KR20120074512A - Rf repeater having a function of interference cancellation - Google Patents

Abstract

The present invention relates to a wireless relay apparatus, and more particularly, to a wireless relay apparatus having an interference cancellation function that enables efficient data transmission by eliminating indirect phenomena between uplink and downlink generated in a relay node of an LTE system.
In a wireless relay apparatus having an interference canceling function according to the present invention, a wireless relay apparatus providing a downlink signal applied from a base station to a terminal and providing an uplink signal applied from the terminal to a base station, the signal transmission and reception with the base station A high directional backhaul antenna having a first beamwidth for transmitting, an access antenna having a second beamwidth wider than a first beamwidth of a high directional antenna for transmitting and receiving signals with the terminal, and applied from the high directional backhaul antenna and the access antenna It characterized in that it comprises a relay processing means for relaying the signal to the base station or the terminal.

Description

RF repeater having a function of interference cancellation

The present invention relates to a wireless relay apparatus, and in particular, has an interference cancellation function that enables efficient data transmission by eliminating indirect phenomena generated during signal relay on the uplink from the terminal to the base station and the downlink from the base station to the terminal. It relates to a wireless relay device.

In the wireless communication system, the LTE (Long Term Evolution) system is a mobile communication system that has evolved from the Universal Mobile Telecommunications (UMT) system. The standard was established by the 3rd Generation Partnership Project (3GPP), an international standardization organization.

1 is a system schematic diagram showing a schematic configuration of an LTE system.

As shown in FIG. 1, the LTE system is basically configured by combining a plurality of terminals 20 with respect to one base station 10. In addition, a radio relay, that is, a relay node (RN) 30, is provided between the base station 10 and the terminal 20 to improve coverage or cell edge throughput. Combined. At this time, the signal connection from the base station 10 to the terminal 20 is called downlink, and the signal connection from the terminal 20 to the base station 10 is called uplink.

The relay node 30 is a device for supplementing the communication because the communication is not performed smoothly when the distance between the base station 10 and the terminal 20 is far, the downlink signal from the base station 10 to the terminal 20 And a relay process for the uplink signal from the terminal 20 to the base station 10.

In particular, in the frequency division duplexing (FDD) LTE system, the relay node 30 distinguishes the downlink and the uplink using different frequencies. That is, the relay node 30 amplifies the backhaul downlink signal applied from the base station 10 and transmits the backhaul downlink signal to the terminal 20 as an access downlink signal, and also applies it from the terminal 20. The amplified access uplink signal is transmitted to the base station 10 as a backhaul uplink signal.

However, since the backhaul downlink, the access downlink, the backhaul uplink, and the access uplink each use the same frequency band in the FDD LTE system, as shown in FIG. Likewise, in the relay node 30, an interference phenomenon occurs because a backhaul signal is fed as an access signal or an access signal is fed back as a backhaul signal on the uplink and the downlink. There is a problem.

Therefore, recently, a method of controlling the backhaul signal and the access signal to not enable the downlink or the uplink in time is proposed.

However, the time division method between the backhaul signal and the access signal uses only 50% of the allocated communication channel, resulting in a decrease in communication efficiency of the entire system.

Accordingly, the present invention has been made in view of the above-described circumstances, and, based on the gain difference between the backhaul signal and the access signal, the backhaul signal between the relay node and the base station is transmitted and received through an antenna having a high directivity characteristic. It is a technical object of the present invention to provide a wireless relay device having an interference canceling function to maintain the call quality without reducing the communication efficiency of the overall system by removing the interference signal.

In the wireless relay apparatus having an interference cancellation function according to the present invention for achieving the above object is provided in the wireless relay apparatus for providing a downlink signal applied from the base station to the terminal, the uplink signal applied from the terminal to the base station, A high directional backhaul antenna having a first beamwidth for transmitting and receiving signals with the base station, an access antenna having a second beamwidth wider than a first beamwidth of a high directional antenna for transmitting and receiving signals with the terminal, and the high directional backhaul antenna And relay processing means for relaying a signal applied from the access antenna to a base station or a terminal.

In the present invention, the backhaul antenna is set so that the level of the signal received from the base station is 70dB or more greater than the level of the signal received from the access antenna.

Further, in the present invention, the relay processing means may be configured to remove feedback signals having a different signal level by more than a predetermined level among the signals received through the backhaul antenna or the access antenna.

According to the present invention, a high directional antenna having a narrow beam width is configured for signal transmission and reception with a base station, and a wide beam width antenna is configured for signal transmission and reception with a terminal. By setting the transmit / receive signal levels to be different from each other by a predetermined level or more, it is possible to eliminate the interference phenomenon of the feedback signal applied to the radio relay apparatus with a simple configuration.

Therefore, it is possible not only to maintain the call quality in the overall communication system, but also to use all the allocated frequency and time domains on the downlink and the uplink, thereby improving communication efficiency in the overall communication system.

1 is a system schematic diagram showing a schematic configuration of an LTE system.
2 is a view for explaining the interference phenomenon generated in the relay node 30 shown in FIG.
3 is a diagram showing a schematic configuration of an LTE system to which a wireless relay apparatus having an interference cancellation function according to the present invention is applied;
Figure 4 is a block diagram showing the functional separation of the internal configuration of the relay processing means 130 shown in FIG.

Hereinafter, an embodiment according to the present invention will be described with reference to the drawings. However, the embodiments described below exemplarily illustrate one preferred embodiment of the present invention, and examples of such embodiments are not intended to limit the scope of the present invention. The present invention can be variously modified without departing from the technical idea thereof.

