KR20060027077A - Repeater network between a base station and communications terminals using microwave repeater - Google Patents

Abstract

The present invention relates to a relay network used in a mobile communication system such as a personal mobile communication system or a cellular system. In the relay network between the base station and the terminal according to the present invention in the relay network between the base station and the terminal for relaying signals transmitted and received between the base station and the terminal, receives the RF signal transmitted from the base station and transmits it to the donor M / W repeater, The donor RF repeater 20, which transmits the RF signal received from the donor M / W repeater to the base station, is coupled through the donor RF repeater and the cable 30, and the RF signal received from the donor RF repeater M / W Donor M / W repeater 40, which is converted into a signal and transmitted through an airwave transmission network, and converts an M / W signal received from the airwave transmission network into an RF signal and transmitted to a donor RF repeater, M received from a donor M / W repeater Converts / W signal into RF signal and transmits it to remote RF repeater, and converts RF signal received from remote RF repeater into M / W signal The remote M / W repeater 60 which transmits to the transmission network and the remote M / W repeater and the cable 70 are combined, and the RF signal received from the remote M / W repeater is transmitted to the airwave transmission network, And a remote RF repeater 80 for transmitting the RF signal received from the transmission network to the remote M / W repeater through the cable.

Repeater, microwave

Description

Repeater network between a base station and communications terminals using microwave repeater}

1 is a block diagram showing the configuration of a general relay network between a base station 1 and a terminal.

2 is a block diagram showing a relay network between the base station 10 and the terminal according to an embodiment of the present invention.

3 is a block diagram showing an internal configuration example of the donor RF repeater 20 in FIG.

4 is a block diagram showing an internal configuration example of the donor M / W repeater 40 in FIG.

FIG. 5 is a block diagram illustrating an internal configuration example of the M / W repeater 50 in FIG. 2.

FIG. 6 is a block diagram showing an internal configuration example of the remote M / W repeater 60 in FIG.

FIG. 7 is a block diagram showing an internal configuration example of the remote RF repeater 80 in FIG.

FIG. 8 is a block diagram showing another configuration example of the donor M / W repeater 40 in FIG.

FIG. 9 is a block diagram showing an internal configuration example of a synchronization signal generator 81 in FIG.

10 is a block diagram showing another configuration example of the remote M / W repeater 60 in FIG.                 

FIG. 11 is a block diagram illustrating an internal configuration example of a synchronization signal generator 110 in FIG. 10.

*** Brief description of the main parts of the drawing ***

10: base station, 11, 21, 81: RF antenna,

20: donor RF repeater, 30, 70: cable,

40: donor M / W repeater, 50: M / W repeater,

60: remote M / W repeater, 80: remote RF repeater.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a relay network used in a mobile communication system such as a personal mobile communication system or a cellular system. In particular, the present invention relates to a base station using a microwave repeater capable of providing smooth data transmission and reception between a base station and a terminal using a microwave repeater. The relay network between the terminal and the terminal.

Recently, a mobile communication system that enables a user to perform voice calls and data transmission and reception while traveling is widely used. Such a mobile communication system divides a call area into cell units, and sets base stations for each cell unit so that users can perform communication through these base stations. These base stations and terminals usually perform data transmission and reception using frequency signals between several hundreds of MHz and several kilohertz, and also install and operate a plurality of relay devices in consideration of communication shadow areas such as indoors.                         

The relay device is generally installed between the terminal and the base station to amplify the signal (forward link signal) from the base station to the terminal, and to amplify the signal from the terminal (reverse link signal) to the base station.

On the other hand, the relay device is also used for the purpose of extending the service area of the base station with the resolution of the shadow area. It is not economically and technically desirable to install a base station in each service area because the installation of optical cables is very difficult and the number of service users in the service area is very small when there are many mountainous areas such as Korea. Therefore, in the case of such an area, as shown in FIG. 1, it is preferable to extend a service area of the base station by cascading a plurality of repeaters 2: 2-1, ..., 2-n with respect to the base station 1. Done.

However, such a conventional relay network has the following problems.

That is, since the RF repeater is usually limited to 5 km within the service distance, when the distance between the base station and the service area is far, it is necessary to install a plurality of repeaters between the base station and the service area. In particular, when there are many mountainous areas such as Korea, it is necessary to install a large number of repeaters in order to secure visibility.

