KR20020055223A - A device of transmitting digital data between bts - Google Patents

Abstract

PURPOSE: A digital data transmission apparatus between base stations is provided to mix CDMA(Code Division Multiplexing Access) signals by channels with a control signal of a base station in a digital signal state of the baseband, change the mixed signal into a serial signal and transmit the signal through an optical cable, thereby restoring the error generating in transmission and reducing the transmission loss. CONSTITUTION: A master signal processing unit(310) includes a CDMA unit(320) and a modulation unit(330). The CDMA unit(320) converts a subscriber's signal applied by each channel into the CDMA signal of the baseband and outputs the converted signal. The modulation unit(330) modulates the baseband signal into an RF(Radio Frequency) signal of a mobile communication band by an up converting operation and outputs the modulated signal. A master combiner(340) mixes or annexes the modulated signal and then outputs to a path. An amplifying unit(150) receives the RF signal from the combiner(340), amplifies the signal and then outputs the amplified signal to the corresponding antenna(30). A master base station control unit(350) controls a master base station(300), simultaneously separates and outputs a signal for controlling a slave base station(400). A multiplexer(360) multiplexes the control signal from the master base station control unit(350) and the CDMA signal of the baseband of the master signal processing unit(310). A P/S converter(370) converts the parallel digital signal output from the multiplexer(360) into a serial digital signal and outputs the converted signal. An E/O(Electroptic) converter(190) converts an electric signal output from the P/S converter(370) into an optical signal and then outputs the converted signal to an optical cable(20).

Description

Digital data transmission apparatus between base stations {A DEVICE OF TRANSMITTING DIGITAL DATA BETWEEN BTS}

The present invention relates to a digital data signal transmission apparatus between a base station and a base station, and more particularly, to an apparatus for transmitting a digital data signal to a remote base station for a shadow area for providing a mobile communication service in a small shadow area. will be.

The mobile communication system, which allows subscribers to communicate instantly anywhere in the country while moving, provides a uniform base station (BTS: Base Transmission Subsystem) that can send and receive data wirelessly with the subscriber terminal. Wireless communication is performed between base stations.

The base station transmits a radio signal to communicate with the terminal and receives a radio signal transmitted from the terminal. The base station transmits a radio signal to and from the terminal. It must be installed.

Even when the base station is installed at a constant interval throughout the country, radio waves cannot reach the high-rise buildings and the rear of the multifunctional zone or the underground living area due to the characteristics of the radio signal and thus cannot provide a mobile communication service. In the case of a shadow area, and when a new high-rise building enters, a shadow area naturally occurs behind a high-rise building due to the characteristics of radio waves.

In order to enable the mobile communication service in the shaded area as described above, the base station must be newly installed. However, since there is a frequency allocation problem, the same allocated frequency and data signal as the corresponding base station covering the shaded area in the normal case. And a small base station or a remote base station for transmitting and receiving radio waves as a control signal.

Hereinafter, a data transmission apparatus between base stations according to the prior art will be described with reference to the accompanying drawings.

1 is a block diagram of a data signal transmission function between a master base station and a slave base station according to the prior art, and FIG. 2 is a detailed functional block diagram of a master base station and a slave base station according to the prior art. .

Referring to FIG. 1, the analog data transmission apparatus between a master base station and a slave base station according to the related art includes a mobile switching center (MSC) that monitors and controls the entire mobile communication system. Mobile Switching Center) (10),

A master base station 100 connected to the mobile switching center 10 and wirelessly connected to the mobile terminal by a CDMA method according to an input communication channel signal and a control signal to provide a mobile communication service;

The master base station 100 is connected to the optical cable 20 through an optical cable 20, which is installed in a shadow area of a service area of the master base station 100, and has a shadow area terminal and a CDMA scheme. It is composed of a slave base station (200) for wirelessly connected to provide a mobile communication service.

