KR100231514B1 - Ring period control method in satellite communication system - Google Patents

Abstract

The present invention relates to a ring period control method in a satellite communication system in which a system operator can arbitrarily adjust a period of a ring signal. The present invention relates to a plurality of base stations coupled to a plurality of subscribers, and to provide a call channel between each base station. A satellite communication system having a central control station for allocating and controlling a usable communication channel for a base station having a satellite and a call request, wherein the operator inputs ring period adjustment data inputted through an operator terminal of the central control station. A packet generation step of generating a ring period adjustment message packet based on the inputted data, a message transmission step of transmitting to the base station generated in this packet generation step, and ring period adjustment data from an adjustment message transmitted from the central control station. The adjustment data extraction step of extracting the A ring signal supply step of supplying a ring signal of a predetermined period to the subscriber based on the data updated in the ring period data updating step when a ring signal transmission reason for the subscriber occurs Characterized in that configured to include.

Description

Ring Cycle Control Method in Satellite Communication System

The present invention relates to a satellite communication system, and more particularly, to a ring period control method in a satellite communication system that allows a system operator to arbitrarily adjust the period of a ring signal.

1 is a block diagram showing a configuration of a base station of a general satellite communication system. In FIG. 1, reference numeral 21 denotes an antenna for transmitting and receiving an uplink signal and a downlink signal with respect to the satellite 1. 22 is an Orthogonal Mode Transducer (OMT) which separates and inputs and receives signals transmitted and received through the antenna 22 using a polarization property of frequency, and 23 is inputted through the Orthogonal Mode Transducer 22 Low Noise Amplifier (LNA) for low-noise amplifying downlink frequency signals of 12.25-12.75 GHz, 24 is an intermediate frequency signal (IF) of 70 MHz, for example. Frequency Down Converter (DC)

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. Intermediate frequency combiner / distributor (IF C / D: IF Combiner / Distributer) for combining and outputting the intermediate frequency signal applied from SCU: 61, and 61 (61 _{1 to} 61 ₃₂ ) are the intermediate frequency combiner / distributor. An SCPC channel unit 61 which demodulates, decodes and outputs an intermediate frequency signal applied from (25), or vice versa, which encodes and modulates a transmission signal to be transmitted to a central control station or another base station. This is for transmitting and receiving signals to and from a station or other station.

In addition, reference numeral 27 is a trunk interface port (Trunk Interface Port) for connecting the E1 trunk module and the like of the base station and the ground network (PSTN) switch, 32 is 70 M applied from the IF combination / distribution unit 25 A frequency upconverter (UC) for converting an IF signal of 로 to an microwave of 14.0 to 14.5 GHz to generate an uplink frequency signal, 33 is an uplink frequency signal output from the frequency upconverter 32. It is a high power amplifier (HPA) that amplifies.

Reference numeral 60 denotes a telephone data card for connecting a terminal such as a telephone, a data terminal, or a facsimile, and reference numeral 63 denotes the SCPC channel unit 61, a trunk interface port 27, and telephone data. A network controller which controls the card 60 to provide a predetermined communication channel to the subscriber, and generates and outputs message data for informing the central control station of the current status of the base station; It is designed to exchange control data with the above-described SCPC channel unit (SCU) 61, trunk interface port (TIP) 27, and telephone data card (TDC) 60 through UPH (65: Utility PCM Highway). In addition, traffic data communication with each module is performed through the MPH 66: Main PCM Highway.

That is, in the conventional satellite communication system having the above-described configuration, the subscriber of the telephone data card (TDC) 60 can communicate with the subscriber of another base station through the SCPC channel unit 61 under the control of the network controller 63. It is supposed to be.

On the other hand, since the ring signal provided by the telephone data card 60 is conventionally fixed as a single type, sufficient support for service contents requiring more various ring signals, such as a morning call function provided as a special service, etc. Failed to provide functionality

The present invention has been made in view of the above circumstances, and an object thereof is to provide a ring cycle control method in a satellite communication system in which a system operator can arbitrarily adjust a cycle of a ring signal.

1 is a block diagram schematically showing a configuration of a base station in a general satellite communication system.

Figure 2 is a block diagram showing a satellite communication system with a ring period control function according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

21: antenna, 22: orthogonal mode converter,

23: low noise amplifier, 24: frequency down converter,

25: intermediate frequency combination / distribution, 27,37: trunk interface port,

32: frequency up converter, 33: high power amplifier,

60, 75: telephone data card, 61: SCPC channel unit,

63: network control unit, 65: UPH (Utility PCM Highway),

66: MPH (Main PCM Highway),

74: ring period data initial value storing unit, 75a: ring generating unit,

75b: ring period data initial value storage unit, 75c: line control unit,

The ring cycle control method according to the present invention for realizing the above object is a communication channel that can be used for a plurality of base stations each coupled with a plurality of subscribers, and a base station having a satellite and a call request for providing a communication channel between each base station. In a satellite communication system having a central control station for allocation control, a ring period adjustment message packet is generated on the basis of the input data when the operator inputs the ring period adjustment data inputted by the operator terminal of the central control station. A packet generation step, a message transmission step sent to the base station generated in this packet generation step, an adjustment data extraction step of extracting ring period adjustment data from the adjustment message transmitted from the central control station, and the extracted adjustment data. Ring cycle data updating step and subscriber to change ring cycle data In case of a ring signal transmission reasons, including the ring signal supply step of supplying a ring signal having a predetermined period for the subscriber based on the updated data in the ring cycle data updating step it is characterized in that configured.

