KR20030070438A - Method for transmitting and receiving data between base stations and a base station controller efficiently in a mobile communication system - Google Patents

Abstract

PURPOSE: A method for transmitting and receiving data between a BSC(Base Station Controller) and base stations in a mobile communication system is provided to efficiently transmit and receive the data by connecting the BSC to the base stations, bidirectionally transmitting, and receiving the data. CONSTITUTION: A BSC(100) and a plurality of base stations(11,13,15,17) are connected by a ring structure. Data are transmitted and received between the BSC(100) and the base stations(11,13,15,17) in the first and second directions. The data transmitted and received in the first direction are processed as valid data in a normal state. If link fault is generated while the data are transmitted and received in the first direction, the data transmitted and received in the second direction are processed as valid data.

Description

METHODS FOR TRANSMITTING AND RECEIVING DATA BETWEEN BASE STATIONS AND A BASE STATION CONTROLLER EFFICIENTLY IN A MOBILE COMMUNICATION SYSTEM}

The present invention relates to a base station controller and a base station in a mobile communication system, and more particularly, to a mobile communication system consisting of a base station controller and a base station for efficient data transmission and a data transmission method between the base station controller and the base station.

In general, in a mobile communication system, a base station controller and a plurality of base stations are matched in a point to point structure as shown in FIG. 1. 1 is a diagram illustrating a connection between a conventional base station controller and a base station. Referring to Fig. 1, since the base station controller 10 and the plurality of base stations 1, 3, 5, and 7 are tens of kilometers or more apart, the optical transmission apparatus 20 is connected as a relay point. At this time, the base station controller 10 is connected to the optical transmission device 20 by a plurality of DS-E1 relay lines transmitting data at a rate of up to 2.048 Mbps, and the optical transmission device 20 and a plurality of base stations (1, 3, 5). And 7) are also connected by multiple DS-E1 repeaters. However, this one-to-one DS-E1 relay line matching does not support the increased data capacity while the mobile communication system provides high-speed data. That is, the capacity of the DS-E1 relay line between the base station controller 10 and the base stations 1, 3, 5, and 7 is 2.048 Mbps, and the wireless capacity used by a single mobile communication terminal subscriber exceeds this. In addition, economic losses caused by the optical transmission apparatus 20 provided with the base station controller 10 and the base stations 1, 3, 5, and 7 also act as a burden on the operator.

Accordingly, an object of the present invention is to provide a mobile communication system comprising a base station controller and a base station for efficiently transmitting and receiving a large amount of data, and a data transmission method between the base station controller and the base station.

In order to achieve the above object, the present invention provides a method for transmitting and receiving data between a base station controller and a plurality of base stations in a mobile communication system, the process of connecting the base station and the plurality of base stations in a ring structure, and the base station connected in the ring structure Characterized in that the process consists of transmitting and receiving data in both directions between the controller and the plurality of base stations.

A mobile communication system comprising a base station controller for transmitting and receiving data in both directions and a plurality of base stations, comprising: a transmitter for transmitting data, a receiver for receiving data, and a data inputted from the transmitter for switching in both directions And a base station controller including a plurality of switches for switching data received and input in both directions to be output to the receiving unit, two transmitting units for transmitting data corresponding to each direction, and corresponding to each direction. Two receivers for receiving data, a plurality of FIFOs for storing data so that the data can be transmitted and received in both directions, and the data inputted to each transmitter are switched to be transmitted in both directions, and received in both directions Input data is output to each of the receivers Having a plurality of switches for switching so as to feature a constituted by any of the plurality of base stations.

1 is a diagram illustrating a connection between a conventional base station controller and a base station;

2 illustrates a base station controller and a base station connected in a ring structure according to the present invention;

3 is a diagram illustrating a practical connection configuration of a base station controller and a base station in a ring structure according to the present invention;

4 is a block diagram of a base station controller to which the present invention is applied;

5 is a configuration diagram of a base station to which the present invention is applied;

6 is a view showing a flow of data transmission and reception in a steady state according to the present invention;

7 is a diagram illustrating a data transmission and reception flow when another data transmission error occurs in accordance with the present invention.

