KR100591856B1 - Wireless repeater - Google Patents

Abstract

The present invention relates to a wireless repeater in which a terminal device for communication with a wireless terminal is multi-stage coupled with an amplifying means, and each terminal device is configured to temporarily process radio signals of different frequency bands provided by a plurality of wireless communication systems. It relates to a wireless relay device.

The wireless relay apparatus according to the present invention is an interface for communicating with a base station and a terminal for communicating with a wireless terminal, and an amplification means coupled to the interface and the terminal for performing signal amplification processing for a forward signal and a reverse signal. In the wireless relay device configured, the interface and the amplifying means are respectively provided to correspond to the first to third systems using different frequency bands, and the forward device is applied from each amplifying means between the terminating device and the amplifying means. By separating / synthesizing the signal by frequency so as not to be affected by the harmonics between frequencies, the signal is provided to the terminator via the first and second transmission lines, and the reverse signal applied from the terminator is separated through the first and second transmission lines. Path processing means provided to each of the amplification means is configured to combine, The stage device may be coupled to the path processing means through first and second transmission lines, and the first and second coupling means may branch a predetermined level of the forward signal through magnetic coupling with the first and second transmission lines. And forwarding forward signals of the first to third frequency bands applied from the first and second coupling means to the antenna, branching the forward signal to a predetermined level, and applying a reverse signal from the antenna. And a power detecting means for displaying and outputting a signal power level for forward signals in the first to third frequency bands applied from the routing setting means.

Description

Wireless repeater {Wireless repeater}

1 is a diagram illustrating a configuration of a conventional wireless relay device.

2 is a block diagram showing the configuration of a wireless relay apparatus according to a first embodiment of the present invention.

Figure 3 is a block diagram showing the functional separation of the internal configuration of the termination device 400 shown in FIG.

4 to 7 are views for explaining the configuration of the line coupler shown in FIG.

8 and 9 are views for explaining the configuration of the power detection display unit shown in FIG.

Figure 10 is a block diagram showing the functional separation of the internal configuration of the termination device according to a second embodiment of the present invention.

******* Brief description of the main parts of the drawing *******

100: interface unit, 200: amplification unit

300: path processing unit, 400: terminal device,

410, 420: line coupler, 430: routing section,

440: power detection means.

The present invention relates to a wireless repeater in which a terminal device for communication with a wireless terminal is multi-stage coupled with an amplifying means, and each terminal device is configured to temporarily process radio signals of different frequency bands provided by a plurality of wireless communication systems. It relates to a wireless relay device.

In general, a wireless communication system amplifies a signal received from a base station and transmits the signal received from a base station to a wireless terminal in a communication shadow area to prevent degradation of communication service due to a shadow area formed in a basement or a building. A wireless repeater that amplifies the received signal and transmits it to the base station is installed and operated in the shaded area.

1 is a block diagram schematically showing the configuration of a conventional wireless relay apparatus. As shown in FIG. 1, the wireless relay device includes an interface unit 11 for communication with a base station, a terminal device 12 for communication with a wireless terminal, and an interface between the interface unit 11 and the terminal device 12. Coupled to the amplification unit 13 which amplifies a forward signal applied from the interface unit 11 to the terminator 12 and amplifies a reverse signal applied from the terminator 12 to the interface unit 11. It is configured to include).

In this case, as shown in FIG. 1, a plurality of terminators 12 are multi-stage coupled to one amplifying unit 13 in a building having a predetermined size to perform a relay process for a wider area through one wireless relay device. To be configured.

On the other hand, the communication service provider is provided with a predetermined frequency band to provide a communication service for the wireless terminal. Recently, as the types of communication services provided through wireless terminals are diversified, the difference in frequency bands for wireless communication services is gradually narrowing. For example, the currently provided general mobile communication service is allocated about 800M ~ 900MHz band, about 1.9G ~ 2.1GH band is allocated for IMT-2000 service, about 2.6G ~ for DMB (Digital Multimedia Broadcasting) service 2.7GHz band will be allocated. At this time, the above communication service is performed wirelessly and all require a wireless relay device. However, in the case where a telecommunication service provider provides all of the above-mentioned wireless communication services, the installation of the wireless relay device for each system has the inefficiency of producing and installing several identical devices having different frequency bands. In particular, in the case of the termination device 12, because a plurality of them are coupled to one wireless relay device, its inefficiency may be further added. In other words, there is a need for a wireless relay device capable of smoothly performing relay processing for different frequencies through one wireless relay device.

