KR20050011764A - Microwave repeating system and method for realizing receipt diversity using the same - Google Patents

Abstract

PURPOSE: A microwave repeating system and method for implementing reception diversity in the microwave repeating system is provided to remarkably enhance receive sensitivity and transmission characteristics compared to an existing repeater. CONSTITUTION: A remote RF unit(120) receives a source RF signal from a user terminal(110) through a main path antenna and plural path antennas, generates a plural path RF signals by converting the RF signals which have been received through the plural path antennas to have a time delay value with a predetermined size and a frequency interval with a predetermined size compared with the RF signals which have been received through the main path antenna, combines the plural path RF signals and the main path RF signal to generate a combined RF signal, and transfers the combined RF signal. A remote MW(Microwave) unit(130) converts the combined RF signal into a microwave band signal and radiates it in the air through the first parabola antenna(140). A donor MW unit(160) restores the combined RF signal by using the microwave band signal received through the second parabola antenna(150) and transfers the combined RF signal. A donor RF unit(170) converts the combined RF signal received from the donor MW unit(160) according to the predetermined first method to generate a converted RF signal, and transfers the converted RF signal to a base station(180).

Description

MICROWAVE REPEATING SYSTEM AND METHOD FOR REALIZING RECEIPT DIVERSITY USING THE SAME}

The present invention relates to a microwave relay system and a method for implementing receive diversity in a microwave relay system, and in particular, a microwave relay system for allowing a receiver of a base station to accurately distinguish and demodulate a signal without fading. The present invention relates to a method for implementing receive diversity in a microwave relay system.

The mobile communication service system improves frequency reuse by dividing a service area into a plurality of cells, and each cell has a wireless base station to cover each cell area. However, there is a dead zone in the service area, such as underground or tunnel, where the strength of the received signal is weak and communication quality is low. In this way, a repeater is installed in an area where the call quality is extremely poor or the call is not possible to enable the call.

However, in general, since a line of sight is not formed between the repeater and the base station or the repeater and the mobile communication terminal, and a radio wave obstacle (for example, a building or a mobile vehicle) exists, it is not a straight line. Signals are received via multi-path. Multipath means that a plurality of transmission signals are received by a receiving antenna through a branch path in the air. When multiple signals are received through different paths, they experience different amplitude attenuation and phase changes. When these signals are combined in reception, the signal strength changes from the transmission signal with time, which is called fading.

The diversity technique is used as a method for overcoming such fading, and the diversity technique refers to a method of receiving and combining a plurality of signals affected by independent fading.

Types of diversity techniques include space diversity, polarization diversity, angle diversity, frequency diversity, time diversity, and the like. However, the conventional diversity technique is a technique applied only to a base station or an optical repeater, and has a limitation that cannot be applied to a microwave repeater. The microwave repeater is a point-to-point repeater for securing service coverage such as radio shadow areas generated by mobile communication services, islands with insufficient wired network transmission lines, and special areas where base stations cannot be installed. It is a device that converts and transmits the frequency band to the microwave frequency band and converts it to the PCS frequency band.

In addition, the conventional diversity technique applied to the optical repeater has a problem that requires excessive implementation cost.

Accordingly, an object of the present invention is to provide a microwave relay system and a microwave relay system that can remove fading by applying a diversity technique to a repeater using microwave waves (17.7 GHz to 19.7 GHz) as well as low cost. It is to provide a method for implementing receive diversity.

It is another object of the present invention to provide a microwave relay system and a method for implementing receive diversity in a microwave relay system that can significantly improve reception sensitivity and transmission characteristics by eliminating fading using a diversity technique. To provide.

1 is a view showing a schematic overall configuration of a microwave relay system according to a preferred embodiment of the present invention.

2 is a view showing a schematic configuration of a remote RF unit according to an embodiment of the present invention.

3 is a view showing a schematic configuration of a remote MV unit (Remote Microwave Unit) according to an embodiment of the present invention.

4 is a view showing a schematic configuration of a donor MV unit (Donor Microwave Unit) according to an embodiment of the present invention.