3 is a diagram illustrating a schematic configuration of an LTE system to which a wireless relay apparatus having an interference cancellation function according to the present invention is applied.

As shown in FIG. 3, the wireless relay device having the interference canceling function according to the present invention is configured by combining a wireless relay device, that is, a relay node 100, between the base station 10 and the terminal 20.

The relay node 100 is applied through a backhaul antenna 110 for communicating with the base station 10 and an access antenna 120 for communicating with the terminal 20 and the backhaul antenna 110 as shown. The downlink signal from the base station 10 is recovered and amplified and transmitted to the terminal 20 through the access antenna 120, and the uplink signal from the terminal 20 applied through the access antenna 120 is received. It is configured to include a relay processing means 130 to restore and amplify and transmitted through the backhaul antenna 110.

In this case, the relay node 100 is configured to narrow (A) the beam width using a high-direction backhaul antenna with respect to the backhaul signal with the base station 10 and with the terminal 20. The access signal is configured to use an omni directional antenna in which the beam width is set wide (B). For example, the high-directional antenna may be configured to have a directing angle of 50 ° or less, and the access antenna may be configured to have a directivity of 90 ° or more.

This is because the base station 10 and the relay node 100 is configured at a specific location because the high-directional antenna having a narrow beam width, while the terminal 20 has a mobility within a certain range can cover a certain range The access antenna is configured to have a wider beam width than the base station 10 side antenna.

In addition, the high-direction backhaul antenna 110 may be set such that when the relay node 100 receives the backhaul downlink, the backhaul downlink received signal is 70 dB or more greater than the signal signaled by the access downlink feedback. . In addition, the high-direction backhaul antenna 110 may be set such that, when the relay node 100 receives the access uplink, the access uplink received signal is 70 dB or more greater than the received signal due to the feedback of the backhaul uplink.

Meanwhile, the relay processing means 130 includes an RF signal processing block 131, an amplification processing block 132, and a digital signal processing block 133, as shown in FIG.

The RF signal processing block 131 is coupled to the backhaul antenna 110 and the access antenna 120. The RF signal processing block 131 performs baseband signal processing, processing of converting an analog signal into a digital signal, and converting an input signal into an intermediate frequency signal. That is, the RF signal processing block 131 converts a received signal applied from the backhaul antenna 110 and the access antenna 120 into an intermediate frequency or a signal of a baseband. In addition, the RF signal processing block 131 wirelessly transmits the signal restored and amplified through the digital signal processing block 133 and the amplification processing block 132 through the backhaul antenna 110 and the access antenna 120. do.

In addition, although not shown, the RF signal processing block 131 may allow a baseband digital signal processing block applied from the backhaul antenna 110 or the access antenna 120 to process a signal or may have a predetermined bandwidth or more. And a filter for removing the signal. In addition, the RF signal processing block 131 may be configured to include a filter for processing a baseband digital signal is processed so that the signal emitted to the backhaul antenna 110 or access antenna 120 is not emitted as a signal of a predetermined bandwidth or more. .

The amplification processing block 132 amplifies the RF signal provided from the RF signal processing block 131 to a predetermined level and provides it to the digital signal processing block 133. In addition, the amplification processing block 132 may be configured to perform an amplification process on the demodulated signal through the digital signal processing block 133 and then provide the amplified signal to the RF signal processing block 131. Can be.

The digital signal processing block 133 performs a demodulation process on the amplified RF signal applied from the amplification processing block 132 and provides the corresponding signal to the RF signal processing block 131. In addition, the digital signal processing block 133 may be configured to perform a demodulation process on the signal applied from the RF signal processing block 131 and then provide the demodulated signal to the amplification processing block 132.

That is, according to the above embodiment, a high directional antenna having a narrow beam width is configured for signal transmission and reception with a base station, and a wide beam width antenna is configured for signal transmission and reception with a terminal, thereby minimizing signal interference due to the feedback signal. It is possible to provide a wireless relay device.

In addition, by setting the transmission and reception signal level with the base station and the transmission and reception signal level with the terminal is more than a predetermined level, by analyzing the feedback input signal based on the signal level applied through a high-directional antenna or an access antenna to easily remove You can do it.

Therefore, according to the present invention, since it is possible to eliminate the interference phenomenon of the feedback signal applied to the radio relay apparatus with a simple configuration, it is possible to maintain the call quality in the entire communication system, as well as to be allocated on the downlink and uplink. It is possible to use both the entire frequency and time domain, thereby improving the communication efficiency in the overall communication system.

10: base station, 20: terminal,
100: wireless repeater, 110: backhaul antenna,
120: antenna, 130: relay processing means.
131: RF signal processing block, 132: amplification processing block,
133: digital signal processing block.

Claims (3)

A wireless relay apparatus for providing a downlink signal applied from a base station to a terminal and providing an uplink signal applied from the terminal to a base station,
A highly directional backhaul antenna having a first beamwidth for transmitting and receiving signals with the base station;
An access antenna having a second beamwidth wider than a first beamwidth of a high-directional antenna for transmitting and receiving a signal with the terminal;
And a relay processing means for relaying a signal applied from the high-direction backhaul antenna and the access antenna to a base station or a terminal. The method of claim 1,
And the backhaul antenna is set so that the level of the signal received from the base station is 70 dB or more greater than the level of the signal received from the access antenna. The method according to claim 1 or 2,
The relay processing means is a wireless relay device having an interference cancellation function, characterized in that configured to remove the feedback signal having a signal level difference of more than a predetermined level among the signals received through the backhaul antenna or the access antenna.

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