Referring to FIG. 2, the detailed configuration of the master base station 100 according to the related art is a CDMA for receiving a channel-specific subscriber signal from the mobile switching center 10 and converting the signal for each channel to a CDMA scheme. Unit 120; A master signal processor comprising a modulator 130 for up-converting a base band CDMA signal applied to each channel from the CDMA unit 120 to a radio frequency (RF) signal and outputting each channel. 110),

A first combiner 140 for mixing a high frequency signal output for each channel from the master signal processor 110 and outputting it as one path;

A divider 145 which partially divides the level of the signal output from the first combiner 140 and divides the signal into two paths;

An amplifier 150 which receives a signal output from one path of the distributor 145 and amplifies the signal at high power and wirelessly transmits the signal through the antenna 30;

The master base station is controlled by the control signal input from the mobile switching center 10 and transmitted to the slave base station. The control signal input from the mobile switching station 10 is analyzed to control and monitor the master base station 100. A master processor 170 for equally outputting a control signal input from the mobile switching center; A master base station controller (160) comprising a master frequency shift keying (FSK) modem unit 180 for frequency shift keying (FSK) modulation of the signal applied from the master processor 170;

A second combiner 148 that combines the control signal applied from the master base station controller 160 and the CDMA signal for each channel input from the distributor 145 and outputs one path;

E / O converter for converting the electrical signal input from the second combiner 148 into an optical signal and output to the optical cable (20),

Referring to FIG. 2, the detailed configuration of the slave base station 200 according to the related art includes an optical converter that inputs an optical signal applied through the optical cable 20 and converts the optical signal into an electrical signal. With 210,

A splitter 220 for dividing a signal output from the photoelectric converter 210 into a control signal and a CDMA signal, respectively, and outputting the split signal;

A slave frequency shift keying (FSK) modem unit for demodulating a control signal input from the distribution unit 220 and modulated into an FSK by receiving and receiving a control signal output from the distribution unit 220. 250; A slave base station controller 240 comprising a slave processor 260 for controlling and monitoring the slave base station 200 by receiving, analyzing, and processing signals output from the slave FSK modem unit 250;

Comprising a slave amplifier 230 for amplifying the CDMA signal output from the distribution unit 220 to a high output and output through the antenna 40,

Hereinafter, with the above-described configuration, a data transmission apparatus between a base station and a base station according to the prior art will be described in detail with reference to the accompanying drawings.

The mobile communication service signal output from the mobile switching center 10 is output to the master base station 100, converted to CDMA and wirelessly transmitted through the antenna 30, and the slave base station 200 is installed in the shaded area. Since the same signal as the signal applied to the master base station 100 is input and processed, the mobile communication service can be received in the corresponding shadow area through the corresponding antenna 40.

The data transmission apparatus between the master base station 100 and the slave base station 200 for providing a mobile communication service in the shaded area as described above, after the master signal processing unit 110 converts the signal applied from the subscriber to the CDMA method When output for each channel, it is coupled by the first combiner 140 and separated by two paths by the distributor 145 is output.

The signal output from one path of the distributor 145 is applied to the amplifier 150 and amplified to high power, and then transmitted through the antenna 30 so that the terminal uses a mobile communication service.

The function of controlling and monitoring the master base station 10 to operate as described above is based on the function of the master base station controller 160 which analyzes and processes the signal input from the mobile switching center 10.

In order to partially expand the shadow area or the service area in the master base station 100 service area, the slave base station 200 installed or installed in the corresponding area should transmit the same signal as that of the master base station 100.

Therefore, the CDMA system signal transmitted from the master base station 100 and the control signal for controlling the base station 100 should also be applied to the slave base station 200.

As described above, the high frequency (RF) CDMA signal output from the first combiner 140 of the master base station 100 is distributed by the distributor 145 and input to the second combiner 148 and at the same time the master base station. The base station control signal output from the control unit 160 is input to the second combiner 148, mixed and applied to the slave base station 200 through the all-optical conversion unit 190 and the optical cable 20.

The slave base station 200 converts an input optical signal into an electrical signal and then separates a control signal and a high frequency CDMA signal and outputs them to the slave amplifier 230 and the slave base station controller 240, respectively. The mobile communication service can be used in the shaded area by the CDMA wireless signal output from the slave amplifier 230 by the control signal of 240.

However, the data transmission apparatus between the base station and the base station according to the prior art as described above, since the signal transmitted from the master base station 100 to the slave base station 200 through the optical cable 20 is an analog RF signal (Analog RF) signal There is a problem that the loss of the optical cable (Loss) is increased by the rise of the temperature.

In addition, since multiple channels of CDMA high frequency (RF) signals pass through the optical cable 20 in an analog form, between the high frequency signals of each channel in an all-optical (E / O) conversion and transmission process and an optoelectronic (O / E) conversion process. There was a problem in that noise (Interference Noise) is generated due to mutual interference.

