KR100427701B1 - Optic repeater of digital type - Google Patents

Abstract

A digital optical repeater is disclosed in which an optical repeater installed in a base station constituting a mobile communication network and a radio shadowing area converts an analog intermediate frequency signal into a digital signal through an optical path and transmits and receives each other. The RF signal, which is an analog signal applied from the base station to the forward master part of the master part, is converted into an intermediate frequency signal and then converted into a digital signal and transmitted to the slave part through an optical path along with the NMS signal, which is a control signal, and the slave slave part forward slave. The part converts the digital signal into an analog signal and then converts it into an RF signal and transmits it to the mobile terminal so that the mobile terminal can receive a clean signal without noise.In contrast, the RF signal, which is an analog signal applied to the reverse slave unit of the slave unit from the mobile terminal, The signal is also converted into an intermediate frequency signal and transmitted to the master unit through the optical path along with the NMS signal, which is a control signal, and the reverse master unit of the master unit converts the digital signal into an analog signal and then converts it into an RF signal and transmits it to the base station. Can be performed. In addition, the configuration of the optical repeater is simplified by transmitting and receiving the NMS signal for controlling the operation of the slave unit with the digital signal without a separate device.

Description

Digital repeater of digital type

The present invention relates to an optical repeater of a mobile communication network, and more particularly, a base station constituting a mobile communication network and an optical repeater installed in a radio shadowing area can convert an intermediate frequency signal, which is analog, through a optical path into a digital signal and transmit and receive each other. Digital optical repeater.

In general, a wireless line control station constituting a mobile communication network functions to determine which base station is closest to the mobile terminal, and to determine which frequency the base station communicates with the mobile terminal. In order to expand the communication area, a plurality of base stations are installed. Accordingly, the mobile terminals belonging to one of the base stations transmit and receive signals to and from the base station of the corresponding area. When the base station is a long distance or a radio shading area, the base station does not perform smooth transmission and reception with the mobile terminal. There is a ham.

Therefore, in the related art, many base stations are installed in various places to remove the radio shade area or install an optical repeater separately in the radio shade area in which the base station cannot be installed so that the mobile terminal can communicate smoothly with the base station through the optical repeater. In this case, an optical repeater is installed in each of the base station and the radio shading area, and a second optical repeater installed in the radio shading area and the first optical repeater installed in the vicinity of the base station are connected to each other through an optical path and connected to each other through an optical path. Send and receive. That is, the base station receives the RF signal, which is an analog signal, from the first optical repeater, amplifies the signal, and transmits the signal to the second optical repeater in the radio shade region through the optical path. The second optical repeater amplifies an RF signal having a reduced signal size in an optical path and transmits the RF signal to a mobile terminal. On the contrary, the second optical repeater amplifies the RF signal and transmits the RF signal to the first optical repeater through the optical path, and the first optical repeater amplifies the RF signal whose signal size is reduced in the optical path and applies it to the base station. The mobile station can communicate by transmitting the RF signal applied from the first optical repeater to the radio line base station.

The first optical repeater installed in the vicinity of the base station and the second optical repeater installed in the radio shade area are connected to each other via a light path to transmit and receive signals, the RF signal transmitted and received by the first optical repeater and the second optical repeater Since is an analog signal, since the magnitude of the signal is greatly reduced in the process of transmitting through the optical path, each of the first optical repeater and the second optical repeater is provided with a signal amplifier for amplifying the RF signal. However, since the noise is present in the RF signal amplified by the signal amplifier, the noise is also amplified together when amplifying the RF signal in the signal amplifier.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to maximize the transmission efficiency of the signal by converting the intermediate frequency signal, which is an analog signal, into an analog signal and transmitting and receiving each other through an optical path. To provide a digital optical repeater to enable.

1 is a view showing the installation structure of a general optical repeater.

2 is a view schematically showing a forward master part constituting a master part according to the present invention.

