KR20060119288A - In-building rf distribution repeater with rx diversity - Google Patents

Abstract

An in-building RF(Radio Frequency) distributive repeater having a receive diversity function is provided to improve the structure of a master remote module and a donor module so that an RF distributive system can use dual receiving paths, thereby reducing influence on a base station receiving stage. A master remote module(300) comprises the followings. A 3-wavelength WDM(Wavelength Division Multiplexer)(301) transceives signals through a donor module and one optical fiber, and performs photoelectric and electrooptic conversions. The first RF distributor(308) receives a reverse signal from a slave remote module. The first reverse RF unit(306) receives the reverse signal from the distributor(308), and sends the received signal to the WDM(301). The second RF distributor(309) receives another reverse signal from the slave remote module. The second reverse RF unit(307) receives another reverse signal from the distributor(309), and sends the received signal to the WDM(301).

Description

In-Building RF Distribution Repeater with Rx Diversity

1 is a configuration diagram of a conventional light scattering repeater,

2 is a configuration diagram of a conventional RF distributed repeater,

3 is a block diagram of an RF distributed repeater according to an embodiment of the present invention;

4 is a configuration diagram of the donor module of FIG.

5 is a configuration diagram of the master remote module of FIG.

FIG. 6 is a diagram illustrating the configuration of a slave remote module of FIG. 3.

<Description of Symbols for Main Parts of Drawings>

100: base station 200: donor module

300: master remote module 310, 320: slave remote module

The present invention relates to an in-building RF distributed repeater having a receive diversity function. More particularly, the present invention relates to a receive diverter capable of using receive dual paths (Rx0, Rx1) in an RF distributed repeater system for mobile telephone service in a building. An inbuilding RF distributed repeater having a city function.

The inbuilding repeater system can be largely divided into an optical dispersion system and an RF distribution system. Referring to the configuration of the conventional optical dispersion type repeater of FIG. 1, the optical dispersion system includes a donor module 20 that receives an RF signal from a base station 10 and converts the light into an optical signal, and receives an optical signal from the donor module 20. It is composed of a hub 21 for dividing into a plurality of optical signals and a plurality of remote modules 22 for receiving an optical signal through the hub 21, amplifying the RF signal of the base station through an amplifier, and radiating through an antenna. .

In the optical dispersion system as described above, Rx0 and Rx1 can be designated and used for each remote module, so that reception diversity can be implemented.

Referring to the RF distributed system through FIG. 2 showing a conventional RF distributed repeater configuration diagram, the RF distributed system includes a donor module 40 for converting an RF signal of the base station 30 to light and the donor module 40 from the donor module 40. The RF signal is received from the master remote module 41 and the master remote module 41 which receives an optical signal, converts and branches it into an RF signal, radiates a base station signal through its own amplifier, or transmits the signal to the slave remote module 42. It consists of a plurality of slave remote modules 42 which receive, amplify and radiate into amplifiers.

The RF distribution system as described above does not require the use of expensive optical modules, thereby enabling low-cost system implementation. However, in the conventional system structure, the master remote module 41 and the plurality of slave remote modules 42 have the same RF receiving path. There is a disadvantage in that it is impossible to implement receive diversity because

Accordingly, the present invention is to solve the above disadvantages and problems of the prior art, the base station receiving end by improving the structure of the master remote module and the donor module to use the receive dual path (Rx0, Rx1) in the RF distribution system SUMMARY OF THE INVENTION An object of the present invention is to provide an in-building RF distributed repeater having a receive diversity function that can reduce the effects on the network.

