KR20040060435A - node synchronized device of the W-CDMA system and controlling method therefore - Google Patents

Abstract

PURPOSE: A node synchronization unit of a broadband CDMA system and a controlling method thereof are provided to synchronize a system without a reference signal by transmitting a down-link control frame including BFN synchronization information to a base station. CONSTITUTION: A node synchronization unit of a broadband CDMA system includes a base station controller and a plurality of base stations. The base station controller(2) is used for transmitting a BFN synchronization signal having a predetermined period in order to tune a synchronous signal. The base stations(1A-1N) are used for receiving the BFN synchronization signal from the base station controller and initializing a system by using the BFN synchronization signal. The base station controller includes a RFN generator(3) for generating an RFN signal, a synchronization information generator(4) for generating the synchronization information, and a DCF transmitter(5) for inserting the synchronization information into the RFN signal and loading the RFN signal into a downlink control frame.

Description

Node synchronized device of the broadband CDM system and its control method {node synchronized device of the W-CDMA system and controlling method therefore}

The present invention relates to a node synchronization device of a broadband CDM system and a method of controlling the same. In particular, a base station controller transmits synchronization information to a BFN signal in a downlink control frame transmitted to a base station every cycle, and the BFN synchronization is performed at each base station. The present invention relates to a node synchronization device of a broadband CDM system for synchronizing a system using information and a control method thereof.

In general, mobile phones, especially mobile phones, are divided into hexagonal cells of several km to several ten kilometers in diameter in North America in the early 1980s, and the same frequency channel is repeatedly used in geographically separated cells. According to the first commercialization of a cellular phone (cellular-phone) that implements the radio channel switching function between cells has grown rapidly. In addition, such a mobile phone is usually provided with a plurality of mobile communication base station for the subscriber owning the terminal to smoothly communicate with other communication subscribers in the remote area using the mobile communication network, wherein the mobile communication base station is a base station After synchronizing according to the instructions of the RADIO NETWORK CONTROLLER, functions such as status or alarm information that may occur during call processing are reported frequently.

Then, referring to FIG. 1, a base station controller synchronous processing apparatus of a conventional asynchronous W-CDMA system as described above, a plurality of base station 70A-N signals a base station frame number (RFN) signal to obtain a synchronization signal. And a plurality of base stations 70A-N for synchronizing using the RFN signal transmitted from the base station controller 71.

Here, the base station controller 71 includes an RFN generator 72 for generating an RFN signal and a downlink control frame (DCF) transmitter for loading and transmitting the RFN signal of the RFN generator 72 in a downlink control frame ( 73, a CF (control frame) receiving unit 74 for receiving an uplink control frame transmitted from the base stations 70A-N, and the CF receiving unit 74 to control the functions of the base station controller 71. The control unit 75 is included.

In addition, the base station 70A-N has a BFN generator 76 for generating a NodeB frame number (BFN) signal, and a UCF (UPlink) for loading and transmitting a BFN signal of the BFN generator 76 in an UPlink control frame. A base station 71A- includes a control frame (77) transmitting unit (77), a downlink control frame (DCF) receiving unit (78) for receiving a downlink control frame transmitted from the base station controller (71), and the DCF receiving unit (78). CPU 79 that controls the function of N).

On the other hand, when the operation of the base station controller synchronous processing device of the conventional asynchronous W-CDMA system as described above, the control unit 75 of the base station controller 71 because there is no reference clock signal for synchronization in the W-CDMA FDD system For generation, the RFN signal is generated through the RFN generator 72 and input to the DCF transmitter 73. Then, the DCF transmitter 73 inserts the input RFN signal into the payload field of the control frame and transmits the received RFN signal to each base station 70A-N through the downlink control frame.

The CPU 79 of each base station 70A-N receives the RFN signal transmitted from the base station controller 71 through the DCF transmitter 73 and outputs the RFN signal to the BFN generator 76. Then, the BFN generation unit 76 generates a BFN signal with reference to the reception point of the RFN signal of the base station controller 71 and transmits the BFN signal to the UCF transmission unit 77. The UCF transmitter 77 inserts the input BFN signal into the uplink control payload field and then transmits the BFN signal to the base station controller 71.

Therefore, the CF receiving unit 74 of the base station controller 71 receives and processes the uplink control frame signal transmitted from each base station 70A-N, and accordingly the CF receiving unit 74 of the base station controller 71 receives the base station. The relative time deviation information between the base station controller 71 and the individual base stations 70A-N is determined using the RFN and BFN information specified in the payload field of the uplink control frame transmitted from 70A-N. As shown in FIG. 2, the control unit 75 of the base station controller 71 provides time information for transmitting downlink data frames to each base station 70A-N using the identified relative time deviation information. Recognize and synchronize.