5 is a view showing a schematic configuration of a donor RF unit according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

120: remote RF unit

123: main path antenna

126: multipath antenna

130: Remote MW Unit

140: first parabolic antenna (Parabola antena)

150: second parabola antenna 160: donor MW unit (Donor Microwave Unit)

170: Donor RF Unit

210: low noise amplifier

215: first RF / IF converter

220: filter unit

225: second RF / IF conversion unit

230: local oscillation signal providing unit

240: signal synthesis unit

510: duplexer filter

520: RF signal separation unit

570: RF signal combiner 570

In order to achieve the above objects, according to an aspect of the present invention, in a microwave relay system for signal relay between a user terminal and a base station in a mobile communication network, the raw RF received from the user terminal through a main path antenna and a multi-path antenna The RF signal received through the multipath antenna using a signal is converted to have a time delay value of a predetermined magnitude and a frequency interval of a predetermined magnitude compared to the main path RF signal received through the main path antenna to convert the multipath. A remote RF unit for generating an RF signal, synthesizing the multipath RF signal and the main path RF signal to generate a synthesized RF signal, and delivering the synthesized RF signal, wherein the user terminal is a mobile communication terminal, an individual And at least one of a handheld terminal (PDA) and the remote RF unit. The synthesized RF signal from the received RF signal by converting the synthesized RF signal into a microwave band signal and radiating it into the air through a first parabola antenna; and using the microwave band signal received through a second parabola antenna. A donor MW unit for restoring the signal and delivering the synthesized RF signal, and converting the synthesized RF signal received from the MW unit in a second predetermined manner to generate a converted RF signal, and transmitting the converted RF signal to a base station A microwave relay system is provided, characterized in that it comprises a donor RF unit. In the microwave relay system according to the present invention, the remote RF unit includes the main path antenna and the plurality of main path antennas for receiving a raw RF signal from a user terminal. A path antenna and received through the multi-path antenna A first RF / IF converter for converting the processed raw RF signal into a raw IF signal, a filter unit for generating a time delay raw IF signal having a predetermined time delay value using the raw IF signal, and A second RF / IF converter configured to generate the multipath RF signal using a time delay raw IF signal, and a local part of the first RF / IF converter and the second RF / IF converter under control of a microprocessor A local oscillation signal providing unit for providing an oscillation signal, and a signal synthesis unit for synthesizing the main path RF signal and the multi-path RF signal to generate a synthesized RF signal, in this case, the multi-path RF signal is the main path signal A frequency interval corresponding to the path RF signal and the local oscillation signal may be provided.

The predetermined time delay may be any one of 1 μs to 3 μs (eg, 2 μs), and the frequency interval may be specified as any one of 10 MHz to 30 MHz (eg, 20 MHz).

In addition, in the microwave relay system according to the present invention, the remote MW unit, the microwave band signal using the duplexer for receiving the composite RF signal from the remote RF unit and the synthesized RF signal received from the duplexer The up-converter unit may be generated, and a synthesizer module may be configured to provide a local oscillation signal to the up-converter unit under control of a microprocessor.

In the microwave relay system according to the present invention, the donor MW unit is a low noise amplifier for amplifying the microwave band signal received through the second parabola antenna, and the amplified microwave signal to restore the synthesized RF signal A down converter unit and a synthesizer module may be configured to provide a local oscillation signal to the down converter unit under control of a microprocessor.

Further, in the microwave relay system according to the present invention, the donor RF unit is a duplexer for receiving a composite RF signal from the donor MV unit, and a first RF for converting the composite RF signal received through the duplexer to a composite IF signal And a filter unit for generating a time delay synthesized IF signal having a time delay value of a predetermined size using the synthesized IF signal, a synthesized IF signal, and generating the converted RF signal using the time delay synthesized IF signal. A second RF / IF converter may include a local oscillation signal providing unit configured to provide a local oscillation signal to the first RF / IF converter and the second RF / IF converter under the control of a microprocessor. In this case, the converted RF signal has a time delay as much as the time delay value compared to the raw RF signal, and the second scheme uses the local oscillation signal to generate the frequency of the multipath RF signal included in the converted RF signal. The band may be converted to match the frequency band of the main path RF signal.

In addition, in the microwave relay system according to the present invention, the donor RF unit may further include an RF signal separation unit for separating the main path RF signal and the multi-path RF signal included in the converted RF signal.

The donor RF unit may further include: an RF signal combiner configured to generate a compensated RF signal to which a reception diversity scheme is applied using the multipath RF signal having the main path RF signal and a time delay value, and the compensated RF signal to the base station. It may further include an RF signal transmission unit for transmitting to.

The donor RF unit may further include an RF signal transfer unit configured to transmit the main path RF signal and the multipath RF signal to the base station through independent paths, and in this case, the main path RF signal and the main path RF signal. A compensation RF signal to which a reception diversity scheme is applied may be generated using the multipath RF signal.