The object of the present invention is a donor module for converting the RF signal of the base station into an optical signal, and receives the optical signal from the donor module to convert and separate the RF signal to radiate the base station signal through its own amplifier or transfer to the slave remote module An in-built RF distributed repeater comprising: a master remote module; and a plurality of slave remote modules receiving the signal of the master remote module and amplifying the amplifier into an amplifier to radiate a base station signal. A three-wavelength wavelength division multiplexing device which transmits and receives Tx, Rx0, and Rx1 signals through optical fibers of the optical fiber, and performs photoelectric conversion and all-optical conversion; A first RF spreader receiving a reverse Rx0 signal from the slave remote module, and a first reverse RF receiver receiving a reverse Rx0 signal from the first RF spreader and transmitting the reverse Rx0 signal to the three wavelength division multiplexer; A second RF dispersion unit receiving a reverse Rx1 signal from the slave remote module, and a second reverse RF unit receiving a reverse Rx1 signal from the second RF dispersion unit and transmitting the reverse Rx1 signal to the three wavelength division multiplexer; It is configured by including, is achieved by the in-building RF distributed repeater having a receive diversity function configured to receive signals in two paths.

In addition, the object of the present invention is a donor module for converting the RF signal of the base station into an optical signal, and receives the optical signal from the donor module to convert and separate the RF signal to radiate the base station signal through its own amplifier or slave remote module An in-building RF distributed repeater comprising a master remote module for transmitting a signal to the master remote module and a plurality of slave remote modules that amplify an amplifier by receiving a signal from the master remote module and emit a base station signal, wherein the donor module is the master remote module. A three-wavelength wavelength division multiplexing device for transmitting and receiving Tx, Rx0, and Rx1 signals through one optical fiber and performing photoelectric conversion and all-optical conversion; A first reverse RF unit for receiving a reverse Rx0 signal from the three wavelength division multiplexer and transmitting the reverse Rx0 signal to a base station through amplification and attenuation; A second reverse RF unit which receives a reverse Rx1 signal from the three wavelength division multiplexer and transmits the reverse Rx1 signal to a base station through amplification and attenuation; It is achieved by an in-building RF distributed repeater having a reception diversity function made to include, it is possible to receive signals from two paths.

Details of the above object and technical configuration of the present invention and the resulting effects thereof will be more clearly understood from the following detailed description based on the accompanying drawings.

First, Figure 3 is a block diagram of an RF distributed repeater according to an embodiment of the present invention.

As shown, the RF distributed repeater of the present invention receives the base station 100 signal and converts the donor module 200, and receives the optical signal from the donor module 200, amplified through its own amplifier to radiate Or slave remote modules 310 and 320 that receive the forward signal Tx from the master remote module 300 and the master remote module 300 to transfer to the slave remote modules 310 and 320. do.

Here, the slave remote module is divided into a slave remote module 310 receiving a signal Rx0 from the first receiving path and a slave remote module 320 receiving a signal Rx1 from the second receiving path. Accordingly, the master remote module 300 receives the forward signal Tx from the donor module 200 and transmits the forward signal Tx to the corresponding slave module, and receives the first reverse signal Rx0 from each slave remote module 310 or 320. In addition, it should be able to receive the second reverse signal Rx1 and transmit it to the donor module 200.

Therefore, the RF distribution module included in the master remote module 300 should be redundant, and the structure of the master remote module 300 and the donor module 200 for this purpose will be described with reference to FIGS. 4 and 5 as follows. .

First, FIG. 4 is a configuration diagram of the donor module of FIG. 3.

The donor module 200 of the present invention converts the RF signal of the base station into an optical signal and transmits the optical signal to the master remote module 300, and receives the reverse optical signal for the dual path from the master remote module 300 to receive the base station 100 Forward RF unit 201, a first reverse RF unit 202 and a second reverse RF unit 203, a three wavelength division multiplexing device 204 for implementing a receiving dual path It is configured to include.

The forward RF unit 201 receives the base station forward RF signal, amplifies or attenuates it, and transmits the input signal to the three wavelength division multiplexer 204 as an appropriate input.

The first reverse RF unit 202 receives the reverse Rx0 signal of the first reception path from the three wavelength division multiplexer 204 and transmits the reverse Rx0 signal to the base station 100 through amplification and attenuation. 203 receives the reverse Rx1 signal of the second receiving path from the three wavelength division multiplexer 204 and transmits it to the base station 100 through amplification and attenuation.

