KR20030072645A - Reference frequency oscillating apparatus for mobile communicating repeater - Google Patents

Abstract

PURPOSE: A device for oscillating a reference frequency of a mobile communication repeater is provided to generate a reference frequency by using received digital data, and to accord a reference frequency of a base station with a reference frequency and a phase of the repeater, thereby minimizing frequency deviations between the base station and the repeater. CONSTITUTION: A GPS receiver(370) comprises as follows. A GPS engine(371) performs changes of many satellite data electric waves and tolerance compensation, and extracts the first digital data. A D/A converter(373) converts the first digital data into an analog signal. A reference frequency oscillator(374) oscillates a reference frequency according to the analog signal. A divider(375) outputs the second digital data for dividing the reference frequency. A comparator(372) compares the first digital data with the second digital data, varies the analog signal to control the reference frequency, and supplies the controlled reference frequency to a forward signal processor(320) and a reverse signal processor(350).

Description

Reference frequency oscillator of mobile communication repeater {REFERENCE FREQUENCY OSCILLATING APPARATUS FOR MOBILE COMMUNICATING REPEATER}

The present invention relates to a reference frequency oscillation apparatus of a mobile communication repeater, and more particularly, to a reference frequency oscillation apparatus of a mobile communication repeater to minimize the frequency deviation between the base station and the repeater, the mobile station and the repeater.

In order to economically extend coverage in mobile communication networks such as PCS, cellular, and IMT-2000, various types of mobile communication repeaters (Radio Frequency) are widely used.

The mobile communication repeater receives the transmission signal of the base station through the base station facing antenna, amplifies the received signal and transmits the signal to the mobile station through the mobile station facing antenna.

In addition, the repeater receives a signal from the mobile station through the mobile station facing antenna, amplifies the received signal and transmits the signal to the base station through the base station facing antenna.

With reference to the accompanying drawings, a mobile communication repeater according to the prior art for performing the above operation.

1 is a schematic configuration diagram of a mobile communication relay system according to the prior art, and FIG. 2 is an internal configuration diagram of a mobile communication repeater according to the prior art.

Referring to FIG. 1, a mobile communication relay system according to the related art receives and receives signals from a base station 100, a mobile station 110 and a base station 100 or a mobile station 110 for wireless communication with a base station 100. The mobile communication repeater 120 amplifies and transmits the mobile station 110 or the base station 100.

Here, the mobile communication repeater 120 includes a base station facing antenna 122 and a mobile station facing antenna 124, and the base station facing antenna 122 and the mobile station facing antenna 124 are both transmit and receive antennas.

As shown in FIG. 2, the mobile communication repeater according to the related art includes a base station facing antenna 200, a first duplexer 210, a forward signal processor 220, a second duplexer 230, and a mobile station facing antenna 240. And a reverse signal processor 250.

Here, the base station facing antenna 200 and the mobile station facing antenna 240 are a transmitting and receiving antenna.

The base station facing antenna 200 of the mobile communication repeater receives a signal from a base station (not shown) by the first duplexer 210, and the forward signal processor 220 is connected to the reference frequency generated by the reference frequency oscillator 270. Accordingly, the received signal is output to the second duplexer 230 through filtering, frequency conversion, and amplification.

The second duplexer 230 transmits the signal whose transmission intensity is converted to the mobile station (not shown) through the mobile station counter antenna 240.

Meanwhile, the mobile communication repeater receives a signal from the mobile station through the mobile station counter antenna 240 by the second duplexer 230, and the reverse signal processor 250 receives the signal according to the reference frequency generated by the reference frequency oscillator 270. The processed signal is output to the first duplexer 210 through filtering, frequency conversion, and amplification.

The first duplexer 210 transmits a signal input from the reverse signal processor 250 to the base station through the base station facing antenna 200.

In the mobile communication repeater according to the prior art configured and operated as described above, the reference frequency oscillator 270 is implemented as a conventional frequency oscillator. ^It is required to be within ^-5 Hz (50 Hz for 850 MHz frequency).

However, a reference frequency deviation occurs between the reference frequency of the base station 100 generating the reference frequency according to the data provided from the plurality of satellites and the reference frequency of the repeater 120 generating the reference frequency in the conventional frequency oscillator. Due to this frequency deviation, the capacity of the base station 100 is reduced, which has a fatal effect on the quality of mobile communication. In severe cases, the base station 100 may be disturbed, and coverage of the mobile communication repeater may not be stably secured. There is this.