According to another aspect of the present invention, in a signal relay method between a user terminal and a base station in a mobile communication network using a microwave relay system, the remote RF unit is received from the user terminal through the main path antenna and the multi-path antenna, Generating a synthesized RF signal from a raw RF signal in a first predetermined manner, and then delivering the generated synthesized RF signal, a remote MW unit receiving the synthesized RF signal from the remote RF unit, the synthesized RF signal; Generating a microwave band signal using the signal, radiating the generated microwave band signal into the air through a first parabola antenna, and a donor MW unit receives the microwave band signal through a second parabola antenna; The sum using the microwave band signal Restoring the synthesized RF signal, and delivering the synthesized RF signal, and a donor RF unit receives the synthesized RF signal from the MW unit, converts the synthesized RF signal into a second predetermined method, and converts the converted RF signal. Generating and delivering the converted RF signal to a base station, wherein the first predetermined scheme pre-computes the RF signal received through the multipath antenna relative to the main path RF signal received through the main path antenna; After generating a multi-path RF signal by converting to have a time delay value of a predetermined size and a frequency interval of a predetermined size, and combining the multi-path RF signal and the main path RF signal, the second scheme is the local The frequency band of the multipath RF signal included in the converted RF signal using the oscillation signal is the frequency band of the main path RF signal. Provided is a method for implementing receive diversity in a microwave relay system, the method comprising: converting to match, and a system, apparatus, and a recording medium for enabling the execution of the method for implementing receive diversity in the microwave relay system are provided. .

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, a description will be given of a reverse path for transmitting a signal received from a mobile communication terminal to a base station by applying a diversity scheme. FIG. 1 is a microwave relay system according to an exemplary embodiment of the present invention. Figure is a schematic overall configuration of.

1, a microwave relay system according to the present invention is a remote RF unit (remote RF unit) 120, a remote MW unit (Remote Microwave Unit) 130, a first parabolic antenna (Parabola antena) (140) And a second parabola antenna 150, a donor microwave unit 160, and a donor RF unit 170. The remote RF unit 120 is a remote MW unit in the case of a forward path. Amplified by the RF (Radio Frequency) signal received from the 130 and radiates to the air through the antenna. In addition, the reverse path received from the user terminal 110 (eg, a mobile communication terminal, a personal digital assistant (PDA), etc.) through the main path antenna 123 and the multi-path antenna 126. The RF signal is converted into a predetermined method, synthesized, and then transmitted to the remote MW unit 130. The remote RF unit 120 communicates with the remote MW unit 130 through an IF modem, and communicates with the donor MW unit 160 and the donor RF unit 170 through an RF modem. Detailed operation of the remote RF unit 120 in the reverse path will be described in detail later with reference to FIG. 2.

The remote MW unit 130 creates a path of the RF MODEM signal, and performs a function of enabling communication between the remote RF unit 120 and the donor RF unit 170. The RF signal received from the remote RF unit 120 is converted into a microwave band signal and radiated into the air through the first parabola antenna 140. The detailed operation of the remote MW unit 130 in the reverse path will be described in detail later with reference to FIG. 3. The donor MW unit 160 may microwave the RF signal received from the remote MW unit 130 in the case of the forward path. Converted into a band signal and radiated into the air through the second parabolic antenna 150. In addition, in the reverse path, after receiving the microwave band signal from the remote MW unit 130 through the second parabola antenna 150, converts the received microwave band signal into an RF signal, and converts the RF signal into a donor RF. Transfer to unit 170. Detailed operation of the donor MW unit 160 in the reverse path will be described in detail later with reference to FIG. 4.

In the case of the forward path, the donor RF unit 170 receives an RF signal using a coupler (Coupler) after the UPC (Uplink Power Control) of the BTS, amplifies the received RF signal, and transmits the received RF signal to the donor MW unit 160. do. In addition, the reverse path receives an RF signal from the donor MW unit 160, and the RF signal is transmitted to the base station 180 by using a coupler (Coupler) in front of the digital migration interface (DNC). Detailed operation of the donor RF unit 170 in the reverse path will be described in detail later with reference to FIG. 5.

2 is a view showing a schematic configuration of a remote RF unit according to an embodiment of the present invention.