In addition, when an error occurs in the high frequency channel signal transmitted through the optical cable, there is a problem that can not be recovered because it is an analog signal.

In addition, when a base station uses a sector antenna, there is a problem in that signals by the same allocated frequency of sector A, sector B, and sector C cannot be combined using a combiner.

According to the present invention, the channel-specific CDMA signal is mixed with the base station control signal in the baseband digital signal state, converted into a serial signal, and then transmitted through an optical cable, thereby recovering errors occurring during transmission and reducing transmission loss. It is also an object of the present invention to provide a digital data transmission apparatus between base stations, which does not have mutual interference for each channel and can transmit a signal for each sector even when using the same channel frequency.

In order to achieve the above object, the present invention provides a mobile communication base station system comprising a master base station and a slave base station, wherein the master base station converts and outputs a subscriber signal inputted for each channel into a baseband CDMA signal. A master signal processor for simultaneously up-modulating and outputting a high frequency signal; A master combiner for mixing the signals output by the high frequency modulation for each channel in the master signal processor and outputting them in one path; An amplifying unit which receives a high frequency signal applied from the master combiner and amplifies the antenna to a high output and outputs it to an antenna; A master base station controller for receiving and analyzing a signal for controlling the base station to control the master base station and to separate and output a signal for controlling the slave base station; A mux for receiving, mixing and outputting a control signal applied from the master base station controller and a baseband CDMA signal applied from the master signal processor; A parallel conversion unit converting the parallel digital signal outputted from the mux into a serial digital signal and outputting the serial digital signal; A digital data transmission device between base stations comprising an all-optical converter for converting an electrical signal output from the parallel converter into an optical signal and outputting the optical signal.

In addition, the present invention has been made in order to achieve the above object, in the mobile communication base station system consisting of a master base station and a slave base station, the slave base station, photoelectric conversion for converting an optical signal applied through an optical cable into an electrical signal Wealth; A serial-to-parallel converter which converts a signal output in series from the photoelectric converter into a parallel signal and outputs the parallel signal; A demux for classifying signals output from the serial-to-parallel converter and separating the signals into baseband CDMA signals and base station control signals and outputting the divided signals; An up-modulator for receiving a baseband CDMA signal output from the demux, up-modulating the high-frequency signal, and amplifying the high-frequency signal to output the corresponding antenna; Characterized in that the digital data transmission device between the base station consisting of a slave base station controller for monitoring and controlling the base station by receiving and analyzing the base station control signal output from the demux.

1 is a block diagram of a data signal transmission function between a master base station and a slave base station according to the prior art;

2 is a detailed functional block diagram of a master base station and a slave base station according to the prior art;

3 is a functional block diagram of a digital data transmission apparatus between base stations according to the present invention;

4 is a detailed functional block diagram of a mux according to the present invention;

5 is a detailed functional block diagram of a demux according to the present invention;

6 is a timing diagram of a mux input signal and an output signal and an all-optical converter according to the present invention.

** Explanation of symbols on the main parts of the drawing **

10: mobile switching center 20: optical cable

30,40: antenna 100,300: master base station

110,310: master signal processing unit 120,320: CDMA unit

130,330: Modulator 140,148,340,460: Combiner

145: Splitter 150, 230, 470: Amplifier

160,350: master base station control unit 170,260: processing unit

180,250: FSK modem unit 190: all-optical conversion unit

200,400: slave base station 210,410: photoelectric conversion unit

220: distribution unit 240,480: slave base station control unit

330,450: modulation unit 360: mux

370: vertical conversion unit 420: direct conversion unit

430: demux 440: up-modulator

500,600: clock part

Hereinafter, a digital data transmission apparatus between base stations according to the present invention will be described with reference to the accompanying drawings.

3 is a functional block diagram of a digital data transmission apparatus between base stations according to the present invention, FIG. 4 is a detailed functional block diagram of a mux according to the present invention, and FIG. 6 is a detailed functional block diagram of a demux according to the present invention, and FIG. 6 is a timing diagram of an input signal and an output signal of the mux according to the present invention and an all-optical converter.