Accordingly, the present invention has been made to solve the problems of the prior art, the reference of the mobile communication repeater that can minimize the frequency deviation between the base station and the repeater by matching the reference frequency of the base station and the reference frequency and phase of the repeater The purpose is to provide a frequency oscillation device.

The present invention for achieving the above objects,

A mobile communication repeater comprising a forward signal processor for processing a forward signal transmitted to a base station through a base station facing antenna and a reverse signal processor for processing a reverse signal received from a mobile station through a mobile station facing antenna,

And a GPS receiver which generates a reference frequency according to a plurality of satellite data to match the reference frequency of the base station, and transmits the reference frequency to the forward signal processor and the reverse signal processor, respectively.

Here, the GPS receiver,

A GPS engine unit configured to extract first digital data by compensating for variation and tolerance of a plurality of satellite data waves received by a GPS receiver antenna;

A D / A converter converting the first digital data of the GPS engine unit into an analog signal;

A reference frequency oscillator for oscillating a reference frequency in accordance with an analog signal provided from the D / A converter;

A divider for outputting second digital data for dividing a reference frequency of the reference frequency oscillator;

Compare the second digital data of the frequency divider with the first digital data of the GS engine unit, and vary the analog signal output from the D / A converter according to a comparison result to control the reference frequency, and the controlled reference frequency. It includes a comparator for providing to the forward signal processor and the backward signal processor.

1 is a diagram showing the configuration of a general mobile communication relay system.

FIG. 2 is a diagram illustrating an internal configuration of the mobile communication repeater of FIG. 1.

3 is a view showing in detail the configuration of a mobile communication repeater according to the present invention.

<Description of the code for the main part>

300: base station opposed antenna 310: first duplexer

320: forward signal processor 321: first low noise amplifier

322: First RF / IF Converter 323: First SAW Filter

324: First IF / RF Converter 325: First RF Bandpass Filter

326: first high power amplifier 330: second duplexer

340: mobile station opposing antenna 350: reverse signal processing unit

351: second low noise amplifier 352: second RF / IF converter

353: second SAW filter 354: fourth IF / RF converter

355: second RF band pass filter 356: second high power amplifier

370: GPS receiver 371: GPS engine

372: comparator 373: D / A converter

374: reference frequency oscillator 375: divider

Hereinafter, a preferred embodiment of a reference frequency oscillation control apparatus of a mobile communication repeater according to the present invention will be described with reference to the accompanying drawings.

3 is a view showing in detail the configuration of a mobile communication repeater according to the present invention.

Referring to FIG. 3, the mobile communication repeater according to the present invention includes a base station facing antenna 300, a first duplexer 310, a forward signal processor 320, a second duplexer 330, a mobile station facing antenna 340, and a reverse direction. And a signal processor 350 and a GPS receiver 370.

Here, the base station facing antenna 300 and the mobile station facing antenna 340 are a transmitting and receiving antenna.

Here, the forward signal processor 320 may pass through the first low noise amplifier 321, the first RF / IF converter 322, the first SAW filter 323, the first IF / RF converter 324, and the first RF band pass. A filter 325, and a first high power amplifier 326.

The reverse signal processor 350 may include a second low noise amplifier 351, a second RF / IF converter 352, a second SAW filter 353, a second IF / RF converter 354, and a second RF band pass filter ( 355, and a second high power amplifier 356.

The base station facing antenna 300 of the mobile communication repeater receives a signal from a base station (not shown) by the first duplexer 310, and the first low noise amplifier 321 removes the unwanted wave in the signal received from the base station. Amplifying the signal, and appropriately converts the received intensity of the amplified signal and outputs it. The first RF / IF converter 322 intermediates the signal whose received intensity is converted according to the reference frequency provided from the GPS receiver 370 described later. Convert to frequency.

The process of oscillating a reference frequency in the GPS receiver 370 will be described.

The GPS engine unit 371 receiving the radio wave received by the GPS receiver antenna A compensates for the change and tolerance of multiple satellite data propagation, extracts first digital data, and receives the D / D received the first digital data. A converter 373 converts the first digital data into an analog signal. Here, the first digital data is 1 pulse per second (1PPS).

Then, the reference frequency oscillator 374 receiving the analog signal provided from the D / A converter 373 oscillates the reference frequency according to the analog signal. Here, the normal analog signal is a voltage of about 0-10V, the reference frequency is 10MHz.

The reference frequency of the reference frequency oscillator 374 is provided to the divider 375, and the divider 375 divides the reference frequency of 10 MHz into 10 ⁻⁷ to output second digital data of 1 PPS.