Referring to FIG. 2, the remote RF unit 120 includes a main path antenna 123, a multipath antenna 126, a low noise amplifier 210, a first RF / IF converter 215, and a filter 220. , A second RF / IF converter 225, a local oscillation signal providing unit 230, and a signal synthesizing unit 240. Of course, the remote RF unit 120 may further include a linear power amplifier (LPA), a low pass filter (Low Pass Filter), a signal divider (duplexer), etc., but the description thereof is omitted for convenience of description. The main path antenna 123 is a device for receiving a radio frequency (RF) signal from the user terminal 110 or radiating an RF signal to the air, and the RF signal received by the main path antenna 123 occupies 20 MHz. It is delivered through the main path, which has bandwidth and amplifies output without any conversion.

The multi-path antenna 126 receives a radio frequency (RF) signal from the user terminal 110 or radiates an RF signal to the air, and the RF signal received by the multi-path antenna 126 is provided to the following devices. Multiple paths that are not only converted to frequencies lower by a predetermined magnitude (e.g. 10 to 30 MHz) relative to the RF signal propagated through the main path, but also delayed by a predetermined amount (e.g. 1 to 3 μs) It is passed through the diversity path. However, hereinafter, for the convenience of explanation, the RF signal transmitted through the diversity path is converted to a frequency about 20 MHz lower than that of the RF signal transmitted through the main path, and by about 2 μs. The case of delay is explained as an example.

The low noise amplifier 210 is an amplifier that minimizes noise power when amplifying an RF signal received through the multipath antenna 126.

The first RF / IF converter 215 is an apparatus for converting an RF signal amplified by the low noise amplifier 210 into an intermediate frequency (IF) signal.

The filter unit 220 performs a function for filtering the fine noise of the IF signal converted by the first RF / IF converter 215 and causing the IF signal to have a predetermined time delay. Perform. The filter unit 220 may be a SAW filter. Here, the reason why the first RF / IF converter 215 converts the RF signal into an IF signal is that the filter 220 (for example, the SAW filter) used to remove noise in the signal is 70 MHz in the middle. In order to improve the filtering efficiency, the filtering characteristic is excellent in the frequency band. In addition, although not shown in FIG. 2, a loss may occur in the process of converting an RF signal into an IF signal by the first RF / IF converter 215. The amplification unit may be further included to amplify the IF signal to provide the filter unit 220 to compensate for the corresponding loss.

The second RF / IF converter 225 performs a function of converting the IF signal subjected to the filtering and the time delay by the filter 220 into an RF signal.

The local oscillation signal providing unit 230 provides a function of providing a local oscillation signal to the first RF / IF converter 215 and the second RF / IF converter 225 by the control of a microprocessor (not shown). Device to perform (Local Oscillator). The RF signal transmitted through the multiple paths by the local oscillation signal provided by the local oscillation signal providing unit 230 has a frequency value lower by about 20 MHz than the RF signal transmitted through the main path.

The signal synthesizing unit 240 performs a function of synthesizing the RF signal transmitted through the main path and the RF signal transmitted through the diversity path. The two RF signals synthesized by the signal combiner 240 have a time delay of about 2 μs and a frequency difference of about 20 MHz.

The RF signal synthesized by the signal synthesizing unit 240 is input to the remote MW unit 130. Of course, the process of power amplifying the synthesized RF signal by the power amplifier before the synthesized RF signal is input to the remote MW unit 130 may be further included.

3 is a view showing a schematic configuration of a remote MV unit (Remote Microwave Unit) according to an embodiment of the present invention.

Referring to FIG. 3, the remote microwave unit 130 includes a duplexer filter 310, an up converter 320, and a synthesizer module 330. do. Of course, the remote MV unit 130 may further include a down converter, a modulator, an attenuator, an amplifier, etc., but a description thereof is omitted for convenience of description. The duplexer filter 310 is a device in which a band pass filter for a transmitter and a receiver is configured as a filter to separate a transmission / reception signal of a frequency. The duplexer filter 310 transmits the RF signal received from the remote RF unit 120 to the up converter 320.

The up converter 320 converts the RF signal received from the duplexer filter 310 into a microwave signal, and transmits the converted microwave signal to the donor MW unit 160 through the first parabola antenna 140. Of course, the up-converter 320 and the first parabola antenna 140 may be coupled through a duplexer.

The synthesizer module 330 provides a local oscillation signal to the up converter unit 320 under the control of a microprocessor (not shown).

4 is a view showing a schematic configuration of a donor MV unit (Donor Microwave Unit) according to an embodiment of the present invention.