3 is a view schematically showing a forward slave unit constituting a slave unit according to the present invention.

4 is a view schematically showing a reverse slave unit constituting a slave unit according to the present invention.

5 is a view schematically showing a reverse master unit constituting a master unit according to the present invention.

<Description of reference numerals for main parts of the drawings>

20: master unit 30: slave unit

100: forward master portion 200: forward slave portion

300: reverse slave unit 400: reverse master unit

In order to achieve the above object, the present invention is an optical repeater comprising a master unit for transmitting and receiving a signal through a base station and an RF cable, and a slave unit for transmitting and receiving a signal transmitted and received from the master unit through an optical path, The master unit converts an RF signal, which is an analog signal applied from a base station, into an intermediate frequency signal, converts the digital signal into a digital signal, and transmits the digital signal to the slave side through the optical path, and the digital signal applied from the slave side through the optical path as an analog signal. A second means for converting an RF signal into a base station and converting the digital signal, which is an intermediate frequency signal applied through an optical path, into an analog signal, and then converting and amplifying the RF signal into an RF signal and transmitting the RF signal to a mobile terminal. Means and analogue received from the mobile terminal Sport then converts the RF signal into an intermediate frequency signal to convert it back into a digital signal and provides a digital optical repeater, it characterized in that it has a fourth means for sending a master part via the optical line.

The first means may include means for including the NMS signal applied from the first controller in the digital signal and transmitting the signal to the slave unit through the optical path.

The second means may include means for separating the NMS signal from the digital signal applied from the slave unit and applying it to the first control unit.

The third means may include means for separating the NMS signal from the digital signal applied from the master unit side and applying the NMS signal to the second control unit.

In addition, the fourth means may include means for transmitting the digital signal to the master unit via the optical path including the NMS signal applied from the second control unit.

In addition, the master unit comprises a forward master unit performing the first means, a reverse master unit performing the second means, the slave unit is a forward slave unit performing the third means, and a reverse slave unit performing the fourth means. It is characterized by consisting of wealth.

Hereinafter, a preferred embodiment of the digital optical repeater according to the present invention will be described with reference to the accompanying drawings.

1 is a view showing the installation structure of a general optical repeater, Figure 2 is a view showing a forward master part constituting a master unit according to the present invention, Figure 3 is a schematic view of a forward slave unit constituting a slave unit according to the present invention 4 is a diagram schematically illustrating a reverse slave unit constituting a slave unit according to the present invention, and FIG. 5 is a diagram schematically illustrating a reverse master unit constituting a master unit according to the present invention.

In the drawings, reference numerals 208, 304, and 402 denote oscillators.

Hereinafter, the present invention will be described with reference to FIGS. 1 to 5.

First, the RF signal applied to the forward master unit 100 of the master unit 20 constituting the optical repeater 1 from the base station 10 through the RF cable is converted into an intermediate frequency signal close to DC by the first means. And then mixed with the NMS signal applied from the first control unit 107 and applied to the forward slave unit 200 through the optical path, and the forward slave unit 200 is included in the intermediate frequency signal by the third means. The signal is separated and applied to the second control unit 204, and the digital signal is converted into an intermediate frequency signal, which is an analog signal, and then the intermediate frequency signal is converted into an RF signal and transmitted to the mobile terminal 40.

That is, the forward master unit 100 of the master unit 20 constituting the optical repeater 1 converts an RF signal, which is an analog signal applied from the base station 10, into an intermediate frequency signal, and then converts the signal into a digital signal. The first means for transmitting to the slave unit 30 side through the furnace 50 is performed.

