KR100438177B1 - Apparatus and Method for processing signal of Access-point - Google Patents

Abstract

The present invention includes a front end unit for receiving a plurality of frequency signals through an antenna and separating each frequency band, a frequency processing unit for converting each frequency signal transmitted separately from the front end unit into an IF signal, and a plurality of units converted in the frequency processing unit. Combining unit for combining the frequency signal of, characterized in that consisting of an optical transmitter for converting and transmitting the frequency signal coupled in the combining unit to an optical signal.

According to the present invention, the frequency signal is separated by each frequency signal, each frequency signal is converted to IF before converting each frequency signal into an optical signal, and then selectively amplified and converted back into a frequency signal, and then combined into an optical signal. Through the process, the frequency signal is converted into an optical signal as it is, and the effect of minimizing the loss and noise generated in the process of converting the optical signal into the frequency signal is expected to be maximized.

Description

Apparatus and Method for processing signal of Access-point

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a frequency receiver of a smart access point (hereinafter referred to as S-AP) of high data rate (HDR), and in particular, an optical signal of a frequency signal (FA) received at the S-AP. A signal processing apparatus and method for an access point that down-converts a frequency signal (FA) to an IF, up-converts it again through an automatic gain control block, and converts and converts it into an optical signal so as to reduce loss and noise generated during the luxury process. will be.

HDR is Qualcomm's newly developed technology for high-speed wireless data service, which has succeeded in the generalization of CDMA IS-95 technology and the rapid confidence of CDMA technology worldwide.

HDR can utilize a data rate of up to 2.547Mbps using an existing IS-95 network, and has the advantage of providing a new high-speed data service without incurring a large cost in network construction.

That is, an access point (AP) serving as a base station for communicating with a wireless terminal in the HDR system is used together with a base station of an existing IS-95 system, and the AP is connected to a router to charge and Network configuration is possible by connecting with operator network for user authentication and data service.

The AP supports up to three sectors in one frequency signal (FA) and shares the antenna because it has the same RF characteristics as the IS-95 and occupies a small space. It can be installed in.

In particular, the S-AP according to the present invention uses a method of converting a frequency signal FA received through an antenna into an optical signal and transmitting it through an optical cable.

1 is a block diagram showing the structure of a conventional HDR smart access point.

Referring to FIG. 1, the S-AP includes a duplexer 11a for transmitting and receiving a frequency signal FA through an antenna, a front-end unit 11 including a low noise amplifier 12b, and the antenna. RU (RF Unit) 10 including a first optical transceiver 12 for converting a plurality of frequency signals FA received through the optical signal to transmit and receive, and an optical signal connected to the RU 10 by an optical cable A second optical transceiver 21 for transmission and reception, a frequency up / down converter 22 for converting the frequency signal FA received from the second optical transceiver 21 up / down and transmitted, and the received signal are changed. And a digital unit (DU) 20 comprising a modem channel card 23 for demodulation.

In the S-AP configured as described above, when the frequency signal FA is received through the front end unit 11, the first optical transceiver 12 converts the frequency signal FA into an optical signal to convert the optical cable. Transmit to DU 20 via.

When the DU 20 receives the optical signal through the optical cable at the second optical transceiver 21 and converts the optical signal back into the frequency signal FA, the DU 20 transmits the frequency signal FA at the frequency up / down converter 22. Downconverts to IF and transmits the final baseband signal (I, Q).

The final baseband signal is finally input to the modem channel card 23 and demodulated.

As described above, in the conventional S-AP, the received frequency signal FA is converted into an optical signal, transmitted to the DU, and then a final baseband signal is demodulated.

However, as described above, the process of converting the frequency signal FA into an optical signal in the RU and converting the optical signal into the frequency signal FA in the DU again may cause excessive loss and noise. There is a problem that the reception sensitivity is lowered due to the exponential performance.

In addition, when a low noise amplifier is additionally used to solve the problem of deterioration of reception sensitivity, excessive gain and IP3 (third order intercept point), that is, the output power of the original signal and the third-order intermodulation distortion (IMD) Due to the performance limitation of the point that the output power of the signal is the same, the dynamic range is reduced compared to the existing system, and the performance may be lowered than the system without the light.

