KR19980027347A - Device for preventing charging information loss of base station in satellite communication system and method thereof - Google Patents

Abstract

The present invention transmits the charging information to the central control station when the base station completes the call of the subscriber. If the charging information cannot be transmitted due to the loss of communication with the central control station, the base station stores the charging information in a predetermined memory and then controls the central control. The present invention relates to an apparatus and a method for preventing the loss of billing information of a base station in a satellite communication system that prevents the loss of billing information by transmitting billing information stored in a memory when communication with the station is resumed. A satellite communication system comprising a plurality of base stations and a central control station for controlling and controlling the base stations; The base station stores the call cancellation message including the billing information, the call cancellation message storing means, and if the corresponding response message is not received within a predetermined time after the call cancellation message is received, the call cancellation message is received. And storing control in the release message storage means and transmitting a release message through the packet when the reserved packet is allocated.

Description

Device for preventing charging information loss of base station in satellite communication system and method thereof

The present invention relates to a communication system using a satellite, and in particular, the base station transmits the charging information to the central control station upon completion of the subscriber's call, if the charging information is not transmitted due to the loss of communication with the central control station. The present invention relates to an apparatus and a method for preventing the loss of charging information of a base station in a satellite communication system that stores the information in a predetermined memory and then resumes communication with the central control station to prevent the loss of the charging information by transmitting the charging information stored in the memory. It is about.

Recently, with the rapid development of communication technology, satellite communication, which enables subscribers who are located at remote sites to make calls through satellites, has become increasingly common. Since such satellite communication does not require a separate signal line for a call, It is mainly used as a long distance communication between countries or as a communication method in a mountainous country such as Korea.

In the above-mentioned satellite communication, a PAMA (Pre-Assignment Multiple Access) method for allocating communication channels for each subscriber according to the channel assignment method and a DAMA (Demand Assignment Multiple Access) method for allocating communication channels according to a subscriber's request There are two methods. In general, in the satellite communication system for communication between subscribers, many DAMA methods are adopted in consideration of the cost and the effectiveness of the communication channel.

1 is a block diagram showing the overall system configuration of a general satellite communication system according to the DAMA method.

In Figure 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, 3 (3A, 3B) is a data terminal and facsimile, such as an exchange, a telephone, a computer, etc. A base station having an interface function for a terminal and providing a call function between the various terminals through data transmission and reception with the central control station 2.

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 is an antenna for transmitting / receiving an satellite 1, an uplink signal, and a downlink signal, and 22 is an antenna 21 through the antenna 21 using a polarization property of frequency. Orthogonal Mode Transducer (OMT) for separating and transmitting and receiving signals, 23 is a low-noise amplifier for low-noise amplifying 12.25 to 12.75 GkHz downlink frequency signal input through the orthogonal mode converter (22) Low Noise Amplifier (LNA), 24 is a frequency down converter (DC) for converting a frequency signal applied through the low noise amplifier 23 into an intermediate frequency signal IF of 70 MHz, for example.

In addition, reference numeral 25 separates and outputs the intermediate frequency signal IF applied from the frequency down converter 24 into a plurality of intermediate frequency signals, and also describes a Single Channel Per Carrier (SCP) channel unit to be described later. An intermediate frequency combiner / distributor (IF C / D) for combining and outputting an intermediate frequency signal applied from the SCU: 26, and 26 is an intermediate applied from the intermediate frequency combiner / distributor 25. It is a SCPC channel unit for demodulating, decoding, and outputting a frequency signal, and encoding and modulating and outputting a message output from the network controller 40 to be described later.

Here, the intermediate frequency combination / distributor 25 is employed for system scalability when using a plurality of SCPC channel units.

Further, reference numeral 27 denotes a frequency up-converter for converting an IF signal of 70 MHz applied from the IF combination / distributor 25 into an microwave of 14.0 to 14.5 GHz to generate an uplink frequency signal. And 28 are high power amplifiers (HPAs) for amplifying uplink frequency signals output from the frequency up-converter 27.