DETAILED DESCRIPTION A detailed description of preferred embodiments of the present invention will now be described with reference to the accompanying drawings. It should be noted that reference numerals and like elements among the drawings are denoted by the same reference numerals and symbols as much as possible even though they are shown in different drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

According to the present invention, a base station controller and a plurality of base stations are matched in a ring structure. This is illustrated in FIGS. 2 and 3. 2 is a diagram illustrating a base station controller and a base station connected in a ring structure according to the present invention. Base station controller 100 and a plurality of base stations (11, 13, 15, 17) is connected via an optical cable, and because of the ring structure, each node transmits and receives data in both directions. Hereinafter, according to an embodiment of the present invention, data transmission and reception in the counterclockwise direction is called first direction data transmission and reception, and data transmission and reception in the clockwise direction is called second direction data transmission and reception. The base station controller 100 and the base stations 11, 13, 15, and 17 process data transmitted and received in the first direction as valid data under a normal state, and the base station controller 100 and the base stations 11 and 13 If a failure occurs in the data transmission / reception link between the servers 15 and 17, the data transmitted and received in the second direction is selectively processed as valid data. 3 is a diagram illustrating a matching board configuration and connection structure of a base station controller and a base station to be connected in a ring structure according to the present invention. The configuration of the base station controller 100 and the base stations 11, 13, 15, and 18 shown in FIG. 3 shows only the configuration necessary for ring structure matching. The detailed configuration of the base station controller 100 and the base station is shown in FIG. A description with reference to FIG.

First, the configuration according to the present invention of the base station controller 100 will be described with reference to FIG. 4 is a block diagram of a base station controller 100 to which the present invention is applied. As shown in FIG. 4, the base station controller 100 includes a base station controller switch unit 101 and a base station eliminator matching unit 117. The base station controller matching unit 117 includes a transmitter (TX) 103, a receiver (RX) 105, framers 107, 109, a first switch (SW1) 111, a second switch (SW2) 113 , The third switch SW3 (115). The transmitting unit 103 outputs the base station controller data to be transmitted to the base station controller switch unit 101 to the plurality of base stations 11, 13, 15, and 17 to the matching unit 117. Base station data received from 17) is transmitted to the higher processing function unit. The base station controller data is data transmitted by the base station controller 100 and is data to be received by the base stations 11, 13, 15, and 17. The base station data is data transmitted by the base stations 11, 13, 15, and 17 to the base station controller 100 or other base stations. The transmitter 103 outputs the base station controller data received from the base station controller switch 101 to the third switch 115 and the framer 107. The receiving unit 105 outputs base station data input from the first switch 113 and the second switch 103 to the base station controller switch unit 101. The first framer 107 outputs base station controller data in the first direction and outputs base station data input in the second direction to the first switch 111 and the second switch 113. The second framer 109 outputs base station data input from the first direction to the first switch 111 and outputs base station controller data input from the third switch 115 in the second direction. The first switch 111 and the second switch 113 output base station data input under the control of a control unit (not shown) of the base station controller 100 to the receiving unit 105. The third switch unit 115 outputs the input base station controller data to the first framer 107 and the second framer 109.

The controller of the base station controller 100 having the above structure switches the third switch 115 so that the base station controller data is output in both directions in the normal state, and the base station data is processed so that the data received in the first direction is processed as valid data. The first and second switches 111 and 113 are controlled.

Next, the configuration of the first base station 11 will be described with reference to FIG. According to the embodiment of the present invention, the configurations of the first base station 11 to the fourth base station 17 are the same. 5 is a configuration diagram of a base station to which the present invention is applied. The base station 11 includes a first base station digital processing unit 123 and a base station matching unit 121. The base station matching unit 121 includes a first framer 125, a second framer 127, a first transmitter 129, a second transmitter 131, a first receiver 133, a second receiver 135, and a first First-In First-Out (141), Second-FIFO (143), First-Back First-Out (L / B FIFO) 137, Second-Back Loop FIFO (139), First The first switch 145, the second switch 147, the third switch 149, and the fourth switch 151 are configured.

