KR20130016600A - Relay apparatus for coupling femto-cell - Google Patents

Abstract

PURPOSE: A femto cell coupling relay device is provided to eliminate channel interference generated in a service overlap area between a relay device and a femto cell base station. CONSTITUTION: A femto cell FA(Frequency Assignment) signal coupler(213) generates a coupling FA signal by coupling signals outputted from a femto cell base station and by eliminating the overlapped FA signal from a digital signal converted in a first signal converter. An amplifier(214) receives the coupling FA signal generated by the femto cell FA signal coupler. The amplifier amplifies the received coupling FA signal to a set size. A transceiver(216) transmits the coupling FA signal amplified by the amplifier through an antenna. [Reference numerals] (100) Core network; (211) Photosignal combining unit; (212) First signal converter; (213a) FA signal removing unit; (213b) Second signal converter; (213c) First output adjusting unit; (213d) Second output adjusting unit; (213e) FA signal combining unit; (214) Amplifier; (215) Filter; (216) Transceiver; (233a) Third signal converter; (233b) Fourth signal converter

Description

Femtocell Coupling Relay Device {Relay Apparatus for Coupling Femto-Cell}

The present invention relates to a femto-cell coupled relay device, and more particularly, a FA (Frequency Assignment) signal that overlaps between a relay device such as a base station and a repeater and a femtocell base station and a FA signal of the relay device. An apparatus for removing channel interference between FA signals of a femtocell base station.

Existing mobile communication service has been progressed based on voice service-oriented business model. However, with the advent of various high-speed data service systems such as HSDPA, WiBro, and Mobile WiMAX, the focus of the business is shifting to wireless data services.

However, even a system that provides such a high-speed data service has only a few Mbps of channel capacity, and the channel capacity is shared by hundreds of users located within base station coverage, so that the available download speed per person is only tens to hundreds of Kbps. Do. Therefore, for users who experience several tens of Mbps speeds of wired and wireless LAN, satisfaction is greatly reduced.

In order to solve this problem, according to the development of semiconductor technology, it can be manufactured inexpensively, and it can be installed at home or indoor and used by a few users (about 1 ~ 4), which can reach several Mbps per subscriber in mobile communication systems. Attempts have been made to provide transmission capacity.

 In this regard, recently, a femto-cell, which is a personal base station installed indoors and serving 1-4 subscribers, has been proposed. The femtocell is a combination of femto, which represents one-tenth of a trillion (10 to 15 squared), and a cell, which represents a unit of a service area in charge of one base station in mobile communication. It refers to a service that covers an area much smaller than the service radius, and it is possible to connect a wired / wireless communication and a home network with a mobile phone by connecting a micro base station, which looks like a DSL modem, to a home Internet network. .

 In this regard, the femtocell is connected to the mobile communication access network and the core network of the operator through the Internet network and performs call processing such as voice call reception and message transmission and reception to the terminal in the femtocell service area.

1 is a diagram illustrating a service area of a conventional relay device and a service area of a femtocell base station.

Referring to FIG. 1, a conventional relay device 110 forms a service area A of a plurality of relay devices through a plurality of antennas 110a and 110b, and outside the service area A of the relay device 110. The existing service shadow area is solved by installing femtocell base stations 131 and 133.

However, when the femtocell base stations 131 and 133 are installed in order to eliminate the service shadow area of the relay device 110 as in the related art, the service area A and the femtocell base stations 131 and 133 of the relay device 110 are provided. The area C overlapping the coverage area B is generated, which causes channel interference between the FA signal provided by the relay device 110 and the FA signal provided by the femtocell base stations 131 and 133. have.

Therefore, there is a need for a device for removing channel interference generated between the relay device 110 and the femtocell base stations 131 and 133.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problem, and an object thereof is to provide a femtocell combined relay apparatus which eliminates channel interference caused by a service overlapping region occurring between a relay apparatus and a femtocell base station.

According to an aspect of the present invention, there is provided a femtocell combined relay apparatus comprising: a first signal converter configured to receive an optical signal including a FA (FA) signal for a mobile communication service from a mobile communication network and convert the optical signal into a digital signal; A femtocell FA signal combiner for generating a combined FA signal by removing the FA signal overlapping with the FA signal of the femtocell base station from the digital signal converted by the first signal converter and combining the FA signal output from the femtocell base station; An amplifier configured to receive the combined FA signal generated by the femtocell FA signal combiner and amplify it to a predetermined size; And a transceiver for transmitting the combined FA signal amplified by the amplifier through an antenna. .

The femtocell FA signal combiner according to the present invention comprises: an FA signal remover configured to generate a first FA signal from which a FA signal overlapped with a FA signal of a femtocell base station is converted from a digital signal converted by the first signal converter; A second signal converter converting the first FA signal generated by the FA signal remover into an RF signal to generate a second FA signal; A first output adjusting unit generating a third FA signal in which the second FA converted signal is adjusted to a preset magnitude; A second output adjuster configured to generate a third FA signal in which a femtocell FA signal transmitted from a femtocell base station is adjusted to a preset output magnitude; A FA signal combiner for generating a combined FA signal combining the third FA signal adjusted by the first output adjuster and the femtocell FA signal adjusted by the second output adjuster, and transmitting the combined FA signal to the amplifier; Characterized in that it comprises a.