Reference numeral 40 denotes a state of each base station 3 based on a response message transmitted from the base station after transmitting a control message to each base station 3 through an arbitrary SCPC channel unit 26 _{1 to} 26 _N. Perform a polling function that checks whether a call is received from a specific base station, and determines if the other base station is in a communication state based on the information obtained in the polling process, and uses a satellite in a communication state. It is a network control unit that performs system control, such as by assigning possible traffic channels (T) and modems to both base stations to directly communicate with each other.

In addition, reference numeral 50 is a network management system for the system administrator to manage the network control unit 40 to manage the overall network of the satellite communication system.

3 shows the configuration of the base station 3 in FIG.

In general, the base station 3 has a configuration similar to that of the central control station 2 in FIG. 3, and since most of the configuration performs the same function as that of the central control station 2, Detailed description will be omitted.

In FIG. 3, reference numeral 70 denotes a base station controller which performs overall control of the base station. In particular, the base station controller 70 generates and transmits a predetermined S-ALOHA packet according to a call request from a subscriber. It is controlled to perform communication between subscribers through the available SCPC channel units 66 _{1 to} 66 _n or communication channels received from the control station 2. When the call is released, the call cancellation message including the billing information is sent.

The S-ALOHA packet is divided into a reserved packet and a random packet. The reserved packet is an area allocated by the central control station 2 to transmit various status information of the base station. A packet is an area set arbitrarily from the base station 3 in order to transmit irregularly occurring data in connection with call request or call release.

Further, base station information such as a call setup state and a channel use state of a subscriber coupled to the base station 3 is transmitted to the central control station 2 with respect to the polling of the central control station 2.

Next, the operation of the satellite communication system having the above configuration will be described.

In the normal state, the network controller 40 of FIG. 2 periodically performs a polling operation to check the state of each base station and, based on the call request message requested by the base station 3, selects a random communication channel and an SCPC channel unit. Will be allocated.

That is, the network controller 40 generates a TDM stream message from the packet data for checking the status of each base station, and then designates an arbitrary SCPC channel unit 26 to output the message.

Subsequently, the corresponding SCPC channel unit 26 converts the message into an intermediate frequency signal of 70 MHz by encoding and modulating the message, and outputs the intermediate frequency signal, which is combined by frequency in the IF combination / distributor 25. After that, the frequency increase converter 27 converts the frequency into an uplink frequency signal of, for example, 14.5GHz. The uplink frequency signal is output through the high power amplifier 28, the quadrature mode converter 22, and the antenna 21, and then transmitted to each base station 3 through the satellite 1 in FIG.

Then, when the base station control unit 70 of the base station 3 receives the downlink frequency signal of the TDM stream through the satellite 1, it extracts packet information from the frequency signal to the subscriber to any communication channel or SCPC channel. By allocating units, the controller can control the mutual communication or generate a response message of the S-ALOHA packet for the polling message and send it to the central control station 2.

On the other hand, the response message received by the antenna 21 from each base station 3 via the satellite 1, i.e., the downlink frequency signal of 12.25GHz, is frequency down through the orthogonal mode converter 22 and the low noise amplifier 23. It is applied to the converter 24 and converted into an intermediate frequency signal of 70 MHz, and then applied to an arbitrary SCPC channel unit 26 through the IF combination / distributor 25, demodulated and decoded, and then to the network controller 40. To be authorized.

In addition, the network controller 40 extracts packet information from the received message to generate an S-ALOHA packet, and then updates and registers a predetermined base station information storage unit based on this to hold state information for all base stations.

In addition, the network control unit 40 outputs the base station state information received from each base station 3 to the network management system 50, the network management system 50 to send the state information to the operator through a predetermined display device Will be displayed.

In addition, the above-described polling operation is continuously performed for each base station.

On the other hand, when there is a call request from another base station to another base station during the above-described polling operation, the network controller 40 searches for the state information of the called base station from a predetermined memory storing state information of each base station. It will assign the currently available communication channel and SCPC channel unit to the calling base station. When the communication channel and the SCPC channel unit is allocated, the base station 3 controls the subscribers to perform mutual communication through the corresponding SCPC channel units 66 _{1 to} 66 _N and the communication channel.