By the way, the conventional relay network is configured by using an RF repeater, wherein the frequency used in the RF repeater is approximately 800 MHz band, which is the frequency of the same band as the frequency used in the RF repeater. Therefore, when the number of repeaters is increased, the number of frequency channels usable in the RF repeater is substantially reduced, thereby limiting the increase in the number of RF repeaters by a certain amount or more.

Therefore, in the case of the conventional relay network, there is a problem that it is difficult to use as a use for expanding the service area of the base station.

Accordingly, the present invention has been made in view of the above circumstances, and an object thereof is to provide a relay network between a base station and a terminal that can be suitably applied and used to expand the service area of a base station.

A relay network between a base station and a terminal using a microwave repeater according to the present invention for realizing the object, in the relay network between the base station and the terminal for relaying signals transmitted and received between the base station and the terminal, receives the RF signal transmitted from the base station And a donor RF repeater for transmitting the RF signal received from the donor M / W repeater to the base station, the donor RF repeater and the RF signal received from the donor RF repeater. It converts the signal into M / W signal and transmits it through the airwave transmission network, and receives from the donor M / W repeater and donor M / W repeater which converts the M / W signal received from the airwave transmission network into an RF signal and transmits it to the donor RF repeater. M / W signal is converted into RF signal and transmitted to remote RF repeater, remote RF repeater Remote M / W repeater that converts RF signal received from M / W signal to air wave transmission network and combines with remote M / W repeater through cable, and also receives RF signal received from remote M / W repeater In addition to transmitting to the wave transmission network, characterized in that it comprises a remote RF repeater for transmitting the RF signal received from the air wave transmission network to the remote M / W repeater through the cable.

In addition, at least one M / W repeater is provided between the donor M / W repeater and the remote M / W repeater.

The donor M / W repeater may further include a synchronization signal transmitting means for transmitting a reference clock signal used for internal frequency conversion, and the remote M / W repeater is configured based on the received reference clock signal. The phase of the reference clock signal is adjusted.

Hereinafter, an embodiment according to the present invention will be described with reference to the drawings.

2 is a block diagram showing the configuration of a relay network between a base station and a terminal using a microwave repeater according to an embodiment of the present invention.

The relay network between the base station and the terminal shown in FIG. 2 includes a plurality of RF repeaters 20, 80 and microwave repeaters 40, 50, 60 (hereinafter, M / N) between the base station 10 and the terminal (not shown). W repeater). Here, the RF repeater 20 is coupled to the base station 10 through an RF signal, and is coupled by wire through the M / W repeater 40 and the cable 30. Hereinafter, the RF repeater 20 is referred to as a donor RF repeater, and the M / W repeater 40 is referred to as a donor M / W repeater.

The donor M / W repeater 50 is coupled to the M / W repeater 50 via a microwave signal (hereinafter referred to as an M / W signal), and the M / W repeater 50 is again an M / W signal. It is coupled with the M / W repeater 60 through. The M / W repeater 60 is then coupled to the RF repeater 80 via a cable 70. Hereinafter, the M / W repeater 60 is referred to as a remote M / W repeater, and the RF repeater 80 is referred to as a remote RF repeater 80.

Here, although only one M / W repeater 50 is shown in the drawing, a plurality of M / W repeaters 50 may be coupled depending on the distance between the donor M / W repeater 40 and the remote M / W repeater 60. Of course, the donor M / W repeater 40 and the remote M / W repeater 60 will be directly coupled without the M / W repeater 50 when the separation distance is close. The remote RF repeater 80 is for providing a communication service to the terminal.

Base station 10 is conventional. The base station 10 transmits various signals for providing a communication service to the terminal. The RF signal transmitted from the base station 10 is transmitted to the over-the-air transmission network through the RF antenna 11. The RF signal transmitted from the base station 10 is received through the RF antenna 21 of the donor RF repeater 20, and the signal is transmitted to the donor M / W repeater 40 through the cable 30 to M / W. It is transmitted to the M / W repeater 50 side through the antenna 41. The M / W repeater 50 amplifies the M / W signal received through the M / W antenna 51 and transmits it to the remote M / W repeater 60 through the M / W antenna 52, and the remote M The / W repeater 60 converts the M / W signal received through the M / W antenna 61 into an RF signal and transmits the RF signal to the remote RF repeater 80 through the cable 80. The remote RF repeater 80 transmits the received signal through the RF antenna 81 to provide a communication service to the terminal.                     