Referring to FIG. 2, the forward master unit 100 receives an RF signal applied from the base station 10 through the RF cable 60, the first bidirectional filter 101, and the amplifier 102. RF which is connected to the first divider 103 and the output terminal of the first divider 103, respectively, which are divided and outputted according to a set number (eg, four) of various frequencies, and are applied from the first divider 103 A first mixer 120 for generating an intermediate frequency signal by mixing a signal and an oscillation frequency applied from the first local unit 110, and a first band pass filter from the first mixer 120. The second mixer unit generating an intermediate frequency signal close to DC by mixing the intermediate frequency signal applied through the BPF) unit 130 and the first amplifier 140 with the oscillation frequency applied from the second local unit 105. And a second band pass filter 160 and a second amplifying unit 170 from the second mixer 150. A first A / D converter 180 for converting an intermediate frequency signal, which is a analog signal, into a digital signal, and all the digital signals and the first controller applied from the first A / D converter 180. A first mux for mixing the NMS signal applied from the 107 and outputting the serial data signal to the forward slave unit 200 side of the slave unit 30 through the first optical conversion unit 190 and the optical path 50 ( 104).

In more detail, the first divider 103 distributes an 800 MHz or 1800 MHz RF signal according to an allocated frequency. For example, if a frequency band of 10 MHz is allocated, 4 FAs are arbitrarily selected when 4FA is used among 8FAs (where 1FA is set to 1.23 MHz) that can be set at 10 MHz (e.g., 801.23, 803.69, 806.15, and 808.61 MHz). To distribute the output. Four mixers 122, 124, 126, and 128 of the first mixer 120 are connected to four output terminals outputting 801.23, 803.69, 806.15, and 808.61 MHz, respectively, and a first local part is connected to the first mixer 120. Four locals 112, 114, 116, 118 of 110 are connected respectively. The first mixer 120 should output an intermediate frequency signal (for example, 70 MHz) of the same magnitude, but since the magnitudes of the RF signals applied to the mixers 122, 124, 126, and 128 from the first divider 103 are different. The oscillation frequencies applied from one local unit 110 to each mixer of the first mixer unit 120 are also different.

Therefore, each mixer of the first mixer unit 120 mixes an RF signal applied from the first divider 103 and an oscillation frequency applied from each local of the first local unit 110 so as to have an intermediate frequency signal of the same magnitude. (Eg, 70 MHz) The first band pass filter unit 130 filters only a corresponding frequency band among intermediate frequency signals applied from the first mixer unit 120, and thus, each of the second mixer unit 150 through the first amplifier unit 140. To the mixers 152, 154, 156, and 158.

Each mixer of the second mixer unit 150 mixes an intermediate frequency signal applied from the first mixer unit 120 and an oscillation frequency of the same magnitude applied from the second local unit 105 to obtain the same intermediate frequency close to DC. The signal is applied to the first A / D converter unit 180. For example, when 70 MHz is applied to the second mixer unit 150, the second local unit 105 applies an oscillation frequency of 68.77 MHz or 68.5 MHz to each mixer of the second mixer unit 150. Each mixer of the two mixers 150 outputs an intermediate frequency signal of 1.23 MHz or 1.5 MHz and applies it to the first A / D converter unit 180.

The first A / D converter unit 180 converts an intermediate frequency signal, which is an analog signal of 1.23 MHz or 1.5 MHz, into a 12-bit digital signal and applies it to the first mux 104, and the first mux 104. Is a 52-bit serial data signal obtained by muxing digital signals applied from four A / D converters 182, 184, 186 and 188 and NMS signals applied from the first control unit 107 through four output stages. Each of the optical converters 192, 194, 196, and 198 of the 190 is output. The 52-bit serial data signals respectively outputted through the four output terminals of the first mux 104 are converted into optical signals by respective optical modulators, and the forward slave unit of the slave unit 30 through the optical path 50 ( 200).

The first local unit 110 and the second local unit 105 convert the oscillation frequency applied from the oscillator 106 to correspond to each mixer and the second mixer 150 of the first mixer 120, respectively. Apply the oscillation frequency.