In addition, each end device 12 should always maintain a constant signal level enough to provide a relay service for a certain area in the radio transmission of the forward signal branched from the amplifier 13. However, in the wireless relay device configured as shown in FIG. 1, the amplification level of the forward signal amplified and output from the amplifying unit 13 is changed or is terminated between the amplifying unit 13 and the terminating device 12 or between the terminating device 12 and the terminating device 12. When the signal level of the forward signal branching from the signal branching points formed between the devices 12 is not constant, the end device 12 may not be able to smoothly provide a relay service for the corresponding area. For example, when the branched signal level is reduced, the service area is reduced, thereby forming a communication shadow area. Therefore, there is a problem that stable service is not possible due to the formation of some communication shade areas even though the radio relay apparatus is installed.

Accordingly, the present invention has been made in view of the above circumstances, and in a wireless relay device in which a plurality of terminal devices are combined, one terminal device can simultaneously process relay processing with a wireless terminal for different frequency signals. The technical purpose is to provide a wireless relay device.

In addition, in the wireless repeater in which the terminator is multi-stage coupled to the amplifier, each terminator allows the administrator to easily adjust the signal level of the forward signal branched from the transmission line so that a forward signal of a certain level is always transmitted wirelessly. As a result, there is another technical purpose to provide a stable communication service to the user.

A wireless relay apparatus according to the present invention for achieving the above object is an interface for communicating with a base station and a terminal for communicating with a wireless terminal, and a signal amplification processing for the forward signal and the reverse signal is coupled between the interface and the terminal In the wireless relay device comprising an amplifying means for performing a, wherein the interface and the amplifying means are provided to correspond to the first to third systems using different frequency bands, respectively, between the termination device and the amplifying means The forward signal applied from the amplifying means is separated / synthesized by frequency so as not to be affected by the harmonics between frequencies, and provided to the terminator via the first and second transmission lines, and applied from the terminator through the first and second transmission lines. Path processing means for separating the reverse signal is provided to each of the amplification means The terminating device is a multi-stage coupled through the path processing means and the first and second transmission lines, the first termination device for branching the forward signal of a predetermined level through the magnetic coupling with the first and second transmission lines And a second coupling means and a forward signal of the first to third frequency bands applied from the first and second coupling means to the antenna, branching the forward signal by a predetermined level, and applying reverse from the antenna. The signal is provided with routing means for sending out to said first and second coupling means, and power sensing means for displaying and outputting a signal power level for forward signals in the first to third frequency bands applied from the routing means. It is characterized in that the configuration.

That is, according to the above, it is possible to simply implement a wireless relay device that performs radio relay processing for a plurality of wireless communication systems, thereby significantly reducing the installation cost, and to minimize the occurrence of internal noise due to signal branching. It is possible to keep the signal quality stable.

In addition, it becomes easy to manage such that the forward signal of a certain level is always sent from each end device, it is possible to provide a stable wireless communication service provided to a plurality of wireless communication system to the user.

Hereinafter will be described an embodiment according to the present invention.

First, the present embodiment provides a first system for providing IMT-2000 service with a transmit / receive frequency band of 1.9 GHz to 2.1 GHz, a second system for providing general mobile communication service with a transmit / receive frequency band of 800 MHz to 900 MHz, and a unidirectional service. An embodiment of the radio relay apparatus configured to perform radio relay processing for a third system for providing satellite broadcasting service whose transmission frequency band is 2.6 GHz to 2.7 GHz will be described.

2 is a block diagram showing an internal configuration of a wireless relay apparatus according to a first embodiment of the present invention.

The wireless relay apparatus according to the present invention includes an interface 100 for performing signal transmission / reception processing with base stations constituting the first to third systems, and an amplifier for amplifying and outputting a forward signal and a reverse signal by a predetermined level ( 200, a terminal device 400 performing wireless transmission / reception with the wireless terminal, and a forward signal applied from the amplifier 200 by being coupled between the amplifier 200 and the terminal device 400 for each frequency band. It is provided with a path processor 300 that separates / combines and provides a reverse signal applied from the terminator 400 to the amplifier 200.