The signal transmitted from the terminal to the base station is transmitted through the reverse path and the aforementioned path. That is, the RF signal transmitted from the terminal is transmitted to the remote M / W repeater 60 through the remote RF repeater 80, and the remote M / W repeater 60 converts the received RF signal into an M / W signal. It transmits over the air transmission network. The M / W signal transmitted from the remote M / W repeater 60 is received by the donor M / W repeater 40 through the M / W repeater 50. The donor M / W repeater 40 converts the received M / W signal into an RF signal and transmits the received M / W signal to the donor RF repeater 20. The donor RF repeater 20 transmits the received RF signal to the base station 10. Send it out.

3 is a block diagram showing the configuration of the donor RF repeater 20.

The donor RF repeater 20 is a base station 10 is coupled to the duplex filter 22 for separating the transmission and reception frequency to the RF antenna 21 for transmitting and receiving the RF signal with the base station 10, the base station output through the duplex filter 22 The received signal from 10 is coupled to the duplex filter 25 via a low noise amplifier (LNA) 23 and an amplifier 24. Here, the low noise amplifier 23 low-noise amplifies the received signal from the base station 10 output from the duplex filter 22, the amplifier 24 is a predetermined signal output from the low noise amplifier 23 Amplify to gain. And, the duplex filter 25 is to separate the transmission and reception frequency, which is coupled via the donor M / W repeater 40 and the cable 30, from the base station 10 applied from the amplifier 24 The reception signal is transmitted to the donor M / W repeater 40, and the reception signal received from the donor M / W repeater 40 is applied to the amplifier 26.                     

The amplifier 26 amplifies and outputs a signal received from the donor M / W repeater 40 with a predetermined amplification gain, and the output signal is a high gain in a high power amplifier 27 (HPA: High Power Amplifier). After being amplified, it is transmitted to the base station 10 through the duplex filter 22 and the antenna 21.

In the donor RF repeater 20 having the above-described configuration, when an RF signal is received from the base station 10 through the antenna 21, the signal is input through the duplex filter 22 to be amplified with the low noise amplifier 23. After being amplified by the unit 24, the duplex filter 25 and the cable 30 are transmitted to the donor M / W repeater 40.

Further, the received signal from the donor M / W repeater 40 is input through the duplex filter 25, and the input signal is amplified by the amplifier 26 and the high output amplifier 27 and then the duplex filter 22. And it is transmitted to the base station 10 through the antenna 21.

4 is a block diagram showing the configuration of the donor M / W repeater 40 in FIG.

In FIG. 4, the RF signal applied from the donor RF repeater 20 is coupled to the amplifier 43 through the duplex filter 42, and the RF signal amplified by the amplifier 43 is a frequency upconverter (UC). 44). The frequency up-converter 44 converts an RF signal in the 800 MHz band applied from the donor RF repeater 20 into an M / W signal in the 17-18 kHz band. The M / W signal output from the frequency up-converter 44 is amplified by the high output amplifier 45 and then applied to the circulator 46, and then the M / W antenna 41 through the circulator 46. ) Is sent to the over-the-air transmission network.

In addition, the M / W signal received from the over-the-air transmission network via the M / W antenna 41 is amplified by the low noise amplifier 47 through the circulator 46, and the M / W signal output from the low noise amplifier 47 is It is applied to a frequency down converter (DC) 48. The frequency down-converter 48 converts an M / W signal of, for example, 17 to 18 GHz band input from the low noise amplifier 47 into an RF signal of, for example, an 800 MHz band. The RF signal output from the frequency down converter 48 is amplified by the amplifier 49 and then transmitted to the donor RF repeater 20 through the duplex filter 42 and the cable 30.

That is, the donor M / W repeater 40 converts an RF signal received from the donor RF repeater 20 through a cable 30 into an M / W signal, and then converts the RF signal into an M / W antenna 41 through an airwave transmission network. And the M / W signal received through the M / W antenna 41 is converted into an RF signal and transmitted to the donor RF repeater 20 through the cable 30.

5 is a block diagram showing the configuration of the M / W repeater 50 in FIG.

