KR19980059144A - Base station information management method of satellite communication system - Google Patents

Abstract

In the present invention, the base station data storage unit 524 and the base station information storage unit 351 are divided into tables, and each table stores predetermined error check data corresponding to the data in the table. The error check data is generated through an exclusive OR of the data stored in the storage units 351 and 524.

When the parameter update command is received in the base station 3, the parameter update operation is first performed according to the corresponding command, and then the result data of exclusively ORing the error check data of the updated data and the table including the data. Is added as error check data to generate an acknowledgment message, and the obtained error check data is updated and registered in the base station data storage unit 524.

On the other hand, when the confirmation message is received from the predetermined base station 3 in the central control station 2 as described above, the update data included in the received message and the update data of the base station information storage unit 351 are added to the data. The error check is performed by exclusively ORing the error check data stored in the corresponding table and comparing the result data with the error check data included in the received message.

Description

Base station information management method of satellite communication system

The present invention relates to a satellite communication system, and more particularly, to a method for managing base station information of a satellite communication system, which is capable of preventing a malfunction of a system due to a data mismatch between a central control station and a base station in managing information of a base station at a central control station. It is about.

Recently, with the rapid development of communication technology, satellite communication, which enables subscribers located at remote sites to perform mutual communication through satellites, has become increasingly common.

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

In Fig. 1, reference numeral 1 is a satellite having a plurality of communication channels, 2 is a central control station for controlling the entire satellite communication system, and 3 (3A, 3B) is an exchanger (11A, 11B) or a telephone (12A, 12B). And interface functions for terminals such as data terminals 13A and 13B and facsimile 14A and 14B, such as a computer, and communication between the various terminals through data transmission and reception with the central control station 2. It provides a base station.

In FIG. 1, reference numeral S denotes a service channel for transmitting and receiving control data, and T denotes a traffic channel for transmitting and receiving data or voice.

That is, in the satellite communication system, the central control station 2 first generates packet data for inquiring the status of each base station 3, and transmits the packet data to each base station 3 through the service channel S. And the polling operation of determining the state of each base station 3 based on the state data transmitted from each base station 3 with respect to the packet data.

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

On the other hand, in the satellite communication system described above, since the central control station 2 and each base station 3 are located at remote locations, software or various operations of the apparatus used in the base station 3 or the central control station 2 are performed. There is a big inconvenience when updating parameters.

Therefore, in the satellite communication system, in general, the base station 3 located at a remote location is reconfigured through a method of transmitting software or parameters to be updated from the central control station 2 to each base station 3.

However, in the parameter updating method as described above, since the parameter data is transmitted from the central control station 2 to the base station 3 through the wireless communication network, when the weather condition or the communication condition is not good, part of the transmitted data is damaged. There is a possibility of becoming.

If a difference occurs between the base station data held by the central control station 2 and the data of the corresponding base station held by the base station due to the damage of the transmission data as described above, the control process of the central control station 2 and The inconsistency between the operations of the base station 3 makes it impossible to precisely control the entire satellite communication system.

Accordingly, the present invention has been made in view of the above circumstances, and in particular, a base station information management method of a satellite communication system that can prevent data inconsistency between the base station and the central control station when updating parameters, such as the base station. The purpose is to provide.

1 is a system configuration diagram showing an overview of a general satellite communication system.

2 is a block diagram showing the configuration of a central control station to which the present invention is applied;

3 is a block diagram showing the configuration of a network management system in FIG.

Figure 4 is a block diagram showing the configuration of a base station to which the present invention is applied.

FIG. 5 is a block diagram illustrating a configuration of a network controller in FIG. 4. FIG.

6 is a memory map diagram of a base station information (data) storage unit of FIGS. 2 and 5;

7 shows an example of the format of a confirmation message sent from the base station to the central control station.

* Brief description of the main parts of the drawing

1: satellite, 2: central control station,

3: base station, 21, 41: antenna,

22, 42: quadrature mode converter, 23, 43: low noise amplifier,

24, 44: frequency down converter, 25, 45: frequency combination / distribution,

26, 46: telephone data card, 27, 47: trunk interface port,

28, 48: channel modem, 30, 50: frequency up converter,

31, 51: high power amplifier, 32, 52: network control unit,

35: network management system.