Referring to FIG. 3, the digital data transmission apparatus between base stations according to the present invention is a mobile communication base station system (BTS: Base) comprising a CDMA master base station and a slave base station of a mobile communication system providing a mobile communication service. In the Transmission Subsystem, the master base station 300 converts a subscriber signal input for each channel into a baseband CDMA signal and outputs the same, up-converts and outputs a radio frequency (RF) signal. A CDMA unit 320 converting a subscriber signal applied for each channel into a baseband CDMA signal and outputting the converted signal; A master signal processor 310 comprising a modulator 330 for up-converting and outputting a baseband signal applied from the CDMA unit 320 to a corresponding radio frequency (RF) signal of a mobile communication band; ,

A master combiner 340 that mixes or merges the signals output by the RF signal by the master signal processor 310 for each channel and outputs them as one path;

An amplifying unit 150 which receives a high frequency (RF) signal applied from the master combiner 340, amplifies it to a high power, and outputs the amplified signal to the antenna 30;

A master base station controller 350 which receives and analyzes a signal for controlling a base station (BTS) to control the master base station 300 and separates and outputs a signal for controlling a slave base station 400 to be described later;

A mux 360 for receiving, mixing and outputting a control signal applied from the master base station controller 350 and a baseband CDMA signal applied from the master signal processor 310;

A parallel conversion unit (P / S converter) 370 for converting and outputting a parallel digital signal output from the mux 360 to a serial digital signal;

It consists of an electro-optical converter (E / O Converter) 190 for converting the electrical signal output from the vertical conversion unit 370 to an optical signal and output to the optical cable (20). .

3, the digital data transmission apparatus between base stations according to the present invention includes a master base station and a slave base station. In the mobile communication base station system, the slave base station 400 includes an optical cable 20 A photoelectric conversion unit (O / E converter) 410 for converting an optical signal applied through the into an electrical signal,

A serial-to-parallel converter (420) for converting and outputting a signal output in series from the photoelectric converter 410 into a parallel signal;

A demux 430 for classifying the signals output from the serial-to-parallel converter 420 and separating the signals into baseband CDMA signals and base station control signals, respectively, and outputting the divided signals;

The baseband CDMA signal output from the demux 430 is received, up-converted to a high frequency (RF) signal, and then amplified by a high power signal to the corresponding antenna 40. A slave modulator 450 for receiving a baseband CDMA signal, up-converting the corresponding high frequency (RF) signal of the mobile communication band, and outputting each channel; A slave combiner 460 for mixing or merging high frequency signals output for each channel from the slave modulator 450 and outputting them as one path; An up-modulator 440 comprising a slave amplifier 470 for amplifying and outputting a high frequency signal output from the slave combiner 460 to a high power signal;

Slave base station control unit 480 for monitoring and controlling the base station (BTS) by receiving and analyzing the base station control signal output from the demux 430,

Hereinafter, a digital data transmission apparatus between base stations according to the present invention having the above configuration will be described in detail with reference to the accompanying drawings.

The master signal processing unit 310 of the master base station 300 receives a communication signal applied for each channel from the mobile switching center 10 by the CDMA unit 320 and converts the signal applied for each channel into an I signal and a Q signal. Separately, each is modulated into a CDMA signal by a corresponding modem.

As an example, a detailed functional block diagram of the CDMA unit 320 having four channels is shown in FIG.

The baseband CDMA signals of I and Q output the signals of each channel to the modulator 330 and the mux 360 as 14-bit signals.

The modulator 330 modulates a signal input as a signal of I and Q for each channel into a corresponding radio frequency (RF) signal for mobile communication and outputs the signal to the master combiner 340, and to the master combiner 340. When mixed by the input to the amplification unit 150 by using one path, it is amplified by a high power (High Power) to be transmitted at a long distance, and then applied to the corresponding antenna 30, it is transmitted wirelessly .

At the same time, the baseband CDMA signal separated into I and Q for each channel from the CDMA unit 320 is output to the mux 360.

The mux 360 mixes the CDMA signal input from the CDMA unit 320 and the base station control signal input from the master base station control unit 350 and outputs the synchronization signal to the parallel conversion unit 370 together with the synchronization signal.

The parallel converter 370 converts the parallel digital data signal applied from the mux 360 into a serial digital data signal based on a clock signal applied from the clock unit 500.

The electrical signal output from the parallel converter 370 as a serial digital data signal is applied to the all-optical converter 190, converted into an optical signal, and output to the optical cable 20, thereby being applied to the slave base station 400.

A timing diagram of a signal input to and output from the mux 360 and a signal input / output from the all-optical converter 190 are as shown in FIG. 6.