In FIG. 5, the M / W signal from the donor M / W repeater 40 received through the M / W antenna 51 is input to the low noise amplifier 54 through the duplex filter 53, and the low noise amplifier 54 is provided. The amplified and output M / W signal is amplified by the high power amplifier 55 and then transmitted to the airwave transmission network through the duplex filter 56 and the M / W antenna 52.

Further, the M / W signal from the remote M / W repeater 60 received through the M / W antenna 52 is input to the low noise amplifier 57 through the duplex filter 56 and amplified, and then a low noise amplifier ( The M / W signal output from 57 is amplified by the high power amplifier 58 and then transmitted to the airwave transmission network through the duplex filter 53 and the M / W antenna 51.

That is, the M / W repeater 50 receives and amplifies the M / W signal transmitted from the donor M / W repeater 40 and sends it to the remote M / W repeater 60, while the remote M / W The M / W signal transmitted from the repeater 60 is received and amplified and then sent to the donor M / W repeater 40.

6 is a block diagram showing the configuration of the remote M / W repeater 60.

In FIG. 6, the M / W signal from the M / W repeater 50 received through the M / W antenna 61 is coupled to the low noise amplifier 63 through the circulator 62, and this low noise amplifier 63 is provided. The M / W signal of, for example, 17 to 18 GHz band, which is amplified and output from the frequency downconverter 64, is converted into an RF signal of, for example, 800 MHz band. The RF signal is amplified by the amplifier 65 and then transmitted to the remote RF repeater 80 through the multiplexer 66 and the cable 70.

In addition, an RF signal of, for example, an 800 MHz band received from the remote RF repeater 80 is amplified by the amplifier 67, and the amplified signal is, for example, a 17 to 18 kHz band through the frequency up-converter 68. It is converted into M / W signal. The M / W signal output from the frequency up-converter 68 is amplified by the high power amplifier 69 and then transmitted to the airwave transmission network through the circulator 62 and the M / W antenna 61.

That is, the remote M / W repeater 60 converts the M / W signal received from the donor M / W repeater 40 through the M / W repeater 50 into an RF signal, and then converts the cable 70 into an RF signal. Transmitted to the remote RF repeater 80 through, the RF signal received from the remote RF repeater 80 is converted to the M / W signal is sent to the donor M / W repeater 40 side.

7 is a block diagram showing the configuration of the remote RF repeater 80.                     

In FIG. 7, the RF signal received from the remote M / W repeater 60 through the cable 70 is applied to the amplifier 72 through the multiplexer 71, and the RF signal output from the amplifier 72. Is coupled to the transmitting RF antenna 81a through a band pass filter 73 and a lightning arrester 74 for removing band signals other than the service band. The RF signal transmitted through this RF antenna 81a is provided to the user's terminal.

In addition, the RF signal from the user terminal received through the receiving RF antenna 81b is input to the low noise amplifier 77 through the lightning arrestor 75 and the band pass filter 76 for noise signal removal, and this low noise The RF signal output from the amplifier 77 is amplified by the amplifier 78 and then transmitted to the remote M / W repeater 60 through the multiplexer 71 and the cable 70.

That is, the remote RF repeater 80 amplifies and transmits the RF signal received from the remote M / W repeater 60 to the user's terminal, and amplifies the RF signal received from the user's terminal to the remote M / W. Transmission to the repeater 60.

In the relay network between the base station and the terminal according to the present invention, the RF signal transmitted from the base station 10 is first received by the donor RF repeater 20 to disconnect the cable 30 from the donor RF repeater 20. It is transmitted to the donor M / W repeater 40 through. Subsequently, the donor M / W repeater 40 converts an RF signal received from the donor RF repeater 20 into an M / W signal and then transmits the RF signal through the M / W antenna 41. The M / W signal transmitted from the donor M / W repeater 40 is transmitted to the remote M / W repeater 60 through the M / W repeater 50, and the remote M / W repeater 60 receives the received M. After converting the / W signal back to the original RF signal, the RF signal is transmitted to the remote RF repeater 80 through the cable 70. In addition, the remote RF repeater 80 transmits an RF signal received from the remote M / W repeater 60 through the RF antenna 81 to receive an RF signal from the base station 10 with respect to a terminal existing in its service area. Send a signal.

