KR100250616B1 - Method for monitoring service channel message in satellite communication system - Google Patents

Abstract

PURPOSE: A method for monitoring a service channel message in a satellite communication system is provided to make a system operator monitor transceiving control messages between a central control station and many base stations, so that the system operator can easily detect a cause when a failure occurred in the system. CONSTITUTION: If a monitoring operation command for monitoring a control message transceived through a service channel is inputted, a processor stands by an inputting of monitoring condition data. If the monitoring condition data is inputted, the processor extracts a transceiving message of an appropriate service channel on the basis of the monitoring condition data, and stores the extracted transceiving message in a message storage. If a monitoring operation canceling command is inputted, the processor outputs the transceiving message stored in the message storage, and initializes the message storage.

Description

Service Channel Message Monitoring Method in Satellite Communication System

The present invention relates to a communication system using an artificial satellite, and in particular, a satellite communication that allows a system operator to monitor a communication message between a central control station performing overall control of the system and a base station directly connected to a plurality of subscribers. A control channel signal monitoring method in a system.

At present, satellite communication, which enables subscribers who are located at remote sites to communicate through satellites, is becoming more common. Such satellite communication does not require a separate signal line for communication. It is also useful as a communication method in mountainous countries such as Korea or Korea.

In the above-mentioned satellite communication, a pre-assignment multiple access (PAMA) method of pre-assigning each communication channel for each subscriber in advance according to the channel allocation method and a demand assignment multiplex (DAMA) for allocating a communication channel according to a subscriber's request Access) method, in general, voice communication uses the DAMA method and data communication uses the PAMA method in consideration of the price and the effectiveness of the communication channel.

1 is a system configuration diagram showing an overall configuration of a satellite communication system employing the DAMA method described above.

In Fig. 1, reference numeral 1 is an artificial 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). Communication function between the various terminals through data transmission and reception with the central control station 2 as well as an interface function for terminals such as data terminals 13A and 13B and facsimile 14A and 14B, such as a computer. The base station that provides.

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.

In the above-described configuration, the central control station 2 transmits a control message through a service channel in a normal state and then, based on a response message sent from the base station 3, that is, communication It performs a polling function to check the available capacity or the utilization status of the communication channel. When there is a call request from a specific base station, for example, the base station 3A to the terminal of the base station 3B, it is determined whether the corresponding base station 3B is in a state in which communication is possible based on the information obtained in the polling process. In the case of the communicable state, the available traffic channel T of the satellite is allocated to both base stations 3A and 3B so that both base stations 3A and 3B can directly communicate with each other.

Subsequently, when the communication between the base stations 3A and 3B is terminated and the communication termination signal is applied through the service channel S from the base station 3A, which has been requested for communication, the central control station 2 is applied to both base stations. By executing the communication termination process, the traffic channel T which has been provided to both base stations 3A and 3B is released.

2 is a block diagram showing the configuration of the central control station 2 described above.

In FIG. 2, reference numeral 21 denotes an antenna for transmitting and receiving an satellite 1, an uplink signal, and a downlink signal, and 22 denotes an antenna 21 using a polarization property of frequency. Orthogonal Mode Transducer for separating and transmitting and receiving signals transmitted and received through, Low Noise Amplifier (Low Noise Amplifier) for low noise amplification of 12.25 to 12.75G kHz downlink frequency signal input through the orthogonal mode converter, A frequency down converter for converting a frequency signal applied through the low noise amplifier to, for example, an intermediate frequency signal IF of 70 MHz, and a 70 MHz applied from an IF combination / distributor 23 to be described later. A frequency upconverter for converting an IF signal into a microwave of 14.0 to 14.5GHz for generating an uplink frequency signal, and an upstream output from the frequency upconverter An RF processor including a high power amplifier for amplifying a link frequency signal.

In addition, reference numeral 23 separates and outputs the intermediate frequency signal applied from the RF processor 22 into a plurality of intermediate frequency signals, and is applied from the SCPC (Single Channel Per Carrier) channel unit 24 to be described later. An IF combination distributor (Combiner / Distributer) for combining and outputting the intermediate frequency signal to be used, 24 is a network control unit 30 to demodulate and decode the intermediate frequency signal applied from the IF combination distribution unit 23 to be described later And an SCPC channel unit for encoding and modulating the signal output from the network control unit 30 and outputting the same to the IF combination distribution unit 23.

Here, the IF combination distribution unit 23 is adopted for system scalability when using a plurality of SCPC channel units 24.

Further, reference numeral 30 denotes a network controller for controlling the overall system, which transmits a control message to each base station 3 through a TDM channel and then is transmitted from the corresponding base station 3 through an S-ALOHA channel. The polling function of checking the state of each base station 3 is performed based on the response message. When there is a call request from the specific base station 3, the network control unit 30 determines whether the other base station 3 is in a communication state on the basis of the information obtained in the polling process. In this case, the available traffic channel T and modem of the satellite 1 are allocated to both base stations 3 so that both base stations 3 can directly communicate with each other.

