KR100451787B1 - System interface apparatus between base station and remote base station - Google Patents

Abstract

A system interface apparatus between a base station and a remote base station according to the present invention includes: a slave remote base station controller for outputting local station control data; a slave CDMA channel signal processor for outputting digital baseband channel signals according to a signal provided by a terminal; A mux part receiving and receiving a local control signal and digital baseband CDMA channel signals, a parallel-to-serial conversion part converting an output of the mux part into serial data, and converting the serial data into an optical signal to an base station through an optical cable. A remote base station having an E / O converter for transmitting; An O / E converter unit for converting an optical signal received by interfacing the remote base station with an optical cable to an electric signal, a serial-parallel converter for converting the electric signal into parallel data, and converting the parallel data into a remote base international language data. A demux unit for separating digital baseband CDMA channel signals, a master remote base station control unit receiving a remote base station control signal from the demux unit and reporting a status of the remote base station, and a digital baseband CDMA channel from the demux unit And a base station having a master CDMA channel signal processing unit for enabling communication with a terminal receiving signals.

Description

System interface device between base station and remote base station {SYSTEM INTERFACE APPARATUS BETWEEN BASE STATION AND REMOTE BASE STATION}

The present invention relates to a system interface technology between a base station and a remote base station, and more particularly, to a system interface device using digital transmission.

Referring to FIG. 1, which shows a system interface architecture between a base station and a remote base station according to the related art, the remote base station 100 and the base station 200 are connected by an optical cable. The remote base station 100 is connected to an E / O converter block 102, a combiner 104, a slave CDMA channel signal processor 106, and a slave remote base station controller 110. It is composed.

The antenna A1 receives a radio frequency (RF) signal through a radio transmission line (AIR) and provides the signal to a low noise amplifier (LNA) 108 of the slave CDMA channel signal processor 106. The slave CDMA channel signal processing unit 106 receives a CDMA channel signal for communication with the terminal and amplifies low noise through the LNA 108.

The slave remote base station control unit 110 includes an FSK modem 112 and a remote base station control signal unit 114. The remote base station control signal unit 114 is for the internal CPU to send a control signal in response to the base station control signal to the base station CPU. The FSK modem 112 modulates a control signal to be transmitted to a base station in a frequency shift key scheme.

The combiner 104 combines several analog signals into one analog signal and provides the same to the E / O converter 102. The E / O converter 102 converts an electrical signal provided by the combiner 104 into an optical signal and transmits the converted optical signal to an base station through an optical cable.

The base station 200 includes a master CDMA channel signal processor 220, a master remote base station controller 210, a combiner / splitter unit 206, an LNA 208, a splitter unit 216, an O / E converter unit ( 218, and an antenna A2.

The antenna A2 receives a high frequency signal through a wireless transmission path and provides it to the LNA 208. The LNA 208 low noise amplifies the analog high frequency signal received from the antenna A2. The O / E converter section 218 converts the optical signal into an electrical signal. The splitter unit 216 separates and outputs the control analog signal and the CDMA channel signal from the analog signal provided by the O / E converter unit 218.

The master remote base station controller 210 includes a base station control signal unit 212 and an FSK modem 214. The FSK modem 214 demodulates the analog control signal provided by the splitter unit 216 and provides it to the CPU of the base station control signal unit 212. This analog control signal is a control signal informing the state of the remote base station 100.

The combiner / splitter 206 combines the CDMA channel signals provided by the LNA 208 and the splitter 216 with a high frequency signal, and then generates a plurality of frequency allocation signals (FAs) such as 1FA, 2FA, 3FA, and 4FA. ).

The master CDMA channel signal processor 220 includes a base station CDMA channel signal source unit 202 and a convergence unit 204. The convergence unit 204 demodulates a plurality of FA signals modulated by a high frequency signal from a terminal and converts the FA signals into baseband CDMA channel data. The baseband CDMA channel data of the terminal thus received is connected to the modem of the base station CDMA channel signal source unit 202 to communicate with the terminal.

The operation of the system interface device between the base station 200 and the remote base station 100 configured as described above will be described.