That is, according to the present invention having the above-described configuration, it is possible to provide various kinds of ring signals required by a special service according to the key operation of the system operator.

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

FIG. 2 is a block diagram showing a satellite communication system having a ring period control function according to an embodiment of the present invention, in which components which perform substantially the same functions as those shown in FIG. The detailed description thereof will be omitted.

In FIG. 2, reference numeral 2 denotes a configuration of a central control station of the satellite communication system, and reference numerals 3A and 3B respectively denote a base station configuration.

On the other hand, reference numeral 10 of the configuration of the central control station (2) is an antenna for transmitting and receiving the uplink (UP LINK) signal transmitted to the satellite (1) side and the downlink (DOWN LINK) signal transmitted from the satellite (1) 20 converts the downlink signal of the ultra high frequency band received by the antenna 10 into an intermediate frequency (IF) signal and simultaneously converts the intermediate frequency (IF) signal of the 70 MHz band to the uplink signal. An RF transceiver for converting and outputting an RF signal.

Further, reference numeral 30 denotes an IF processor for processing an intermediate frequency (IF) signal in the 70 MHz band, and 40 transmits a control message to each base station through the IF processor 30 and then transmits from the corresponding base station. Performs a polling function to check the status of each base station based on the response message that is received, and if there is a call request from a specific base station, whether the other base station is in a state capable of communication based on the information obtained during the polling process. If it is determined that the communication is possible, the network control unit performs system control, such as by allocating the available traffic channels of the satellites to both base stations so as to directly communicate with each other, and reference numeral 50 denotes a satellite communication network. In addition to enabling operations managers to monitor overall network operations According to a network management system to control the overall system including the base station satellite.

In the meantime, 74 provided in the base station 3 is a ring cycle data initial value storage unit for receiving and storing ring cycle control data input by an operator through the network management system 50, and 75 denotes a plurality of subscribers 100. ) Is a telephony data card to which is connected.

Next, the operation of the device having the above configuration will be described.

When the system administrator of the central control station 2 inputs the ring period setting data by operating an operator terminal (not shown) provided in the network management system 50, the network controller 40 is inputted by the operator. The ring period setting data is packetized and sent to the corresponding base station through the IF processing stage 30 and the RF transmitting and receiving stage 20.

On the other hand, the network control unit 73A of the base station 3A analyzes the message transmitted from the central control station 2, extracts the ring period setting data set by the operator, and extracts the extracted data from the ring period data initial value. Registration is stored in the storage unit 74A.

Subsequently, the network control unit 73A transfers the ring period data changed and set by the operator to the telephone data card (TDC) 75A through the UPH 65A, and thus the line control unit 75c of the telephone data card 75A. Registers the ring period data transmitted from the network control unit 73A to the ring period data storage unit 75b.

When the ring period adjustment data registration process by the above-described procedure is completed, if a call is made to any subscriber terminal thereafter, the line control unit 75c based on the data registered in the ring period data storage unit 75b. As a result, the ring signal generated by the ring generator 75a is periodically interrupted and supplied to the subscriber station, thereby executing a calling function for the subscriber station.

On the other hand, when the subscriber station is a morning-call service registered subscriber which is one of special service functions, the line control unit 75c calls for a morning-call execution command transmitted from the network control unit 73A at a contracted time. By sending a separate ring signal different from the signal, the service subscriber is provided with convenience to recognize the morning-call function through the distinctive ringing sound.

That is, according to the above embodiment, it is possible to provide a ring cycle control method in a satellite communication system in which a system operator can arbitrarily adjust a cycle of a ring signal.

On the other hand, the present invention is not limited to the above embodiments and can be modified in various ways without departing from the technical gist of the present invention.

As described above, according to the present invention, it is possible to provide various kinds of ring signals required by a special service according to the key operation of the system operator.

Claims (1)

A satellite communication system having a plurality of base stations, each coupled with a plurality of subscribers, and a central control station for allocating and controlling a usable communication channel for a satellite and a base station with a call request to provide a communication channel between the base stations. A packet generation step of generating a ring period adjustment message packet based on the input data when the operator inputs the ring period adjustment data inputted through the operator terminal of the central control station; and a corresponding base station generated in this packet generation step; A message transmission step of transmitting a message, a ringing data extraction step of extracting ring period adjustment data from an adjustment message transmitted from a central control station, a ring period data updating step of changing and setting ring period data based on the extracted adjustment data, and a subscriber; The ring cycle data updating step when a reason for transmitting a ring signal for a Standing ring cycle control method in a satellite communication system, characterized in that constructed on the basis, including the updated data to the ring signal supply step of supplying a ring signal having a predetermined period for that subscriber.

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