In this case, the interface 100 and the amplifier 200 may be configured to correspond to the frequency band used in each system. In addition, the path processing unit 300 is configured to separate the reverse signal applied from the terminal device 400 for each frequency band and provide the amplification units 200 (210, 220, 230).

In addition, in the present embodiment, at least one terminal device 400 is sequentially coupled to the path processing unit 300 according to the relay processing scale. At this time, the path processing unit 300 is sequentially coupled with the terminal device 400 through the first and second transmission lines (P1, P2), each terminal device is connected to the first and second transmission lines (P1, P2) It is configured to synthesize the reverse signal provided from the wireless terminal as well as branching the forward signal through the magnetic coupling.

In addition, the path processor 300 may include a first filter 310 for filtering forward signals TX1 / reverse signal RX1 of 1.9 GHz to 2.1 GHz, which is a first frequency band, and a second frequency band. A second filter 320 for filtering the forward signal TX2 and the reverse signal RX2 of 800 MHz to 900 MHz, and a second processing filter for forward signal TX3 of 2,6 GHz to 2.7 GHz, which is a third frequency band. The third filter 330 and the TX1 / TX2 signals applied from the first and second filters 310 and 320 are synthesized and provided to the terminating device 400 through the first transmission line P1 and the first transmission line P1. The triplexer 340 for providing the RX1 signal from the terminator 400 to the first filter 310 and the TX3 signal applied from the third filter 330 through the second transmission line P2). The duplexer 35 which provides an RX2 signal applied from the terminator 400 through the second transmission line P2 to the second filter 320 while providing the terminator 400 through the second transmission line P2. 0).

That is, the TX1 / RX1 / TX2 signal is transmitted between the path processing unit 300 and the terminating device 400 or between the terminating device 400 and the terminating device 400 through the first transmission line P1, and the second transmission is performed. The RX2 / TX3 signal is configured to be transmitted through the line P2. This primarily separates the TX2 / RX2 signals required by the second system, and the 2.6 MHz of the third system affected by the 800 MHz to 900 MHz band TX2 transmission signal of the second system and the third harmonic of the 800 MHz to 900 MHz band TX2 signal. By separating the TX3 signal transmission line in the GHz to 2.7 GHz band, harmonics of the frequency set as the signal band are prevented from generating internal noise by being affected by the frequency set as another signal band.

3 is a block diagram illustrating a functional separation of the internal structure of the termination device 400 shown in FIG.

As shown in FIG. 3, the terminal device 400 is coupled to one end of the path processing unit 300 or the terminal device 400 of the previous stage and the other end thereof is coupled to the terminal device of the next stage, and is fixed from the corresponding transmission line. First and second line couplers 410 and 420 which branch the level forward signal TX and combine the reverse signal RX signal provided from the wireless terminal into a transmission line. In this case, the first line coupler 410 is coupled to the first transmission line P1, and the second line coupler 420 is configured to be coupled to the second transmission line P2. The first and second antennas ANT1 and ANT2 are separated and synthesized by the forward signals applied from the first and second line couplers 410 and 420 and transmitted to the first and second antennas ANT1 and ANT2. A path setting unit 430 for providing a reverse signal applied from the first and second line couplers 410 and 420 and a signal power level of a forward signal branched from the first and second line couplers 410 and 420. It is configured to include a power detecting means 440 for display output.

Here, the routing unit 430 transmits the TX1 / TX2 signal applied from the first line coupler 410 to the power sensing means 440 which will be described later through the first output terminal, and transmits the TX2 signal to the second output terminal. RX1 signal transmitted through the first duplexer 432, TX1 signal to the second triplexer 434 through the third input / output terminal, and also applied through the third input / output terminal from the second triplexer 434. Transmits the first triplexer 431 transmitted to the first line coupler 410, the TX2 signal applied from the first triplexer 431 through the first antenna ANT1, and the first antenna ANT1. ) Transmits the RX2 signal applied from the first duplexer 432 to the second duplexer 433 to be described later, and the TX3 signal applied from the second line coupler 420 to the power sensing means 440 to be described later. In addition to the first through the first input and output to the second triplexer 434 to be described later, and the first The RX2 signal applied from the flexure 432 is transmitted from the second duplexer 433 to the second line coupler 420 and the TX1 signal and the second duplexer 440 applied from the first triplexer 431. A second triplexer 434 is provided to transmit the applied TX3 signal through the second antenna ANT2 and to transmit the RX1 signal applied from the second antenna ANT to the first triplexer 431. It is configured by.