Accordingly, the master base station 300 wirelessly transmits a signal input for each channel from the mobile switching center 10 as a CDMA mobile communication signal to its own service area, and simultaneously transmits a baseband communication data signal applied for each channel. The base station control signal is modulated into a digital signal, mixed, and output to the slave base station 400 as an optical signal.

The slave base station 400 receives a signal applied from the optical cable 20 by the photoelectric conversion unit 410, converts the signal into an electrical signal and outputs the signal to the serial-to-parallel conversion unit 420.

The serial-to-parallel converter 420 converts an input baseband serial data signal into a parallel data signal and outputs the parallel data signal to the demux 430, and the demux 430 is divided into I and Q channels for each CDMA communication. The signal and the control signal for controlling the base station are separated and output to each path.

The slave modulator 450 receiving the CDMA communication signals separated by I and Q for each channel from the demux 430 receives the I and Q baseband CDMA signals for each channel and is assigned to the mobile communication system. Upconverting to a high frequency (RF) signal, mixed by the slave combiner 460, output as one path, and input to the slave amplifier 470.

The slave amplifier 470 amplifies the input CDMA high frequency signal to a high power (High Power), and is then wirelessly transmitted through the antenna 40.

At the same time, the base station control signal separated and output from the demux 430 is input to the slave base station controller 480 to control and monitor each function unit as described above.

Therefore, the mobile communication channel-specific signals and the base station control signals processed by the master base station 300 are also applied and processed in the slave base station 400 in the same way.

In addition, since the signal applied from the master base station 300 to the slave base station 400 is mixed into a baseband signal and transmitted through the optical cable 20, the transmission frequency (Loss) of the cable is low because the frequency is low, and each There is no mutual interference for each channel.

In addition, since a digital signal, when an error occurs in the transmission process, it is easy to restore, and can be transmitted by combining the signals of the A, B, and C sectors of the base station using the same channel.

According to the present invention having the above-described configuration, since the channel signal and the control signal transmitted between the base station and the base station are mixed and transmitted to the baseband signal, there is no mutual interference in the signals between the channels, and the transmission frequency is low and the transmission loss is low. It works.

In addition, since the data is transmitted as a digital data signal, data errors occurring during transmission can be easily recovered on the receiving side, thereby improving the reliability of the system.

Claims (4)

In the mobile communication base station system consisting of a master base station and a slave base station, The master base station, the master signal processing unit for converting the subscriber signal input for each channel into a baseband CDMA signal and outputs the modulation and up-modulation as a high frequency signal; A master combiner for mixing the signals output by the high frequency modulation for each channel in the master signal processor and outputting them in one path; An amplifying unit which receives a high frequency signal applied from the master combiner and amplifies the antenna to a high output and outputs the antenna to an antenna; A master base station controller which receives and analyzes a signal for controlling a base station to control a master base station and simultaneously separates and outputs a signal for controlling a slave base station; A mux for receiving, mixing and outputting a control signal applied from the master base station controller and a baseband CDMA signal applied from the master signal processor; A parallel conversion unit for converting the parallel digital signal output from the MUX into a serial digital signal and outputting the serial digital signal; And an all-optical converter configured to convert an electrical signal output from the parallel converter into an optical signal and output the converted optical signal to an optical cable. The method of claim 1, wherein the master signal processing unit, A CDMA unit for converting a subscriber signal applied for each channel into a baseband CDMA signal; And a modulation unit for up-modulating the baseband signal applied from the CDMA unit into a high frequency signal. In the mobile communication base station system consisting of a master base station and a slave base station, The slave base station includes a photoelectric conversion unit for converting an optical signal applied through an optical cable into an electrical signal; A serial-to-parallel converter for converting a signal output in series from the photoelectric conversion unit into a parallel signal and outputting the parallel signal; A demux for classifying signals output from the serial-to-parallel converter and separating the signals into baseband CDMA signals and base station control signals, respectively, and outputting the divided signals; An up-modulator for receiving a baseband CDMA signal output from the demux and up-modulating the high-frequency signal and amplifying the high-frequency signal to output the corresponding antenna; And a slave base station controller configured to monitor and control a base station by receiving and analyzing a base station control signal output from the demux. The method of claim 3, wherein the uplink modulator, A slave modulator which receives a baseband CDMA signal and up-modulates a high frequency signal and outputs each channel; A slave combiner for mixing the high frequency signals output for each channel from the slave modulator and outputting them in one path; And a slave amplifier for amplifying a signal output from the slave combiner into a high output signal and outputting the signal to a corresponding antenna.