Antenna A1 of remote base station 100 receives the high frequency CDMA channel signal from the terminal and provides it to LNA 108 of remote base station 100. The LNA 108 amplifies the high frequency CDMA channel signal of the received terminal.

The CPU of the remote base station 100 outputs control data indicating the state of the remote base station 100, which is frequency-shifted key modulated by the FSK modem 112 and output as an analog control signal.

The combiner 104 of the remote base station 100 combines a high frequency CDMA channel signal with a remote base station analog control signal. The combined electrical signal is converted into an optical signal through the E / O converter 102 and transmitted to the base station 200.

The O / E converter unit 218 of the base station 200 converts the optical signal transmitted through the optical cable into an electrical signal. The splitter unit 216 of the base station 200 separates the high frequency CDMA channel signal and the analog control signal. The FSK modem 214 of the master remote base station controller 210 receives an analog control signal and performs FSK demodulation. The CPU of the remote base station control signal unit 212 receives a demodulated digital control signal and reports the state of the remote base station 100.

The combiner / splitter unit 206 of the base station 200 combines the high frequency CDMA channel signal of the base station 200 and the high frequency CDMA channel signal of the remote base station 100 into a plurality of FA signals. The convergence unit 204 of the master CDMA channel signal processor 220 of the base station 200 converts a plurality of FA signals, which are high frequency signals, into baseband signals I and Q. The baseband signals I and Q may be transmitted to the CDMA modem of the base station 200 to communicate with the terminal.

According to the conventional technology, since the signal transmitted through the optical cable is an analog high frequency signal, there is a problem that the cable loss increases with temperature.

In addition, since a large number of analog high frequency signals are transmitted through the optical cable, mutual interference noise can be generated.

In addition, since the signal transmitted by the optical cable is an analog high frequency signal, it cannot be restored when it is damaged during transmission.

There is a problem that one FA of sector A, one FA of sector B and one FA of sector C cannot be combined in one combiner.

Accordingly, an object of the present invention is to solve the above-mentioned problems of the prior art, and to easily recover a damaged signal by using a digital signal of a signal transmitted through an optical cable, and a base station can serve a remote base station. It can be installed in the shaded area without any service so that the service for all regions can be performed normally, and it can support several FAs in the shaded area, maximize the use area of the channel card block of the base station, and one FA in several sectors. The present invention relates to a system interface device capable of preventing mutual interference that may occur when used as a service.

1 is a block diagram of a system interface device between a base station and a remote base station according to the prior art.

2 is a block diagram of a system interface device between a base station and a remote base station according to a preferred embodiment of the present invention.

3 is a detailed configuration diagram of the muxing unit of FIG.

4 is a detailed configuration diagram of the demux of FIG. 2.

* Description of the symbols for the main parts of the drawings *

300: remote base station 302: E / O converter

304: parallel-to-serial conversion unit 306: mux unit

308: slave CDMA channel signal processing unit

316: slave remote base station control unit

400: base station 402: master CDMA channel signal processing unit

408: splitter 410: LNA

412: master remote base station control unit

416: demux unit 418: series-parallel conversion unit

420: O / E converter section

In the system interface device between the base station and the remote base station of the present invention for achieving the above object, the slave remote base station control unit for outputting the local station control data, and the slave CDMA for outputting the digital baseband channel signals according to the signal provided by the terminal A channel signal processing unit, a mux unit receiving and receiving the local control signal and the digital baseband CDMA channel signals, a parallel-serial conversion unit converting the output of the mux unit into serial data, and converting the serial data into an optical signal Remote base station having an E / O converter unit for transmitting to the base station via an optical cable;

An O / E converter unit for converting an optical signal received by interfacing the remote base station with an optical cable to an electric signal, a serial-parallel converter for converting the electric signal into parallel data, and converting the parallel data into a remote base international language data. A demux unit for separating digital baseband CDMA channel signals, a master remote base station control unit receiving a remote base station control signal from the demux unit and reporting a status of the remote base station, and a digital baseband CDMA channel from the demux unit And a base station having a master CDMA channel signal processing unit for enabling communication with a terminal receiving signals.

Hereinafter, with reference to the accompanying drawings will be described the configuration and operation of the present invention.

2 is a block diagram of a system interface device between a base station and a remote base station according to an exemplary embodiment of the present invention. 2, the base station 400 and the remote base station 300 is connected by an optical cable.

