step of receiving check result data from each processor, a check result message analyzing step of analyzing a received check result message, and analyzing the check result message to be abnormal Processor exists In this case, it characterized in that it comprises a check result sending step of sending the check result of the processor to the network management system, and the abnormal processor recovery step of restarting the abnormal processor.

The processor may recognize the processor as an abnormal processor when there is a processor in which the check message is not received after the check message is sent to the processor of each system in the check result message receiving step.

That is, according to the present invention having the above configuration, the central control station of the satellite communication system having a check processor for checking the processor of each system, by checking the operating state of the processors of each system, when an abnormal processor is generated You will be able to recover immediately.

Therefore, the system can be prevented from being interrupted while the satellite communication system is in operation, thereby improving reliability of the satellite communication.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 3 is a block diagram illustrating an apparatus for explaining an automatic recovery method of an abnormal processor in a satellite communication system according to a first embodiment of the present invention.

In FIG. 3, the network controller 32 is controlled through an MPH bus (Main PCM Highway BUS) 33 for transmitting and receiving processing data such as voice data and a UPH (Utility PCM Highway: 34) bus for transmitting and receiving predetermined control data. The network control unit processor 301, the processor 302 for controlling the network management system 35, and the processors 303 to 305 of the respective channel modems SCU1 to SCUn are combined, and the operating states of the processors are combined. An inspection processor 306 for inspecting is coupled.

Next, the operation of the device having the above configuration will be described with reference to the operation flowchart shown in FIG.

First, when the system administrator turns on the satellite communication system according to the present invention, each system operates according to the power supply. The main system, that is, the network controller processor 301 is driven and operated, and other subsystems are operated. Initialization operations in which the processors are sequentially driven are executed (step ST1).

After the initialization operation is executed, the check processor 306 generates a check message for checking the operation state by the processor of each system operation and sends it to each system through the UPH bus 34 (step ST2).

Accordingly, the processor of each system executes a check program based on a check message received from the check processor 306 to check the operation state, and sends the result back to the check processor 307.

Subsequently, the check processor 306 determines whether a check result message is received from each subsystem (step ST3). The check processor 306 recognizes the processor of the subsystem that does not receive the check result message as an abnormal processor (ST4). step).

However, when a check result message is received from each subsystem, the check processor 306 analyzes the received check result message (step ST5). Therefore, if there is no processor that is determined to be an abnormal processor by analyzing the received check result message, the time is counted until the next periodic check time (step ST7).

On the other hand, if there is a processor that is determined to be an abnormal processor by analyzing the received check result message, and transmits the check result of the processor to the network management system 35, so that the network administrator can know it ( ST8 step).

Then, the check processor 306 generates and sends a control message for restarting the system to the system found to be the abnormal processor, so that the operation of rebooting the processor found to be the abnormal processor is executed again (ST9). step).

That is, according to the embodiment, by performing the initialization of the satellite communication system to check the operating state of each system processor, it is possible to immediately recover if an abnormal processor occurs.

In addition, this invention is not limited to the said Example, It can variously deform and implement within the range which does not deviate from the technical summary of this invention.

As described above, according to the present invention, it is possible to prevent communication from being interrupted due to the occurrence of an abnormal processor during operation of the satellite communication system, thereby improving reliability of satellite communication.

Claims (2)

In the central control station of the satellite communication system having a check processor coupled to the processor of each system for checking the operating state of each processor, and a network management system for managing the overall network of each system, An initialization execution step in which a processor of the main system is driven and a processor of another subsystem is sequentially driven to perform initialization; A check message sending step of sending a check message for checking the operation status of the processor to the processor of each system, Check result message receiving step of receiving check result data from each processor, Check result message analysis step of analyzing the received check result message, A check result sending step of sending a check result of the corresponding processor to the network management system if an abnormal processor exists by analyzing the check result message; And an abnormal processor recovering step of restarting the abnormal processor. The method of claim 1, Abnormal processor in the satellite communication system characterized in that the processor is recognized as an abnormal processor, if there is a processor that transmits the check message to the processor of each system in the receiving step of the check result message, the check result message is not received. How to recover automatically.