The base station information management method of the satellite communication system according to the present invention for realizing the above object comprises a first base station information storing means for storing base station data for each base station and based on the base station information stored in the base station information storing means. And a base station including a central control station configured to perform control processing for the base station, and a second base station information storing means for storing its own base station information, wherein the storing means is divided into areas by a predetermined table. In the satellite communication system, a first error check data generation step of generating predetermined error check data by processing data stored in the first and second base station information storage means in a table unit, and changing and setting base station information. An input step of inputting an update command for the corresponding base station; A first data update step of executing a data update operation for the second base station information storage means according to the update command, transmitting the updated data to the central control station as a confirmation message; An acknowledgment message sending step of adding and transmitting predetermined error check data obtained by exclusively ORing the checked data and the error check data included in the table including the data, the update data included in the confirmation message and the corresponding data An error detection step of detecting data inconsistency between the base station and the central control station by exclusively ORing the error check data in the table to generate predetermined error check data, and comparing the error check data with the received data; Based on the confirmation message The first base station to update the information storage means characterized by configured to include a second data updating step.

According to the present invention having the above-described configuration, the data stored in the base station information storage unit provided in the base station and the base station data storage unit provided in the central control station as well as the data currently updated through the comparison operation of the error check message It is possible to determine whether they match completely. Therefore, the operational stability of the satellite communication system can be achieved.

In addition, since the stored data comparison between the base station information storage unit and the base station data storage unit is performed in a table unit, the data restoration operation is very easy when data mismatch is detected.

Hereinafter, an embodiment according to the present invention will be described with reference to the drawings.

2 is a configuration diagram showing the configuration of a central control station to which the present invention is applied.

In FIG. 2, reference numeral 21 is an antenna for transmitting and receiving an uplink signal and a downlink signal with respect to the satellite (1: FIG. 1), and 22 is a signal for transmitting and receiving through the antenna 21 using a polarization property of frequency. Orthogonal mode converter for separately inputting and outputting, 23 is a low noise amplifier for low noise amplification of 12.25 to 12.75 GkHz downlink frequency signal input through the orthogonal mode converter 22, 24 is applied through this low noise amplifier 23 A frequency down converter for converting the frequency signal, for example, into an intermediate frequency signal IF of 70 MHz, and outputting the intermediate frequency signal IF applied from the frequency down converter 24 into a plurality of intermediate frequency signals. In addition, the intermediate frequency combination / distribution unit outputs a combination of intermediate frequency signals applied from the channel modems 28:28 _{1 to} 28n to be described later.

In the drawing, reference numeral 26 denotes a telephone data card for connecting terminals such as a telephone 12, a data terminal 13, a facsimile 14, or the like as shown in FIG. Trunk Interface Port for connecting to other exchanges.

In addition, reference numerals 28 (28 _{1 to} 28n) in the drawing demodulate and decode the frequency signals from the base station input through the intermediate frequency combination / distributor 25 described above, and also use the trunk interface port 27. Encoding, modulating and outputting a transmission signal from an exchange signal input through the terminal or a transmission signal from a terminal input from the telephone data card 26 and control data for another base station output from the network controller 32 to be described later. Channel modem.

In the drawing, reference numeral 30 denotes a frequency up-converter for generating an uplink frequency signal by converting a 70 MHz intermediate frequency signal output from the intermediate frequency combination / distributor 25 into a frequency of 14.0 to 14.5 GHz, for example. And 31 denotes a high output amplifier for amplifying the uplink frequency signal output from the frequency up-converter 30.

On the other hand, the reference numeral 31 in the drawing is a polling to check the status of each base station 3 based on a response message transmitted from the base station 3 after sending a control message to each base station 3 through a specific channel modem 28 If there is a call request from a specific base station, the other base station determines whether or not the other base station can communicate with each other based on the information obtained during the polling process. It is a network control unit that performs system control such as assigning T) to both base stations so that both base stations can directly communicate with each other.

Here, the network control unit 32, the channel modem 28, the trunk interface port 27 and the telephone data card 26 are MPH bus (Main PCM Highway BUS: 33) for transmitting and receiving processing data, such as voice data And UPH bus (Utility PCM Highway BUS 34) for transmitting and receiving the predetermined control data.

In the drawing, 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.

3 is a block diagram showing the configuration of the network management system 35. In the drawing, reference numerals 351 (351 _{1 to} 351n) denote base station data storage units for storing information on each base station provided in the satellite communication system. The base station data storage unit 35 stores the same data as the base station data stored in the base station.

6 is a memory map illustrating a memory configuration of the base station information storage unit 351. The base station information storage unit 351 stores base station information in table units and corresponds to the last address of each table. In the area, error check data corresponding to data stored in the table is stored.