According to the present invention, the first output adjuster enlarges the output size of the second FA signal to a preset output size, and the second output adjuster reduces the output size of the femtocell FA signal output from the femtocell base station to a preset output size. Characterized in that.

The femtocell combined relay apparatus according to the present invention transmits an optical signal received from a mobile communication network to a first signal converter or a femtocell base station, or combines an optical signal transmitted from a first signal converter and a femtocell base station and transmits the optical signal to the mobile communication network. Optical signal coupling unit; And further comprising:

The femtocell combined relay apparatus according to the present invention is characterized in that the base station or repeater supporting any one of the LTE, WiBro, WiMAX, CDMA, WCDMA scheme.

According to the present invention, by removing the FA signal overlapping the FA signal of the femtocell base station among the FA signals of the relay device and combining and transmitting the FA signal output from the femtocell base station, the channel according to the service overlapping area generated between the relay device and the femtocell base station It is possible to eliminate the interference, which has the effect of providing a high quality mobile communication service over a wider area.

1 is a diagram illustrating a service area of a conventional relay device and a service area of a femtocell base station.
2 is a block diagram of a femtocell combined relay apparatus according to an embodiment of the present invention.
3 is a diagram illustrating a process of processing an FA signal by a femtocell FA signal combiner according to an embodiment of the present invention.
4 is a diagram illustrating a service area of a femtocell combined relay device according to an embodiment of the present invention.

With reference to the accompanying drawings, a preferred embodiment of the present invention will be described in more detail, but already known technical parts will be omitted or compressed for the sake of brevity of description.

2 is a block diagram of a femto-cell combining relay device according to an embodiment of the present invention, Figure 3 is a FA signal in the femtocell FA (FA: Frequency Assignment) signal combiner according to an embodiment of the present invention 4 is a diagram illustrating a process of processing a process, and FIG. 4 is a diagram illustrating a service area of a femtocell combined relay device according to an embodiment of the present invention. Here, an embodiment of the present invention will be described with reference to the process of transmitting the FA signal in the femtocell combined relay device for convenience of description. In addition, the femtocell combined relay apparatus according to an embodiment of the present invention is preferably a base station or a repeater supporting any one of LTE, WiBro, WiMAX, CDMA, WCDMA scheme.

2, the femtocell coupling relay 210 according to an embodiment of the present invention includes an optical signal coupling unit 211, a first signal conversion unit 212, a femtocell FA signal coupling unit 213, and an amplification unit. 214, a filter 215, and a transceiver 216.

The optical signal combiner 211 receives a mobile communication service signal in the form of an optical signal from the core network 100 providing the mobile communication service and transmits the received signal to the first signal converter 212 and the femtocell base station 233.

In addition, the optical signal combiner 211 combines the signal transmitted from the first signal converter 212 and the signal transmitted from the femtocell base station 223 and transmits the signal to the core network 100.

The first signal converter 212 converts the optical signal transmitted from the optical signal combiner 211 into a digital signal and transmits the digital signal to the first signal converter 212.

The femtocell FA signal combiner 213 uses the FA signal remover 213a, the second signal converter 213b, the first output adjuster 213c, the second output adjuster 213d, and the FA signal combiner 213e. And a FA signal overlapping with the femtocell base station 233 from the signal transmitted from the first signal converter 212 and combining the FA signal output from the femtocell base station 233 to the amplifying unit 214. send. For convenience of description, an operation process of the components of the femtocell FA signal combiner 213 will be described in detail with reference to FIG. 3.

The FA signal removing unit 213a generates a first FA signal from which the femtocell FA signal overlapped with the femtocell base station 233 is removed from the FA signal D of the digital signal format transmitted from the first signal converter 212. Here, the FA signal D received from the first signal converter 212 by the FA signal remover 213a includes FA signals of all bands provided by the core network 100, and the femtocell base station 233 The transmitted first femtocell FA signal G includes a part of the FA signal provided by the core network 100. For example, the first femtocell FA signal transmitted from the femtocell base station 233 includes 1FA, 2FA, 3FA, 4FA, 5FA, and 6FA in the FA signal D digitized by the first signal converter 212. If GFA includes 5FA and 6FA, the FA signal remover 213a removes 5FA and 6FA, which are signals overlapped with the FA signal D digitized by the first signal converter 212, to convert the second signal. It transfers to part 213b.

The second signal converter 213b converts the first FA signal in the digital format transmitted from the first signal converter 212 into a second FA signal E in the RF signal format to the first output adjuster 213c. send.