The second digital data of the divider 375 and the first digital data of the GPS engine unit 371 are provided to the comparator 372, and the comparator 372 is configured to provide the first digital data and the second data data. When the phases and the frequencies of the two digital data match each other, a first comparison signal is generated, and the D / A converter 375 receiving the first comparison signal generates an analog signal.

The analog signal of the D / A converter 375 is provided to the reference frequency oscillator 374, which receives the analog signal and oscillates the reference frequency according to the analog signal.

The oscillated reference frequency is provided to the first RF / IF converter 322 of the forward signal processor 320.

However, if the frequency and phase of these two digital data do not match, the comparator 372 outputs the second comparison signal, and the D / A converter 375 receiving the second comparison signal receives the first comparison signal. A reference frequency oscillator 374 generates an analog signal lower or higher than the analog signal, and receives the generated voltage to oscillate the reference frequency according to the analog signal.

The oscillated reference frequency is provided to the first RF / IF converter 322 of the forward signal processor 320.

The first SAW filter 323 filters the signal converted to the intermediate frequency to remove fine noise, and the first IF / RF converter 324 filters the signal filtered by the first SAW filter 325 to the GPS receiver. The frequency is converted back to an RF signal according to the reference frequency provided from 370.

The first RF band pass filter 325 filters the frequency-converted signal into an RF signal and then outputs the filtered signal to the first high output amplifier 326 in order to appropriately convert the transmission strength.

The first high power amplifier 326 amplifies the input signal to have a signal level for transmission through the mobile station facing antenna 340 and outputs the signal to the second duplexer 330.

The second duplexer 330 transmits the signal whose transmission intensity is converted to the mobile station (not shown) through the mobile station opposing antenna 340.

On the other hand, the mobile communication repeater receives a signal from the mobile station by the second duplexer 330 through the mobile station opposing antenna 340, and the second low noise amplifier 351 amplifies the signal which eliminates the unwanted wave in the signal received from the mobile station. In addition, the second RF / IF converter 354 converts the signal whose amplification and reception strength is converted into an intermediate frequency IF according to the reference frequency of the GPS receiver 370, and the second SAW filter 355. ) Filters the signal converted to the intermediate frequency to be removed within the unwanted region range excluding the signal bandwidth.

The second IF / RF converter 356 converts the filtered signal into an RF signal according to the reference frequency of the GPS receiver 370 and passes a second RF band that receives the frequency converted signal into the RF signal. The filter 355 filters the frequency-converted signal into an RF signal and then outputs it to the second high power amplifier 356 to appropriately convert the transmission strength.

The second high power amplifier 356 amplifies the signal input from the second RF band pass filter 355 to have a signal level for transmission through the base station counter antenna 300 and outputs the signal to the first duplexer 310. .

The first duplexer 310 transmits a signal input from the second high power amplifier 356 to the base station through the base station facing antenna 300.

In the exemplary embodiment of the present invention, the mobile communication repeater has been described as an example, but may also be applied to an optical repeater.

The reference frequency oscillation apparatus of the mobile communication repeater according to the present invention generates a reference frequency using digital data received from the GPS receiver to match the reference frequency of the base station and the reference frequency and phase of the repeater, thereby causing a frequency deviation between the base station and the repeater. Can be reduced to a minimum, so that the call quality of the repeater area can be improved.

While the invention has been shown and described with respect to specific preferred embodiments thereof, the invention is not limited to the embodiments described above, and is commonly used in the art to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Anyone with knowledge will be able to make various variations.

Claims (2)

A mobile communication repeater comprising a forward signal processor for processing a forward signal transmitted to a base station through a base station facing antenna and a reverse signal processor for processing a reverse signal received from a mobile station through a mobile station facing antenna, And a GPS receiver which generates a reference frequency according to a plurality of satellite data to match the reference frequency of the base station, and transmits the reference frequency to the forward signal processor and the reverse signal processor, respectively. Reference frequency oscillator. The method of claim 1, wherein the GPS receiver A GPS engine unit configured to extract first digital data by compensating for variation and tolerance of a plurality of satellite data waves received by a GPS receiver antenna; A D / A converter converting the first digital data of the GPS engine unit into an analog signal; A reference frequency oscillator for oscillating a reference frequency in accordance with an analog signal provided from the D / A converter; A divider for outputting second digital data for dividing a reference frequency of the reference frequency oscillator; And Compare the second digital data of the frequency divider with the first digital data of the GS engine unit, and vary the analog signal output from the D / A converter according to a comparison result to control the reference frequency, and the controlled reference frequency. The reference frequency oscillator of the mobile communication repeater comprising a comparator for providing the forward signal processor and the reverse signal processor.