That is, the routing unit 430 separates and combines the forward signals applied from the first line coupler 410 and the second line coupler 420 for each frequency band, so that the TX2 signal of the 800 MHz to 900 MHz band is the first antenna ANT1. TX1 / TX3 signals in the 1.9 GHz to 2.1 GHz and 2.6 GHz to 2.7 GHz bands are transmitted through the second antenna ANT2, and 1.9 GHz to 2.1 GHz RX1 applied from the first antenna ANT1. The signal is transmitted to the first line coupler 410, and the RX2 signal in the 800 MHz to 900 MHz band applied from the second antenna ANT2 is transmitted to the second line coupler 420.

Meanwhile, in FIG. 3, the first and second line couplers 410 and 420 are configured such that a forward signal of a predetermined level is branched through magnetic coupling so as to prevent internal noise caused by a physical connection point.

That is, Figure 4 illustrates the shape of the line coupler shown in Figure 3, the lower body 510, the upper body 520 and the front plate 530 is screwed to both sides of the housing 500, the first side Alternatively, the first and second connectors 540 and 550 for physically coupling with the second transmission lines P1 and P2 are coupled to each other. The front plate 530 has third and fourth connectors 560 and 570 fixedly coupled to the plate 610 installed inside the housing and physically coupled to the first triplexer 441 or the second duplexer 433. Through holes 531 and 532 are formed to protrude.

In addition, a metallic first signal line L1 is connected to the inside of the housing between the first and second couplers 540 and 550, and the metallic second signal line L2 is parallel to the first signal line L1. Is placed. In addition, the plate 610 for conveying the second signal line L2 back and forth is combined with the knob 580 provided at the center of the front plate 530. In this case, the knob 580 is rotatable and coupled to the second signal line L2 closer to or farther from the first signal line L1 in accordance with the rotation direction of the knob 580. The knob 580 is configured to display a scale Z as shown in FIG. 4. In this case, the scale Z displayed on the knob 580 indicates distance information between the first signal line L1 and the second signal line L2 corresponding to the amount of rotation of the knob 580. In addition, a fixing device 581 is installed outside the knob 580 to stop the operation of the knob 580 by fixing the state of the knob 580 when the position of the second signal line L2 is set. do.

In this case, the coupling of the line coupler may be changed according to the distance and length between the first signal line L1 and the second signal line L2 and the thickness of the signal line itself. This coupling value directly affects the output signal level of the branched signal line. For example, when the distance between the signal lines decreases, the coupling value increases, and thus the output signal level of the branched signal line becomes large. You lose. That is, the air in the line coupler of the first signal line (L1) and the second signal line (L2) is a dielectric medium (dielectric constant = 1) and the first signal line (L1) and the second signal line (L2) are coupled to each other. Since the coupling method by air between the first signal line L1 and the second signal line L2 is based on the coupling theory of the line coupler, a detailed description thereof will be omitted.

In other words, the line coupler forms a transmission path with an amplifying unit (not shown) through the first signal line L1 and is disposed in parallel with the first signal line L1 by operating the knob 580. By moving the two signal lines L2 in the front-rear direction, the coupling value induced according to the distance between the first signal line L1 and the second signal line L2 can be variably set. In particular, the manager can more easily transfer the second signal line L2 based on the scale displayed on the knob 580. At this time, the coupling value corresponding to each scale is measured in advance, and the administrator can easily set the coupling value of the line coupler by rotating the knob 580 by the corresponding scale to correspond to the desired coupling value.

Next, the configuration of the above-described line coupler will be described in more detail with reference to FIGS. 5 to 7. 5 is an exploded perspective view of the line coupler, and FIGS. 6 and 7 are cross-sectional views of the line coupler, and FIG. 6 is an initial view in which the distance D between the first signal line L1 and the second signal line L2 is farthest. FIG. 7 illustrates a state in which the second signal line L2 is moved a predetermined distance in all directions by the manager.

First, a first signal line L1 and a second signal line L2 are accommodated in a first accommodating space 511 in the lower body 510, and the second signal line is in a second accommodating space 512. The plate 610 for conveying (L2) is accommodated.

