KR101007394B1 - Apparatus for receiving in frequency division duplex system - Google Patents

Abstract

PURPOSE: A receiving device in a FDD(Frequency Division Duplex) system is provided to select FA in a receiving device, thereby reducing a digital IF transmission amount. CONSTITUTION: A remote RF(Radio Frequency) unit(250) senses a frequency allocation output from a neighboring base station. A remote RF unit selects lowest power FA(Foreign Agent) among the sensed FA. The remote RF unit multiples a receiving signal and a monitor signal. Based on the selected FA, there receiving signal and a monitor signal are processed. The remote RF unit transmits the selected FA and multiplexed signal to a baseband unit(270). Based on FA, a processing unit(210) processes a signal of a transmission device.

Description

Receiver in frequency division duplex system {APPARATUS FOR RECEIVING IN FREQUENCY DIVISION DUPLEX SYSTEM}

The present invention relates to a frequency division duplex system, and more particularly, to a receiver in an FDD system.

In a general mobile communication system, according to a pre-cell plan plan and network optimization, a place where a base station is installed, a frequency allocation of a base station (FA), an output of a base station, and the like are set. However, if the base station is installed by unplanned network planning such as in-building or military tactical network, the function of automatically setting the base station should be utilized. In this case, parameters required for automatically setting a base station use outputs for each FA, a neighbor base station identifier (ID), and the like.

In addition, a time division duplex (TDD) system such as WiMAX utilizes a transition gap time to temporarily set a reception mode or force a base station reception mode in a short time. Set to collect the surrounding base station information.

However, unlike the TDD system, in a frequency division duplex (FDD) system, a reception apparatus must be configured as shown in FIG. 1 to recognize neighboring base stations.

First, the FDD system refers to a system that divides a frequency in one transmission medium and connects a forward and a reverse communication channel.

As described above, an example of a receiver in a conventional FDD system is shown in FIG. 1 below. Hereinafter, a receiver of a conventional FDD system will be described with reference to FIG.

1 is a diagram illustrating a receiver of a conventional FDD system.

Referring to FIG. 1, a receiver includes a first processor 110 that receives a received signal, and a second processor 150 that receives a monitor signal to recognize a neighboring base station.

The received signal refers to a terminal transmission signal of an FDD system, and the monitor signal refers to a signal in which the received signal and a neighbor base station transmission signal are mixed.

As shown in FIG. 1, a receiver of a conventional FDD system includes a first processor 110 and a second processor 150.

The first processor 110 low noise amplifies the received received signal through a low noise amplifier (LNA) 111, and a low pass amplified signal is a band pass filter (hereinafter referred to as BPF). Filter through baseband frequency 113 to pass to mixer 117. The first mixer 117 mixes the signal filtered at the baseband frequency and the frequency oscillated from the FA selection local oscillator (LO) 115 to form a first low pass filter. LPF) 119. In the first processing unit 110, the LPF 119 designed by the FA selection filter 121 filters the mixed signal output from the first mixer 117 to a baseband frequency, thereby increasing the second mixer 125. To pass) The second mixer 125 mixes the signal filtered to the baseband frequency output from the LPF 119 and the frequency oscillated from the fixed LO 123. In addition, the first processing unit 110 filters the mixed signal to a low frequency through a second low pass filter 127 and then the low frequency through an analog digital converter (ADC) 129. The converted signal is converted into a digital signal and transmitted to the multiplexer (MUX) 170.

The second processor 150 low noise amplifies the received monitor signal through the LNA 151, filters the amplified signal to a baseband frequency through the BPF 153, and the baseband through the mixer 157. The frequency filtered signal from the 3FA selection LO 115 is mixed with the signal filtered by the frequency and transmitted to the BPF 159. The second processor 150 filters the mixed signal to a baseband frequency through the BPF 159 designed by the multi-FA selection filter 161, and filters the mixed signal to the baseband frequency through the mixer 165. The frequencies oscillated from the LO 163 fixed to the signal are mixed. In addition, the second processor 150 filters the mixed signal to a low frequency through the LPF 167, and then converts the signal filtered to the low frequency through the ADC 169 into a digital signal and multiplexer (MUX). Forward to 170.

As described above, the receiving apparatus of the conventional FDD system receives the received signal and the monitor signal, respectively, and processes the received signal and the monitor signal in the first processor and the second processor, respectively, and multiplexes them in the multiplexer 170.

The multiplexer 170 multiplexes the signals transmitted from the ADCs 129 and 169, and the optical converter 190 converts the multiplexed signals into optical signals for transmission over an optical cable.

However, as shown in the related art, the receiving apparatus of the conventional FDD system requires a second processing unit 150 for receiving a monitor signal in order to recognize neighboring base stations. In addition, the receiving apparatus of the FDD-based system includes a baseband portion corresponding to the optical converter 190 and a radio frequency (RF) portion corresponding to the first and second processing units 110 and 150 separated from each other and separated by an optical cable. In the case of a remote RF unit corresponding to 170), since the optical cable bandwidth is limited, it is necessary to transmit separate received Digital Intermediate Frequency (IF) data to the baseband unit. There is this.

Accordingly, there is a need for a method of efficiently recognizing neighboring base stations in a receiver of an FDD-based system.

The present invention provides a method for efficiently recognizing neighboring base stations in the reception apparatus of the FDD-based system.