The first output adjuster 213c adjusts the output of the second FA signal E in the RF signal format transmitted from the second signal converter 213b. Here, since the output magnitude of the signal output from the femtocell base station 233 transmitted to the second output adjuster 213e is relatively large, the first output adjuster 213c is the FA signal E and the femtocell base station 233. In order to combine the output signal, a third FA signal E 'which is enlarged to an appropriate size to be combined with the first femtocell FA signal G is generated and transmitted to the combiner 213d. do. In addition, the first output adjuster 213c may adjust the reverse gain of the signal transmitted from the FA signal combiner 213e.

The second output adjuster 213d adjusts the output of the first femtocell FA signal G output from the femtocell base station 233 to generate a second femtocell FA signal G '. Here, since the magnitude of the output of the first femtocell FA signal G output from the femtocell base station 233 is larger than the magnitude of the FA signal E 'adjusted by the first output adjustment unit 213c, the second output is output. The adjusting unit 213d reduces the output size of the first femtocell FA signal G to a size suitable for combining the first femtocell FA signal G and the second FA signal E 'to a second femtocell FA signal. (G ') is generated and transmitted to the FA signal combiner 213d.

Also, the second output adjuster 213e may adjust the reverse gain of the signal transmitted from the FA signal combiner 213e.

The FA signal combiner 213e includes a third FA signal E 'whose output is adjusted by the first output adjuster 213c and a second femtocell FA signal G' whose output is adjusted by the second output adjuster 213d. Combined to generate a combined FA signal (F) and transmits to the amplifier 214.

The amplifier 214 amplifies the combined FA signal F transmitted from the FA signal combiner 213e to a size necessary for external transmission to the filter unit 215, and transmits the amplified combined FA signal F. The received filter unit 215 transmits to the service area through the transceiver 216 and the antenna 210a.

The femtocell base station 233 includes a third signal converter 233a and a fourth signal converter 233b, and converts an optical signal transmitted from the optical signal combiner 211 into a femtocell signal to output a second signal. It transmits to the adjustment part 213d. Here, the third signal converter 233a converts the optical signal transmitted from the optical signal combiner 211 into an internet signal, and the fourth signal converter 233b is converted by the third signal converter 233a. Converts internet signals to femtocell signals.

Accordingly, as shown in FIG. 4, the femtocell combined relay device 210 and the femtocell base station 210 are generated by combining the FA signals transmitted from the femtocell base station 233 to generate an integrated service area A ′. 233) the service overlap area disappears, thereby eliminating channel interference due to the service overlap area occurring between the relay device and the femtocell base station.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100 core network 210 femtocell coupling relay device
210a: antenna 211: optical signal coupling unit
212: first signal converter 213: femtocell FA signal combiner
213a: FA signal removal unit 213b: second signal conversion unit
213c: first output adjustment unit 213d: second output adjustment unit
213e: FA signal combining unit 214: amplifying unit
215: filter unit 216: transceiver unit
233: femtocell base station 233a: third signal converter
233b: fourth signal converter

Claims (5)

A first signal conversion unit receiving an optical signal including a FA (FA) signal for a mobile communication service from a mobile communication network and converting the optical signal into a digital signal;
A femtocell FA that generates a combined FA signal by removing an FA signal overlapping an FA signal of a femto-cell base station from the digital signal converted by the first signal converter and combining the FA signal output from the femtocell base station. Signal coupling unit;
An amplifier configured to receive the combined FA signal generated by the femtocell FA signal combiner and amplify it to a predetermined size; And
A transceiver for transmitting the combined FA signal amplified by the amplifier through an antenna; ≪ RTI ID = 0.0 >
Femtocell coupling relay device.
The method of claim 1,
The femtocell FA signal coupling unit,
A FA signal removing unit generating a first FA signal from which the FA signal overlapping with the FA signal of the femtocell base station is removed from the digital signal converted by the first signal converter;
A second signal converter converting the first FA signal generated by the FA signal remover into an RF signal to generate a second FA signal;
A first output adjuster configured to generate a third FA signal in which the second FA converted signal is adjusted to a preset magnitude;
A second output adjustment unit configured to generate a third FA signal in which a femtocell FA signal transmitted from the femtocell base station is adjusted to a preset output magnitude;
A FA signal combiner for generating the combined FA signal combining the third FA signal adjusted by the first output adjuster and the femtocell FA signal adjusted by the second output adjuster, and transmitting the combined FA signal to the amplifier; ≪ RTI ID = 0.0 >
Femtocell coupling relay device.
The method of claim 2,
The first output adjustment unit enlarges the output size of the second FA signal to a preset output size,
The second output adjuster may reduce an output size of the femtocell FA signal output from the femtocell base station to a preset output size.
Femtocell coupling relay device.
The method of claim 3, wherein
The femtocell combined relay device,
An optical signal combiner which transmits an optical signal received from a mobile communication network to the first signal converter or the femtocell base station, or combines an optical signal transmitted from the first signal converter and the femtocell base station to the mobile communication network; ≪ RTI ID = 0.0 >
Femtocell coupling relay device.
The method of claim 4, wherein
The femtocell combined relay device,
It is characterized in that the base station or repeater supporting any one of LTE, WiBro, WiMAX, CDMA, WCDMA scheme
Femtocell coupling relay device.

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