On the other hand, when the RF signal from the terminal in the service area of the remote RF repeater 80 is received through the RF antenna 81, the remote RF repeater 80 receives the received RF signal via the cable 70 to the remote M / W to the W repeater 60, the remote M / W repeater 60 converts the RF signal received from the remote RF repeater 80 to the M / W signal to transmit it through the M / W antenna 61 do. The M / W signal transmitted from the remote M / W repeater 60 is transmitted to the donor M / W repeater 40 side through the M / W repeater 50. Subsequently, the donor M / W repeater 40 converts the M / W signal received through the M / W antenna 41 into an RF signal and transmits the M / W signal to the donor RF repeater 20 through the cable 30. The donor RF repeater 20 transmits the received RF signal to the base station 10 through the antenna 21.

Therefore, in the above-described embodiment, first, the RF signal transmitted from the base station 10 is smoothly provided to the terminal, and the RF signal transmitted from the terminal is also smoothly provided to the base station 10. That is, it is possible to provide a normal communication service to a terminal remote from the base station 10.                     

In addition, in the above-described embodiment, up to two RF repeaters are used to provide a communication service for a service area remote from the base station 10, and in particular, one RF repeater is used for transmission and reception. Since only the channel is used, comparing the network of FIG. 2 with the relay network of FIG. 1 results in using only one RF repeater between the base station and the terminal. Therefore, in the above-described embodiment, an efficient relay network is formed between the base station and the terminal, and the RF channel of the base station can be efficiently operated.

Meanwhile, in the above-described embodiment, the donor M / W repeater 40 and the remote M / W repeater 60 up-convert the RF signal to generate the M / W signal, and the M / W signal downconverts the frequency. To generate an RF signal. In this case, frequency up-conversion and down-conversion are implemented through a method of mixing a predetermined reference frequency signal with a received frequency. However, if there is a phase difference between the reference frequencies used in the donor M / W repeater 40 and the remote M / W repeater 60, the original signal may be restored at a later stage due to distortion between signals transmitted and received. The problem of becoming impossible becomes.

In order to solve the above problem, a method of generating a reference frequency signal, that is, a reference clock signal using a high precision device may be considered. However, in the above-described embodiment, the distance between the donor M / W repeater 40 and the remote M / W repeater 60 is at least 5 km or more, so the donor M / W repeater 40 and the remote M / W repeater 60 There may be a big difference in the surrounding environment, such as the temperature and humidity of the surrounding environment. In addition, the difference in the characteristics of the device for generating the reference clock signal due to the difference in the surrounding environment may cause a phase difference between the two reference clock signals.

In addition, as another solution to solve the above problem, a visual synchronization method using GPS may be considered. However, this time synchronization method is disadvantageous in that the cost of the device is very expensive and a separate antenna must be installed for the GPS depending on the installation location of the donor or the remote M / W repeater.

8 is a block diagram showing the configuration of the donor M / W repeater 40 according to another embodiment of the present invention in consideration of the above problem. In addition, in FIG. 8, the same reference numeral is attached | subjected to the substantially same part as FIG. 4 mentioned above, and the detailed description is abbreviate | omitted.

In FIG. 8, a synchronization signal generator 81 for generating a synchronization signal is provided. The synchronization signal generator 81 generates a predetermined reference clock signal and supplies it to the frequency up-converter 44 and the frequency down-converter 48. This reference clock signal is used for frequency conversion in the frequency up-converter 44 and the frequency down-converter 48. In addition, the synchronization signal output from the synchronization signal generator 81 is input to the coupler 82, and is coupled to the input terminal of the high output amplifier 45 by the coupler 82. The synchronous signal is amplified by the high output amplifier 45 and then transmitted through the circulator 46 and the M / W antenna 41.

9 is a block diagram showing a specific configuration of the synchronization signal generator 81. As shown in FIG.

In FIG. 9, the synchronization signal generator 81 includes a reference clock signal generator 811, a spread spectrum channel modulator 812, a digital to analog converter 813, and a frequency converter 814.                     

The reference clock signal generator 811 is configured to generate a reference clock signal having a predetermined frequency, and is configured to include an OXCO (Oven Crystal Oscillator). The reference clock signal output from the reference clock signal generator 811 is supplied to the frequency up-converter 44 and the frequency down-converter 48 of FIG. 8 and input to the spread spectrum channel modulator 812 as described above. . Although not specifically illustrated in the drawing, the reference clock signal output from the reference clock signal generator 811 is multiplied through a separate frequency multiplier or the like as necessary to be used in the frequency up-converter 44 and the frequency down-converter 49. Can be used.

The spread spectrum channel modulator 812 modulates the reference clock signal by multiplying a predetermined CDMA code by an input reference clock signal. The digital / analog converter 813 converts the digital modulated signal output from the spread spectrum channel modulator 812 into an analog signal and outputs the analog signal. The frequency up-converter 814 converts the input analog signal into an M / W signal. Will print.

Subsequently, as described above, the M / W signal output from the synchronization signal generator 81 is input to the high output amplifier 45 through the coupler 82, and the circulator 46 and the M / W antenna 41 are provided. The M / W signal is outputted through the M / W repeater 50 described with reference to FIG. 5 to the remote M / W repeater 60.

10 is a block diagram showing another configuration example of the remote M / W repeater 60. As shown in FIG.

In FIG. 10, the coupler 100 is coupled between the low noise amplifier 63 and the frequency downconverter 64 of the remote M / W repeater 60. The coupler 100 branches the M / W signal from the donor M / W repeater 40 input through the low noise amplifier 63 and couples the M / W signal to the input of the synchronization signal generator 110.

The sync signal generator 110 extracts a sync signal from the M / W signal received from the donor M / W repeater 40, and outputs the sync signal from the sync signal generator 81 in FIG. 8 based on the extracted sync signal. A clock signal synchronized with the reference clock signal becomes substantially the same, that is, has the same phase and frequency. The generated reference clock signal is supplied to the frequency downconverter 64 and the frequency upconverter 68 to be used for frequency conversion of the signal transmitted and received with the donor M / W repeater 40.

11 is a block diagram illustrating a specific configuration example of the synchronization signal generator 110.

In FIG. 11, the synchronization signal generator 110 includes a frequency down converter 111, an analog / digital converter 112, a digital filter 113, a channel demodulator 114, a digital phase locked loop (PLL) 115, and an oscillator. And 116.

The frequency down-converter 111 corresponds to the frequency up-converter 814 in FIG. 9, which down-converts the frequency of the input signal so that the input signal is output from the digital / analog converter 813 of FIG. 9. It has a frequency equal to the signal frequency.

The analog signal output from the frequency down converter 111 is converted into digital data by the analog / digital converter 112 and input to the digital filter 113. The digital filter 113 filters and outputs predetermined channel data, that is, data generated and transmitted by the synchronization signal generator 81 of FIG. 8, from the input digital data. The data output from the digital filter 113 is input to the channel demodulator 114.

The channel demodulator 114 corresponds to the spread spectrum channel modulator 812 of FIG. The channel demodulator 114 demodulates the signal input from the digital filter 113 with the same code as the CDMA code multiplied by the clock signal in the spread spectrum channel modulator 812. Accordingly, the channel demodulator 114 demodulates and outputs a clock signal having the same phase and frequency as the clock signal output from the reference clock signal generator 811 of FIG. 9.

The clock signal output from the channel demodulator 114 is input to the digital PLL 115. The digital PLL 115 compares the phase of the clock signal input from the channel demodulator 114 with the clock signal output from the reference clock signal generator 116 and outputs a voltage signal corresponding to the phase difference.

The reference clock signal generator 116 is substantially the same as the reference clock signal generator 811 of FIG. 9, and is configured with, for example, OXCO. This generates and outputs a clock signal having a frequency corresponding to the control voltage applied from the digital PLL 115. The reference clock signal output from the reference clock signal generator 116, that is, the reference clock signal output from the synchronization signal generator 110 in FIG. 10, is supplied to the frequency downconverter 64 and the frequency upconverter 68. To be used for frequency conversion. Of course, in this case as well, the reference clock signal output from the reference clock signal generator 116 may be multiplied through a separate frequency multiplier or the like, as necessary, to obtain the frequency up-converter 64 and the frequency down-converter 68. Can be used).

8 and 9, the clock signal from the reference clock signal generator 811, which generates the reference clock signal of the donor M / W repeater 40, is spread spectrum channel modulator 812. After being modulated at, the digital / analog converter 813 and the frequency up-converter 814 are converted into M / W signals and output. The output signal of the synchronization signal generator 81 is input to the high output amplifier 45 through the coupler 82 and amplified, and then the circulator 46 and the M / W antenna are operated in the same manner as the general M / W signal. It is transmitted to the airwave transmission network through 41.