The error check data is composed of one byte of data obtained by exclusively ORing the data stored in each of the tables (Tables 1 to n).

In FIG. 3, reference numeral 352 denotes a keyboard for the system administrator to execute control processing for the satellite communication system, 353 denotes a monitor for displaying various operating conditions of the central control station 2 or the base station 3, and 354 It is a printer for printing and outputting various processing data related to satellite communication system.

Reference numeral 355 denotes a processor that performs control processing of the entire satellite communication system according to the manipulation data input through the keyboard 352.

4 is a block diagram showing the configuration of the base station 3, which is substantially the same as the configuration of the central control station 2 described above.

In FIG. 4, however, unlike the central control station 2, a network management system is not installed, and the network control unit 52 is provided to a predetermined subscriber in accordance with control data transmitted from the central control station 2. Assignment control of the channel modem 48 is executed.

In addition, the network control unit 52 manages base station data such as various parameters for the base station, and performs an update function according to a predetermined parameter update command sent from the central control station 2, in particular. The base station data is sent to the central control station 2.

5 is a configuration diagram showing the configuration of the network control unit 52 described above.

In FIG. 5, reference numeral 521 denotes a processor which controls the entire system of the base station and performs a base station data update operation. In particular, reference numeral 522 denotes a TDM from the central control station applied through a predetermined channel modem 48 in FIG. A service channel controller (SCC: Service Channel) that receives a message of a time division multiplex stream and extracts packet information and generates and outputs an S-ALOHA message based on the packet information output from the processor 521. Controller 523 is a dual port RAM for data transmission and reception between the processor 521 and the service channel controller 522.

In the drawing, reference numeral 524 denotes a base station data storage unit for storing information such as various parameters of the base station, and 525 denotes a program memory in which an operation program of the processor 521 is stored.

In addition, the base station data storage unit 524 has a memory map structure as shown in FIG. 6, and is configured substantially the same as the base station information storage unit 351 provided in the central control station 2.

Next, the operation of the apparatus according to the present invention will be described.

When a system administrator inputs a parameter update command for a predetermined base station by operating a keyboard 352 provided in the network management system 35 (FIG. 2), the processor 355 issues the parameter update command to the network controller 32. ), And the network control unit 32 outputs the input command data through a predetermined channel modem 28.

Accordingly, the parameter update command is output to the corresponding base station through the intermediate frequency combination / distributor 25, the frequency up-converter 30, the high power amplifier 31, the quadrature mode converter 22, and the antenna 21. do.

On the other hand, in the base station 3, when a parameter update command transmitted from the central control station 2 is received through the antenna 41, it is a quadrature mode converter 42, a low noise amplifier 43, and a frequency down converter. 44, the intermediate frequency combination / distributor 45 and the predetermined channel modem 48 are input to the network controller 52.

Subsequently, when the parameter update command is input, the processor 521 (FIG. 5) of the network controller 52 executes the parameter update operation by updating and registering the base station information storage unit 524 based on the command data. do.

When the update operation is completed, the processor 524 sends an acknowledgment signal to the central control station 2.

6 is a block diagram showing the data format of the confirmation signal, which is a message ID indicating the type of the message, a message length indicating the total number of bytes of the message, an update code indicating the type of update, and whether the update is successful. The update result indicating whether the failure, the packet number of the message, the UDL indicating the total number of DDL, the base station ID, the table number where the data to be updated is located, the offset data indicating the address value in the table, the number of data to be updated, That is, it includes DDL indicating the number of bytes, data changed by this parameter update (Data 1 to Data n), and 1 byte of error checking data which enables the receiving side to check whether there is an error of the corresponding message.

In addition, the error check data may be generated by, for example, performing exclusive OR on the table including the updated data (Data 1 to Data n) and the data updated in the base station data storage unit 524 shown in FIG. 6. In addition, the error check data generated in this manner is updated and registered as the error check data of the corresponding table of the base station data storage unit 524.

Subsequently, the confirmation message having the above format is transmitted in the reverse direction to the above-described update command.

That is, when the above-mentioned message is generated and output by the network controller 52, it is a predetermined channel modem 48, the intermediate frequency combination / distributor 45, the frequency converter 50, and the high output amplifier 51. It is output through the orthogonal mode converter 42 and the antenna 41.

Then, when the confirmation message is received through the antenna 21 of the central control station 2: FIG. 2, it is again orthogonal mode converter 22, low noise amplifier 23, frequency down converter 24, The intermediate frequency combination / distributor 25 and the predetermined channel modem 28 are input to the network control unit 32, and the network control unit 32 transmits this to the network management system.