Both ends of the first signal line L1 disposed in the first accommodating space 511 are connected to the first and second connectors 540 and 550 through through holes 513 and 514 formed at both sides of the lower body 511. The second signal line L2 is arranged to be parallel to the first signal line L1, and pins L2 ₁ and L2 ₂ having a predetermined length are perpendicular to the second signal line L2 at both ends thereof. It is constructed to protrude integrally. The pins L2 ₁ and L2 ₂ penetrate through the plate 610 provided in both wall surfaces of the first storage space 511 and the second storage space 512, and are screwed to opposite surfaces thereof. It is fixedly coupled with the connector (560, 570). In this case, Teflon insulators 515 and 517 and outer shields 516 and 518 may be applied to the outer circumferences of the pins L2 ₁ and L2 ₂ to prevent impedance mismatch due to diffuse reflection of the second signal line L2. .

The plate 610 is disposed in the second receiving space 512 and is coupled to the shaft 582 coupled to the knob 580 formed on the front plate 530. At this time, the screw thread 583 is formed in the center of the shaft 582, the screw thread 583 of the shaft 582 is formed in the center of the plate 610 is screwed. In addition, guide holes 612 and 613 are formed on both sides of the plate 610 to guide the pins L2 ₁ and L2 ₂ of the second signal line L2 to the third and fourth connectors 560 and 570. .

That is, the line coupler is fixedly coupled to the third and fourth connectors 560 and 570 through pins L2 ₁ and L2 ₂ protruding from both ends of the second signal line L2 through the plate 610. The screw 610 is screwed with the shaft 582 of the central part cloud knob 580 so that the plate 610 is conveyed in the front-rear direction according to the rotation operation of the knob 580.

In this case, the second signal line L2 should be transported in the front-rear direction while maintaining a parallel state with respect to the first signal line L1 in order to stably provide a coupling value with the first signal line L1. To this end, a predetermined groove is formed in the wall surface of the plate 610 and the second storage space 512, and the elastic member 620 such as a spring is installed in the groove. That is, the plate 610 is elastically supported on the wall surface of the second storage space 512 by the elastic member 620, so that the movement of the plate 610 in the front and rear direction is stabilized.

In addition, the end of the shaft 581 penetrating the screw hole 611 of the plate 610 is located in the groove 519 formed on the wall surface of the second storage space 512, the groove 519 portion A locking groove 584 is formed at the end of the shaft 582. In addition, the upper body 520 corresponding to the locking groove 584 is formed with a through groove 521 whose screw is formed at the lower end thereof, and an end of the screw fitted through the through groove 521 is locked by the locking groove 584. In order to be positioned in the to secure the shaft (582). This is to compensate for the fine vertical movement of the plate 610 by preventing the vertical movement of the plate 610 coupled with the shaft 582.

In addition, screw holes 614 and 615 are formed on both sides of the plate 610 so as to meet the guide holes 612 and 613 through which the pins L2 ₁ and L2 ₂ pass, and are coupled to the screw holes 614 and 615. screws (N2, N3) of the pins to the pin (L2 _1, L2 ₂₎ so as to contact the (L2 _1, L2 ₂₎ end of this is adapted to be stably fastened to the plate 610.

Meanwhile, in FIG. 3, the power sensing means 400 separates the TX1 / TX2 signal applied from the first triplexer 431 through the filter 441 and transmits the TX1 signal through the first and second power sensing display units 442 and 443. And display and output the power level for the TX2 signal, and the TX3 signal provided from the second duplexer 433 is configured to display and output the signal power level through the third power detection display unit 444.

In this case, the power detection display may be configured, for example, as shown in FIG. 8. That is, the power detection display unit branches the signal of a predetermined level from the main signal line through the branching unit 710, converts the branched signal into a DC component, and then displays and outputs the branched signal level to the power display unit 740. It is composed.

That is, the branching means 710 is metallic with respect to the first signal line L1 connected to the main signal line, for example, the filter 441 or the second duplexer 433 and the first signal line L1. When the second signal line L2 is disposed in parallel and a current is applied to the first signal line L1, a change in the magnetic field occurs around the first signal line L1. It is configured to be induced to the second signal line (L2). In this case, the ground terminal characteristic impedance Z of the second signal line L2 is set to, for example, 50Ω. Fig. 9 is a diagram illustrating the configuration of the branching means 710 in the case where the main signal line is constituted in a specific device, for example the filter F. Figs. That is, as shown in FIG. 9, the branching means 710 arranges the second signal line L2 in parallel with the first signal line L1 of the filter 441 or the second duplexer 433. One end of the second signal line L2 may be configured to be coupled to the SMA port 711 that is electrically coupled to the attenuation circuit 720 through the filter 441 / the second duplexer 433.