In addition, reference numeral 40 is a network management apparatus for allowing a system operator to grasp and manage the overall situation of the system by using a predetermined operating platform.

3 is a block diagram showing the configuration of the network control unit 30 in FIG. 2, in which, reference numeral 31 is a processor for performing overall control of the system, and 32 is the SCPC channel unit 24. The service channel controller extracts packet information from the authorized message and outputs it to the processor 31, and generates a series of TDM stream messages according to the control signal of the processor 31 and outputs the same to the SCPC channel unit 24. (Service Channel Controller), 33 is a dual port RAM provided for data transmission and reception between the processor 31 and the service channel controller 33.

Reference numeral 34 denotes a program storage unit for storing an operation program of the processor 31, and reference numeral 34 denotes a base station information storage unit for storing state information of each base station 3 transmitted through a service channel (S). to be.

That is, in the satellite communication system having the above configuration, the processor 31 periodically sends a polling signal through the TDM channel, and then based on the response message transmitted from the base station 3 through the S-ALOHA channel. The state of the base station is checked and state information of each base station 3 is retained. In addition, when a predetermined call request is made, the processor 31 allocates an available communication channel and a communication modem based on the recording data of the base station information storage unit 35 to provide a communication function between subscribers and to release a predetermined call. Based on the message, it controls to release the communication channel and modem used by the call.

Meanwhile, the service channel S is one TDM channel which is a transmission channel from the central control station 2 to the base station 3 and up to four S channels which are transmission channels from the base station 3 to the central control station 2. It is composed of an ALOHA channel. The TDM channel uses a time division multiplexing (TDM) scheme, and the S-ALOHA channel uses a multiple protocol based on a slotted aloha (S-ALOHA) scheme.

However, since there is no monitoring function for the communication message between the central station 2 and the base station 3, it is impossible to determine the cause when a problem occurs in the system, so that the system operator may have to spend a lot of time in troubleshooting the system. do.

Accordingly, an object of the present invention is to provide a service channel message monitoring method in a satellite communication system that allows a system operator to monitor transmission and reception control messages between a central control station and a plurality of base stations. There is this.

1 is an overall system configuration for explaining the outline of a general satellite communication system.

FIG. 2 is a block diagram showing the configuration of the central control station 2 in FIG.

3 is a block diagram showing the configuration of the network control unit 30 in FIG.

Figure 4 is a block diagram for explaining the hardware service channel message monitoring method in a satellite communication system according to an embodiment of the present invention.

5 is a flowchart illustrating a service channel message monitoring method in a satellite communication system according to an embodiment of the present invention.

* Brief description of the main parts of the drawing

1: satellite 2: central control station

3A, 3B: Base station 11A, 11B: Switchboard

12A, 12B: Telephone 13A, 13B: Data Terminal

14A, 14B: Facsimile 21: Antenna

22: RF processing unit 23: IF combination distribution unit

24: SCPC channel unit (SCU) 30: network control unit

31, 101: processor 32: dual port RAM (DP RAM)

33: service channel controller (SCC) 34, 104: program storage unit

35: base station information storage unit 40: network management device

105: monitoring condition information storage unit 106: monitoring message information storage unit

In the satellite communication system according to the present invention for realizing the above object, the service channel message monitoring method comprises: a satellite communication system for providing a communication function between subscribers by combining a plurality of base stations respectively coupled with a plurality of subscribers through satellites; A monitoring condition data input standby step of waiting for input of monitoring condition data when a monitoring operation command for monitoring control messages transmitted and received through a service channel is input; Extracting and storing the transmission and reception message to extract the transmission and reception messages of the service channel and store them in the message storage, and when the command to cancel the monitoring operation is input after the transmission and reception of the transmission and reception message, And a first message output step of outputting to the operating system and initializing the message storage unit.

On the other hand, the present invention outputs the transmission and reception messages stored in the message storage unit to the storage and the message storage unit when the storage area of the message storage is filled in the state that the monitoring operation release command is not input after the step of extracting and storing the transmission and reception message And a second message outputting step of initializing, and when an output request command for a stored message is input after the transmitting / receiving message extracting and storing step is not inputted, a monitoring operation cancel command is stored in the message storing part. And a third message outputting step of outputting a transmission / reception message to the operating system and initializing the message storage unit.

That is, according to the above, by allowing the system operator to monitor the control messages transmitted and received through the service channel, it is possible to quickly determine the cause when a problem occurs in the system.

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

FIG. 4 is a block diagram illustrating a hardware method of monitoring a service channel message in a satellite communication system according to an embodiment of the present invention.

In the figure, reference numeral 101 denotes communication continuously available for call request based on the status information of each base station 3 through the periodic polling operation as described in FIG. A processor for performing overall system control such as controlling communication between subscribers by allocating a channel and a communication modem, in particular, the processor 101 is a service channel message monitoring command message transmitted from the network management device 40. And extracting and storing the transmission / reception control message through an appropriate service channel based on the monitoring condition message, and outputting the transmission / reception control message to the network management device 40 when a predetermined condition is reached.

