KR20060112268A - Radio repeater for in-building service - Google Patents

Abstract

A wireless repeater for an in-building service is provided to reduce a fabrication cost and expand the number of remote units at a low cost by directly connecting a base station with a remote through an RF interface without using a doner for relaying between the base station and remote. A master remote unit(200) is connected with a base station(100) by an RF interface, receives an RF signal from the base station(100), splits it into a plurality of signals, and outputs them to a plurality of slave remote units(310-330), or amplifies a signal received from an antenna or each slave remote unit and transmits it to the base station so as to be down-converted. The slave remote units(310-330) are connected with the master remote unit(200) by an RF interface, receive the split signals from the master remote unit(200), and amplify/output them to the antenna, or amplify a signal received by the antenna and transmit it to the master remote unit(200).

Description

Radio repeater for in-building service {Radio Repeater for In-building Service}

1 is an exemplary diagram of a wireless relay device for a general in-building service;

2 is another exemplary diagram of a wireless relay device for a general in-building service;

3 is a configuration diagram of a wireless relay device according to the present invention;

4 is a detailed configuration diagram of the wireless relay device shown in FIG. 3;

5 is a detailed configuration diagram of a master remote applied to the present invention;

6 is a detailed configuration diagram of a slave remote according to the present invention.

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

100: base station 200: master remote

210: forward high frequency signal processing unit 220: amplification unit

230: duplexer 240: RF dispersion unit

250: low noise amplifier 260: reverse high frequency signal processing unit

310, 320, 330: slave remote 3010: the first duplexer

3020: forward high frequency signal processing unit 3030: amplifying unit

3040: second duplexer 3050: low noise amplifier

3060: reverse high frequency signal processing unit

The present invention relates to a relay apparatus, and more particularly, to a wireless relay apparatus for an in-building service for amplifying and relaying a signal of a base station in order to provide a high quality mobile communication service in a building and indoors.

With the development and generalization of mobile communication services, subscribers want to provide higher quality services, including mountainous areas and remote islands, as well as underground buildings, in-buildings, etc., where the radio environment is poor due to poor radio environment in urban areas. Doing. However, in order to meet these demands, it is a waste of resources to install and operate a base station at a high cost in a low-traffic area. Therefore, a repeater is used to improve a radio wave environment in a building having an unfavorable condition for installing a base station.

1 is an exemplary diagram of a wireless relay device for a general in-building service.

As shown in the drawing, the wireless relay device converts and outputs an electrical signal applied from the base station 10 to an optical signal, or converts an optical signal input from the hub 30 into an electrical signal and transmits the electrical signal to the base station 10. 20 converts the optical signal received from the donor 20 into an electrical signal to branch into a plurality (for example, eight), converts the branched signal into an optical signal, and transmits the signal to the remote 40; A signal received from the hub 30 and the hub 30 for transmitting the optical signal received from the 40 to the donor 20 is converted into an electrical signal and output through an antenna, or received a signal from the mobile communication terminal It consists of a plurality of remotes (40, 42) for converting into an optical signal to transmit to the hub (30).

In the relay device having such a configuration, since the communication between the hub 30 and the plurality of remotes 40 and 42 is performed through light, a plurality of expensive optical elements must be employed, thereby increasing the manufacturing cost of the relay device. It is difficult to expand the number of remotes. In addition, in order to install such a relay device in a building, it is necessary to install both the hub 30 and the plurality of remotes 40 and 42, so that the system configuration is complicated.

2 is another exemplary diagram of a wireless relay device for a general in-building service.

As shown in the drawing, the wireless relay apparatus converts and outputs an electrical signal applied from the base station 10 to an optical signal, or converts an optical signal input from the master remote 32 into an electrical signal and transmits the electrical signal to the base station 10. A master remote 32 for converting an optical signal received from the donor 20 and the donor 20 into electrical signals, dividing the optical signal into a plurality, and outputting them to the antenna, the slave remote 36, and the other master remote 34, respectively. And slave remotes 36 and 38 for outputting electrical signals received from the master remotes 32 and 34 through an antenna.

The wireless relay apparatus for the in-building service shown in FIG. 2 uses an optical signal for communication between the donor 20, the master remote 32, and the master remotes 32, 34, and the master remotes 32, 34 and the slave remotes. 36 and 38 use high frequency signals.

In the wireless relay device shown in Figs. 1 and 2, since the base station 10 and the remotes 32, 40, 42 are generally located in different buildings, the donor 20 is used to connect the base station and the remote through the optical core. Connect. However, this configuration has a problem in that the price of the wireless relay device increases because an expensive optical module is used even when the wireless relay device is used in the same building.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and has a purpose to limit the use of an optical module by transmitting and receiving data using a high frequency signal in a wireless relay device installed in the same building. .