In addition, the forward slave unit 200 of the slave unit 30 constituting the optical repeater 1 converts the digital signal applied from the master unit 20 side through the optical path 50 into an intermediate frequency signal which is an analog signal. After the conversion, the third means converts the RF signal and transmits the converted RF signal to the mobile terminal 40.

The third means will be described with reference to FIG. 3, and the forward slave unit 200 receives the serial data signal applied through the optical path 50 and the second light conversion unit 201 from the forward master unit 100 side. A second demux unit 202 and a digital signal of different frequency bands applied from the second demux unit 202 are demultiplexed and converted into parallel data signals and separated and output at different frequencies through the output port. A second D / A converter 210 for converting an analog signal, and an intermediate signal of 1.23 MHz or 1.5 MHz, which is an analog signal applied from the second D / A converter 210 through the sixth amplifier 220. A fifth mixer 230 for mixing an oscillation frequency applied from the fifth local unit 206 to output an intermediate frequency signal of 70 MHz, and a second saw filter unit from the fifth mixer 230. The intermediate frequency signal applied through the 240 and the seventh amplifier 250 to the sixth local unit 270. The sixth mixer 260 for generating an RF signal by mixing with the oscillation frequency applied from the RF signal, and the RF signals of four different frequency bands applied from the sixth mixer 260 through the eighth amplifier 280. The second combiner 290 transmits to the mobile terminal 40 through the second power amplifier 292 and the second two-way filter 294.

In more detail, the second demux unit 202 demuxes the 52-bit serial data signal applied from the second light conversion unit 201 and converts it into a parallel data signal to convert the 12-bit intermediate frequency signal to 4. It is applied to the second D / A converter 210 through two output ports. At this time, since the 52-bit serial data signal includes the NMS signal, it is demuxed by the second demux unit 202 and applied to the second control unit 204.

The second D / A converter 210 is provided with four D / A converters 212, 214, 216, and 218, and is connected one to one to four output ports provided in the second demux 202, respectively. The second D / A converter 210 converts a 12-bit digital signal into an intermediate frequency signal, which is an analog signal (1.23 or 1.5 MHz), to the fifth mixer 230 through the sixth amplifier 220. Is authorized.

The fifth mixer 230 includes four mixers 232, 234, 236, and 238, respectively, and is connected one to one to four D / A converters of the second D / A converter 210, respectively, and at the same time, the fifth local unit 206. ) Is connected. The fifth local unit 206 generates the same oscillation frequency (68.77 MHz or 68.5 MHz) and simultaneously applies them to each mixer of the fifth mixer 230. Each mixer of the fifth mixer 230 mixes an intermediate frequency signal applied from the second D / A converter unit 210 and an oscillation frequency applied from the fifth local unit 206 to generate an intermediate frequency signal of 70 MHz. Will print

Each mixer of the fifth mixer 230 applies a 70 MHz intermediate frequency signal to the sixth mixer 260 through the second saw filter unit 240 and the seventh amplifier 250. The sixth mixer 260 is composed of four mixers 262, 264, 266, and 268, and sixth local units 270 that generate different oscillation frequencies are connected to the mixers. Each of the locals 272, 274, 276 and 278 constituting the sixth local unit 270 outputs different oscillation frequencies and applies them to the mixers of the sixth mixer 260.

Each mixer of the sixth mixer 260 has a 70 MHz intermediate frequency signal applied from the fifth mixer 230 and a different oscillation frequency (730 to 740 MHz) applied from the sixth local unit 270. By mixing, the RF signals of different frequency bands are output. That is, the four RF signals output from the mixers of the sixth mixer 260 are in different frequency bands (801.23, 803.69, 806.15, and 808.61 MHz). Four RF signals output from the sixth mixer 260 are applied to the second combiner 290 through an eighth amplifier 280, and the second combiner 290 is a sixth mixer. After combining RF signals of different frequency bands applied from the four mixers constituting the unit 260, the second power amplifier 292 amplifies the magnitude and the level to the mobile terminal 40 through the second two-way filter 294. By transmitting, the mobile terminal 40 smoothly receives the RF signal generated from the base station 10 through the optical repeater. In this case, the second power amplifier 292 greatly amplifies the magnitude of the RF signal applied from the second combiner 290.