The first framer 125 outputs data received from the first direction to the first switch 145 and the second switch 147, and outputs data input from the first transmitter 129. The second framer 127 outputs data received from the second direction to the second receiver 131 and outputs data input from the third switch 149. The first receiver 129 outputs data input from the first switch 145 to the fourth switch 151 and the second loopback FIFO 139. The second receiver 131 outputs data input from the second framer 127 and the second switch 147 to the fourth switch 151. The first transmitter 133 outputs data input from the first FIFO 141 and the first loopback FIFO 137 to the first framer 125 and the third switch unit 149. The second transmitter 131 outputs data input from the second switch 147 and the second framer 127 to the fourth switch 151. The first loopback FIFO 137 outputs data input from the second receiver 131 to the first transmitter 133. The second loopback FIFO 139 outputs data input from the first transmitter 129 to the second transmitter 135. The first FIFO 141 outputs the data input from the first base station digital unit 123 to the first transmitter 133. The second FIFO 143 outputs data input from the first base station digital unit 123 to the second transmitter 135. Under the control of a controller (not shown) of the first base station 11, the first switch 145 outputs data input from the first framer 125 to the first receiver 129. The second switch 147 outputs data input from the first framer 125 to the second receiver 131 under the control of the controller. The third switch 149 selects data input from the first transmitter 133 and the second transmitter 135 under the control of the controller and outputs the data to the second framer 127. The fourth switch 151 selects data input from the first receiver 129 and the second receiver 131 under the control of the controller and outputs the first base station digital unit 123. The control unit switches the switches 145, 147, 149 and 151 according to the data link connection state between each of the base stations 13, 15 and 17 and the base station controller 100 so that appropriate data is transmitted and received as valid data.

A process of transmitting and receiving data between the base station controller 100 and the base stations 11, 13, 15, and 17 having the above configuration will be described with reference to FIGS. 6 and 7. The base station controller 100 and the base stations 11, 13, 15 and 17 transmit and receive data in both directions, but process the base station controller 100 and the base stations 11, 13 and 15 under a normal state according to an embodiment of the present invention. 17 process data transmitted and received in the first direction as valid data and discard data transmitted and received in the second direction. This steady state data flow will be described with reference to FIG. 6 is a diagram illustrating a data transmission / reception flow in a steady state according to the present invention. ABCD is base station controller data, which is received and processed by each of the base stations 11, 13, 15, and 17, and abcd is base station data. 100) is the data that must be received and processed. The base station controllers 100 at both ends are the same base station controller 100.

The base station controller 100 transmits the base station controller data ABCD to the first base station 11 and the fourth base station 17 in the same step 301 and step 301 '. First, the data flow in the first direction will be described. The first base station 11 processes only data A that the first base station 11 needs to process among the base station controller data ABCD received from the base station controller 100 in step 303. In operation 305, the first base station 11 transmits the base station data a together with the base station controller data BCD to the second base station 13. The second base station 13 processes only the data B to be processed by the second base station 13 among the data aBCDs received from the first base station 11 in step 307. In operation 309, the second base station 13 transmits the base station data b together with the remaining data aCD to the third base station 15. The third base station 15 processes only the data C to be processed by the third base station 15 among the data abCD received from the second base station 13 in step 311. In operation 313, the third base station 15 transmits the base station data c together with the remaining data abD to the fourth base station 17. The fourth base station 17 processes only data D of the data abcD received from the third base station 15 in step 315 to be processed by the fourth base station 17. In operation 317, the fourth base station 17 transmits the base station data d together with the remaining data abc to the base station controller 100. The base station controller 100 processes the received data abcd in step 319.

Looking at the data flow and processing in the second direction, in step 303 ', the fourth base station 17 discards D of the base station controller data ABCD received in step 301'. The fourth base station 17 transmits the base station data d together with the base station controller data ABC to the third base station 15 in step 305 '. The third base station 15 discards the data C to be processed by the third base station 15 among the data ABCd received from the fourth base station 17 in step 307 '. The third base station 15 transmits the base station data c together with the remaining data ABd to the third base station 15 in step 309 '. The second base station 13 discards the data B to be processed by the second base station 13 of the data ABcd received from the third base station 15 in step 311 '. The second base station 13 transmits the base station data b together with the remaining data Acd to the first base station 11 in step 313 '. The first base station 11 discards the data A to be processed by the first base station 11 of the data Abcd received from the second base station 13 in step 315 '. In operation 317 ', the first base station 11 transmits the base station data a together with the remaining data bcd to the base station controller 100. The base station controller 100 discards the received data abcd in step 319 '.