However, since the base station controller synchronous processing apparatus of the conventional asynchronous W-CDMA system does not use the reference clock signal for the network synchronizer, the BFN signals generated by each base station have different values. Therefore, since the base station controller receives uplink control frames from each base station and has relative time deviation information for each base station for node synchronization with each base station, the processing load of the base station controller is considerably increased when a plurality of base stations are connected. In addition, since the communication must be performed separately for each base station for synchronization, the control function of the base station controller is also significantly complicated.

Accordingly, the present invention has been invented to solve the conventional problems as described above. Even in an asynchronous system that does not use a reference clock, the base station controller and a plurality of base stations can be constantly synchronized, thereby significantly improving the control functionality of the base station controller. It is an object of the present invention to provide a node synchronization device and a control method of the broadband CDM system.

Another object of the present invention is to provide a node synchronization device and a method of controlling the same in a broadband CDM system in which the base station controller does not need to have time deviation information in order to synchronize the synchronization between the base stations. have.

The present invention for achieving the above object is a base station controller for transmitting a BFN synchronization signal having a predetermined period in order to match the synchronization signal, and a plurality of synchronization to initialize the system using the BFN synchronization signal transmitted from the base station controller It provides a node synchronization device of a broadband CDM system consisting of a base station of.

In another aspect of the present invention, the base station controller device transmits BFN synchronization information having a certain period to the base station controller BFN synchronization information transmission step to each base station, and after the base station controller synchronization information transmission step is transmitted from the current base station controller A synchronization information checking step of confirming whether the synchronized information PD is reliable information SD, and whether the synchronization information PD currently transmitted from the base station controller is reliable information SD during the synchronization information checking step. If confirmed, the base station initializes and synchronizes the BFN counter, and then provides a method of controlling the node synchronization device of the broadband CDM system comprising a base station synchronization execution step of transmitting the synchronized BFN signal to the base station controller.

1 is an explanatory diagram illustrating a synchronization device of a conventional asynchronous base station controller.

2 is an explanatory diagram for explaining an example of base station synchronization applied by the apparatus of FIG.

3 is an explanatory diagram illustrating an apparatus of the present invention.

4 is a flowchart of the present invention.

5 is an explanatory diagram for explaining a downlink control frame format of the apparatus of the present invention.

6 is an explanatory diagram illustrating an example of base station synchronization applied by the present invention apparatus.

<Detailed Description of Codes>

1A-N: base station 2: base station controller

3: RFN generator 4: synchronization information generator

5: DCF transmitter 6: CF receiver

7: control unit 8: DCF receiving unit

9: BFN generation unit 10: UCF transmission unit

11: CPU

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The apparatus of the present invention is a base station controller (2) for transmitting a BFN (RNC frame number) count signal having a certain period to a plurality of base stations (1A-N) as shown in Figure 3, and the base station controller It consists of a plurality of base stations 1A-N for initializing and synchronizing the system by using the BFN synchronization information signal transmitted from (2).

The base station controller 2 includes an RFN generator 3 for generating an RFN signal and a synchronization information generator for generating synchronization information by counting a predetermined period, for example, every 40.96 sec, for synchronization of the base stations 1A-N. (4), a downlink control frame (DCF) transmitter 5 for loading and transmitting the BFN signal of the RFN generator 3 and the synchronization information of the synchronization information generator 4 into a downlink control frame, and the base station A control frame (CF) receiver 6 for receiving an uplink control frame transmitted from (1A-N), and a control unit 7 for controlling the functions of the base station controller 2, including the CF receiver 6; do.

The base station 1A-N further includes a downlink control frame (DCF) receiving unit 8 that receives a downlink control frame signal including synchronization information transmitted from the base station controller 2, and the DCF receiving unit 8; The BFN generator 9 initializes the BFN synchronization signal generated by the base station controller 2 and generates the BFN signal, and loads the BFN signal initialized by the BFN generator 9 in an UPlink control frame. And a CPU 11 for controlling the functions of the base stations 1A-N, including the UCF transmitter 10 and the DCF receiver 6.

The synchronization information generator 4 and the BFN generator 9 are counters that count a certain period.

Here, the synchronization information generator 4 is inserted into the payload field of the downlink control frame signal every 40.96 sec, for example, because the period of the RFN and BFN counters is 40.96 sec.

Next, the control method of the present invention as described above will be described.

The apparatus of the present invention proceeds to the base station controller synchronization information transmission step (S2) in the initial state (S1) as shown in FIG. 4 and transmits synchronization information having a certain period in the downlink control frame to each base station. After the base station controller synchronization information transmission step S2, the process proceeds to the synchronization information checking step S3 to check whether the synchronization information PD currently transmitted from the base station controller is reliable information SD. At this time, if the synchronization information PD transmitted from the base station controller is not reliable information SD as a result of checking during the synchronization information checking step S3, the process proceeds to the general function execution step S4 and the normal call processing is performed. Execute the action.

