KR20060118379A - Repeater in mobile communication system - Google Patents

Abstract

A repeater of a mobile communication system is provided to apply a main amplifier module where small signal amplification and attenuation functions and control functions are realized, thus gain control in accordance with user's control is available. A remote unit(200) comprises as follows. A modem(211) performs communication with an NMS(Network Management System). A remote transceiving module(220) transceives a signal with a transceiving module(140) of a donor unit(100). A main amplifier module(230) consists of an amplifier unit(232) composed of an attenuator(232-2) for attenuating the signal received through the module(220) and an amplifier(232-3) for amplifying the signal, and a controller(231) for performing gain control of the amplifier(232-3). A forward BPF(Band Pass Filter)(240) passes a desired frequency band only from the signal received from the amplifier(232-3), so that the signal of the corresponding frequency band can be transmitted to a terminal, and executes signal coupling for measuring output of a system. An arrestor(250) arrests a thunderstroke of a transmission antenna. An arrestor(260) arrests a thunderstroke of a receiving antenna.

Description

Repeater in Mobile Communication System

1 is a block diagram of a conventional repeater,

2 is an internal configuration diagram of a repeater according to an embodiment of the present invention,

3 is an internal configuration diagram of a repeater according to another embodiment of the present invention;

4 is an optical module configuration diagram of an optical repeater according to an embodiment of the present invention;

5 is a perspective view of a repeater housing according to an embodiment of the present invention;

6 is a side view of FIG. 5;

7 is a side view of a repeater housing according to another embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: donor unit 110: central control unit

111, 212: fluorescent display tube (VFD) 112, 211: modem

113: CPU 120: Tx Drive Module

121, 132: ATT 122, 131: AMP

123: power detection unit 130: Rx drive module

140: donor transceiver module 200: remote unit

220: remote transmission and reception module 230: main amplifier module

231: control unit 232: amplifier unit

240, 270: Band Pass Filter (BPF) 241: Sampling Port (S / P)

250, 260: lightning breaker 271: signal generator (S / G)

280: drive amplifier 410: laser diode (LD) module

420: TEC module 430: lower case

510: main enclosure 520: heat sink

530: insertion groove 540: amplifier housing

550: cable connector 560: cooling fan

The present invention relates to a repeater and a repeater housing of a mobile communication system, and more particularly, the main amplifier of the remote unit performs the small signal amplification and attenuation functions, and the main amplifier performs the output monitoring by itself without a separate device. In the repeater of the mobile communication system and the repeater housing for the efficient cooling of the repeater, so that the control unit of the main amplifier performs the entire remote control without implementing a CPU for the remote control of the It is about.

The optical repeater includes a donor part 10 and a remote part 20. As shown in FIG. 1, the conventional repeater donor part 10 includes a central control unit 11, a Tx drive module 12, and an Rx. The drive module 13, the donor transceiver module 14, the remote unit 20 is a remote transceiver module 21, the central control unit 22 and the Tx drive module 23 for forward signal processing, main Amplifier 24, Band Pass Filter 25, Coupler 25-1, Power Sensing Unit 25-2, and Band Pass Filter 26, Coupler 26-1, Low Noise Amplifier for Reverse Signal Processing And a drive amplifier 28 or the like.

As described above, when the conventional repeater is viewed from the structural point of view, as the remote unit 20 is subdivided, the structure is complicated and unnecessary space is required. The disadvantage is that it is inconvenient. In addition, the separation of modules caused unnecessary cost increases.

In particular, the Tx drive module 23 and the main amplifier 24 of the remote unit 20 are configured to be separated, and the main amplifier 24 has a fixed gain. The main amplifier 24 is again inside the Tx drive module 23. A small output amplifier for adjusting the gain of the amplifier 24 should be provided, and the gain of the small output amplifier is also fixed, and the overall amplifier gain of the remote unit 20 has a disadvantage in that it cannot be adjusted after design.

In the conventional remote unit 20 as described above, the coupler 25-1 is connected to the forward band pass filter 25, and the output level is adjusted using a signal coupled from the coupler 25-1. It includes a separate power sensing unit (PDU) 25-2 for sensing and reporting to the network management system (NMS) via the CPU and modem of the central control unit 22, which makes the structure very complicated and inconvenient to deploy. do.