FIG. 7 is a diagram illustrating a data flow when a data link fails between the base station controller 100 and the base stations 11, 13, 15, and 17. 7 is a case where a failure occurs in the data flow in the first direction.

Referring to FIG. 7, the base station controller 100 transmits the base station controller data ABCD to the first base station 11 and the fourth base station 17 in step 501. The first base station 11 processes only data A to be processed in step 503. In operation 505, the first base station 11 transmits the base station data a together with the base station controller data BCD to the second base station 13. At this time, if a data link failure occurs between the first base station 11 and the second base station 13, the second base station 13 detects a failure and transmits a link error signal to the first base station 11 in step 507. do. In step 509, the second base station 13 transmits the received transfer signal to the third base station 15. Upon receiving this, the third base station 15 controls the switches to process data input in the second direction as valid data, and transmits the received transfer signal to the fourth base station 19 in step 511. The fourth base station 17 controls the switches to process the data input in the second direction as valid data according to the reception of the received transfer signal, and in step 513, processes D of the ABCD received in step 501 as valid data. Proceed to step. In step 515, the fourth base station 17 transmits the received transfer signal to the base station controller 100 and proceeds to step 517. The base station controller 100 switches the switch to process the data input in the first direction and the data input in the second direction as valid data according to the reception transfer signal. In step 517, the fourth base station 17 transmits the base station data d together with the ABC to the third base station 15. The third base station 15 processes, as valid data, the data C to be processed by the third base station 15 among the data ABCd received from the fourth base station 17 in step 517. In operation 521, the third base station 15 transmits the base station data c together with the remaining data ABd to the second base station 13. The second base station 13 processes only the data B to be processed by the second base station 13 among the data ABcd received from the third base station 15 in step 523, and because the data link has failed, the first base station 11 Data transfer is not possible.

In operation 601, the first base station 11 transmits the base station transmission data a to the base station controller 100. Since the base station controller 100 receives the received transfer signal in step 515, the base station controller 100 processes the base station data a received in step 601 as valid data in step 603. Since the second base station 13 does not receive the base station controller data from the first base station 11 in step 605, it transmits only the base station data b to the third base station 15. In step 607, the third base station 15 transmits only the base station data b. The base station data c is transmitted to the fourth base station 17 together with the data a received from the second base station 13. The fourth base station transmits the base station data d to the base station controller 100 in step 609 with the received bc. The base station controller 100 processes the received data bcd as valid data.

As described above, since a base station controller and a plurality of base stations connected in a ring structure transmit and receive data in both directions, even if a failure occurs, the base station controller and a plurality of base stations can transmit and receive data without loss of data before troubleshooting.

In the above description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be determined by the equivalent of claims and claims.

As described above, the present invention can transmit and receive data efficiently by connecting the base station controller and the base station in a ring structure to transmit and receive data in both directions.

Claims (4)

A method of transmitting and receiving data between a base station controller and a plurality of base stations in a mobile communication system, Connecting the base station and the plurality of base stations in a ring structure; And transmitting and receiving data in both directions between the base station controller and the plurality of base stations connected in the ring structure. The data transmitting / receiving method of claim 1, wherein the two directions are formed in a first direction and a second direction, and in a normal state, data transmitted and received in the first direction is processed as valid data. The method of claim 2, wherein if a link failure occurs while transmitting or receiving data in the first direction, the data transmitted and received in the second direction is processed as valid data. In the mobile communication system having a base station controller for transmitting and receiving data in both directions and a plurality of base stations, A transmitter for transmitting data, a receiver for receiving data, and a plurality of switches for switching the data input from the transmitter to be transmitted in the bidirectional direction, and for switching the data received and input in the bidirectional direction to the receiver. The base station controller, Two transmitters for transmitting data corresponding to each direction, two receivers for receiving data corresponding to each direction, a plurality of FIFOs for storing data so that the data can be transmitted and received in both directions, and And a plurality of base stations including a plurality of switches configured to switch data input to each transmitter to be transmitted in both directions, and switch data to be output to the receivers. Communication system.