The wireless relay device of the present invention for achieving the above-described technical problem is connected to a base station and a high frequency interface, receives a high frequency signal distributed up-converted from the base station, divides it into a plurality of signals, and then antennas and a plurality of signals. A master remote for dividing into a plurality of slave remotes and outputting each to a plurality of slave remotes, or amplifying a signal received from an antenna or each slave remote and transmitting the signal to the base station for down-frequency conversion; And a high frequency interface connected to the master remote and receiving and amplifying a signal divided into a plurality of signals from the master remote and outputting the amplified signal through an antenna, or amplifying a signal received from the antenna and transmitting the amplified signal to the master remote. And a plurality of slave remotes.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

3 is a block diagram of a wireless relay apparatus according to the present invention.

As shown in the drawing, the wireless relay apparatus according to the present invention receives an electrical signal applied from the base station 100, amplifies and outputs it through an antenna, and divides the electrical signal applied from the base station 100 into a plurality of high frequency signals. And a high frequency signal divided and transmitted from the master remote 200 and the master remote 200 to amplify the signals received through the antenna or received from the plurality of slave remotes 310, 320 and 330 and transmit them to the base station. And a plurality of slave remotes 310, 320, and 330 that respectively receive and amplify and output through an antenna or amplify a signal received through the antenna and transmit the amplified signal to the master remote 220.

Here, each of the master remote 200 and the slave remotes (310, 320, 330) has a configuration similar to the amplifier stage, low noise amplifier stage, the duplexer stage of the base station 100, the modem chip, digital processing stage, frequency conversion stage of the base station In common, the wireless relay device of the present invention can be referred to as a distributed base station in this respect. Specifically, it is as follows.

4 is a detailed configuration diagram of the wireless relay device shown in FIG. 3.

As shown, the base station 100 includes a modem chip 102 for performing demodulation and demodulation on forward and reverse signals, and a digital-to-analog converter (DAC) for converting a forward digital signal transmitted from a mobile communication system into an analog signal. 104), an uplink frequency converter 106 for converting an analog converted signal into a high frequency signal, an amplifier 108 for amplifying the high frequency converted signal, a duplexer 110, for removing noise from a signal received by an antenna Low noise amplifier 112, downlink frequency converter 114 for converting the noise-removed signal into an intermediate frequency signal, analog-to-digital converter (ADC, 116) for digitally converting the converted signal into the intermediate frequency signal, antenna A filter 118 for filtering out the received signal, a low noise amplifier 120 for removing noise from the filtered signal, And a downlink frequency converter 122 for converting into a wavenumber signal and an analog-to-digital converter (ADC) 124 for digitally converting a signal converted into an intermediate frequency signal.

In order to relay the signal transmitted from the base station 100 having such a configuration in the same building without using a donor, the output signal of the uplink frequency converter 106 is distributed so that one of the divided signals is the amplifier 108. And output through the duplexer 110 to the antenna, the remaining signal is used as an input signal of the master remote (200). In addition, the master remote 200 distributes a high frequency signal input from the base station 100 into a plurality of signals, one amplified and output through the antenna and the other of the plurality of slave remotes (310, 320, 330) Provided with each input signal. Each of the slave remotes 310, 320, and 330 compensates for the loss of the connection cable with the master remote 200, amplifies the signal, and transmits the signal through the antenna.

Also, the slave remotes 310, 320, and 330 receive a signal from the antenna, amplify low noise, compensate for the amount of connection cable loss, and transmit the signal to the master remote 200. In addition, the master remote 200 combines the signal received from the antenna and the signal received from each slave remote (310, 320, 330) and transmits to the downlink frequency converter (114, 122).

5 is a detailed configuration diagram of a master remote applied to the present invention.

The master remote 200 applied to the present invention is a high frequency signal for amplifying or attenuating a high frequency signal received from the uplink frequency converter 106 of the base station 100 to a predetermined signal level and then dividing it into two or more signals to output the high frequency signal. From the processing unit 210, the amplifier (AMP, 220), the forward high frequency signal processor 210 for outputting a large signal amplification of the first output signal from the forward high frequency signal processor 210 to the antenna through the duplexer 230 Amplifies and divides the second output signal of the slave to the slave remotes 310, 320, 330, respectively, or amplifies the signal received from each slave remote 310, 320, 330 to the specified signal level. RF dispersion unit 240 for outputting, a low noise amplifier (LN) for removing noise after receiving the signal transmitted from the mobile communication terminal via the duplexer 230 A, 250, and the reverse frequency signal processor 260 for combining the signals received from the RF dispersion unit 240 and the low noise amplifier 250, respectively, into one signal and amplifying or attenuating the signal level.