In the reverse direction, a coupler 26-1 is provided separately from the band pass filter 26. The coupler 26-1 receives a signal input of a signal generator (S / G) 26-2 for adjusting the reverse gain. For the sake of this, this also causes a complex structure.

In addition, the conventional optical repeater has a wide temperature range of the laser diode LD, so that the characteristics of the optical module, which is the remote transceiver module 21, are changed, and if the level of the base station forward signal is changed, the setup of the optical repeater is required. There is a problem that unnecessary failure factors such as contact ports between modules are inherent due to the subdivision of modules.

And, in general, the repeater is composed of a housing unit including the repeater internal components described above, and a heat dissipation unit provided on one side of the enclosure for heat dissipation of the amplifier inside the housing unit, but conventionally, the amplifier inside the housing unit As it is included, there is a disadvantage that the area of the heat dissipation portion is enlarged and cooling is inefficient.

Accordingly, the present invention is to solve the above-mentioned disadvantages and problems of the prior art, to simplify the implementation by the integration of the system function block and distributed control, to enable the gain control of the main amplifier, optical repeater In the case of the mobile communication system repeater to achieve the low-cost optical module implementation and compatibility by stabilizing the optical wavelength, and to induce cost reduction and miniaturization by implementing a separate housing of the amplifier, it is easy to manufacture and operate / maintain a low-cost repeater And it is an object of the present invention to provide a repeater housing.

The above object of the present invention comprises a remote unit and a donor unit, which relays a signal between a base station and a mobile communication terminal, comprising: a modem for communicating with a network management system (NMS) for monitoring a repeater; A display device for various displays; A remote transmission / reception module for transmitting and receiving a signal through a transmission / reception module of the donor unit and a specific transmission path; An amplifier unit including an attenuator ATT for attenuating the signal received through the remote transceiver module and an amplifier AMP for amplifying a signal, a gain adjusting unit for gain adjustment of the amplifier unit, and the gain according to a user input A main amplifier module comprising a control unit which performs gain control of the amplifier unit through an adjustment unit; A forward band pass filter configured to pass only a desired frequency band from the signal from the amplifier of the amplifier unit so that a signal of the corresponding frequency band is transmitted to the terminal through a transmitting antenna, and perform signal coupling for measuring the output of the system; A sampling port (S / P) for outputting a signal coupled from the forward band pass filter to the outside; A lightning blocker positioned between the forward band pass filter and the transmitting antenna to block lightning of the transmitting antenna; A lightning blocker for blocking lightning of the receiving antenna; Signal generator (S / G) for receiving a RF signal from the terminal through the receiving antenna and passing only a desired frequency band and generating a signal corresponding to a transmission loss (Loss) between the base station and the repeater for the reverse gain control A reverse band pass filter for performing signal coupling for signal input; A drive amplifier for amplifying the signal from the reverse band pass filter and transmitting it to the remote transmission / reception module; And a sampling port for sampling a signal passing through a drive amplifier before being transmitted to the remote transceiver module. It is achieved by the repeater of the mobile communication system comprising a.

In addition, the object of the present invention is a terrestrial RF repeater which is formed integrally with the remote unit and the donor unit to relay a signal between the base station and the mobile communication terminal, and a modem for performing communication with a network management system (NMS) for repeater monitoring; ; A display device for various displays; A first lightning blocker for blocking lightning of the donor antenna; A first duplexer for dividing up and down signals so that a signal from a donor antenna is input only to a down circuit; A low noise amplifier for reducing noise components of the RF signal and amplifying the signal components; An amplifier unit including an attenuator ATT for attenuating a signal received through a donor antenna and an amplifier AMP for amplifying a signal, a gain adjusting unit for adjusting gain of the amplifier unit, and the gain adjusting unit according to a user input A main amplifier module comprising a control unit which performs gain control of the amplifier unit through; A second lightning blocker to block lightning of the remote antenna; A second duplexer configured to radiate an output signal of the main amplifier module to a terminal through a remote antenna and to separate an upstream and a downlink signal so that a signal from the remote antenna is input only to an upstream circuit; A drive amplifier for amplifying the signal from the second duplexer; A high output amplifier amplifying the effective signal for wireless transmission to radiate a signal from the drive amplifier through a donor antenna; It is achieved by the repeater of the mobile communication system comprising a.

