KR20100118405A - In-building repeater applicable to multi input multi output mobile telecommunication system - Google Patents

Abstract

PURPOSE: An in-building repeater which is applicable to a MIMO(Multi Input Multi Output) mobile communication system is provided to supply a service without expanding a coaxial cable or adding additional antenna. CONSTITUTION: A repeater device(600) includes a master unit(200), a UTP(Unshielded Twisted Pair) cable(400) and a remote unit(300). To transmit a digital signal to two or more transmission paths, the UTP cable is classified into two or more groups. The remote unit which is connected to the UTP cable is classified into two or more groups. The remote antennas of the remote unit in different group within a predetermined coverage area are arranged alternatively.

Description

In-building repeater applicable to multi input multi output mobile telecommunication system}

The present invention relates to an in-building relay system, and more particularly, to an in-building relay device that can be used in a multi-input multi-output mobile communication system, which is one of the main technologies of the existing 2nd generation mobile communication system as well as a 4th generation mobile communication system. It is about.

A mobile communication service system generally consists of a base station, base station controller, switching center and terminal station. The base station and the terminal station communicate in a constant frequency band, each base station has a constant call radius. Therefore, by arranging a plurality of base stations as appropriate, the call radius of each base station overlaps each other, thereby expanding the area where the call is possible. However, even though the entire city is covered by the arrangement of such a plurality of base stations, a call-shadowed area where a call is not possible in an island area or a large building underground space and a high-rise building is generated. One of the ways to solve such a call shadow area occurrence and to extend coverage is to install a relay device. Such a relay device includes an optical relay device, an RF relay device, a microwave relay device, and an in-building relay device according to an application area or a relay method. Optical repeaters are used in the outskirts, etc., and when the visible distance is several kilometers, microwave repeaters are used, and in-building repeaters can be used for apartment complexes, large buildings, and underground parking lots.

1 is a schematic diagram of an in-building relay device according to the prior art.

Referring to FIG. 1, an in-building relay device according to the related art is an in-building relay device used in a 2G mobile communication system. The in-building relay device includes a master antenna 11, a master relay unit 12, and a wired transmission line. 13 to 13a to 13d, remote relay units 14 to 14a to 14d, and remote antennas 15 to 15a to 15d. The master antenna 11 transmits and receives an RF signal between base stations in the downlink, and the master relay unit 12 converts the RF signal received from the master antenna 11 into a digital signal and then remotely via the wired transmission line 13. It transmits to the relay unit 14. The remote relay unit 14 converts the received digital signal into an RF signal and then transmits the received digital signal to the terminal 20 through the remote antenna 15, and the uplink is made of downlink and reverse path. Meanwhile, the in-building relay device according to the related art is used in a second generation mobile communication system, and the in-building relay device is a multi-input multi-output mobile, which is one of the main technologies of the fourth generation mobile communication system, that is, the fourth generation mobile communication system. It cannot be used as it is in a communication system. In order to be used in a multi-input multi-output mobile communication system, a problem arises in that an additional remote antenna and coaxial cable have to be installed.

Therefore, there is an urgent need for the development of an in-building relay device that can be used in a second generation mobile communication system as well as a fourth generation mobile communication system without installing an additional remote antenna and coaxial cable.

The present invention is to overcome the above-mentioned conventional problems, the problem to be solved by the present invention, as well as the use of the existing second generation mobile communication system without additional equipment of the antenna or wired transmission line as well as the fourth generation mobile communication system, that is, It is to provide an in-building relay device that can be used in a multiple input multiple output mobile communication system.

According to an exemplary embodiment of the present invention, a relay device for relaying signals between a base station and a terminal in a mobile communication system, and converts an RF signal received from the base station into a digital signal and outputs it through a master output port during downlink. A master unit converting the digital signal received through the master output port into an RF signal during uplink; A UTP cable for transmitting the digital signal; When downlink, converts the digital signal received through the UTP cable into an RF signal and outputs it through the remote antenna, and during the uplink, converts the RF signal received through the remote antenna into a digital signal and outputs it through the UTP cable. A remote unit, wherein the UTP cable is divided into two or more groups in order to transmit the digital signal to two or more transmission paths; and the remote unit connected to the UTP cable is also divided into two or more groups, and certain coverage is provided. There is provided an in-building relay apparatus applicable to a multiple input multiple output mobile communication system, characterized in that alternately disposing remote antennas of remote units belonging to different groups within an area.