The remote base station 300 includes an E / O converter 302, a parallel-to-serial converter 304, a mux 306, a slave CDMA channel signal processor 308, a slave remote base station controller 316, an antenna ( A3).

The antenna A3 receives a high frequency signal through a wireless transmission line.

The slave CDMA channel signal processor 308 is configured to communicate with the terminal and includes a conversion unit 310, a splitter 312, and an LNA 314. The LNA 314 amplifies the analog high frequency CDMA channel signal provided from the antenna A3.

The splitter 312 separates one analog high frequency CDMA channel signal into a plurality of FA signals 1FA, 2FA, 3FA, and 4FA. The conversion unit 310 receives the plurality of FA signals and converts them into digital baseband CDMA channel signal sources.

The slave remote base station controller 316 outputs digital control data for the CPU to notify the state of the remote base station 300.

The digital baseband CDMA channel source and the remote base station digital control signal are input to a mux unit 306 made of an FPGA, and the mux unit 306 muxes the digital baseband CDMA channel source and the remote base station digital control data. . The parallel-serial conversion unit 304 receives the parallel data muxed from the mux unit 306, converts the serial data into serial data, and outputs the serial data.

The E / O converter 302 receives serial data, that is, an electrical signal from the parallel-serial converter 304, converts the signal into an optical signal, and provides the converted signal to the base station 400 through an optical cable.

The base station 400 includes a master CDMA channel signal processor 402, a master remote base station controller 412, a demux 416, a serial-to-parallel converter 418, an LNA 410, and an O / E converter 420. ) And an antenna A4.

The O / E converter 420 converts the optical signal transmitted through the optical cable into an electrical signal, that is, serial data, and provides the serial-parallel converter 418. The serial-parallel converter 418 receives serial data from the O / E converter 420 and converts the serial data into parallel data and provides the serial data to the demux unit 416. The demux unit 416 demuxes the parallel data into a digital baseband CDMA channel signal source and a remote base station digital control data.

The master CDMA channel signal processor 402 receives a digital baseband CDMA channel signal source from the demux 416 and receives data for communication with a terminal.

The master remote base station control unit 412 is composed of a base station control signal unit 414, and receives the remote base station digital control data informing the status of the remote base station 300 from the demux unit 416.

Referring to the operation of the system interface between the base station and the remote base station according to the preferred embodiment of the present invention configured as described above, the antenna A3 of the remote base station 300 receives the CDMA channel high frequency signal from the terminal 400, The received signal is low noise amplified by the LNA 314.

The high frequency signal amplified by the LNA 314 is divided into a plurality of FA signals FA1, FA2, FA3, and FA4 through the splitter 312 and input to the convergence unit 310.

The convergence unit 310 converts the plurality of high frequency FA signals FA1, FA2, FA3, and FA4 into digital baseband CDMA signals BB_1FA, BB_2FA, BB_3FA, and BB_4FA and provides them to the mux unit 306. The CPU 318 of the slave remote base station control signal unit 316 outputs the digital control data for reporting the state of the remote base station and provides it to the mux unit 306.

The mux unit 306 muxes the digital baseband CDMA signals BB_1FA, BB_2FA, BB_3FA, BB_4FA and digital control data and inputs them to the parallel-serial conversion unit 304 as parallel data.

The parallel-serial converter 304 converts the parallel data into serial data and provides it to the E / O converter 302. The E / O converter 302 converts the serial data into an optical signal. Provided to the base station 400 through the optical cable.

The O / E converter 420 of the base station 400 converts an optical signal provided through the optical cable into an electrical signal, that is, serial data, and then provides the serial-parallel converter 418. The serial-parallel converter 418 converts the input serial data into parallel data and provides the demux 416.

The demux unit 146 separates the parallel data into a digital baseband CDMA modem channel signal and a remote base station digital control data. The remote base station digital control data is provided to the CPU 414 of the master remote base station control unit 412 so that the CPU 414 can grasp the state of the remote base station.

The master CDMA channel signal processor 402 receives a digital baseband CDMA channel signal and receives data for communication with the terminal.