In addition, the object of the present invention is an optical repeater comprising a remote unit and a donor unit each having an optical module for performing photoelectric conversion and all-optical conversion, and relays a signal between the base station and the mobile communication terminal, wherein the optical module is the external temperature A laser diode module whose optical wavelength and intensity change according to the present invention; In order to stabilize the optical module characteristics by the laser diode module, a thermoelectric cooling element (TEC) is provided on the lower surface of the laser diode module to enable cooling of the lower surface of the laser diode module LD in the optical module by the Peltier effect. Thermal Electronic Cooler); And a lower case for removing the dew condensation caused by the vertical temperature difference caused by the application of the thermoelectric cooling element; Is achieved by a repeater of a mobile communication system consisting of a sequentially stacked structure.

In addition, the object of the present invention is a housing of a repeater, which relays a signal between a base station and a mobile communication terminal and includes a cooling device therein, the housing including a repeater component including an amplifier control unit, excluding an amplifier; ; A heat sink fixedly installed at one side of the repeater main enclosure and having an insertion groove formed at one side thereof; An amplifier housing inserted into an insertion groove of the heat sink and accommodating an amplifier of a high heat generating unit; A cable connector configured to accommodate a cable for connecting the amplifier control unit of the main body and the amplifier of the amplifier housing; It is achieved by the repeater enclosure of the mobile communication system comprising a.

In the present invention, the repeater may be an optical repeater, a microwave repeater, a terrestrial light RF repeater, etc., which are remotely constituted by donors and remotes according to the transmission path thereof, and a non-oscillating RF repeater which is a repeater composed of a donor and a remote unit. (ICS), RF repeaters and other similar RF systems, gap fillers for satellite DMB, terrestrial repeaters, and the like, and include cellular systems, PCS systems, WCDMA systems, portable Internet WiBro systems, It can be applied to various mobile communication systems such as satellite DMB and terrestrial waves.

Details of the above object and technical configuration of the present invention and the resulting effects thereof will be more clearly understood from the following detailed description based on the accompanying drawings.

First, Figure 2 is a block diagram of a repeater according to an embodiment of the present invention.

As shown, the repeater receives and outputs the RF signal of the base station, the donor unit 100 for transmitting the input signal to the base station as an RF signal, and receives the signal of the donor unit 100 through a specific transmission path And a remote unit 200 which transmits the RF signal to the mobile communication terminal and transmits the RF signal from the terminal to the donor unit 100 through the transmission path.

The donor unit 100 includes a central control unit 110, a Tx drive module 120, an Rx drive module 130, and a donor transmission / reception module 140.

The central control unit 110 includes a fluorescent display tube (VFD) 111 that is a display device, a modem 112 for communication with an external network management system (NMS) for monitoring a repeater, and the fluorescent lamp. The display tube 111, the modem 112, the Tx drive module 120, and the Rx drive module 130 are configured to control the CPU 113.

The Tx drive module 120 is a forward signal processing module, and includes an attenuator ATT 121 that receives and attenuates a base station RF signal, and amplifies the attenuator output signal so that the amplified signal is input to the donor transceiver module 140. The amplifier AMP 122 is configured to include a power sensing unit PDU 123 at the input of the attenuator 121.

The power sensing unit 123 couples the input signal to the attenuator 121 to automatically measure the forward signal level input from the base station to the optical repeater, and reports it to the network management system (NMS) through the modem 112. As a unit, this allows the attenuation value to be adjusted remotely according to the input level.

The Rx drive module 130 couples an amplifier (AMP) 131 for amplifying a signal received from the donor transmission / reception module 140, an attenuator (ATT, 132) for attenuating the output signal of the amplifier, and the attenuator output signal. The ring comprises a power sensing unit (PDU) 133.