As can be seen in FIG. 5, the master remote 200 applied to the present invention includes an amplifier 108, a duplexer 110, and low noise amplifiers 112 and 120, which are components of the base station 100. It operates as a distributed base station that amplifies the signal output from the uplink frequency converter 106 of 100 and amplifies the signal received from the antenna or the slave remotes 310, 320, 330.

6 is a detailed configuration diagram of a slave remote according to the present invention.

Slave remote (310, 320, 330) applied to the present invention is a high-frequency signal processing unit for receiving a signal received from the master remote 200 through the first duplexer (3010) to amplify or attenuate to a specified signal level ( 3020, amplification unit (AMP) 3030 for outputting the signal output from the forward high frequency signal processing unit 3020 to the antenna through the second duplexer (3040), the signal transmitted from the mobile communication terminal to the antenna The first duplexer 3010 is amplified or attenuated by a low noise amplifier (LNA) 3050 and a low noise amplifier 3050 for receiving noise through the second duplexer 3040 to a predetermined signal level. It includes a reverse high frequency signal processor 3060 for output through.

Here, the forward high frequency signal processor 3020 and the reverse high frequency signal processor 3060 amplify the signal in consideration of the cable loss between the master remote 200 and the slave remotes 310, 320, and 330. By doing in this way, the signal intensity attenuation phenomenon according to the separation distance between the master remote and the slave remote can be compensated.

In the present invention, when the wireless relay device is installed in the same building, the wireless relay device can be connected without using an expensive optical module by directly connecting the base station and the remote to a high frequency interface without using a donor for relaying between the base station and the remote. Implement

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not as restrictive. 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.

According to the present invention described above by implementing a wireless relay device that is connected to the base station and the remote by a high-frequency interface by limiting the use of expensive optical modules, the manufacturing cost of the wireless relay device used to improve the quality of the building service The number of remotes can be reduced and the cost can be reduced.

In addition, in the portable Internet service, it is difficult to install the optical relay device due to the delay in the optical module. When using the wireless relay device according to the present invention, a delay compensation is performed within a maximum distance of 2 km from the base station to the remote antenna terminal. It is possible to relay mobile Internet services without implementing a device.

Claims (4)

Connected to the base station by a high frequency interface, the base station receives an up-converted high frequency signal and divides the signal into a plurality of signals, and then divides the signal into a plurality of signals and outputs them to a plurality of slave remotes, respectively. A master remote for amplifying a signal received from each slave remote and transmitting the signal to the base station for down-frequency conversion; And A plurality of signals connected to the master remote by a high frequency interface, for receiving and amplifying signals divided into a plurality of signals from the master remote and outputting them through an antenna, or for amplifying a signal received by the antenna and transmitting the signals to the master remote; Slave remote; Wireless relay device for the in-building service comprising a. The method of claim 1, The master remote may include: a forward high frequency signal processor for amplifying or attenuating a high frequency signal received by the uplink frequency conversion at the base station to a predetermined signal level and dividing the signal into two or more signals; An amplifier for amplifying the first output signal from the forward high frequency signal processor to an antenna through a duplexer; An RF dispersion unit for amplifying and dividing a second output signal from the forward high frequency signal processor to a designated signal level and transmitting the split signal to a slave remote, or for amplifying and outputting a signal received from each slave remote to a specified signal level; A low noise amplifier for removing noise after receiving a signal transmitted through the antenna via the duplexer; And A reverse high frequency signal processor for combining the signals received from the RF spreader and the low noise amplifier into a single signal, amplifying or attenuating the signal level, and transmitting the signals to the base station; Wireless relay device for the in-building service comprising a. The method of claim 1, The slave remote may include a forward high frequency signal processor configured to receive a signal received from the master remote through a first duplexer and to amplify or attenuate the signal at a predetermined signal level; An amplifier for amplifying the signal output from the forward high frequency signal processor and outputting the large signal to an antenna through a second duplexer; A low noise amplifier for removing noise by receiving the signal transmitted to the antenna through the second duplexer; And A reverse high frequency signal processor for amplifying or attenuating the signal output from the low noise amplifier to a predetermined signal level and outputting the signal to the master remote through the first duplexer; Wireless relay device for the in-building service comprising a. The method of claim 3, wherein And the forward high frequency signal processor and the reverse high frequency signal processor amplify a signal based on a cable loss amount with the master remote.

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