In addition, when the subscriber in communication terminates communication by placing the handset, the base station 3 receives a call cancellation message including charging information such as an incoming / outgoing call number, a call start time, and a call end time for the subscriber. 2), the central control station 2 performs a call release process by sending a response message to the base station 3 in response to the receipt of the charging information.

On the other hand, the operator (or manager) who operates the DAMA-SCPC system has the purpose of promoting the prompt and smooth communication of the general public through this system, but in general, it has no choice but to pursue profits in terms of maintenance of facilities. .

Thus, the operator manages the billing information of the subscriber who uses the communication channel as very important information, and has to seek special measures so that the billing information is not lost.

Accordingly, the present invention has been made in view of the above circumstances, and the base station releases the billing information of subscribers using the communication line and transmits the call to the central control station, whereby communication between the central control station and the base station is interrupted. If the response message is not received from the central control station for the reason, the corresponding charging information is stored in a predetermined memory, and then retransmission is performed when communication is communicated to prevent the loss of the charging information. The present invention relates to an apparatus and a method for preventing the loss of charging information of a base station in a satellite communication system.

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 a base station 3 in FIG.

Figure 4 is a block diagram showing the configuration of the charging information loss prevention device in the base station in the satellite communication system according to an embodiment of the present invention.

FIG. 5 is an operational flowchart for explaining the operation of the apparatus of FIG. 4. FIG.

* Brief description of the main parts of the drawing

1: satellite 2: central control station

3A, 3B: base station 21, 61: antenna

22, 62: orthogonal mode converter 23, 63: low noise amplifier

24, 64: Frequency down converter 25, 65: Intermediate frequency combination / distribution

26, 66: SCPC channel unit 27, 67: frequency converter

28, 68: high power amplifier 40: network control unit

50: network management system

70, 80: base station controller 81: counter

82: billing information storage

In the satellite communication system according to the first aspect of the present invention for realizing the above object, a method for preventing the loss of charging information of a base station is respectively combined with a plurality of subscribers, and a plurality of base stations are connected with different base stations and a central control station. A satellite communication system configured to perform communication between any subscribers by being coupled via satellite; The base station transmits a call release signal including a billing information when a call release request signal is received from a subscriber using a communication line; and if the response message according to the call release signal is not received for a predetermined time, the subscriber's billing A call clearing message storing step of storing a call clearing message containing information in a predetermined memory, and a call for reading a message stored in the memory and sending it through the allocated reserved packet when a reserved packet is allocated from the central control station. And a release signal retransmission step.

In addition, in the satellite communication system according to the second aspect of the present invention, the apparatus for preventing the loss of billing information of a base station includes a plurality of base stations coupled to a plurality of subscribers, and a satellite communication system including a central control station for managing and controlling the base station. In; The base station stores the call cancellation message storing the call cancellation message including billing information, and if the response message is not received within a predetermined time after the call cancellation message is received, the call cancellation message is received. It is characterized in that it comprises a control means for storing the release message storage means and sends a call release message via the packet when the reservation packet is allocated.

That is, according to the above configuration, if the response message for receiving the charging information is not received from the central control station, the charging information can be stored in a predetermined memory to prevent the loss of the charging information.

On the other hand, Figure 4 is a block diagram showing the configuration of the charging information loss prevention device of the base station in the satellite communication system according to an embodiment of the present invention, the embodiment according to the present invention with reference to the same diagram in more detail.

In Fig. 4, reference numeral 81 denotes a counter for performing a predetermined counting operation. The counter 81 increases the count value in accordance with a predetermined control signal of the base station controller 80, which will be described later.

Reference numeral 82 denotes a billing information storage unit for storing billing information including, for example, a call type, an incoming / outgoing call number, a call start time, a call end time, or the like of a communication line subscriber.