The remote unit 200 includes a modem 211 for communication with a network management system (NMS), a fluorescent display tube (VFD) 212 that is a display device, and a remote transmission / reception module 220. The configuration includes a main amplifier module 230 for signal amplification, a forward band pass filter (BPF, 240), a lightning arrester (Arrestor, 250), and a configuration for reverse signal processing, a lightning blocker 260, a band pass filter 270, a drive amplifier 280, and a sampling port 281.

The remote transmission / reception module 220 performs signal transmission and reception with the remote transmission / reception module 220 of the donor unit 100.

The main amplifier module 230 is composed of a control unit 231 and an amplifier unit 232, and the amplifier unit 232 is a gain adjusting unit 232-1, an attenuator 232-2, and an amplifier 232-3. Is done. In this case, the gain adjusting unit 232-1 performs gain adjustment of the amplifier 232-3 under the control of the control unit 231, and the attenuator 232-2 performs signal attenuation for system output control. In addition, the amplifier 232-3 is changed in gain according to user control through the controller 231, and is responsible for signal amplification and high output according to the gain.

That is, the gain adjusting unit 232-1 is configured to adjust the gain of the amplifier to +40 dB to +70 dB by performing a gain change of -10 dB to +20 dB using the attenuation block and the gain block, so that the amplifier is always in operation. It is possible to change the gain.

On the other hand, although the amplifier unit 232 is shown and described as consisting of a gain adjusting unit 232-1, an attenuator 232-2 and one amplifier 232-3, the input terminal of the attenuator 232-2 A small output amplifier may be additionally configured in the present invention. In the present invention, the main amplifier module 230 integrates the functions of the existing Tx drive module for small signal amplification and attenuation functions, and the main amplifier for signal amplification and high output functions. In one embodiment, a separate control unit 231 is configured to perform signal amplification with a variable gain instead of a fixed gain under the control of the user.

The control unit 231 of the main amplifier module 230 performs gain control of the amplifier unit 232 according to a user input, and not only the amplifier unit 232 but also a modem 211 and a display device (VFD) 212. And the drive amplifier 280 for reverse signal processing. Accordingly, the repeater remote unit 200 according to the present invention does not have a separate control unit for overall control of the remote unit 200, and is controlled by the control unit 231 of the main amplifier module 230. Can be controlled.

In addition, the amplifier unit 232 of the main amplifier module 230 monitors the output power of the amplifier 232-3 for gain and automatic output limit (ALC) function, and outputs an output power monitoring value. And the control unit 231 calculates a difference between the reported output monitoring power value and the loss power value between the amplifier 232-3 and the lightning breaker 250, thereby calculating the final output power value. Expect.

In addition, the main amplifier module 230 may provide a function of temperature monitoring, RF waveform monitoring, RF output detection, output value upper limit.

Next, the forward band pass filter 240 passes only the desired frequency band from the signal from the amplifier 232-2 of the amplifier unit 232 so that the signal of the corresponding frequency band is transmitted to the terminal through the transmitting antenna, and the coupler Performs signal coupling for measuring the output of the system, including the function of

The signal coupled from the forward band pass filter 240 is output to the outside through the sampling port (S / P, 241), which is output by the user using a spectrum analyzer (S / A) or the like. Used to measure

The lightning blocker 250 is positioned between the forward band pass filter 240 and the transmitting antenna to serve to block lightning of the transmitting antenna.

Next, in the configuration for reverse signal processing, the reverse band pass filter 270 receives the RF signal of the terminal passing through the lightning blocker 260 for blocking the lightning of the receiving antenna and passes only the desired frequency band, the reverse gain Signal coupling is performed by including a coupler function for adjustment.

In this case, the signal coupling is for signal input of a signal generator (S / G) that generates a signal corresponding to an optical cable loss (Loss) between the base station and the repeater, so that the repeater gain can be known. .

The drive amplifier 280 integrates the configuration of the Rx drive amplifier unit and the low noise amplifier of the conventional remote unit to simplify the structure. The drive amplifier 280 amplifies the signal from the reverse band pass filter 270 and transmits it to the remote transmission / reception module 220. The output signal of the drive amplifier 280 is sampled by the sampling port 281 before being transmitted to the remote transmission / reception module 220.