In order to solve the above problems, the present invention down-converts the received frequency signal FA separately, and converts the optical signal into an optical signal through automatic gain control, and transmits the frequency signal FA to the optical signal as it is. It is expected to reduce the loss and noise in the process of converting the signal into a frequency signal and converting the frequency signal into a frequency signal, and to reduce the reception dynamic range problem and the interference between different channels to achieve more stable reception performance.

1 is a block diagram showing the structure of a conventional HDR smart access point.

2 is a block diagram illustrating a configuration of a signal processing apparatus of an access point according to an exemplary embodiment of the present invention.

3 is a block diagram illustrating a configuration of a frequency down converter of FIG. 2;

4 is a block diagram showing the configuration of the AGC of FIG.

5 is a block diagram illustrating a configuration of the frequency up-conversion unit of FIG. 2.

6 is a block diagram illustrating a configuration of a local frequency generator of FIG. 2.

A signal processing apparatus of an access point according to the present invention includes an access point signal processing apparatus for transmitting a frequency signal received through an antenna through an optical cable, comprising: a front end unit for separating the received frequency signal by frequency bands; A frequency processing unit for converting each frequency signal separated at the front end into an IF signal, a coupling unit coupling a plurality of frequency signals converted in the frequency processing unit, and converting the frequency signal combined at the combining unit into an optical signal to convert the optical cable. It characterized in that it comprises a light transmitter for transmitting through.

Preferably, the frequency processing unit,

A frequency down converter for converting each frequency into an IF;

An automatic gain control unit configured to receive the converted IF and selectively amplify only a required channel;

And a frequency up converter for converting the IF signal amplified by the automatic gain control unit back into a frequency signal.

Preferably, the frequency processing unit,

To the frequency downconverter and the frequency upconverter

It further comprises a local frequency generator for supplying the same local frequency.

Preferably, when IF frequency separation is possible for each frequency,

According to another aspect of the present invention, in the signal processing apparatus of the access point, through the antenna, all the down-converted frequency signal is combined in the splitter and converted into an optical signal without passing through the frequency upconverter. And a radio frequency processing module for separating the received frequency signal into frequency bands and converting the received frequency signal into an IF signal, and converting the received frequency signal into an optical signal, and a digital processing module for demodulating the optical signal input from the radio frequency processing module. According to still another aspect of the present invention, a module for converting an optical signal into a different signal when a frequency signal is received through an antenna, the separation means for separating the received frequency signal by frequency band, in the separation means Frequency downconverting means for converting each separated frequency signal into an IF signal And combining means for combining the down-converted IF signals, and transmitting means for converting the combined signal from the combining means into an optical signal and transmitting the optical signal. According to another aspect of the present invention, there is provided an antenna including: A signal processing method of an access point for transmitting a frequency signal received through an optical cable, the method comprising: separating the received frequency signal by frequency band, converting each of the separated frequency signals into IF signals And converting the combined signal into an optical signal and transmitting the converted signal. The converting and combining the separated frequency signals into IF signals, respectively, converting the separated frequency signals into IF signals, respectively. After conversion, select and amplify only the necessary channels, and convert each of the amplified IF signals back to a frequency signal. It binds.

Referring to the accompanying drawings, a shearing apparatus for an HDR smart access point using a down-converter for each frequency according to the present invention configured as described above is as follows.

2 is a block diagram illustrating a configuration of a signal processing apparatus of an access point according to an exemplary embodiment of the present invention.

Referring to FIG. 2, a signal processing apparatus of an access point receives a front end portion 10 for receiving all frequency signals FA through an antenna and separates each frequency band, and each frequency separated by the front end portion 100. A plurality of frequency processing units 200 for receiving a signal FA and performing operations for improving reception performance for each frequency, and each frequency signal FA for performing an operation for improving reception performance in the frequency processing unit 200. ) And an optical transmitter 400 for converting the frequency signal FA coupled by the coupling unit 300 into an optical signal and transmitting the optical signal to the digital unit.

