KR19990058979A - Base station synchronization method in mobile communication system - Google Patents

Abstract

The present invention relates to a base station synchronization method of a communication system capable of synchronizing between base stations without using a GPS satellite receiver provided in a base station of each mobile communication system. A communication system comprising one or more GPS satellites, a base station controller for receiving time-related information transmitted from the GPS satellites and transmitting a synchronization signal having a set period, and a plurality of base stations synchronized by the synchronization signals transmitted from the base station controller. In this case, only the base station controller receives the GPS signal, generates a synchronization signal, and transmits it to the plurality of base stations through the European standard method of the digital trunk.

Description

Method of synchronization between base stations of mobile communication system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a base station synchronization method of a communication system, and more particularly, to a base station synchronization method of a mobile communication system that is suitable for miniaturization of a base station.

In a code division multiple access (CDMA) mobile communication system, a fixed position and known base station is synchronized using a GPS signal provided by a GPS satellite, which is a low-orbit mobile satellite. In this technique of synchronizing synchronization between base stations in a mobile communication system, operating points of various additional functions including an incoming and outgoing signal of a mobile terminal of each sender and receiver should be synchronized with each other by a control signal of each base station.

Therefore, each base station must be aligned with an absolute time such as a GPS signal for high quality call service.

According to the conventional inter-base station synchronization method as shown in Figure 1, the information transmitting station on the ground transmits the standard time information to a plurality of GSP satellites at regular intervals. Then, the GSP satellite calculates its own location information and transmits the time information and its own location information to a plurality of base stations 21a-21n scattered on the ground at set intervals. Each base station is provided with GPS satellite signal receivers 22a-22n, respectively, and calculates a position by calculating a time difference transmitted from a plurality of GPS satellites (usually three or more), and obtains a position with a distance from one GPS satellite. Correct the sent time. That is, each CDMA base station extracts time information from the GPS satellite receiver using the time information transmitted from the GPS satellites so that the geographically dispersed base stations have the same time information and maintain synchronization.

However, the conventional CDMA synchronization between base stations is a factor to increase the installation cost of the entire communication system because each base station must be made with each GPS satellite signal receiver.

SUMMARY OF THE INVENTION An object of the present invention has been made in view of the problems of the prior art shown in the above description, and it is possible to synchronize between base stations without using a GPS satellite receiver provided in the base station of each mobile communication system. It is to provide.

In order to achieve the above object, the present invention provides a base station controller for transmitting at least one GPS satellite for transmitting standard time information at a set period, and a synchronization signal having a set period for receiving time-related information transmitted from the GPS satellite; In a communication system composed of a plurality of base stations synchronized by a synchronization signal transmitted from a base station controller, only the base station controller receives the GPS signal, generates a synchronization signal, and transmits each to the plurality of base stations through the European standard method of the digital trunk. Characterized in that.

1 is a configuration diagram of a base station for explaining a conventional method of synchronizing between base stations.

2 is a diagram illustrating a configuration of a base station for explaining a method for synchronizing between base stations according to the present invention;

3 is a control flowchart for explaining the flow of the inter-base station synchronization method according to the present invention.

4 is a timing diagram of a simultaneous signal according to the embodiment of FIG. 2;

* Explanation of symbols for main parts of the drawings

101-104: base station 105: mobile switching unit

106: base station controller 107: GPS

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

2 is a diagram illustrating a configuration of a base station for explaining a synchronization method between base stations according to the present invention.

2, a communication system for executing the inter-base station synchronization method according to the present invention includes a plurality of GSP satellites for transmitting standard time information at regular intervals, and a signal including time information transmitted from the GSP satellites. A base station controller 106 having one receiving GSP satellite signal receiver 107, and a plurality of base stations 101-104 connected in a European standard manner of a digital trunk for wireless communication to the base station controller 106. . Here, reference numeral 105 is a moving switching unit.

A method of synchronizing between base stations of a communication system configured as described above will be described with reference to FIGS. 2 to 4.

Information transmitting stations on the ground transmit standard time information to several GSP satellites at regular intervals. Then, the GSP satellite calculates its own location information and transmits time information and its own location information to a plurality of base stations 101-104 scattered on the ground at set periodic intervals. One GPS satellite signal receiver 107 is provided in the base station controller 106 which is connected to the plurality of base stations 101-104 in the European standard manner of digital trunk to enable wireless communication and controls each base station. Accordingly, the GPS satellite signal receiver 107 receives the satellite signal and transmits a synchronization signal having a set time period (2 seconds in this embodiment) to each base station through E1 (not shown), which is a European standard method of digital trunking. . Each base station detects this signal and generates a two second synchronization signal required by the base station.

That is, as shown in FIG. 2, only one GPS satellite signal receiver 107 is provided in the base station controller 106 to generate an E1 frame synchronization signal and a two second synchronization signal (ST1, 2). Here, the channel 1 of the E1 frame has a frequency of 8 KHz. As shown in FIG. 4, the E1 frame that is identical in time to the 2 second sync signal is referred to as frame 0, and the frames are designated with names of 0 to 15999 frames. The difference between the frame synchronization signal of frame 0 and the 2 second synchronization signal is detected (ST3). In frame 0, a preamble (0 × 7E) is sent to indicate frame 0. Frame 1 is sent the same channel number as frame 0 and the 2 second sync signal. It sends the difference clock values to frames 2 and 5. Dummy data is sent to the channel from frame 6 to frame 15998.

In frame 15999, a preamble (O x 7E) is sent (ST4).

Each base station detects an 8 KHz signal of the base station controller 106 and E1 (ST5).

In order to synchronize, the frame 0 is detected by detecting the preamble in the channel (ST6). And frame 1 to 5 information is obtained. A 2-second sync signal is extracted using this information and the El frame sync signal (ST7). Therefore, the synchronization between the base stations is achieved by using this two second synchronization signal.

According to the present invention as described above, it is possible to synchronize between the base stations without installing the GSP satellite signal receiver for each base station of the mobile communication system, saving the construction cost of the communication system, it is very advantageous to miniaturize the base station.

Claims (2)

Synchronization with one or more GPS satellites for transmitting standard time information at a set period, a base station controller for receiving time-related information transmitted from the GPS satellites and transmitting a sync signal having a set period, and a sync signal transmitted from the base station controller In a communication system composed of a plurality of base stations, only the base station controller receives the GPS signal, generates a synchronization signal, and transmits the signals to the plurality of base stations through the European standard method of the digital trunk. Motive method. 2. The method of claim 1, wherein the synchronization signal comprises the steps of: generating an E1 frame synchronization signal and a satellite synchronization signal having a set time period, detecting a difference between the two synchronization signals, and synchronizing a signal to an arbitrary channel of the E1. Transmitting a signal, detecting the E1 frame synchronization signal, extracting a synchronization signal from an arbitrary channel of the E1, and extracting a synchronization signal having a set period from the satellite synchronization signal. A method for synchronizing between base stations of a communication system, characterized in that.