3 is an internal configuration diagram of a repeater according to another embodiment of the present invention, and shows an embodiment of a repeater in which a donor and a remote are integrated.

As shown, the RF repeater 300 which is formed integrally with the remote unit and the donor unit to relay the signal between the base station and the mobile communication terminal includes a donor antenna 301 and a remote antenna 302, the donor antenna 301 Transmit and receive signals with the base station through, and transmits and receives signals with the mobile communication terminal through the remote antenna 302.

The RF repeater is a first lightning to block the lightning of the modem 311 for communication with an external network management system (NMS) for monitoring the repeater, the fluorescent display tube 312 as a display device, the donor antenna 301 signal The circuit breaker 320, a first duplexer 330 that separates the up and down signals so that the signal from the donor antenna 301 is input only to the down circuit, and a low noise amplifier 331 which reduces the noise component of the RF signal and amplifies the signal component. In order to radiate the signal from the drive amplifier 370 through the donor antenna 301, a high output amplifier 332 for amplifying the effective output for wireless transmission, the main amplifier module 340 for signal amplification, the main amplifier module A second duplexer (3) for radiating the output signal of 340 to the terminal through the remote antenna 302 and dividing the up and down signals so that the signal from the remote antenna 302 is input only to an upstream circuit; 50), a second lightning breaker 360 to block lightning of the remote antenna 302 signal and a drive amplifier 370 to amplify the signal from the second duplexer 350.

As in the embodiment of FIG. 2, the main amplifier module 340 includes an attenuator ATT 342-2 for attenuating a signal received through the donor antenna 301 and an amplifier AMP 342-3 for amplifying a signal. An amplifier unit 342 including a), a gain adjusting unit 342-1 for gain adjustment of the amplifier unit 342, and an amplifier unit 342 through the gain adjusting unit 342-1 according to a user input. The control unit 341 performs a gain control of the amplifier, and the amplifier 342-3 is changed in gain according to user control through the control unit 341, and is responsible for signal amplification and high output according to the gain. do.

Therefore, as shown in FIG. 2, the gain adjusting unit 342-1 is configured to adjust the gain of the amplifier to +40 dB to +70 dB by performing a gain change of -10 dB to +20 dB using the attenuation block and the gain block. The amplifier's gain can be changed at any time during operation.

The control unit 341 of the main amplifier module 340 performs gain control of the amplifier unit 342 according to a user input, and not only the amplifier unit 342 but also the modem 311 and the display device (VFD) 312. And a drive amplifier 370 for reverse signal processing. Accordingly, the RF repeater according to the present invention does not have a separate control unit for the entire repeater control, and various control devices can be controlled by the control unit 341 of the main amplifier module 340.

Also, the amplifier unit 342 of the main amplifier module 340 monitors the output power of the amplifier 342-3 for gain and automatic output limit (ALC) function, and outputs the output power monitoring value. 341, the controller 341 calculates a difference between the reported output monitoring power value and the loss power value between the amplifier 342-3 and the lightning breaker, and estimates the final output power value.

In addition, the main amplifier module 340 may provide a function of temperature monitoring, RF waveform monitoring, RF output detection, output value upper limit.

The drive amplifier 370 integrates the configuration of the Rx drive amplifier unit of the conventional repeater and the low noise amplifier to simplify the structure.

Next, Figure 4 is a block diagram of the optical module of the optical repeater according to an embodiment of the present invention.

As shown, the optical module 400 constituting the donor and the remote part of the optical repeater includes laser diode modules LD and 410 whose characteristics such as light wavelength and intensity change according to external temperature change.

The optical module 400 of the present invention has a structure in which a laser diode module 410, a thermoelectric cooling element (TEC) module 420 and a lower case 430 are sequentially stacked, and the laser diode module ( In order to stabilize the characteristics of the optical module by reducing the change in the characteristics of the optical module according to the temperature change of the 410, the structure via the TEC module 420 on the lower surface of the laser diode module (LD, 410) in the optical module 400 to be.