The master unit delays the converted digital signal for each group during downlink for a predetermined time and outputs it through the master output port, and uplinks the digital signal received through the master output port for a predetermined time for each group. Converts to RF signal and outputs.

An exemplary embodiment of the present invention further includes a first expansion unit connected between the master unit and the remote unit via a UTP cable, wherein the first expansion unit receives a digital signal received from the master unit in downlink. It amplifies and transmits to the remote unit, and amplifies the digital signal received from the remote unit during the uplink and transmits it to the master unit.

An exemplary embodiment of the present invention further includes a second expansion unit connected between the first expansion unit and the remote unit via a UTP cable, the second expansion unit being received from the first expansion unit in downlink. A digital signal is amplified and transmitted to the remote unit, and when uplinked, the digital signal received from the remote unit is amplified and transmitted to the first expansion unit.

The master unit includes a master antenna for transmitting and receiving an RF signal with the base station; A master signal separator connected to the master antenna and configured to pass an RF signal of a specific band; A master signal converter connected to the master signal separator to convert the RF signal into an intermediate frequency signal during downlink, and convert the intermediate frequency signal into an RF signal during uplink; Connected to the master signal converter, the intermediate frequency signal received by the master signal converter during downlink is converted into a digital signal and transmitted to the master output port, and the digital signal received by the master output port during uplink A master signal processor for converting the signal into an intermediate frequency signal and transmitting the converted signal to the master signal converter; A master power supply unit supplying power to each component of the master unit; And a master controller for controlling the status information inquiry and operation of each component of the master unit.

The master signal processor of the master unit transmits the digital signal to the master output port by delaying the digital signal for a predetermined time during downlink, and delays and transmits the digital signal received through the master output port for a predetermined time during uplink. It further includes a group.

The remote unit is connected to the UTP cable, and converts the digital signal received through the UTP cable to the intermediate frequency signal during the downlink to the remote signal converter, and the intermediate frequency received by the remote signal converter during the uplink. A remote signal processor converting a signal into a digital signal and transmitting the digital signal to the UTP cable; It is connected to the remote signal processing unit, and converts the intermediate frequency signal received by the remote signal processing unit in the downlink to an RF signal and transmits to the remote signal separation unit, and uplink the RF signal received by the remote signal separation unit in the middle A remote signal converter converting a frequency signal into the remote signal processor; A remote antenna for transmitting and receiving an RF signal with the terminal; A remote signal separation unit connected between the remote antenna and the remote signal conversion unit to pass an RF signal of a specific band; A remote power supply unit supplying power to each component of the remote unit; And a remote control unit that controls the status information inquiry and operation of each component of the remote unit.

The remote unit further includes a signal divider connected between the remote signal separator and the remote antenna to separate the RF signal into multiple paths.

According to the present invention, when the multi-input multi-output mobile communication system, one of the main technologies of the fourth generation mobile communication system, is applied, the service can be performed without additional antenna and coaxial cable extension.

In addition, by applying a structure in which remote antennas belonging to different groups having different data transmission paths are alternately arranged as in the present invention, a multi-input multi-output mobile communication system can be realized without degrading output power.

In addition, the UTP cable having different signal transmission paths can adjust the signal delay time for each group, so that the cell operation can be optimized by matching the total delay time between the base station and the terminal, and the delay time according to each transmission path. Diversity effect can also be obtained by giving.

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

2 is a schematic configuration diagram of an in-building relay device according to a first embodiment of the present invention, Figure 3 is a schematic configuration diagram of a master unit of the in-building relay device of the present invention, Figure 4 is an in-building relay of the present invention It is a schematic block diagram of the remote unit of a device.

2 to 4, the in-building relay device according to the first embodiment of the present invention is disposed between the base station 100 and the terminal to relay a signal between the base station 100 and the terminal (not shown). . The inbuilding relay device 600 is connected to the master unit 200, the remote unit 300 and the master unit 200 and the remote unit 300, wired transmission line 400 for transmitting digital signals, that is, UTP Cable (Unshielded Twisted Pair Cable).