The configuration of the mux unit 306 will be described in more detail with reference to FIG. 3.

Digital baseband CDMA channel signals (BB_1FA_A & B 12 bits (I 6 bits, Q 6 bits), BB_2FA_A & B 12 bits (I 6 bits, Q 6) according to the chip base clock digital control data (Rx_cpu_line 1 bit) and Chipx8 clock Bits), BB_3FA_A & B 12 bits (I 6 bits, Q 6 bits), and BB_4FA_A & B 12 bits (I 6 bits, Q 6 bits) are input to the mux section 306. The 13 lines in which the digital control signal (Rx_cpu_line 1 bit) and the 12 bits of the digital baseband CDMA channel signal are muxed are output from the muxing unit 306 at the Chipx32 speed. Frame_sync is output from the muxing section 306 at the Chipx32 rate to indicate the first start of the digital baseband CDMA channel signal.

The 14-bit parallel data output from the muxing unit 306 is converted into serial data by the parallel-serial conversion unit 304 and then provided to the E / O converter unit 302 at the Chipx640 speed. The serial data provided to the E / O converter unit 302, that is, the electric signal is converted into an optical signal and transmitted to the base station 400 through the optical cable.

The configuration of the demux unit 416 will be described in more detail with reference to FIG. 4.

The O / E converter unit 420 of the base station converts the optical signal transmitted through the optical cable into an electrical signal, that is, serial data, and then provides the serial signal to the serial-parallel converter 422. The serial-parallel converter 422 converts serial data of Chipx640 speed into parallel data of Chipx32 speed. The 14 bits of parallel data consist of 1 bit of frame_sync, 1 bit of Rx_cpu_line, and 12 bits of digital baseband CDMA channel signal.

The parallel data is provided to the demux unit 416. The demux unit 416 refers to the frame_sync indicating the start of the digital baseband CDMA channel signals and the remote base station control signal (Rx_cpu_line 1 bit) and the digital baseband CDMA channel signals (BB_1FA_A & B 12 bits (I6 bits, Q6). Bits), BB_2FA_A & B 12 bits (I 6 bits, Q 6 bits), BB_3FA_A & B 12 bits (I 6 bits, Q 6 bits), BB_4FA_A & B 12 bits (I 6 bits, Q 6 bits), respectively, at Chipx1 speed and Chipx8 speed. Demux and print

The system interface device between the base station and the remote base station according to the preferred embodiment of the present invention described above uses a digital signal as a signal transmitted through an optical cable, so that even if the signal is damaged during transmission, it can be easily recovered.

In addition, the system interface device between the base station and the remote base station according to an embodiment of the present invention, the remote base station is installed in a shaded area that the base station can not service, so that the service for all regions can be performed normally, a plurality of There is an advantage to supporting FA.

In addition, the system interface device between the base station and the remote base station according to an embodiment of the present invention can maximize the use area of the channel card block of the base station, and prevents mutual interference that may occur when using one FA in multiple sectors. can do.

Claims (2)

A slave remote base station controller for outputting its own control data, a slave CDMA channel signal processor for outputting digital baseband channel signals according to a signal provided by a terminal, and receiving and muxing the own control signal and digital baseband CDMA channel signals A remote base station having a mux unit, a parallel-serial conversion unit converting the output of the mux unit into serial data, and an E / O converter unit converting the serial data into an optical signal and transmitting the optical signal to a base station through an optical cable; An O / E converter unit for converting an optical signal received by interfacing the remote base station with an optical cable to an electric signal, a serial-parallel converter for converting the electric signal into parallel data, and converting the parallel data into a remote base international language data. A demux unit for separating digital baseband CDMA channel signals, a master remote base station control unit receiving a remote base station control signal from the demux unit and reporting a status of the remote base station, and a digital baseband CDMA channel from the demux unit A base station having a master CDMA channel signal processing unit for enabling communication with a terminal receiving signals, The slave CDMA channel signal processing unit, An antenna for receiving a signal from a terminal, an amplifier for low noise amplifying the signal received through the antenna, a splitter for separating the amplified signal into analog high frequency CDMA channel signals, and the separated analog high frequency CDMA channel signal And a conversion unit for converting the signals to digital baseband CDMA channel signals. delete