The TEC module 420 is composed of an array of P-type semiconductors and N-type semiconductors, and converts electrical energy into thermal energy to perform a cooling function. An endothermic or exothermic phenomenon at both ends of the device due to the Peltier effect is performed. When the direct current in the (+) direction flows through the N-type device, as the electrons move from the P-type to the N-type device, the cold side absorbs heat and the temperature drops. Perform the cooling action by principle. Since the configuration of such a thermoelectric cooling element is already known, the drawings are omitted.

In addition, the lower case 430 is required to remove the dew condensation caused by the vertical temperature difference caused by the application of the thermoelectric cooling element.

Finally, Figures 5 to 7 show a repeater housing according to an embodiment of the present invention, Figure 5 is a perspective view of the repeater housing according to an embodiment of the present invention, Figure 6 is a side view of Figure 5, Figure 7 is Side view of a repeater enclosure according to another embodiment of the invention.

As shown in Figures 5 and 6, the repeater housing of the present invention comprises the main enclosure 510, the heat sink 520, the amplifier enclosure 540, the cable connector 550.

The main enclosure 510 accommodates all repeater components except the amplifier, that is, a filter, an RF module, a control module, a modem, a rectification module, and the like, and the amplifier enclosure 540 only receives an amplifier that is a high heat generator. As the main amplifier is implemented as a separate enclosure, the replacement of the main amplifier alone can achieve the output up and down of the system.

On the other hand, the position of the amplifier housing 540 is not limited to the position shown in the drawings, it is possible to install either of the front and rear surfaces of the housing 510, it is preferable to implement a waterproof type to suit the outdoor type.

In addition, the door of the main body 510 and the amplifier housing 540 is preferably configured to open the upper surface for maintenance in rainy weather.

The heat sink 520 is fixedly installed at one side of the repeater main enclosure 510, and an insertion groove 530 is formed at one side thereof so that the amplifier enclosure 540 is inserted into the insertion groove 530 of the heat sink 520. Be sure to

The cable connector 550 shown in FIG. 6 is a case accommodating a cable for connecting an amplifier control unit accommodated in the main body 510 and an amplifier housed in the amplifier housing 540, and a transmission output cable and a control cable pass through. Do it.

In addition, as illustrated in FIG. 7, the repeater housing may further include a cooling fan 560, and the cooling fan 560 is disposed for cooling the heat sink on one side of the heat sink 520. do.

The cooling fan 560 is to be driven when high heat is generated in the high heat generating unit is impossible to cool only by the heat sink 520, the wind generated by the cooling fan 560 cools the heat sink 520. Let's do it.

As those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features, the embodiments described above should be understood as illustrative and not restrictive in all aspects. Should be. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

Therefore, the repeater of the mobile communication system of the present invention applies the main amplifier module in which the small signal amplification and attenuation function and the control function are implemented in place of the existing remote amplifier unit separated into the Tx drive module and the main amplifier, thereby controlling the user. According to the present invention, there is an advantage that the gain control is possible, and there is no need to install a separate drive amplifier and there is no need for a separate power sensing unit because power can be detected by itself. In addition, since the control unit of the main amplifier module controls all the controlled devices of the remote unit, there is an advantage that a separate remote unit control unit is unnecessary, thereby simplifying the remote unit and reducing the load of the control unit.

In addition, the repeater of the present invention has an advantage that a separate coupler is unnecessary because the band pass filter performs the coupler function, and the structure is simplified by implementing the Rx drive amplifier and the low noise amplifier of the reverse module of the remote unit as one drive amplifier. The donor's Tx drive amplifier automatically measures the forward signal level, allowing the attenuation value to be adjusted remotely according to the input level.

In addition, the optical repeater adds a thermoelectric cooling element to the optical module so that the characteristics of the optical module are not easily changed according to the external temperature, the repeater housing is configured to separate the power amplifier of the integral structure into the control unit and the amplifier unit, and the amplifier unit The external positioning of the amplifier facilitates heat dissipation of the amplifier and reduces the size of the heat sink, as well as the size of the enclosure, which is advantageous for securing module space inside the system.