The three wavelength division multiplexer 204 transmits and receives a Tx, Rx0, and Rx1 signal with the master remote module 300 through one optical fiber, and converts the photoelectric conversion and forward signals (Rx0, Rx1) into Perform all-optical conversion for Tx).

5 is a configuration diagram of the master remote module of FIG. 3.

The master remote module 300 of the present invention converts and branches an optical signal from the donor module 200 to an RF signal, radiates a base station signal through its amplifier 303, and transmits the signal to a slave remote module 310 or 320. 3 wavelength wavelength division multiplexer 301, forward RF unit 302, amplifier 303, duplexer 304, low noise amplifier 305, first reverse RF unit 306, second reverse RF unit 307, a first RF dispersion unit 308, and a second RF dispersion unit 309.

The three wavelength division multiplexer 301 transmits and receives Tx, Rx0, and Rx1 signals through the donor module 200 and one optical fiber, and performs photoelectric conversion and all-optical conversion.

The forward RF unit 302 receives the forward RF signal Tx from the three wavelength division multiplexer 301 and transmits the forward RF signal Tx to the amplifier 303, the first RF dispersion unit 308, and the second RF dispersion unit 309. .

The amplifier 303 amplifies the forward RF signal from the forward RF unit 302 and transmits it to the duplexer 304.

The duplexer 304 separates and matches a signal of a transmission frequency and a reception frequency with an RF filter, radiates a forward RF signal from the amplifier 303 through an antenna, and receives a reverse RF signal from the antenna.

The low noise amplifier 305 receives the reverse RF signal from the duplexer 304 to low noise amplify and transmit the reverse RF signal to the first reverse RF unit 306.

The first reverse RF unit 306 transmits the reverse RF signal from the low noise amplifier 305 to the three wavelength division multiplexer 301, and transmits the reverse Rx0 signal received from the first RF dispersion unit 308 to the three wavelengths. The wavelength is transmitted to the wavelength division multiplexing device 301. The first RF distributing unit 308 receives the reverse Rx0 signal from the slave remote module 310 using the first receiving path and transmits the reverse Rx0 signal to the first reverse RF unit 306.

In addition, the second reverse RF unit 307 and the second RF dispersion unit 309 are added to implement the reception diversity of the present invention, and the second RF dispersion unit 309 uses a second reception path. Receiving a reverse Rx1 signal from a plurality of slave remote modules 320, the second reverse RF unit 307 receives a reverse Rx1 signal from the second RF dispersion unit 309 to the three wavelength division multiplexer 301 To send.

As described above with reference to FIGS. 4 and 5, the RF dispersion unit of the master remote module is dually configured to use the receive dual path, and transmits Tx / Rx0 and Tx / Rx1, respectively. In addition, the reverse RF unit is also composed of a dual Rx0, Rx1, respectively, and the wavelength division multiplexing device that performs all-optical conversion is also composed of three wavelengths transmit Tx, Rx0, Rx1 respectively. Further, the donor module for converting the base station Tx signal and the Rx0 and Rx1 signals into light also includes a receiver.

Next, FIG. 6 is a configuration diagram of the slave remote module of FIG. 3, and since the slave remote module has the same configuration regardless of the reception path, one of the slave remote modules 310 and 320 of different paths according to the present invention. ), And the structure of the slave remote module is the same as the existing structure.

The slave remote module 310 receives a signal from the master remote module 300 to amplify and radiates a base station signal, and includes a first duplexer 311, a forward RF unit 312, an amplifier 313, and a second duplexer 314. , A low noise amplifier 315, and a reverse RF unit 316.

The first duplexer 311 is responsible for the forward and reverse RF signal coupling and interface with the master remote module 300, the forward RF unit 312 amplifies the forward RF signal to an appropriate level to amplify the amplifier ( 313).

The second duplexer 314 radiates the forward RF signal from the amplifier 313 through the antenna, receives the reverse RF signal from the antenna, and transmits the reverse RF signal to the low noise amplifier 315, and the low noise amplifier 315 is a second duplexer The low frequency amplification of the reverse RF signal from 314 is transferred to the first duplexer 311.