In addition, reference numeral 104 is a program storage unit for storing the operating program of the processor 101, 105 is the monitoring condition data input by the operation of the system operator to the network control unit 100 through the network management device 40 As it is input, the monitoring condition information storage unit 106 for storing the monitoring condition data, 106 is a monitoring message information storage unit for storing the transmission and reception messages extracted according to the control operation of the processor 101.

In addition, reference numeral 110 denotes a network management apparatus having a predetermined operating platform so that a system operator can directly manage the system. In particular, the network management apparatus 110 may include a monitoring function key for monitoring a transmission / reception message of a service channel; A release key for releasing a monitoring function and a predetermined output means for outputting a monitored control message input according to a control signal of the processor 101 are provided. When a key is input, the corresponding key signal is output to the processor 101, and when a message monitored by the processor 101 is transmitted, the key signal is output to the output means.

Next, an embodiment according to the present invention will be described in more detail with reference to FIG. 5.

First, when the system is activated, the processor 101 initializes the monitoring message information storage unit 105.

Thereafter, when a monitoring operation command is received from the network management apparatus 110 (step ST1), the processor 101 waits for a monitoring condition message for a transmission / reception message of a service channel to be received (step ST2).

Subsequently, when the monitoring condition message is received, the processor 101 controls to store the received monitoring condition message in the monitoring condition information storage unit 105 (step ST3).

Here, the monitoring condition message is a system operator directly inputs a specific condition for a transmission / reception message to be monitored through the operating platform, for example, a specific base station unique number, a specific signal transmitted from the central control station 2 to the base station 3. Refers to a condition for extracting a specific message that a system operator wants to grasp, such as a unique code for a command.

Subsequently, the processor 101 stores the TDM channel message among the TDM channel messages outputted to any base station 3 through the service channel controller 32 based on the monitoring condition data stored in the monitoring condition information storage unit 105. A message suitable for the monitoring condition is extracted, and a message suitable for the monitoring condition is extracted from the received S-ALOHA message transmitted from the plurality of base stations 3 and decoded through the service channel controller 32 (step ST4).

In addition, the processor 101 controls to store the extracted monitoring message in the monitoring message information storage unit 106.

Subsequently, the processor 101 continuously checks whether the storage area of the monitoring message information storage unit 106 is full, whether there is an output request for the monitored and stored message, or whether a release command is input to the monitoring operation command. Search (ST5, ST6, ST7 respectively).

At this time, the processor 101 is filled with the monitoring message information storage unit 106 (step ST5), the output request command for the monitored message is input (step ST6), or when the monitoring release command signal is received ( In step ST7), the monitoring message stored in the monitoring message information storage unit 106 is outputted to the network management apparatus 110 (step ST8).

Then, the network management device 110 outputs a monitoring message input under the control of the processor 101 through a predetermined operating platform.

Then, the processor 101 outputs the monitoring message to the network management device 110 and initializes the monitoring message information storage unit 106 (step ST9).

Meanwhile, the monitoring operation for the transmission / reception message as described above is repeatedly performed until the operation release command is input from the network management apparatus 110.

That is, according to the above embodiment, the system operator can monitor the control message transmitted and received through the service channel to quickly determine the cause of the problem in the system.

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

As described above, according to the present invention, the service channel message in the satellite communication system that enables the system operator to monitor the transmission and reception control messages between the central control station and the plurality of base stations so that the cause of the problem can be easily identified. The monitoring method can be realized.

Claims (3)

A satellite communication system for providing a communication function between subscribers by combining a plurality of base stations, each of which is combined with a plurality of subscribers through satellites; A monitoring condition data input standby step of waiting for input of monitoring condition data when a monitoring operation command for monitoring control messages transmitted and received through a service channel is input; Extracting and storing a transmission / reception message for extracting a transmission / reception message of a suitable service channel based on the monitoring condition data and storing the transmission / reception message in a message storage unit based on the monitoring condition data; And a first message output step of outputting a transmission / reception message stored in the message storage unit and initializing a message storage unit when a monitoring operation release command is input after the transmission / reception message extraction and storage step. Service channel message monitoring method in satellite communication system. The method of claim 1, A second message for outputting a transmission / reception message stored in the message storage unit and initializing the message storage unit when the storage area of the message storage unit becomes full after a monitoring operation release command is not input after the extracting and storing the transmission / reception message. Service channel message monitoring method in a satellite communication system, characterized in that configured to include an output step. The method of claim 1, If the output request command for the stored message is input while the monitoring operation release command is not input after the transmission and reception of the transmission / reception message, the transmission and reception message stored in the message storage unit is output as the operation and the message storage unit is initialized. 3. A service channel message monitoring method in a satellite communication system, characterized in that it comprises a message output step.

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