Claims (7)

A repeater comprising a remote unit and a donor unit to relay a signal between a base station and a mobile communication terminal, A modem for communicating with a network management system (NMS) for monitoring a repeater; A display device for various displays; A remote transmission / reception module for transmitting and receiving a signal through a transmission / reception module of the donor unit and a specific transmission path; An amplifier unit including an attenuator ATT for attenuating the signal received through the remote transceiver module and an amplifier AMP for amplifying a signal, a gain adjusting unit for gain adjustment of the amplifier unit, and the gain according to a user input A main amplifier module comprising a control unit which performs gain control of the amplifier unit through an adjustment unit; A forward band pass filter configured to pass only a desired frequency band from the signal from the amplifier of the amplifier unit so that a signal of the corresponding frequency band is transmitted to the terminal through a transmitting antenna, and perform signal coupling for measuring the output of the system; A sampling port (S / P) for outputting a signal coupled from the forward band pass filter to the outside; A lightning blocker positioned between the forward band pass filter and the transmitting antenna to block lightning of the transmitting antenna; A lightning blocker for blocking lightning of the receiving antenna; Signal generator (S / G) for receiving a RF signal from the terminal through the receiving antenna and passing only a desired frequency band and generating a signal corresponding to a transmission loss (Loss) between the base station and the repeater for the reverse gain control A reverse band pass filter for performing signal coupling for signal input; A drive amplifier for amplifying the signal from the reverse band pass filter and transmitting it to the remote transmission / reception module; And A sampling port for sampling a signal passing through a drive amplifier before being transmitted to the remote transmission / reception module; Repeater of the mobile communication system, characterized in that comprises a. The method of claim 1, The donor part, A donor transceiver module configured to transmit and receive a signal through a remote transmission / reception module of the remote unit and a specific transmission path; Attenuator (ATT) and amplifier (AMP) for attenuating and amplifying the base station RF signal, and coupled to the signal input to the attenuator to automatically measure the forward signal level input from the base station to the optical repeater, and the network A Tx drive module including a power sensing unit (PDU) for reporting to a management system (NMS) to adjust attenuation values; An Rx drive module for amplifying and attenuating signals from the optical module and transmitting them to the base station; A central control unit including a modem for communicating with a network management system (NMS) for monitoring a repeater, a display device for various displays, and a CPU for controlling the Tx drive module and the Rx drive module; Repeater of the mobile communication system, characterized in that comprises a. The method according to claim 1 or 2, The transmission path may be any one of an optical cable, a microwave transmission path, and an RF cable, and the repeater may be any one of an optical repeater, a microwave repeater, and an RF repeater according to the transmission path. A terrestrial RF repeater which is formed integrally with a remote unit and a donor unit to relay a signal between a base station and a mobile communication terminal, A modem for communicating with a network management system (NMS) for monitoring a repeater; A display device for various displays; A first lightning blocker for blocking lightning of the donor antenna; A first duplexer for dividing up and down signals so that a signal from a donor antenna is input only to a down circuit; A low noise amplifier for reducing noise components of the RF signal and amplifying the signal components; An amplifier unit including an attenuator ATT for attenuating a signal received through a donor antenna and an amplifier AMP for amplifying a signal, a gain adjusting unit for adjusting gain of the amplifier unit, and the gain adjusting unit according to a user input A main amplifier module comprising a control unit which performs gain control of the amplifier unit through; A second lightning blocker to block lightning of the remote antenna; A second duplexer configured to radiate an output signal of the main amplifier module to a terminal through a remote antenna and to separate an upstream and a downlink signal so that a signal from the remote antenna is input only to an upstream circuit; A drive amplifier for amplifying the signal from the second duplexer; A high output amplifier amplifying the effective signal for wireless transmission to radiate a signal from the drive amplifier through a donor antenna; Repeater of the mobile communication system, characterized in that comprises a. The method according to claim 1 or 4, The gain adjusting unit of the main amplifier module, A repeater of a mobile communication system, characterized in that it performs a gain change of -10 dB to +20 dB. The method according to claim 1 or 4, The amplifier unit of the main amplifier module monitors the output power of the amplifier by itself, reports the output power monitoring value to the controller, And the controller of the main amplifier module calculates a difference between the reported output monitoring power value and the lost power value between the amplifier and the lightning breaker, and estimates the final stage output power value. The method according to claim 1 or 4, The control unit of the main amplifier module, And a modem, a display device, and a drive amplifier control.

Images