In detail, the front end portion 10 includes a duplexer 110 for transmitting and receiving a frequency signal FA and a low noise amplifier (LNA) for low noise amplifying the frequency signal FA received from the duplexer 110. And a splitter 1 (130) for separating the frequency signal FA into bands in the total received bands.

According to an exemplary embodiment of the present invention, if the frequency signal 1 (FA1) and the frequency signal 2 (FA2) are used in HDR, the splitter 1 (130) is the frequency signal 1 (FA1) and all of the received frequency signal (FA) The frequency signal 2 FA2 is separated.

In addition, the frequency processing unit 200 is a block for adjusting gain for improving reception performance for each frequency before converting the received frequency signal FA into an optical signal, and the frequency separated from the splitter 1 130. Processing is performed in each block according to the signal 1 FA1 or the frequency signal 2 FA2.

That is, in the case of the frequency signal 1 (FA1) processing unit, the frequency down converter 210 for receiving and converting the frequency signal 1 (FA1) separated from the splitter 1 (130) into an IF signal, and the converted IF signal The AGC (automatic gain control block) 220 for selectively amplifying only the frequency signal 1 (FA1) channel and the signal selectively amplified through the AGC 220 are again converted into the frequency signal 1 (FA1). And a local frequency generator 240 for providing the same local frequency to the frequency down converter 210 and the frequency up-converter 230. .

The frequency processor 200 configured as described above receives each frequency and converts the frequency signal FA into IF using the local frequency received from the local frequency generator 240 by the frequency downconversion unit 210 and transmits the IF. And selectively amplifies only a desired channel in the AGC 220 and converts the IF amplified by the frequency up-conversion unit 230 into a frequency signal FA using a local frequency input from the local frequency generator 240. To transmit.

The transmitted frequency signal FA is again combined by the combiner 300 and converted into an optical signal by the optical transmitter 400 and then transmitted to the DU.

Each block of the frequency processor will be described in detail with reference to the accompanying drawings, for example, processing of the frequency signal 1 FA1 as follows.

3 is a block diagram illustrating a configuration of the frequency downconverter of FIG. 2, FIG. 4 is a block diagram illustrating the configuration of the AGC of FIG. 2, and FIG. 5 is a block diagram illustrating a configuration of the frequency upconverter of FIG. 2. 6 is a block diagram showing the configuration of the local frequency generator of FIG.

Referring to FIG. 3, the frequency downconverter 210 receives a frequency signal 1 FA1 separated from the splitter 1 130 of the front end 100 and converts it into an IF signal. 211, an amplifier 1 212 for amplifying the IF signal converted by the frequency down converter 211, and a surface acoustic wave filter (SAW) for filtering the signal amplified by the amplifier 1 212. 213).

After the filtering, the IF signal is selectively amplified by the AGC 220. Referring to FIG. 4, the AGC 220 is amplified by the amplifier 2 222 through the attenuator 221. When the channel is selected by the selector 224 for selecting a desired channel, the signal of the selected channel is transmitted to the attenuator 221 through the integrator 225 again. Selectively amplified and output.

The IF signal that has passed through the AGC 220 passes through a frequency up-conversion unit 230 to convert it back into a frequency signal 1 FA1. Referring to FIG. 5, the IF signal transmitted from the AGC 220 has a frequency. A frequency upconverter 231 for converting to a signal FA1 and a band pass filter 232 for filtering the signal converted in the frequency upconverter 231 It is to be output through the amplifier 3 (233) again.

In this case, since the local frequency supplied to the frequency down-converter 210 and the frequency up-converter 230 is the same, the signal input to the frequency down-converter 210 and the frequency up-convert even if the frequency offset is changed to some extent. The signal output from the converter 230 is the same and can operate regardless of frequency synchronization.

Referring to FIG. 6, the local frequency generator 240 generating the local frequency, the splitter 3 242 generates the local frequency generated by the local frequency PLL 241. The dividing is provided through the amplifier 4 243 and the amplifier 5 244 to the frequency down converter 210 and the frequency up converter 230, respectively.