On the contrary, the RF signal applied to the reverse slave unit 300 of the slave unit 30 from the mobile terminal 40 through the antenna is converted into an intermediate frequency signal close to DC by the fourth means and then the second control unit 204. It is mixed with the NMS signal applied from the light source and applied to the reverse master unit 400 through the optical path, and the reverse master unit 400 separates the NMS signal included in the intermediate frequency signal by the second means. 107), the digital signal is converted into an intermediate frequency signal, which is an analog signal, and then the intermediate frequency signal is converted into an RF signal and transmitted to the base station 10 through the RF cable.

That is, the reverse slave unit 300 of the slave unit 30 constituting the optical repeater 1 is a digital signal to the RF de-signal, which is an analog signal applied from the mobile terminal 40 through the third two-way filter 301. The fourth means for converting to the master unit 20 to be transmitted to.

Referring to FIG. 4, the fourth slave unit 300 allocates an RF signal applied from the mobile terminal 40 through the third two-way filter 301 and the amplifier 302 to the assigned frequency band. A second divider 303 distributed through each output port and a plurality of mixers connected to each output port of the second divider 303, and applied from the second divider 303. A seventh mixer 310 to generate an intermediate frequency signal of the same magnitude by mixing a signal and different oscillation frequencies applied from respective localities of the seventh local unit 320 and the seventh mixer 310 from the seventh mixer 310. The intermediate frequency signal applied through the three-band pass filter unit 330 and the ninth amplifier 340 is mixed with the same oscillation frequency applied from the eighth local unit 305 to generate an intermediate frequency signal close to DC. To the eighth mixer 350 and the eighth mixer 350. A second A / D converter unit 380 for converting an intermediate frequency signal, which is an analog signal applied through the fourth band pass filter unit 360 and the tenth amplifier unit 370, into a digital signal, and the second All the digital signals applied from the A / D converter unit 380 and the NMS signals applied from the second control unit 204 are muxed as serial data signals to decode each third optical conversion unit 308 and the optical path 50. It consists of a second mux 307 to output to the reverse master 400 side.

In more detail, the second divider 303 distributes an 800 MHz or 1800 MHz RF signal to the allocated frequency bands 801.23, 803.69, 806.15, and 808.61 MHz (the first divider of the forward master unit 100). 103) and output through 4 output ports.

Four mixers 312, 314, 316, and 318 of the seventh mixer 310 are connected to four output ports for outputting the 801.23, 803.69, 806.15, and 808.61 MHz, respectively, and a seventh local portion to the seventh mixer 310. Four locals 322, 324, 326 and 328 of 320 are connected respectively. Each mixer of the seventh mixer 310 outputs four identical intermediate frequency signals (for example, 70 MHz) by mixing RF signals of different frequency bands with different oscillation frequencies from each local of the seventh local unit 320. Done.

Four intermediate frequency signals output from the mixers of the seventh mixer 310 are applied to the eighth mixer 350 through the third band pass filter 330 and the ninth amplifier 340. The four mixers 352, 354, 356 and 358 of the eighth mixer unit 350 are respectively supplied with an oscillation frequency (68.77 MHz or 68.5 MHz) from the eighth local unit 305, and the four mixers of the eighth mixer unit 350. Outputs an intermediate frequency signal (1.23 MHz or 1.5 MHz) close to DC by mixing an intermediate frequency signal (70 MHz) and an oscillation frequency (68.77 MHz or 68.5 MHz), respectively. The intermediate frequency signal output from the eighth mixer 350 is four A / Ds of the second A / D converter 380 through the fourth band pass filter 360 and the tenth amplifier 370. To converters 382, 384, 386, 388.