The master unit 200 converts the RF signal received from the base station 100 into a digital signal during downlink and transmits it to the UTP cable 400 through a master output port (not shown), and receives through the master output port during uplink. One digital signal is converted into an RF signal and transmitted to the base station 100. The remote unit 300 converts a digital signal received through the UTP cable 400 in the downlink to an RF signal and transmits the RF signal to a terminal (not shown) through the remote antenna. To convert the digital signal to the master unit 200 through the UTP cable 400.

In the present embodiment, the base station 100 includes a first base station 110 for a second generation mobile communication system and a second base station 130 for a fourth generation mobile communication system in which a multiple input multiple output technology is used.

The master unit 200 includes a plurality of master output ports (not shown), and a plurality of UTP cables 400 are connected to the plurality of master output ports. The plurality of remote units 300 are disposed in a shadowed area inside a building such as a building or an underground parking lot, and the plurality of remote units 300 are connected to the plurality of UTP cables 400 and connected to the master unit 200. .

On the other hand, in order to transmit the digital signal that is digitally converted to the master unit 200 or the remote unit 300 by two or more transmission paths, the UTP cable 400 is divided into two or more groups, such a UTP cable Remote unit 300 connected to 400 is also divided into two or more groups. In addition, the remote antenna connected to the remote unit 300 is configured such that the remote antennas of the remote units belonging to different groups are alternately arranged within a certain coverage area, so that a multi-input multi-output mobile communication system is implemented even without a separate antenna installation. Input multiple output service is enabled.

In the present embodiment, in order to transmit the digital signal divided into two transmission paths, for example, A path and B path, the UTP cable 400 is the first UTP cable group 410 and the second UTP cable group 420 Are separated by). Similarly, the remote unit 300 is divided into a first remote unit group 300A connected to the first UTP cable group 410 and a second remote unit group 300B connected to the second UTP cable group 420. Each remote unit 300 is connected to two remote antennas through a coaxial cable. Looking at the arrangement of the remote antenna, it can be seen that the remote antenna connected to the remote unit belonging to the first remote unit group 300A and the remote antenna connected to the remote unit belonging to the second remote unit group 300B are alternately arranged. Can be. As such, when the remote antennas having different data transmission paths are alternately arranged, the terminals located within a certain coverage area can transmit and receive RF signals through different data transmission paths, and thus, multiple input multiplexing without installing additional remote antennas. Output services can be implemented.

Meanwhile, in the present embodiment, eight UTP cables are connected to eight master output ports, and the data transmission paths are also described as being grouped into two. However, this is only an example for convenience of description, and the master output port and the UTP cable are described. The number of and the number of data transmission paths is not limited thereto, and may be variously modified.

Referring to FIG. 3, the master unit 200 includes a master antenna 210, a master signal separation unit 220, a master signal conversion unit 230, a master signal processing unit 240, a master power supply unit 250, and a master control unit ( 260).

The master antenna 210 is connected to the master signal separation unit 220 and performs a function of transmitting and receiving an RF signal with the base station 100. The master signal separator 220 is connected to the master antenna 210 to pass the RF signal of a specific band.

The master signal converter 230 is connected to the master signal separator 220 and, in the downlink, converts the RF signal received from the base station through the master signal separator 220 into an intermediate frequency signal, thereby converting the master signal processor 240. In the uplink, the intermediate frequency signal received from the master signal processor 240 is converted into an RF signal and transmitted to the master signal separator 220.

The master signal processor 240 is connected to the master signal converter 230, and during downlink, converts an intermediate frequency signal received from the master signal converter 230, that is, an analog signal into a digital signal, to convert the UTP cable 400. It is transmitted to the connected master output port (not shown), and in the uplink, the digital signal received at the master output port is converted into an intermediate frequency signal and transmitted to the master signal converter. Meanwhile, the master signal processor 240 delays the converted digital signal for each group for a predetermined time and outputs it through the master output port during the downlink, and the digital signal received through the master output port for uplink for a predetermined time The delay can be converted to an RF signal and output.

The master power supply unit 250 supplies power to each component of the master unit, and the master control unit 260 performs a function of controlling status information inquiry and operation of each component of the master unit.

Referring to FIG. 4, the remote unit 300 includes a remote antenna 310, a remote signal separation unit 320, a remote signal conversion unit 330, a remote signal processing unit 340, a remote power supply unit 350, and a remote control unit ( 360).