Referring to FIG. 4, the donor MW unit 160 includes a low noise amplifier 410, a down converter 420, and a synthesizer module 430. Of course, the donor MW unit 160 may further include an up converter, a modulator, an RF filter, and the like, and a description thereof will be omitted for the convenience of description. An amplification device for minimizing noise power when amplifying the microwave signal received through the two parabolic antenna 150.

The down converter unit 420 converts the microwave signal amplified by the low noise amplifier 410 into an RF signal, and the converted RF signal is transferred to the donor RF unit 170. Of course, the step of amplifying the RF signal by the amplifier before the RF signal is input to the donor RF unit 170 may be further included. Synthesizing module 430 is down by the control of a microprocessor (not shown) The local oscillation signal is provided to the converter unit 420.

5 is a view showing a schematic configuration of a donor RF unit according to an embodiment of the present invention.

Referring to FIG. 5, the donor RF unit 170 according to the present invention includes a duplexer filter 510, an RF signal separation unit 520, a first RF / IF conversion unit 530, a filter unit 540, and a second unit. An RF / IF converter 550, a local oscillation signal providing unit 560, and an RF signal combiner 570 are included. Of course, the donor RF unit 170 may further include a signal divider, a multipoint control unit (MCU), an attenuator, an analog-to-digital converter, and the like. For convenience, a description thereof will be omitted. The duplexer filter 510 is a device in which a band pass filter for a transmitter and a receiver is configured as a filter to separate a transmission / reception signal of a frequency. The duplexer filter 510 transmits the RF signal received from the donor MW unit 160 to the first RF / IF converter 530 via the RF signal separator 520.

The RF signal separator 520 separates the main path RF signal and the multipath RF signal synthesized by the signal synthesizer 240 of the remote RF unit 120. However, when the following frequency band conversion operation is performed using only time delay values of the main path RF signal and the multipath RF signal, the RF signal separation unit 520 may be omitted. ) Converts the RF signal received from the duplexer filter 510 and the RF signal separator 520 into an intermediate frequency (IF) signal, and provides the converted IF signal to the filter unit 540.

The filter unit 540 performs filtering to remove fine noise of the IF signal received from the first RF / IF converter 530, and then the IF signal has a predetermined size (for example, 2 to 3 μs). Function to have a time delay. However, in FIG. 2 described above, there was a time delay of about 2 μs only for the RF signal (that is, the multipath RF signal) transmitted through the multipath, but the filter unit 540 of the donor RF unit 170 may be a remote RF unit ( A time delay of about 2 μs is performed for both the main path RF signal and the multipath RF signal of 120). This is when the frequency band of the multipath RF signal is converted into a frequency band of a predetermined range (that is, up-converted by a frequency of about 20 MHz) by using the local oscillation signal provided by the local oscillation signal providing unit 560 described below. This is because a time delay of only the multipath RF signal causes a time difference of about 4 μs from the main path RF signal. This will be described in detail later. The filter unit 540 may be a SAW filter. Here, the reason why the first RF / IF converter 530 converts the RF signal to the IF signal is that the filter unit 540 (for example, SAW filter) used to remove noise in the signal is 70 MHz. This is to increase the filtering efficiency because the filtering characteristic is excellent in the frequency band.

In addition, although not shown in FIG. 2, since a loss may occur in the process of converting an RF signal into an IF signal by the first RF / IF converter 530, the filter unit may be amplified to compensate for the loss. An amplification unit for providing to the 540 may be further included.

The second RF / IF converter 550 performs a function of converting the IF signal subjected to the filtering and time delay by the filter unit 540 into an RF signal.

The local oscillation signal providing unit 560 provides a function of providing a local oscillation signal to the first RF / IF converter 530 and the second RF / IF converter 550 by the control of a microprocessor (not shown). Device to perform (Local Oscillator). The local oscillation signal provided by the local oscillation signal providing unit 550 increases the frequency of the multipath RF signal by about 20 MHz, so that the multipath RF signal has a frequency band similar to that of the main path RF signal (or a frequency band suitable for a mobile carrier). The RF signal combiner 570 generates a single compensated RF signal using a multipath RF signal having a main path RF signal and a time delay value. In other words, the RF signal is removed from fading. One RF signal generated by the RF signal combiner 570 is input to an input unit of the base station 180. Of course, before the RF signal is transmitted to the base station 180, the process of amplifying the RF signal may be further performed.