The second A / D converter 380 converts an intermediate frequency signal, which is an analog signal, into a digital signal and applies it to the second mux 307. The second mux 307 muxes four intermediate frequency signals, which are digital signals applied from the second A / D converter unit 380, and NMS signals applied from the second control unit 204, as serial data signals. The serial data signal of the bit is applied to the third light conversion unit 308. The third optical conversion unit 308 converts a 52-bit serial data signal into an optical signal and transmits the optical signal to the reverse master unit 400 of the master unit 20 through an optical path.

In addition, the reverse master unit 400 of the master unit 20 converts the digital signal applied from the slave unit 30 side through the optical path 50 into an intermediate frequency signal, which is an analog signal, and then converts it into an RF signal. The second means for transmitting to the base station 10 is performed.

Referring to FIG. 5, the second master unit 400 includes a demux connected to each of the optical paths 50 and the fourth light conversion unit 410, and each slave unit 30. A first demux unit 420 for demuxing the serial data signals applied from the &lt; RTI ID = 0.0 &gt;) &lt; / RTI &gt; The digital combiner unit 430, which combines all the same digital signals applied from each demux of the one digital mixer 420, and the digital signal applied from the digital combiner 430, respectively, are converted into analog signals. 1.23MHz or 1.5MHz intermediate frequency signal which is an analog signal applied from the first D / A converter 440 and the third amplifier 450 from the first D / A converter 440 MIC with the same oscillation frequency applied from the third local unit 403 A third mixer 460 for outputting an intermediate frequency signal, and an intermediate frequency signal applied from the third mixer 460 through the first saw filter 470 and the fourth amplifier 480. A fourth mixer 490 for generating an RF signal by mixing with the oscillation frequencies of different frequency bands applied from the fourth local unit 500, and a fifth amplifier 510 from the fourth mixer 490. The first combiner 404 transmits RF signals of four different frequency bands applied through the first power amplifier 405 and the fourth bidirectional filter 406 to the base station 10.

In more detail, the plurality of slave units 30 are connected to the first demux unit 420 through the fourth light conversion unit 410, and the four demux units forming the first demux unit 420 are formed. The muxes 422, 424, 426, 428 are provided with the same number as the slave units 30, and each demux is connected to the other slave units 30 through the optical transducers 412, 414, 416, 418 and the optical path, respectively. Here, if there are four slave units 30 connected to the master unit 20, the fourth light conversion unit 410 also includes four light converters, and four demuxes constituting the first demux unit 420 also become four. In this case, the intermediate frequency signal and the NMS signal corresponding to four different frequency bands are output from one demux. The NMS signal is applied to the first controller 107.

The first demux unit 420 demuxes a 52-bit intermediate frequency signal applied from the slave unit 30 side through an optical converter, divides the signal into four frequencies, and outputs different signals, respectively. 16 intermediate frequency signals are applied. In addition, the digital combiner unit 430 also includes four digital combiners 432, 434, 436, and 438, and four intermediate frequency signals of the same frequency band output from each demux are applied to one digital combiner.

The digital combiner combines four 12-bit intermediate frequency signals of the same frequency band to form a 14-bit intermediate frequency signal and applies it to the first D / A converter 440. Each of the D / A converters 442, 444, 446, and 448 of the first D / A converter 440 converts a digital signal of 14 bits into an intermediate frequency signal, which is an analog signal, and converts an intermediate frequency signal of 1.23 MHz or 1.5 MHz to a third amplification, respectively. The unit 450 is applied to the mixers 462, 464, 466, and 468 of the third mixer 460. The third mixer 460 is an intermediate frequency signal of 1.23 MHz or 1.5 MHz applied from the first D / A converter 440 and an oscillation frequency of 68.77 MHz or 68.5 MHz applied from the third local unit 403. Mix and output a 70MHz intermediate frequency signal.