On the other hand, in the network management system 35 shown in FIG. 3, when the confirmation message shown in FIG. 6 is input from the network control unit 32 as described above, the processor 355 based on the table number included in the input message. The table corresponding to the data to be updated is determined. Then, the exclusive data of the updated data (Data 1 to Data n) of the message and the error check data stored in the corresponding table of the base station information storage unit 351 is combined, and the error of the result data is included in the message. The data error is checked by comparing it with the check data.

Subsequently, when both data coincide during the data error check, the stored data of the base station information storage unit 351 corresponding to the base station is stored based on the offset data and the update data Data 1 to Data n of the message. In addition to updating, the error checking data of the corresponding table is updated and registered based on the error checking data included in the message.

If the comparison result does not match, an error state is displayed through the monitor 353 after performing an update operation and an error check data update operation on the base station information storage unit 351 based on a message that is input first. Done.

Therefore, in this case, the system manager sends a command to the base station to transmit the data of the table stored in the base station information storage unit 351, and accordingly the base station information based on the data transmitted from the base station. By updating the storage unit 351 as a whole, the base station information of the base station and the central control station is matched.

In addition, if the acknowledgment message is not received until a predetermined time elapses after transmitting the parameter update command, the processor 35 retransmits the parameter update command to the corresponding base station to execute the parameter update operation again.

That is, in the above embodiment, the base station data storage unit 524 and the base station information storage unit 351 are divided into areas by table, and each table stores predetermined error check data corresponding to the data in the table. do. The error check data is generated through an exclusive OR of the data stored in the storage units 351 and 524.

When the parameter update command is received in the base station 3, the parameter update operation is first performed according to the corresponding command, and then the result data of exclusively ORing the error check data of the updated data and the table including the data. Is added as error check data to generate an acknowledgment message, and the obtained error check data is updated and registered in the base station data storage unit 524.

On the other hand, when the confirmation message is received from the predetermined base station 3 in the central control station 2 as described above, the update data included in the received message and the update data of the base station information storage unit 351 are added to the data. The error check is performed by exclusively ORing the error check data stored in the corresponding table and comparing the result data with the error check data included in the received message.

Therefore, in the above embodiment, the base station information storage unit 524 provided in the base station 3 and the base station provided in the central control station 2 as well as the data currently updated through the comparison operation of the error check message described above. It is possible to determine whether the stored data of the data storage unit 351 matches.

In addition, since the data comparison is made in a table unit, if the information of the base station and the information of the central control station are inconsistent with each other, the base station information of the base station and the central control station is restored by restoring information of the table where the mismatch occurs. Can be matched.

In addition, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the technical scope of the present invention.

As described above, according to the present invention, it is possible to realize the base station information management method of the satellite communication system which can prevent data mismatch between the base station and the system information stored in the central control station.

Claims (4)

A central control station having a first base station information storing means for storing base station data for each base station and performing control processing for the base station based on the base station information stored in the base station information storing means; A satellite communication system comprising a base station having a second base station information storage means for storing the data, and wherein the storage means is divided into predetermined table units, the satellite communication system being stored in the first and second base station information storage means. A first error check data generation step of processing predetermined data in table units to generate predetermined error check data, an input step of inputting an update command for changing and setting base station information, and transmitting the update command to the corresponding base station. Command sending step, to the second base station information storing means according to the update command A first data update step of executing a data update operation for the central control station, transmitting updated data to the central control station as an acknowledgment message, and performing exclusive logical OR on the updated data and error checking data included in a table including the data; Acknowledgment message sending step of adding and transmitting the obtained predetermined error checking data, exclusively combining the update data included in the confirmation message with the error checking data of a table corresponding to the data, and generating predetermined error checking data, and An error detection step of detecting a data mismatch state between the base station and the central control station in comparison with the error check data added to the received data, and a second data update step of updating the first base station information storing means based on the confirmation message; Configured including The base station information management method for a satellite communications system, characterized by. The base station information management of the satellite communication system according to claim 1, further comprising a control check data updating step of registering data obtained by exclusively ORing the update data and the existing error check data as new error check data. Way. The method of claim 1, If an error is detected in the error determination step, the base station information management method of the satellite communication system, characterized in that it further comprises an error display step for displaying it to the system administrator. The method of claim 1, wherein if the confirmation message is not received for a predetermined time after the command sending step, the command sending step is executed again.