In addition, although not shown in FIG. 5, an RF signal transmission unit for transmitting the RF signal to the base station 180 may be further included.

So far, referring to FIG. 5, two RF signals (ie, a main path signal and a multipath signal) received from the remote RF unit 120 via the remote MW unit 130 and the donor MW unit 160 are stored as one single. The donor RF unit 170 that converts an RF signal and then transmits the converted RF signal to the base station 180 has been described.

However, according to another embodiment of the present invention, a donor RF unit 170 that performs only a frequency band conversion function is provided.

That is, the donor RF unit 170 according to another embodiment of the present invention converts only the frequency band of the multi-path RF signal similar to the frequency band of the main path RF signal (or converts to an RF signal of a frequency band suitable for a mobile communication service provider). And then input each RF signal to each input terminal of the base station (ie, a first input terminal for receiving the main path RF signal and a second input terminal for receiving the multipath RF signal). In this case, the base station 180 performs a function of converting one RF signal using two RF signals received through two input terminals. In this case, the RF signal combiner 570 of FIG. 5 may be omitted.

Hereinafter, the reason for having a time difference of about 2 μs between the main path RF signal and the multipath RF signal in the microwave relay system and the reception diversity implementation method in the microwave relay system will be briefly described.

For example, the rake receiver of the base station has a function of separating two signals having a time difference (delay) from each other, which can be obtained using the spread spectrum principle of CDMA (code division multiple access). In the case of code division multiple access, since the spreading speed is 1.2288Mbps and the time of 1 chip is 0.814μs, if the time difference between the two signals is shorter than 1 chip, the rake receiver cannot separate the signal. Therefore, the present invention proposes a time delay value of about 2-3 μs longer than 1 chip.

However, it is natural that such a time delay value may be smaller as it can be processed in the donor RF unit 170 when the separation function of the corresponding signal is performed in the donor RF unit 170 as described above.

The present invention is not limited to the above embodiments, and many variations are possible by those skilled in the art within the spirit of the present invention.

As described above, the method for implementing diversity in the microwave relay system and the microwave relay system according to the present invention is not only inexpensive but also by applying a diversity technique to a repeater using microwave waves (17.7 GHz to 19.7 GHz). Fading can be eliminated.

In addition, the present invention can drastically improve reception sensitivity and transmission characteristics by eliminating fading using a diversity technique.

Claims (15)