The intermediate frequency signal output from the third mixer 460 is applied to the fourth mixer 490 through the first saw filter 470 and the fourth amplifier 480, and the fourth mixer 490. ) Mixes the oscillation frequency of the different frequency bands applied from the fourth local unit 500 and the intermediate frequency signal of 70 MHz to convert the RF signals of the 800 MHz different frequency bands through the fifth amplifier 510. Is applied to the binner 404. The first combiner 404 combines RF signals of different frequency bands applied through the fifth amplifier 510 from the four mixers 492, 494, 496, and 498 of the fourth mixer 490, and then combines the first RF amplifier 405. Amplify the size and the level in the) and transmits it to the base station 10 through the fourth bi-directional filter 406 and the RF cable.

As can be seen from the above description, in the present invention, the RF signal, which is an analog signal applied from the base station to the forward master part of the master part, is converted into an intermediate frequency signal, and then converted into a digital signal, through an optical path along with a control signal NMS signal. The slave unit is forwarded to the slave unit, and the slave unit forward slave unit converts the digital signal into an analog signal and then converts it into an RF signal and transmits the signal to the mobile terminal. The mobile terminal can receive a clean signal without noise. The RF signal, which is an analog signal applied to the reverse slave unit of the slave unit, is also converted into an intermediate frequency signal and transmitted along with the NMS signal, which is a control signal, to the master unit through an optical path, and the reverse master unit of the master unit converts the digital signal into an analog signal. After converting to RF signal to the base station Being can perform seamless communication. In addition, it is possible to send and receive the NMS signal to control the operation of the slave unit by mixing the digital signal and the NMS signal in the mixer unit without a separate device, and the mutual transmission and reception between the master unit and the slave unit, and the configuration of the optical repeater is simple by using a digital combiner There is an effect of improving the characteristics as you do.

Claims (8)