A receiving apparatus in a frequency division duplex (FDD) system according to the present invention, detects a frequency allocation (FA) output from a neighboring base station, selects the FA having the lowest power among the detected FA, and the selected FA, A remote radio frequency (RF) unit for multiplexing the received signal and the monitor signal based on the selected FA and transmitting the multiplexed signal to a baseband unit, and processing a signal received from a transmitter based on the selected FA And a processing unit, wherein the processing unit distributes the signal received from the transmitter into a reception signal and a monitor signal, and processes the distributed reception signal and the monitor signal based on the selected FA.

The present invention can select the FA by itself in the receiving apparatus of the FDD system, it is possible to reduce the digital IF transmission amount. In addition, since the receiving apparatus shares the receiving signal antenna and the monitor signal antenna, the components of the receiving apparatus can be minimized in the FDD system.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

The main subject of the present invention is to automatically select the FA in the receiving apparatus of the FDD-based system and to minimize the components so that neighboring base stations can be efficiently recognized.

Hereinafter, referring to FIG. 2, a method of efficiently recognizing a neighbor base station in a reception apparatus of an FDD-based system will be described.

2 is a diagram illustrating a receiver of an FDD system according to an exemplary embodiment of the present invention.

Referring to FIG. 2, the receiver includes a processor 210 for processing a received signal and a monitor signal received from a transmitter (not shown), a remote RF unit 250 for automatically selecting a FA, and a baseband. Section 270.

The power detection preamble detector 251 included in the remote RF unit 250 detects an FA output from a neighboring base station by itself and selects an FA having the lowest power among the detected FAs. That is, the power detection preamble detector 251 may automate FA selection.

In the processing unit 210, the LNA 201 performs low noise amplification on the signal received from the transmission apparatus and transmits the low noise amplification to the first BPF 203. The first BPF 203 filters the signal transmitted from the LNA 201 to a baseband frequency and transmits the signal to the diplexer 205.

The diplexer 205 divides the signal transmitted from the first BPF 203 into a received signal and a monitor signal, transfers the received signal to the first mixer 209, and transmits the monitor signal to a third mixer ( 227). At this time, the diplexer 205 distributes the received signal to maximize the gain. As an example, a distribution method for maximally preserving the gain of the received signal includes a method of dividing the gain between the received signal and the monitor signal by 9: 1. The first mixer 209 mixes the frequency transmitted from the FA select LO 207 to the signal transmitted from the diplexer 205 and delivers the frequency to the second BPF 211.

The second BPF 211 is designed by the FA selection filter 213 using the FA selected from the power detection preamble detector 251 as the center frequency, and converts the signal transmitted from the first mixer 209 into the baseband frequency. The filter is passed to the second mixer 217. The second mixer 217 mixes the frequency oscillated from the LO 215 fixed to the signal transmitted from the second BPF 211 to the first LPF 219. The first LPF 219 filters the signal transmitted from the second mixer 217 to the second ADC 237 by filtering the low frequency frequency, and the second ADC 237 transmits the first LPF 219. The signal transmitted from the digital signal is converted to the MUX 239 and transmitted.

The third mixer 227 mixes the frequency oscillated from the central FA LO 225 to the signal transmitted from the diplexer 205 and delivers the frequency to the third BPF 231. The third BPF 231 is designed to down-convert all FAs by a multi-FA selection filter 229 using a center FA as a center frequency, and baseband the signal transmitted from the third mixer 227. The filter is filtered in frequency and transferred to the fourth mixer 233. The fourth mixer 233 mixes the frequency oscillated from the LO 215 fixed to the signal transmitted from the third BPF 231 and transmits the frequency to the second LPF 235. The second LPF 235 filters the signal transmitted from the fourth mixer 233 to a low frequency and transmits the signal to the ADC 237, and the ADC 237 transmits the signal transmitted from the second LPF 235. The signal is converted into a digital signal and transmitted to the MUX 239.

The multiplexer 253 included in the remote RF unit 350 multiplexes the signals transmitted from the ADCs 221 and 237 and the power detection preamble detector 251 and transmits the signals to the optical converter 271. In this case, the multiplexer 237 generates a tag for each FA and base station IDs of the selected FAs and all detected FAs by the power detection preamble detector 251 and multiplexes them with the received signal and the monitor signal. The amount of digital IF data to be transmitted in the band can be reduced.

The optical converter 271 included in the baseband unit 270 converts the signal transmitted from the multiplexer 237 into an optical signal to transmit an optical cable.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the appended claims, but also by the equivalents of the claims.

1 is a view showing a receiver of a conventional FDD system;

2 is a diagram illustrating a receiving apparatus of an FDD system according to an exemplary embodiment of the present invention.

Claims (5)

In a receiver in a frequency division duplex (FDD) system, Detects a frequency allocation (FA) output from a neighboring base station, selects the FA having the lowest power among the detected FAs, and multiplexes the received FA and the received signal and the monitor signal based on the selected FA and the selected FA. A remote radio frequency (RF) unit for transmitting the multiplexed signal to the baseband unit; A processing unit for processing a signal received from a transmitter based on the selected FA, And the processing unit distributes the signal received from the transmitter into a received signal and a monitor signal, and processes the divided received signal and the monitor signal based on the selected FA. delete The method of claim 1, And each of the divided received and monitor signals are mixed and filtered at an oscillation frequency, and each of the filtered signals is mixed by an oscillation frequency output from the same oscillator. The receiving apparatus as claimed in claim 1, wherein the gains of the received signal and the monitor signal are divided by 9: 1. The receiver of claim 1, further comprising a baseband unit for converting the multiplexed signal into an optical signal.

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