As described above, the frequency signal 1 FA1 output from the frequency up-converter is combined with the other frequency signal 2 FA2 in the combiner 300 and transmitted to the optical transmitter 400, and finally converted into an optical signal. It is then sent to the DU.

On the other hand, if it is possible to separate the IF signal by the frequency to separate the IF (FA1_IF) of the frequency signal 1 and IF (FA2_IF) of the frequency signal 2, the frequency up-conversion unit 230 is removed, and removes the IF signal Even if the optical transceiver 400 is converted into an optical signal can operate without a problem.

As described above, the frequency signal FA is separated for each frequency, and each frequency signal FA is converted to IF before conversion to an optical signal, and then selectively amplified and converted back to a frequency signal FA, and combined. Through the process of combining into an optical signal, the frequency signal FA is converted into an optical signal as it is, and the effect of reducing the loss and noise generated in the process of converting the optical signal to the frequency signal FA again.

In addition, the present invention has the effect of ensuring the cell coverage and channel capacity with excellent performance compared to other base stations that do not use the light by reducing the receiving dynamic range and other channel interference to achieve a more stable reception performance have.

As described above, according to the present invention, the received frequency signal FA is separately down-converted separately, converted into an optical signal through automatic gain control, and transmitted to the DU, thereby converting the frequency signal FA into an optical signal as it is. And the signal processing device and method of the access point to reduce the loss and noise generated in the process of converting back to the frequency signal (FA), and to reduce the reception dynamic range problem and interference between different channels for more stable reception performance Can provide.

Claims (8)

A signal processing apparatus of an access point for transmitting a frequency signal received through an antenna through an optical cable, A front end part separating the received frequency signal for each frequency band; A frequency processor converting each frequency signal separated at the front end into an IF signal; A combiner for combining a plurality of frequency signals converted by the frequency processor; An optical transmitter for converting the frequency signal coupled by the coupling unit to an optical signal for transmission through the optical cable Signal processing apparatus of the access point comprising a. The method of claim 1, wherein the frequency processing unit, A frequency down converter for converting the separated frequency signals into IF signals; An automatic gain control unit for selectively amplifying only a channel required for the IF signal converted by the frequency down converter; A frequency upconverter converting the gain-adjusted IF signal back into a frequency signal by the automatic gain control unit; And a local frequency generator for supplying the same local frequency to the frequency downconverter and the frequency upconverter. The method of claim 1, wherein IF frequency separation for each frequency is possible, And all down-converted frequency signals are combined in the combiner and converted into optical signals without passing through the frequency upconverter. In the signal processing apparatus of the access point, A radio frequency processing module for dividing a frequency signal received through an antenna into frequency signals by converting the frequency signals into frequency signals and then converting the frequency signals into optical signals; Digital processing module for demodulating the optical signal input from the radio frequency processing module Signal processing apparatus of the access point comprising a. In the module for receiving a frequency signal through an antenna converts to an optical signal and transmits to another module, Separating means for separating the received frequency signal for each frequency band; Frequency downconverting means for converting each frequency signal separated by the separating means into an IF signal, respectively; Combining means for combining each down-converted IF signal; and Transmitting means for converting the combined signal in the combining means into an optical signal for transmission Radio frequency processing module of the access point comprising a. The method of claim 5, Automatic gain adjusting means for selectively amplifying only a channel required for the IF signal converted by the frequency downconverting means; Frequency up-converting means for converting the gain-adjusted IF signal into a plurality of frequency signals by the automatic gain adjusting means; And a local frequency generating means for supplying the same local frequency to the frequency downconverting means and the frequency upconverting means. A signal processing method of an access point for transmitting a frequency signal received through an antenna through an optical cable, Dividing the received frequency signal by frequency band; Converting each of the separated frequency signals into IF signals and combining them; and Converting the combined signal into an optical signal and transmitting the optical signal Signal processing method of the access point comprising a. The method of claim 7, wherein And converting the separated frequency signals into IF signals, respectively, Converting each of the separated frequency signals into IF signals, and then selectively amplifying only necessary channels; And converting each of the amplified IF signals back into a frequency signal and combining the amplified signals.