In the optical repeater comprising a master unit for transmitting and receiving a signal through a base station and an RF cable, and a slave unit for transmitting and receiving a signal transmitted and received from the master unit through an optical path, the master unit is an RF signal which is an analog signal applied from the base station First means for converting the signal into an intermediate frequency signal and converting the signal into a digital signal and transmitting the signal to the slave side through the optical path, and a second signal for converting the digital signal applied from the slave side through the optical path into an RF signal as an analog signal and transmitting the signal to the base station. Means; wherein the slave unit converts the digital signal, which is an intermediate frequency signal applied through the optical path, into an analog signal, and then converts and amplifies the RF signal into an RF signal and transmits the signal to the mobile terminal, and the analog signal received from the mobile terminal. After converting RF signal into intermediate frequency signal When converted to a digital signal by the digital optical repeater, it characterized in that it has a fourth means for sending a master part via the optical line. 2. The apparatus of claim 1, wherein the first means comprises means for including the NMS signal applied from the first controller in the digital signal and transmitting the signal to the slave portion via the optical path, and the second means is provided from the digital signal applied from the slave portion. Means for separating and applying the NMS signal to the first control unit, and the third means includes means for separating the NMS signal from the digital signal applied from the master unit side and applying the NMS signal to the second control unit. And means for transmitting to the master unit side through the optical path including the NMS signal applied from the second control unit to the digital optical repeater. 2. The master unit of claim 1, wherein the master unit comprises a forward master unit performing the first means, a reverse master unit performing the second means, and the slave unit is a forward slave unit performing the third means, and the fourth means. Digital optical repeater comprising a reverse slave unit for performing. 4. The apparatus of claim 3, wherein the forward master unit is connected to a first divider for dividing and outputting RF signals applied from a base station to a predetermined number of different frequencies, and to an output terminal of the first divider, and applied from a first divider. A first mixer which generates an intermediate frequency signal of the same frequency band by mixing the RF signal and the oscillation frequency applied from the first local unit, and is applied through the first band pass filter unit and the first amplifier unit from the first mixer unit And a second mixer to generate an intermediate frequency signal close to DC by mixing the intermediate frequency signal to the oscillation frequency applied from the second local part, and through the second band pass filter part and the second amplifier part from the second mixer part. A first A / D converter unit for converting an intermediate frequency signal, which is an applied analog signal, into a digital signal; and all of the signals applied from the first A / D converter unit A digital optical repeater comprising: a first mux for mixing a digital signal and an NMS signal applied from a first control unit and outputting a serial data signal to a forward slave unit side of a slave unit through a first optical conversion unit and an optical path; The second demux unit according to claim 3, wherein the forward slave unit demuxes the serial data signal applied from the forward master unit, converts the serial data signal into parallel data signals, and separates and outputs the signals at different frequencies through the output port. A fifth D / A converter for converting digital signals of different frequency bands applied from the two demux units into analog signals, and an intermediate frequency signal applied through the sixth amplifier from the second D / A converter; A fifth mixer for mixing the oscillation frequency applied from the local unit and outputting an intermediate frequency signal, and an intermediate frequency signal applied from the fifth mixer through the second saw filter unit and the seventh amplifier unit from the sixth local unit; A sixth mixer for mixing the oscillation frequency applied to generate an RF signal, and four other frequencies applied through the eighth amplifier from the sixth mixer. The single digital optical repeater according to claim 2 comprising a combiner for combining the RF signal through the second power amplifier and a second two-way transmission filter in a mobile terminal. 4. The apparatus of claim 3, wherein the reverse slave unit is connected to a second divider for distributing an RF signal applied from a mobile terminal to a predetermined allocated frequency band and outputs the result through each output port, and each output port of the second divider. A seventh mixer comprising a plurality of mixers and mixing an RF signal applied from the second divider with a different oscillation frequency applied from each local of the seventh local unit to generate an intermediate frequency signal having the same magnitude; An eighth mixer unit which generates an intermediate frequency signal close to DC by mixing the intermediate frequency signal applied from the mixer through the third band pass filter unit and the ninth amplifier unit with the same oscillation frequency applied from the eighth local unit; When converting an intermediate frequency signal, which is an analog signal applied from the eight mixer section through the fourth band pass filter section and the tenth amplifier section, to a digital signal The key is a serial data signal which muxes the second A / D converter unit, and all the digital signals applied from the second A / D converter unit and the NMS signal applied from the second control unit, respectively, to the respective third light conversion unit, and A digital optical repeater comprising a second mux outputted to a reverse master section through an optical path. 4. The apparatus of claim 3, wherein the reverse master part comprises a demux connected to each of the optical paths and the fourth optical conversion part, and demuxes the serial data signals applied from the respective slave parts to correspond to the allocated frequency bands. A first demux unit for separating into four different frequency bands and NMS signals and outputting them to five output ports, and a digital combiner connected to each demux of the first demux unit, respectively; A digital combiner unit for adding all of the same digital signals applied from the respective digital demuxes, a first D / A converter unit for converting the digital signals applied from the digital combiner units into analog signals and outputting the analog signals; The intermediate frequency signal, which is an analog signal applied from the first D / A converter unit, through the amplifier, is mixed with the same oscillation frequency applied from the third local unit. A third mixer for outputting a frequency signal and a fourth mixer for generating an RF signal by mixing an intermediate frequency signal applied from the third mixer through a saw filter and an amplifier with oscillation frequencies of different frequency bands applied from a fourth local unit; And a combiner for combining RF signals of four different frequency bands applied from the fourth mixer through the fifth amplifier to the base station through the first power amplifier and the fourth bidirectional filter. Digital optical repeater. 10. The digital combiner of claim 7, wherein each digital combiner constituting the digital combiner unit receives and combines FAs of the same frequency band from each of the digital signals output from the respective demuxes of the first demux unit and combines them into FAs of the same frequency band. And a signal is applied to each of the D / A converters of the first D / A converter unit.