The remote signal processing unit 340 is connected to the UTP cable connected to the master unit 200, and during downlink converts the digital signal received from the master unit 200 through the UTP cable 400 to an intermediate frequency signal to remote In the uplink, the intermediate frequency signal received by the remote signal converter 330 is converted into a digital signal and transmitted to the UTP cable 400.

The remote signal converter 330 is connected to the remote signal processor 340, and converts the intermediate frequency signal received from the remote signal processor 340 into an RF signal and transmits the RF signal to the remote signal separator 320 during downlink. In the uplink, the RF signal received by the remote signal separation unit 320 is converted into an intermediate frequency signal and transmitted to the remote signal processing unit 340.

The remote antenna 310 transmits and receives an RF signal to and from the terminal, and the remote signal separator 320 is connected between the remote antenna 310 and the remote signal converter 330 to pass an RF signal of a specific band. The number of remote antennas 310 connected to the remote unit 300 may vary depending on the coverage area.

The remote power supply unit 350 supplies power to each component of the remote unit 300, and the remote control unit 360 performs a function of controlling status information inquiry and operation for each component of the remote unit 300.

5 is a functional block diagram showing the detailed structure of the master signal processing unit of the master unit of the present invention.

Referring to FIG. 5, the master signal processor 240 includes an analog / digital converter 241, a digital / analog converter 242, a framer 243, a leaf reamer 244, a signal delayer 245, and a converter 246. ) And master output port 247.

The analog / digital converter 241 converts the intermediate frequency signal received from the master signal converter 230 into a digital signal and transmits the digital signal to the framer 243 during the downlink, and the digital / analog converter 242 performs the uplink link. The digital signal received by the framer 244 is converted into an intermediate frequency signal and transmitted to the master signal converter 230. Framers 243 and leaframers 244 function to frame or deframe in a format suitable for data transmission.

The master signal delay unit 245 delays the digital signal for a predetermined time during the downlink and transmits it to the master output port 247 through the master converter 246, and the master output port 247 and the master converter 246 during the uplink. Delay the digital signal received through a certain time to transmit. As such, the master signal delay unit 245 may change and adjust delay times of digital signals coming into individual transmission paths through respective UTP cables, thereby obtaining diversity effects.

FIG. 6 is a diagram illustrating coverage when an inbuilding relay device according to an exemplary embodiment of the present invention is used in a second generation mobile communication system. FIG. 7 is a diagram illustrating multiple inbuilding relay devices according to an exemplary embodiment of the present invention. This figure shows coverage when used in an input multiple output mobile communication system.

When the second generation mobile communication system (1.8 GHz band) is installed, when the remote antennas having different data transmission paths are alternately arranged as in the present invention, frequency characteristics of the second generation mobile communication system and the fourth generation mobile communication system The multi-input multi-output effect can be obtained by using the transmission distance characteristic. If the frequency is cut in half on the same EIRP criterion of the antenna, such as Free Space Path Loss, the distance is doubled and the area is quadrupled.

As a result, the 4G terminal can simultaneously receive the signal of the A path transmitted through the remote unit belonging to the first remote unit group and the signal of the B path transmitted through the remote unit belonging to the second remote unit group. In addition, the uplink signal transmitted from the terminal is simultaneously received by the remote antenna of the A path and the remote antenna of the B path through the remote unit belonging to the first remote unit group, the remote unit belonging to the second remote unit group, and the UTP cable. Is sent to the master unit.

Therefore, the 4th generation multi-input multi-output mobile communication system of 800 MHz band can be realized by using the antenna layout structure based on the 2nd generation mobile communication system of 1.8 ㎓ band without additional antenna and coaxial cable extension. This enables the implementation of multiple input multiple output systems without degrading the output power.

8 is a schematic structural diagram of an in-building relay device according to a second embodiment of the present invention. The second embodiment shown in FIG. 8 is different from the first embodiment in that a signal divider is additionally installed in the remote unit, and the rest of the configuration is similar to the following, focusing on different configurations.

Referring to FIG. 8, the inbuilding relay device 600 is connected to the master unit 200, the remote unit 300, and the master unit 200 and the remote unit 300 to transmit a digital signal. 400, that is, the UTP cable (Unshielded Twisted Pair Cable). The master unit 200 converts the RF signal received from the base station 100 into a digital signal during downlink and transmits it to the UTP cable 400 through a master output port (not shown), and receives through the master output port during uplink. One digital signal is converted into an RF signal and transmitted to the base station 100. The remote unit 300 converts a digital signal received through the UTP cable 400 in the downlink to an RF signal and transmits the RF signal to a terminal (not shown) through the remote antenna. To convert the digital signal to the master unit 200 through the UTP cable 400.

The remote unit 300 may include remote antennas 310A and 310B, a remote signal separation unit (not shown), a remote signal conversion unit (not shown), a remote signal processing unit (not shown), a remote power supply unit (not shown), and a remote control unit ( And further includes signal dividers 370A and 370B connected between the remote signal separator and the remote antenna. The signal distributor divides the RF signal received by the remote signal separator into multiple paths or transmits the RF signals received from the plurality of remote antennas to the remote signal separator. In this way, the signal splitter can be used to cover multiple shadow areas with a single remote unit.

9 is a schematic configuration diagram of an in-building relay device according to a third embodiment of the present invention, and FIG. 10 is a schematic configuration diagram of an expansion unit of the in-building relay device of the present invention. The third embodiment of the present invention is different in that an additional expansion unit is installed in order to overcome the distance limitation between the master unit and the remote unit, and the rest of the configuration is similar to other embodiments, and the following description will focus on different configurations.

Referring to FIG. 9, the in-building relay device according to the third embodiment of the present invention is connected between the master unit 200, the remote unit 300, the expansion unit 500, and each unit to provide digital signals between the units. A wired transmission line 400 for transmitting, that is, includes a UTP cable 400. The expansion unit 500 performs a function of amplifying the digital signal received through the UTP cable 400 and outputting the digital signal to the UTP cable 400 to increase the transmission distance of the digital signal.

In the present embodiment, the expansion unit 500 is composed of a first expansion unit 510 and a second expansion unit 520. The first expansion unit 510 is connected between the master unit 500 and the remote unit 300 to amplify and transmit a digital signal received from the master unit 510 to the remote unit 300 during downlink. When linking, the digital signal received from the remote unit 300 is amplified and transmitted to the master unit 200.

In addition, the second expansion unit 520 is connected between the first expansion unit 510 and the remote unit 300 through the UTP cable 400, the digital signal received from the first expansion unit 510 during downlink To amplify and transmit to the remote unit 300, and amplifies the digital signal received from the remote unit 300 during the uplink and transmits it to the first expansion unit (510).

Referring to FIG. 10, the first expansion unit 510 includes an expansion signal processor 511, an expansion control unit 513, and an expansion power supply unit 515. The extended signal processor 511 amplifies the digital signal received through the UTP cable and retransmits it to the UTP cable. The expansion controller 513 controls the status information inquiry and operation of the extended signal processor 511 and expands the signal. The power supply unit 515 performs a function of supplying power in each configuration. The second expansion unit 520 also has the same configuration as the first expansion unit.

What has been described above is merely an exemplary embodiment of an in-building relay device usable in a multi-input multi-output mobile communication system according to the present invention. The present invention is not limited to the above-described embodiment, and is claimed in the following claims. As will be appreciated, those skilled in the art to which the present invention pertains will have the technical spirit of the present invention to the extent that various modifications can be made without departing from the gist of the present invention.

1 is a schematic diagram of an in-building relay device according to the prior art.

2 is a schematic structural diagram of an in-building relay device according to a first embodiment of the present invention.

3 is a schematic configuration diagram of a master unit of the in-building relay device of the present invention.

4 is a schematic configuration diagram of a remote unit of the in-building relay device of the present invention.

5 is a functional block diagram showing the detailed structure of the master signal processing unit of the master unit of the present invention.

6 is a diagram illustrating coverage when an in-building relay device according to an exemplary embodiment of the present invention is used in a second generation mobile communication system.

7 is a diagram illustrating coverage when an in-building relay device according to an exemplary embodiment of the present invention is used in a multiple input multiple output mobile communication system.

8 is a schematic structural diagram of an in-building relay device according to a second embodiment of the present invention.

9 is a schematic structural diagram of an in-building relay device according to a third embodiment of the present invention.

10 is a schematic structural diagram of an expansion unit of the in-building relay device of the present invention.

* Description of the symbols for the main parts of the drawings *

100: base station

200: master unit

300: remote unit

400: UTP Cable

500: expansion unit

Claims (8)

In the relay device for relaying a signal between the base station and the terminal in a mobile communication system, A master unit which converts the RF signal received from the base station into a digital signal during downlink and outputs it through a master output port, and converts and outputs a digital signal received through the master output port into an RF signal during uplink; A UTP cable for transmitting the digital signal; When downlink, converts the digital signal received through the UTP cable into an RF signal and outputs it through the remote antenna, and during the uplink, converts the RF signal received through the remote antenna into a digital signal and outputs it through the UTP cable. Includes a remote unit, In order to transmit the digital signal to two or more transmission paths, the UTP cable is divided into two or more groups, and the remote unit connected to the UTP cable is also divided into two or more groups, and in different groups within a certain coverage area. An in-building relay device applicable to a multi-input multi-output mobile communication system, characterized in that alternately disposing remote antennas of the remote unit to which the remote unit belongs. The method of claim 1, The master unit delays the converted digital signal for each group during downlink for a predetermined time and outputs it through the master output port, and uplinks the digital signal received through the master output port for a predetermined time for each group. An in-building relay device applicable to a multi-input multi-output mobile communication system, characterized by converting and outputting an RF signal. The method of claim 1, And a first expansion unit connected between the master unit and the remote unit via a UTP cable, The first expansion unit amplifies and transmits the digital signal received from the master unit to the remote unit during downlink, and amplifies and transmits the digital signal received from the remote unit to the master unit during uplink. An in-building relay device applicable to a multiple input multiple output mobile communication system. The method of claim 3, And a second expansion unit connected between the first expansion unit and the remote unit via a UTP cable, The second expansion unit amplifies and transmits the digital signal received from the first expansion unit to the remote unit during downlink, and amplifies the digital signal received from the remote unit during the uplink to the first expansion unit. An in-building relay device applicable to a multi-input multi-output mobile communication system, characterized in that for transmitting. The method of claim 1, wherein the master unit, A master antenna for transmitting and receiving an RF signal with the base station; A master signal separator connected to the master antenna and configured to pass an RF signal of a specific band; A master signal converter connected to the master signal separator to convert the RF signal into an intermediate frequency signal during downlink, and convert the intermediate frequency signal into an RF signal during uplink; It is connected to the master signal converter, and converts the intermediate frequency signal received by the master signal converter in the downlink to a digital signal and transmits it to the master output port, and in the uplink, the digital signal received at the master output port A master signal processor converting the intermediate frequency signal to the master signal converter; A master power supply unit supplying power to each component of the master unit; And And a master controller for controlling the status information inquiry and operation of each component of the master unit. The method of claim 5, wherein the master signal processing unit of the master unit, And a master signal delayer for delaying the digital signal for a predetermined time during downlink and transmitting the delayed digital signal to the master output port, and for delaying and transmitting a digital signal received through the master output port for uplink. In-building relay device applicable to multi-input multi-output mobile communication system. The method of claim 1, wherein the remote unit, Connected to the UTP cable, and converts the digital signal received through the UTP cable into an intermediate frequency signal during downlink and transmits the digital signal to a remote signal converting unit, and transmits the intermediate frequency signal received by the remote signal converting unit during the uplink. A remote signal processor converting the signal to the UTP cable; It is connected to the remote signal processing unit, and converts the intermediate frequency signal received by the remote signal processing unit in the downlink to an RF signal and transmits to the remote signal separation unit, and uplink the RF signal received by the remote signal separation unit in the middle A remote signal converter converting a frequency signal into the remote signal processor; A remote antenna for transmitting and receiving an RF signal with the terminal; A remote signal separation unit connected between the remote antenna and the remote signal conversion unit to pass an RF signal of a specific band; A remote power supply unit supplying power to each component of the remote unit; And And a remote controller for controlling the status information inquiry and operation of each component of the remote unit. The method of claim 7, wherein the remote unit, And a signal divider connected between the remote signal separator and the remote antenna to separate the RF signal into multiple paths.

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