In the microwave relay system for signal relay between a user terminal and a base station in a mobile communication network, Receives a raw RF signal received from the user terminal through the main path antenna and the multi-path antenna, the RF signal received through the multi-path antenna of a predetermined size compared to the main path RF signal received through the main path antenna After generating a multipath RF signal by converting the signal to have a time delay value and a predetermined frequency interval, a multipath RF signal and the main path RF signal are synthesized to generate a synthesized RF signal, and the synthesized RF signal is generated. A remote RF unit for transmitting, wherein the user terminal comprises at least one of a mobile communication terminal and a personal digital assistant (PDA); converting the synthesized RF signal received from the remote RF unit into a microwave band signal A remote MW unit radiating into the air through a first parabolic antenna; A donor MW unit for recovering the synthesized RF signal by using the microwave band signal received through a second parabolic antenna and delivering the synthesized RF signal; A donor RF unit converts the synthesized RF signal received from the donor MW unit into a first predetermined method to generate a converted RF signal, and transmits the converted RF signal to a base station. Microwave relay system comprising a. The method of claim 1, The remote RF unit The main path antenna and the multi path antenna for receiving a raw RF signal from a user terminal; A first RF / IF converter configured to convert the raw RF signal received through the multipath antenna into a raw IF signal; generating a time delay raw IF signal having a predetermined time delay value using the raw IF signal Filter unit to be; A second RF / IF converter configured to generate the multipath RF signal using the time delay raw IF signal; A local oscillation signal providing unit configured to provide a local oscillation signal to the first RF / IF converter and the second RF / IF converter under control of a microprocessor; A signal synthesizer for synthesizing the main path RF signal and the multi-path RF signal to generate a synthesized RF signal, Wherein the multipath RF signal has a frequency interval corresponding to a frequency value corresponding to the main path RF signal and the local oscillation signal. Microwave relay system, characterized in that. The method according to claim 1 or 2, The predetermined time delay is any one of 1μs to 3μs Microwave relay system, characterized in that. The method according to claim 1 or 2, wherein the frequency interval is any one of 10 MHz to 30 MHz. Microwave relay system, characterized in that. The method of claim 1, The remote MW unit, A duplexer for receiving the composite RF signal from the remote RF unit; An up converter unit generating the microwave band signal using the synthesized RF signal received from the duplexer; Synthesizer module for providing a local oscillation signal to the up-converter section under control of a microprocessor Microwave relay system comprising a. The method of claim 1, The donor MW unit, A low noise amplifier configured to amplify the microwave band signal received through the second parabolic antenna; A down converter configured to restore the amplified microwave signal to the synthesized RF signal; Synthesizer module for providing a local oscillation signal to the down converter section under the control of a microprocessor Microwave relay system comprising a. The method of claim 1, The donor RF unit, A duplexer for receiving a composite RF signal from the donor MV unit; A first RF / IF converter converting the synthesized RF signal received through the duplexer into a synthesized IF signal; A filter unit for generating a time delay synthesized IF signal having a time delay value of a predetermined size using the synthesized IF signal; A second RF / IF converter configured to generate the converted RF signal using the time delay synthesized IF signal; Local oscillation signal providing unit for providing a local oscillation signal to the first RF / IF converter and the second RF / IF converter under the control of a microprocessor Including, The converted RF signal has a time delay by the time delay value compared to the raw RF signal, And the first scheme converts the frequency band of the multipath RF signal included in the converted RF signal to match the frequency band of the main path RF signal using the local oscillation signal. The method of claim 7, wherein The donor RF unit, RF signal separation unit for separating the main path RF signal and the multi-path RF signal included in the converted RF signal Microwave relay system, characterized in that it further comprises. The method of claim 7, wherein The donor RF unit, An RF signal combiner configured to generate a compensation RF signal to which a reception diversity scheme is applied using the multipath RF signal having the main path RF signal and a time delay value; RF signal transfer unit for transmitting the compensated RF signal to the base station Microwave relay system, characterized in that it further comprises. The method of claim 8, RF signal transmission unit for transmitting the main path RF signal and the multi-path RF signal to the base station through a separate path, respectively Include more, And generating, by the base station, a compensated RF signal to which a reception diversity scheme is applied using the main path RF signal and the multipath RF signal. In the signal relay method between a user terminal and a base station in a mobile communication network using a microwave relay system, Receiving, by a remote RF unit from a user terminal through a main path antenna and a multipath antenna, generating a synthesized RF signal from the received original RF signal in a first predetermined manner, and then transmitting the generated synthesized RF signal; Receiving, by the remote MW unit, the synthesized RF signal from the remote RF unit, generating a microwave band signal using the synthesized RF signal, and radiating the generated microwave band signal into the air through a first parabolic antenna ; Receiving, by a donor MW unit, the microwave band signal through a second parabolic antenna, restoring the synthesized RF signal using the microwave band signal, and transmitting the synthesized RF signal; Receiving, by the donor RF unit, the synthesized RF signal from the donor MW unit, converting the synthesized RF signal in a second predetermined manner to generate a converted RF signal, and transmitting the converted RF signal to a base station; Including, The first predetermined scheme converts the RF signal received through the multipath antenna to have a time delay value of a predetermined magnitude and a frequency interval of a predetermined magnitude as compared to a main path RF signal received through the main path antenna. Generate a multipath RF signal, and then synthesize the multipath RF signal and the main path RF signal, The second method is to convert the frequency band of the multi-path RF signal included in the converted RF signal using the local oscillation signal to match