As those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features, the embodiments described above should be understood as illustrative and not restrictive in all aspects. Should be. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

Therefore, according to the in-building RF distributed repeater having the reception diversity function of the present invention, Rx0 and Rx1 can be used in an RF distribution system, and the use of the reception dual path can reduce the influence on the base station receiving end in half. Therefore, the number of remote modules that can be mounted is doubled, and the same remote module can reduce the noise level of the base station receiving end.

Claims (4)

A donor module for converting an RF signal of a base station into an optical signal, a master remote module for receiving an optical signal from the donor module, converting the optical signal into an RF signal, separating the RF signal, and radiating the base station signal through its own amplifier or transmitting the slave signal to a slave remote module; In the building RF distributed repeater comprising a plurality of slave remote modules for receiving the signal of the master remote module and amplified by an amplifier to emit a base station signal, The master remote module, A three-wavelength wavelength division multiplexing device that transmits and receives Tx, Rx0, and Rx1 signals through the donor module and one optical fiber, and performs photoelectric conversion and all-optical conversion; A first RF spreader receiving a reverse Rx0 signal from the slave remote module, and a first reverse RF receiver receiving a reverse Rx0 signal from the first RF spreader and transmitting the reverse Rx0 signal to the three wavelength division multiplexer; A second RF dispersion unit receiving a reverse Rx1 signal from the slave remote module, and a second reverse RF unit receiving a reverse Rx1 signal from the second RF dispersion unit and transmitting the reverse Rx1 signal to the three wavelength division multiplexer; An in-building RF distributed repeater having a receive diversity function, comprising: a signal configured to receive a signal through two paths. The method of claim 1, The master remote module, A forward RF unit for receiving a forward RF signal (Tx) from the three wavelength division multiplexer and transmitting the RF signal to a self amplifier, the first RF dispersion unit, and a second RF dispersion unit; An amplifier for amplifying a forward RF signal from the forward RF unit; A duplexer that radiates a forward RF signal from the amplifier through an antenna and receives a reverse RF signal from the antenna; A low noise amplifier which receives a reverse RF signal from the duplexer, amplifies low noise and transmits the reverse RF signal to the first reverse RF unit; In-building RF distributed repeater having a reception diversity function, characterized in that further comprises. A donor module for converting an RF signal of a base station into an optical signal, a master remote module for receiving an optical signal from the donor module, converting the optical signal into an RF signal, separating the RF signal, and radiating the base station signal through its own amplifier or transmitting the slave signal to a slave remote module; In the building RF distributed repeater comprising a plurality of slave remote modules for receiving the signal of the master remote module and amplified by an amplifier to emit a base station signal, The donor module, A three-wavelength wavelength division multiplexing device for transmitting and receiving Tx, Rx0, and Rx1 signals through one optical fiber with the master remote module and performing photoelectric conversion and all-optical conversion; A first reverse RF unit for receiving a reverse Rx0 signal from the three wavelength division multiplexer and transmitting the reverse Rx0 signal to a base station through amplification and attenuation; A second reverse RF unit which receives a reverse Rx1 signal from the three wavelength division multiplexer and transmits the reverse Rx1 signal to a base station through amplification and attenuation; An in-building RF distributed repeater having a reception diversity function, comprising: a signal configured to receive signals from two paths. The method according to claim 1 or 3, The slave remote module, A first duplexer responsible for combining forward and reverse RF signals with and interface with the master remote module; A forward RF unit for amplifying a forward RF signal to an appropriate level and transmitting the signal to an amplifier, and an amplifier for amplifying a signal from the forward RF unit; A second duplexer for radiating a forward RF signal from the amplifier through an antenna and receiving a reverse RF signal from the antenna; A low noise amplifier for receiving low frequency amplification by receiving a reverse RF signal from the second duplexer; A reverse RF unit transmitting the low noise amplified signal to the first duplexer; In-building RF distributed repeater having a reception diversity function, characterized in that comprises a.

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