Reference numeral 80 denotes communication between the subscribers through the SCPC channel units 66 _{1 to} 66 _n and the communication channel allocated from the central control station 2, for example, as described with reference to FIG. Control function to output base station information such as call setup state, channel use state, etc. of subscribers coupled to the base station 3 to the central control station 2, and when the call is released, the call including billing information The release message is sent to the central station.

In addition, the base station controller 80 transmits charging information for a predetermined number of times if a predetermined response message is not received from the central control station 2 after the first charging information transmission. If not, the charging information is controlled to be stored in the charging information storage unit 82.

Next, the operation of the device having the above configuration will be described using the operation flowchart of FIG. 5.

First, when the base station 3 receives a call request from the subscriber, the base station 3 generates a predetermined S-ALOHA packet for the call request message and sends it to the central control station 2, which is then allocated from the central control station 2. The subscriber communication is controlled based on the SCPC channel unit and the communication channel.

Subsequently, the base station controller 80 of the base station 3 receives the On-Hook signal by the subscriber using the communication line by dropping the handset (step ST1), and the call type, origination call number, and call start. A call release message including billing information such as time and call termination time is sent, and the counter 81 is reset (step ST2 and ST3).

Subsequently, the base station controller 80 waits to receive a response message from the central control station 2 for a predetermined time (step ST4). When the response message is received, the base station controller 80 erases the corresponding charging information (step ST5).

On the other hand, when the response message is not received from the central control station 3, the base station controller 80 compares the count value of the counter 81 with the preset counter threshold value (for example, 3). When the two values match, the charging information is stored in the charging information storage unit 82 (step ST7).

If the counter count value does not coincide with the counter threshold value in step ST6, the counter count value is increased by 1 and then the process proceeds to step ST2 to repeat the following operations (step ST8).

If a reserved packet is allocated from the central control station 2 after the step ST7 (step ST9), the base station controller 80 preferentially provides the charging information stored in the accounting information storage unit 82. A predetermined S-ALOHA packet is generated and then transmitted (step ST10).

That is, according to the above embodiment, if the base station transmits the charging information and the response message is not received, the base station stores the charging information so as to prevent the loss of the charging information.

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, when the base station releases the billing information of the subscriber using the communication line and sends it to the central control station, if it fails to transmit the charging information to the central control station due to the disconnection of communication, etc. An apparatus and a method for preventing the loss of billing information of a base station can be realized in a satellite communication system in which the billing information is stored in a predetermined memory and transmitted when communication is subsequently communicated.

Claims (4)

A satellite communication system in which a plurality of subscribers are combined with a plurality of base stations, respectively, and the plurality of base stations are combined with different base stations and a central control station through satellites to perform communication between any of the subscribers; When the base station receives the call release request signal from the subscribers of the communication line using the call release signal sending step of transmitting a call release signal including the charging information; If the response message according to the call cancellation signal for a predetermined time is not received message storage step of storing a call cancellation message including the billing information of the subscriber in a predetermined memory, If the reserved packet is allocated from the central control station, the message information stored in the memory and the call cancellation signal retransmission step of transmitting it through the allocated reservation packet, characterized in that it comprises the charging information of the base station in the satellite communication system How to prevent loss. The method of claim 1, If the response message is not received for a predetermined time after the call message release step, the satellite communication system comprising a repeated call release message to resend a call release message containing a charge information for a predetermined number of times. How to prevent the loss of charging information in the base station A satellite communication system comprising a plurality of base stations each coupled with a plurality of subscribers, and a central control station for managing and controlling the base stations; The base station includes a call release message storing means for storing a call release message including charging information; If the response message is not received from the central control station after sending the call cancellation message within a certain time, the call cancellation message is stored in the call cancellation message storage means. Device for preventing the loss of billing information of the base station in the satellite communication system, characterized in that it comprises a control means for transmitting. The method of claim 3, wherein It further comprises a counter means for counting the number of re-transmission of the call release message, The control means, if the response message according to the transmission of the call cancellation message is not received within a predetermined time, the billing information of the base station in the satellite communication system, characterized in that repeatedly sending a call cancellation message based on the count value by the counter means Loss Prevention Device.