the frequency band of the main path RF signal. A method for implementing receive diversity in a microwave relay system comprising: A microwave band signal transmission system for transmitting an RF signal received from a user terminal to a donor MW unit of a microwave relay system for signal relay between a user terminal and a base station in a mobile communication network, Receives a raw RF signal received from the user terminal through the main path antenna and the multi-path antenna, the RF signal received through the multi-path antenna of a predetermined size compared to the main path RF signal received through the main path antenna After generating a multipath RF signal by converting the signal to have a time delay value and a predetermined frequency interval, a multipath RF signal and the main path RF signal are synthesized to generate a synthesized RF signal, and the synthesized RF signal is generated. A remote RF unit for transmitting, wherein the user terminal comprises at least one of a mobile communication terminal and a personal digital assistant (PDA); converting the synthesized RF signal received from the remote RF unit into a microwave band signal A remote MW unit that radiates into the air through a first parabolic antenna, The donor MW unit recovers the synthesized RF signal using the microwave band signal received through a second parabola antenna, and transfers the synthesized RF signal to a donor RF unit, The donor RF unit converts the synthesized RF signal received from the donor MW unit into a first predetermined method to generate a converted RF signal, and transmits the converted RF signal to a base station, The first predetermined method uses the local oscillation signal to convert the frequency band of the multipath RF signal included in the converted RF signal to match the frequency band of the main path RF signal. system. In an RF signal transmission system for converting a microwave band signal received from a remote MW unit of the microwave relay system for signal relay between a user terminal and a base station in a mobile communication network to the RF base station, and transmitting the RF signal to the base station, A donor MW unit that receives a microwave band signal radiated from the remote MW unit through a first parabolic antenna, restores a synthesized RF signal to a predetermined form using the microwave band signal, and delivers the synthesized RF signal. ; A donor RF unit which converts the synthesized RF signal received from the donor MW unit into a first predetermined method to generate a converted RF signal, and transmits the converted RF signal to a base station. Including, The remote RF unit receives the raw RF signal received from the user terminal through the main path antenna and the multipath antenna, and the RF signal received through the multipath antenna is compared with the main path RF signal received through the main path antenna. After generating a multi-path RF signal by converting to have a time delay value of a predetermined size and a frequency interval of a predetermined size, to generate a composite RF signal by synthesizing the multi-path RF signal and the main path RF signal, When the synthesized RF signal is transmitted to the remote MW unit, the remote MW unit converts the synthesized RF signal received from the remote RF unit into a microwave band signal to radiate into the air through a second parabolic antenna, The first predetermined method is to convert the frequency band of the multipath RF signal included in the converted RF signal using the local oscillation signal to match the frequency band of the main path RF signal. Microwave relay system comprising a. In the signal relay method between a user terminal and a base station in a mobile communication network using a microwave relay system, Receiving, by a remote RF unit from a user terminal through a main path antenna and a multipath antenna, generating a synthesized RF signal from the received original RF signal in a first predetermined manner, and then transmitting the generated synthesized RF signal; Receiving a synthesized RF signal from the remote RF unit by a remote MW unit, generating a microwave band signal using the synthesized RF signal, and radiating the generated microwave band signal into the air through a first parabolic antenna Including, A donor MW unit receives the microwave band signal through a second parabola antenna, restores the synthesized RF signal using the microwave band signal, and transfers the synthesized RF signal to a donor RF unit, The donor RF unit receives a synthesized RF signal from the donor MW unit, converts the synthesized RF signal in a second predetermined manner to generate a converted RF signal, and transmits the converted RF signal to a base station, The first predetermined scheme converts the RF signal received through the multipath antenna to have a time delay value of a predetermined magnitude and a frequency interval of a predetermined magnitude as compared to a main path RF signal received through the main path antenna. Generate a multipath RF signal, and then synthesize the multipath RF signal and the main path RF signal, The second scheme uses the local oscillation signal to convert the frequency band of the multipath RF signal included in the converted RF signal to match the frequency band of the main path RF signal. Method of implementing receive diversity. In the signal relay method between a user terminal and a base station in a mobile communication network using a microwave relay system, Receiving, by a donor MW unit, a microwave band signal from a remote MW unit via a first parabola antenna, reconstructing a synthesized RF signal using the microwave band signal, and then transmitting the synthesized RF signal; Receiving, by the donor RF unit, the synthesized RF signal from the donor MW unit, converting the synthesized RF signal into a first predetermined method, generating a converted RF signal, and transmitting the converted RF signal to a base station; Including, When a remote RF unit receives from the user terminal through a main path antenna and a multi-path antenna, generates the synthesized RF signal in a second predetermined manner by receiving the received raw RF signal, and delivers the generated composite RF signal, The remote MW unit receives the composite RF signal from the remote RF unit, generates a microwave band signal using the synthesized RF signal, radiates the generated microwave band signal into the air through a second parabolic antenna , The first scheme is to convert the frequency band of the multipath RF signal included in the converted RF signal to match the frequency band of the main path RF signal using the local oscillation signal, and the second predetermined method Generating a multi-path RF signal by converting the RF signal received through the multi-path antenna to have a time delay value of a predetermined size and a frequency interval of a predetermined size compared to the main path RF signal received through the main path antenna And then synthesizing the multipath RF signal and the main path RF signal. A method for implementing receive diversity in a microwave relay system comprising: