KR101536279B1 - Mimo repeating system using frequency conversion and method therefor - Google Patents

Abstract

The present invention relates to a MIMO relay system using frequency conversion, in which an antenna port of a repeater for connecting a main and a MIMO signal to each other at a same frequency in a relay service, The present invention provides a MIMO relay system using frequency conversion that enables a MIMO service and a method thereof.
According to an aspect of the present invention, there is provided a MIMO relay system using frequency conversion. The MIMO relay system includes a main signal F1 and a MIMO signal F1 ' Main feature; A remote device which combines the MIMO signal F1 'input from the host device and the main signal F1 and transmits the combined signal to the antenna device; And the combined signal F1 / F3 of the main signal F1 and the frequency-converted MIMO signal F3 and outputs the separated main signal F1 and the frequency-converted MIMO signal F3 to the original Into a MIMO signal F1 'of the antenna, and transmits the MIMO signal to each of the antennas; .

Description

[0001] MIMO REPEATING SYSTEM USING FREQUENCY CONVERSION AND METHOD THEREFOR [0002]

The present invention relates to a MIMO relay system using frequency conversion and a method thereof, and more particularly, to a MIMO relay system using a frequency conversion and an antenna port of a repeater in which main and MIMO signals are relayed at the same frequency, The present invention relates to a MIMO relay system and a method thereof, in which frequency conversion is enabled to enable main and MIMO services.

As shown in FIG. 1A, in the case of a relay service at the same frequency, an existing MIMO repeater needs two antenna ports to service each path (Main, MIMO).

Meanwhile, in relation to the MIMO relaying technique in the in-building, there are a lot of publicly disclosed and registered in addition to the Korean Patent Laid-Open No. 10-2005-0034819 (hereinafter referred to as 'the preceding document').

The repeater system converts the RF signal into a digital signal and transmits the RF signal to the Gigabit Ethernet network through the UTP cable. The repeater system repeats the RF signal to the building, A distribution hub unit (DHU) for transferring the digital signal from the remote distribution unit to the remote distribution unit (RDU), converting the received digital signal into the RF signal through the UTP cable, and transmitting the RF signal to the building; A remote distribution unit for receiving a digital signal from the distribution hub unit (DHU) or an extension hub unit (EHU) connected to the DHU by a UTP cable, converting the digital signal into an RF signal, and relaying the RF signal inside the building through an antenna (RDU); .

That is, the conventional MIMO repeater including the prior art has an antenna port for each Path (Main, MIMO) in a main service and a relay service with MIMO signals of the same frequency, generally two antenna ports, And the service antenna are connected by a feeder cable.

In an in-building MIMO repeater, a plurality of RF cables are branched at the repeater antenna port to cover the inside of a complex building and are connected to the antenna end.

In this case, since the above-mentioned RF cable must be installed and installed double, a large cost is incurred, and installation is difficult

SUMMARY OF THE INVENTION The present invention has been conceived in view of the above problems, and it is an object of the present invention to provide an antenna port of a repeater in which main and MIMO signals are relayed with the same frequency, The present invention provides a MIMO relay system using frequency conversion that enables a MIMO service and a method thereof.

According to an aspect of the present invention, there is provided a MIMO relay system using frequency conversion. The MIMO relay system includes a main signal F1 and a MIMO signal F1 ' Main feature; A remote device which combines the MIMO signal F1 'input from the host device and the main signal F1 and transmits the combined signal to the antenna device; And the combined signal F1 / F3 of the main signal F1 and the frequency-converted MIMO signal F3 and outputs the separated main signal F1 and the frequency-converted MIMO signal F3 to the original Into a MIMO signal F1 'of the antenna, and transmits the MIMO signal to each of the antennas; .

The remote device may further include: a main signal processing unit for transmitting the main signal F1 input from the host device to the coupling / separation processing unit; A frequency converter for converting the frequency of the MIMO signal F1 'input from the host to an arbitrary frequency to generate a frequency-converted MIMO signal F3; And a MIMO signal (F3) having the frequency converted, and a combining / separating processing unit for combining the MIMO signal (F3) with the main signal (F1). And a control unit.

The antenna device further includes a coupling / demultiplexing unit for demultiplexing a combined signal F1 / F3 of the main signal F1 transmitted from the remote device and the frequency-converted MIMO signal F3 through a single RF cable; A main signal gain controller for analyzing a magnitude of the main signal F1 separated through the coupling / demultiplexing unit and adjusting the gain so as to balance the MIMO signal F1 'to the main signal antenna; And a MIMO frequency converter for converting the frequency of the frequency-converted MIMO signal F3 separated through the coupling / demultiplexing unit to the frequency of the original MIMO signal F1 'and transmitting the converted frequency to the MIMO signal antenna. And a control unit.

(A) A master device receives a main signal (F1) and a MIMO signal (F1 ') serviced at the same frequency from a base station and transmits the main signal (F1) and the MIMO signal Transmitting; (b) transmitting the main signal F1 input from the main signal processing unit of the remote device to the coupling-separation processing unit; (c) generating a frequency-converted MIMO signal (F3) by converting the frequency of the MIMO signal (F1 ') input from the host device (100) to an arbitrary frequency; (d) combining the frequency-converted MIMO signal (F3) with the main signal (F1); (e) receiving a coupling signal F1 / F3 between the main signal F1 and the frequency-converted MIMO signal F3 from a remote device via a single RF cable; (f) separating the combined signal F1 / F3 of the main signal F1 transmitted by the coupling / demultiplexing unit of the antenna apparatus and the MIMO signal F3 of which frequency is converted; (g) analyzing the magnitude of the main signal F1 separated by the main signal gain adjuster of the antenna device); (h) adjusting a gain of the main signal gain adjusting unit of the antenna device so as to balance the MIMO signal with the MIMO signal, and transmitting the adjusted gain to the main signal antenna; And (i) converting the frequency of the MIMO signal F3 into a frequency of the original MIMO signal F1 ', and transmitting the converted frequency to the MIMO signal antenna; .

According to the present invention, unlike the prior art in which the RF cable is installed in a duplex manner, only a single RF cable is used, which results in cost reduction and easy installation.

According to the present invention, in addition to an outdoor type repeater in which a connection between a repeater and an antenna is simple, it is also suitable for a configuration of an in-building repeater having a complicated or multiple antenna connection.

FIG. 1A shows an example of a situation of a RF cable facility for a MIMO service in a conventional system.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a MIMO relay system using frequency conversion.
3 is a detailed configuration diagram of a remote device according to the present invention;
4 is a detailed configuration diagram of an antenna device according to the present invention.
5 is an overall flowchart of a MIMO relaying method using frequency conversion according to the present invention.
FIG. 6 is a diagram illustrating an example of a repeater (remote device) and an antenna (antenna device) using a MIMO relay system using frequency conversion according to the present invention, as compared with FIG. 1A.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. It is to be noted that the detailed description of known functions and constructions related to the present invention is omitted when it is determined that the gist of the present invention may be unnecessarily blurred.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

A MIMO relay system and a method thereof using frequency conversion according to the present invention will be described with reference to FIG. 2 to FIG.

FIG. 3 is a detailed configuration diagram of a remote device 200 according to the present invention. FIG. 4 is a detailed configuration diagram of the MIMO relay system Fig. 2 is a detailed configuration diagram of an antenna device 300 according to the invention; Fig.

The MIMO relay system S using the frequency conversion according to the present invention includes the master device 100, the remote device 200, and the antenna device 300, as shown in FIGS.

The master hub unit 100 transmits the main signal F1 and the MIMO signal F1 'input from the base station 10 to the remote device 200.

Here, the main signal F1 and the MIMO signal F1 'are at the same frequency.

At this time, the host 100 adjusts the power of signals to be transmitted and received, converts an analog signal into an optical signal, and converts an optical signal into an analog signal.

The remote unit 200 performs a function of combining the MIMO signal F1 'input from the host device 100 and the main signal F1 and transmitting the combined signal to the antenna device 300, A main signal processor 210, a MIMO frequency converter 220, and a combining / separating processor 230 as shown in FIG.

Specifically, the main signal processing unit 210 transmits the main signal F1 input from the host device 100 to the coupling and separation processing unit 230. [ At this time, the main signal processing unit 210 adjusts the power of signals to be transmitted and received, converts an analog signal into an optical signal, and converts the optical signal into an analog signal.

The frequency converter 220 converts the frequency of the MIMO signal F1 'input from the host device 100 to an arbitrary frequency to generate a frequency-converted MIMO signal F3 and transmits the generated MIMO signal F3 to the combining / separating processor 230 do.

The combining / separating processing unit 230 combines the frequency-converted MIMO signal F3 with the main signal F1.

The antenna apparatus 300 separates the main signal F1 and the combined signal F1 / F3 of the frequency-converted MIMO signal F3 and outputs the separated main signal F1 and the frequency-converted MIMO signal The main signal gain adjuster 320, and the main signal gain adjuster 320, as shown in FIG. 4, as shown in FIG. 4, And a MIMO frequency conversion unit 330. [

Specifically, the combining / separating processing unit 310 receives the combined signal F1 / F3 of the main signal F1 transmitted from the remote device 200 via the single RF cable 20 and the frequency-converted MIMO signal F3, .

The main signal gain adjusting unit 320 analyzes the magnitude of the main signal F1 separated through the coupling and separating unit 310 and adjusts the gain so as to balance the MIMO signal F1 ' 30).

The MIMO frequency converter 330 converts the frequency of the frequency-converted MIMO signal F3 separated through the coupling and separating unit 310 to the frequency of the original MIMO signal F1 'Lt; / RTI >

On the other hand, it has been described that a downlink signal transmitted from a base station, that is, a signal flow transmitted from a base station to an antenna has been described, but it is obvious that a flow of an uplink signal transmitted from an antenna can be easily explained.

That is, in the uplink signal flow transmitted from the antenna to the base station, the combining / separating processing unit 310 of the antenna apparatus 300 performs the signal combining function, and the combining / separating processing unit 230 of the remote apparatus 200 Signal separation function can be performed.

Hereinafter, a MIMO relaying method using frequency conversion using the system according to the present invention will be described with reference to FIG.

FIG. 5 is an overall flowchart of a MIMO relaying method using frequency conversion according to the present invention. As shown in FIG. 5, a master 100 receives a main signal F1 and a MIMO signal F1 ') To the remote device 200 (S10).

The main signal processing unit 210 of the remote device 200 transmits the main signal F1 input from the host device 100 to the coupling and separation processing unit 230 at step S20, The frequency of the input MIMO signal F1 'is converted into an arbitrary frequency to generate a frequency-converted MIMO signal F3 (S30).

Thereafter, the combining / separating processing unit 230 combines the frequency-converted MIMO signal F3 with the main signal F1 (S40).

The combining and separating processing unit 310 of the antenna device 300 receives the combined signal of the main signal F1 transmitted from the remote device 200 through the single RF cable 20 and the MIMO signal F3 whose frequency is converted, (F1 / F3) are separated (S50).

The main signal gain adjuster 320 analyzes the magnitude of the main signal F1 separated through the combining and separating unit 310 in step S60 and adjusts the gain so as to balance the MIMO signal F1 ' And transmits it to the main signal antenna 30 (S70).

The MIMO frequency converting unit 330 converts the frequency of the frequency-converted MIMO signal F3 separated through the combining and separating unit 310 to the frequency of the original MIMO signal F1 ' 40 (S80).

FIG. 6 is a diagram illustrating an example of a repeater (remote device) and an antenna (antenna device) using a MIMO relay system using frequency conversion according to the present invention, as compared with FIG. 1A. Referring to FIG. 6, Service RF cable is reduced from the existing 2 ports to 1 port.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be appreciated by those skilled in the art that numerous changes and modifications may be made without departing from the invention. Accordingly, all such appropriate modifications and changes, and equivalents thereof, should be regarded as within the scope of the present invention.

100: Main device 200: Remote device
300: antenna device 210: main signal processor
220: MIMO frequency conversion unit 230:
310: combining / separating processing unit 320: main signal gain adjusting unit
330: MIMO frequency conversion unit 10: base station
20: RF cable 30: Main signal antenna
40: MIMO signal antenna

Claims (4)

(100) receiving a main signal (F1) and a MIMO signal (F1 ') serviced at the same frequency from a base station (10) and transmitting the same to a remote device (200);
The frequency of the MIMO signal F3 input from the host 100 is converted into a desired frequency to generate a frequency-converted MIMO signal F3, and the generated MIMO signal F3 and the main signal F1 are generated. A remote device 200 coupled to the antenna device 300; And
The main signal F1 and the frequency-converted MIMO signal F3 are separated from each other and the separated main signal F1 and the frequency-converted MIMO signal F3 are converted to the original signal F1 An antenna device 300 for converting the MIMO signal into a MIMO signal F1 'and transmitting the MIMO signal to each antenna; And the MIMO relay system using the frequency transformation.
The method according to claim 1,
The remote device (200)
A main signal processing unit 210 for transmitting the main signal F1 inputted from the host device 100 to the coupling / separation processing unit 230;
A frequency converter 220 for converting the frequency of the MIMO signal F1 'input from the host 100 to an arbitrary frequency and generating a frequency-converted MIMO signal F3; And
A MIMO signal F3 whose frequency is converted, and a combining / separating processing unit 230 which combines the main signal F1 and the MIMO signal F3; And a MIMO relay system using the frequency transformation.
The method according to claim 1,
The antenna device (300)
A coupling separation processing unit 310 for separating a coupling signal F1 / F3 between the main signal F1 transmitted from the remote device 200 through the single RF cable 20 and the MIMO signal F3 converted from the frequency, ;
The gain of the main signal F1 is adjusted by adjusting the magnitude of the main signal F1 to be balanced with the MIMO signal F1 ' An adjuster 320; And
A MIMO frequency conversion unit for converting the frequency of the frequency-converted MIMO signal F3 separated through the coupling / separation processing unit 310 to the frequency of the original MIMO signal F1 'and transmitting the converted frequency to the MIMO signal antenna 40; (330); And a MIMO relay system using the frequency transformation.
(a) receiving, from the base station 10, the main signal F1 and the MIMO signal F1 'which are serviced at the same frequency, and transmitting the main signal F1 to the remote device 200;
(b) transmitting, by the main signal processing unit 210 of the remote device 200, the main signal F1 inputted from the host device 100 to the combining / separating processing unit 230;
(c) The frequency conversion unit 220 of the remote device 200 converts the frequency of the MIMO signal F1 'input from the host device 100 to an arbitrary frequency, and generates a frequency-converted MIMO signal F3 ;
(d) combining the frequency-converted MIMO signal (F3) with the main signal (F1), and the coupling-separation processing unit (230) of the remote device (200)
(e) The coupling / demultiplexing processing unit 310 of the antenna device 300 receives the main signal F1 from the remote device 200 through the single RF cable 20, and the combined signal of the frequency-converted MIMO signal F3 F1 / F3);
(f) separating the combined signal F1 / F3 of the main signal F1 transmitted from the coupling / demultiplexing processing unit 310 of the antenna device 300 and the MIMO signal F3 converted from the frequency;
(g) analyzing a magnitude of the main signal F1 separated by the main signal gain control unit 320 of the antenna device 300;
(h) adjusting the gain of the main signal gain adjusting unit 320 of the antenna device 300 so as to balance the MIMO signal F1 'and transmitting the adjusted gain to the main signal antenna 30; And
(i) The MIMO frequency converter 330 of the antenna apparatus 300 converts the frequency of the separated MIMO signal F3 into the frequency of the original MIMO signal F1 '; The MIMO relay method comprising:

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