However, if the synchronization information PD transmitted from the base station controller is reliable information SD as a result of checking during the synchronization information checking step S3, the base station synchronizes with the base station synchronization execution step S5 and the base station determines the BFN counter. Initialize and synchronize, and transmit the synchronized BFN signal to the base station controller. In addition, after the base station synchronization execution step (S5) to proceed to the data transmission step (S6) the base station controller transmits the necessary data to the base station using the synchronized channel.

In other words, since there is no reference clock signal for synchronization in the W-CDMA FDD system, the control unit 7 of the base station controller 2 generates the RFN signal through the RFN generator 3 for synchronization and the DCF transmitter 5 ). The controller 7 simultaneously generates the synchronization information through the synchronization information generator 4 and inputs the same to the DCF transmitter 5.

At this time, when the RFN value input from the RFN generator 3 is "0", that is, when the base station wants to synchronize the base station, the DCF transmitter 5 indicates "01010101" in the BFN synchronization field of the downlink control frame. On the other hand, if the RFN value is not "0", the value "11111111" is inserted into the corresponding field and transmitted to each base station 1A-N through the downlink control frame.

Here, since the RFN value is a frame number which repeats at 40.96 sec, the period of inserting the value of "01010101" inserted into the BFN synchronization field is 40.96 sec.

The content inserted into the RFN field is a 24-bit RFN counter value generated by the RFN generator 3.

On the other hand, the CPU 11 of each base station 1A-N receives the downlink control frame signal transmitted from the base station controller 2 through the DCF receiver 8 as shown in FIG. After checking whether the field is "00000110", check the value of the value of the BFN synchronization field. At this time, when the value of the BFN synchronization field transmitted from the base station controller 2 is "01010101", the CPU 11 of the base stations 1A-N initializes the BFN counter provided in the BFN generation unit 9. . However, the CPU 11 continues to execute the BFN counter when the BFN synchronization field is not "01010101".

Therefore, the BFN generator 9 synchronizes the synchronization information of the base station controller 2 and then transmits the generated BFN signal to the UCF transmitter 10. The UCF transmitter 10 inserts the input BFN signal into the uplink control payload field and transmits the BFN signal to the base station controller 2.

Accordingly, the CF receiving unit 6 of the base station controller 2 receives and processes the uplink control frame signal transmitted from each base station 1A-N, so that the CF receiving unit 6 of the base station controller 2 receives the base station. The synchronization is confirmed using the BFN information specified in the payload field of the uplink control frame transmitted from (1A-N).

That is, since the plurality of base stations 1A-N generate the BFN signals in the initialized state without having to have time deviation information as conventionally by the BFN synchronization information provided by the base station controller 2, the BFN signals are generated in FIG. As shown in the figure, the same BFN value will be obtained.

As described above, according to the present invention, the base station controller carries BFN synchronization information in a downlink control frame transmitted to the base station every cycle and transmits the BFN synchronization information to each base station to synchronize the system using this synchronization information. Even in an asynchronous system, the synchronization between the base station controller and a plurality of base stations can be consistently achieved, which has the advantage of significantly improving the control functionality of the base station controller.

In addition, according to the present invention, since the base station controller does not have to have a time deviation in order to synchronize between the base stations, the processing load of the base station controller can be reduced accordingly.

Claims (4)

Broadband CD, characterized in that the base station controller for transmitting a BFN synchronization signal having a predetermined period for the synchronization signal and a plurality of base stations for initializing and synchronizing the system using the BFN signal transmitted from the base station controller Node Synchronizer of AM System. 2. The base station controller of claim 1, wherein the base station controller comprises: an RFN generator for generating an RFN signal, a synchronization information generator for generating synchronization information by counting a predetermined period for synchronization of the base station, and inserting the synchronization information into the RFN signal. And a DCF transmitter for loading and transmitting the downlink control frame. The method of claim 1, wherein the base station initializes according to a DCF receiver for receiving a downlink control frame signal including synchronization information transmitted from the base station controller and the synchronization RFN signal of the base station controller extracted by the DCF receiver. And a UCF transmitter configured to load and transmit the BFN signal initialized by the BFN generator in an uplink control frame to the BFN generator. In the base station controller device, the base station controller synchronization information transmission step of transmitting the synchronization information having a predetermined period in the RFN to each base station, and the synchronization information (PD) currently transmitted from the base station controller after the base station controller synchronization information transmission step When the synchronization information confirmation step of checking whether the information is reliable information (SD) and the synchronization information (PD) currently transmitted from the base station controller during the synchronization information confirmation step is confirmed that the reliable information (SD), the base station is a BFN counter And a base station synchronization executing step of transmitting the synchronized BFN signal to the base station controller.