The M / W signal transmitted from the donor M / W repeater 40 is transmitted to the remote M / W repeater 60 through the M / W repeater 50 as described above.

In the remote M / W repeater 60 of FIG. 10, the M / W signal introduced to the M / W antenna 61 through the airwave transmission network is led to the low noise amplifier 63 through the circulator 62 and amplified. After that, it is input to the frequency down converter 64 and the synchronization signal generator 110 through the coupler 100.

In the reference clock signal generator 110 of FIG. 11, the M / W signal from the donor M / W repeater 40 input through the coupler 100 is first transmitted through the frequency down converter 111. Is converted into digital data through the analog-to-digital converter 112 and input to the digital filter 113. Subsequently, the digital filter 113 selectively filters predetermined data among input data, that is, a modulated signal output from the spread spectrum channel modulator 812 of the synchronization signal generator 81 in FIG. ). The channel demodulator 114 recovers the clock signal output from the reference clock signal generator 811 of FIG. 9 by performing a demodulation process of multiplying a predetermined CDMA code with respect to the data input from the digital filter 113. .

Next, the clock signal output from the channel demodulator 114 is applied to the digital PLL 115, and the digital PLL 115 is connected to the demodulated clock signal, that is, the clock signal received from the donor M / W repeater 40. The clock signal output from the reference clock signal generator 116 by comparing the phase of the clock signal output from the reference clock signal generator 116 and controlling the oscillation frequency of the reference clock signal generator 116 based on the phase difference. The phase and frequency are equal to the clock signal input from the channel demodulator 114. The reference clock from the phase-locked reference clock signal generator 116 is supplied to the frequency downconverter 64 and the frequency upconverter 68 of the remote M / W repeater 60 to be utilized for the frequency conversion operation. do.

That is, in the above embodiment, the reference clock signal of the donor M / W repeater 40 is converted into an M / W signal and transmitted to the remote M / W repeater 60, and in the remote M / W repeater 60, the donor M The output frequency of the reference clock signal generator 116 is controlled to phase-synchronize with the reference clock signal received from the / W repeater 40. Therefore, in the above embodiment, even when a phase occurs in the phase of the reference clock signal generator 811 included in the synchronization signal generator 81 due to the environment around which the donor M / W repeater 40 is installed, the donor Since the frequency and phase of the clock signal output from the reference clock signal generator 811 of the M / W repeater 40 and the reference clock signal generator 116 of the remote M / W repeater 60 always match exactly, the donor And stable data transmission and reception between the remote M / W repeaters 40 and 60.

In the above, the Example of this invention was described. However, the above examples illustrate preferred embodiments of the present invention, and the present invention can be implemented in various modifications without departing from the technical spirit of the present invention.

As described above, according to the present invention, it is possible to realize a relay network between a base station and a terminal that can be suitably applied to the expansion of the base station of the base station.

Claims (3)

In the relay network between the base station and the terminal for relaying signals transmitted and received between the base station and the terminal, A donor RF repeater for receiving an RF signal transmitted from the base station and transmitting it to a donor M / W repeater and transmitting an RF signal received from a donor M / W repeater to the base station; Combined with the donor RF repeater and the cable, converts the RF signal received from the donor RF repeater into an M / W signal and transmits it through the airwave transmission network, and converts the M / W signal received from the airwave transmission network into an RF signal Donor M / W Repeater, Transmitting to Donor RF Repeater Remote M / W converts the M / W signal received from the donor M / W repeater into an RF signal and transmits it to the remote RF repeater, and converts the RF signal received from the remote RF repeater into an M / W signal and sends it to the airwave transmission network. Repeater, Combined with the remote M / W repeater and the cable, the RF signal received from the remote M / W repeater is transmitted to the over-the-air transmission network, and the RF signal received from the over-the-air transmission network is transmitted to the remote M / W repeater through the cable. A relay network between a base station and a terminal using a microwave repeater comprising a remote RF repeater for transmitting. The method of claim 1, And at least one M / W repeater between the donor M / W repeater and the remote M / W repeater. The method of claim 1, The donor M / W repeater further comprises a synchronization signal transmitting means for transmitting a reference clock signal used for internal frequency conversion, And the remote M / W repeater adjusts a phase of an internal reference clock signal based on a received reference clock signal.

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