In more detail with reference to the power sensing display, as shown in FIG. 8, the induced current induced from the first signal line L1 to the second signal line L2 in the branching means 710 is attenuated. 720). The attenuation circuit 720 attenuates a signal applied from the second signal line L2 by a predetermined level to provide the rectifying diode D, and the rectifying diode D is an alternating current applied from the sensing circuit 720. The signal is converted into a direct current signal and provided to the power display unit 740 through the smoothing circuit 730. In this case, the attenuation circuit 720 is coupled to the variable resistor (VR) on the signal line coupled to the second signal line (L2) and the rectifying diode (D), as shown in Figure 8, the second signal line A resistor R1 is coupled between the contact point A of L2 and the variable resistor VR and the ground, and a resistor R2 is coupled between the contact point B and the ground of the variable resistor VR and the rectifier diode D. It is configured. That is, the user adjusts the variable resistor VR so that the signal applied from the second signal line L2 is attenuated and output to a signal level of the displayable range of the power sensing display unit described later. In other words, the signal applied from the second signal line L2 is attenuated to a signal level corresponding to the values of the resistors R1 and R2 and the variable resistor VR and applied to the anode terminal of the rectifying diode D. In this case, an impedance matching inductor L having one end grounded between the attenuation circuit 720 and the anode terminal of the diode D is coupled in parallel. In addition, the smoothing circuit 730 is composed of a resistor (R3) and a capacitor (C) coupled in parallel to the cathode terminal of the rectifying diode (D), respectively, the ripple of the DC signal output from the rectifying diode (D) By removing the component, a DC signal having a stable characteristic is provided to the power display unit 740. The power display unit 740 is for displaying a power level corresponding to the DC signal applied through the smoothing circuit 730, and may be implemented as, for example, a micro pamper meter.

Next, the operation of the wireless relay device having the above configuration will be described.

First, the processing operation for the forward signal from the base station to the radio terminal will be described.

TX1 / TX2 / TX3 signals applied from the base stations of the respective systems are applied to the first to third amplifiers 210, 220, and 230 through the first to third interfaces 110, 120, and 130, and amplified by the amplifiers 210, 220, and 230 at a predetermined level. The TX1 / TX2 / TX3 signals are distributed / combined by frequency through the path processing unit 300 and applied to the terminating device 400. In this case, the path processor 300 transmits the TX1 / TX2 signals applied from the first and second amplifiers 210 and 220 to the terminator 400 through the first transmission line P1, and the third amplifier ( TX3 signal applied from 230 is sent to the terminating device 400 through the second transmission line (P2).

In addition, the terminating device 400 provides a TX1 / TX2 / TX3 signal applied from the first transmission line P1 and the second transmission line P2 to the second terminal device of the next stage, and also the path unit 300. It branches the TX1 / TX2 / TX3 signal applied from a certain level. The terminator 400 wirelessly transmits the TX2 signal branched from the first transmission line P through the first antenna ANT1, and transmits the TX1 signal and the second transmission branched from the first transmission line P1. The TX3 signal branched from the line P2 sets the output path of each frequency to wirelessly transmit through the second antenna ANT2.

In addition, the routing unit 430 of the terminating device 400 branches the TX1 / TX2 / TX3 signals branched from the first and second transmission lines P1 and P2 to a predetermined level and provides them to the power detecting means 440. Done. The power detecting means 440 detects and displays the TX1 / TX2 / TX3 signal power levels applied from the first and second transmission lines P1 and P2. At this time, the manager recognizes the signal level of the forward signal TX currently transmitted through the antennas NT1 and ANT2 based on the power information displayed and output through the power sensing means 440, and always relay services for a certain area. Knob 518 of the first and second line couplers 410 and 440 coupled with the first and second transmission lines P1 and P2 when initial setting or when it is determined that adjustment of the output level is necessary to maintain It is possible to obtain a desired output level by changing the distance between the first signal line (L1) and the second signal line (L2).

On the other hand, in the case of the reverse signal from the radio terminal to the base station, the RX2 signal applied from the radio terminal is applied to the routing unit 430 through the first antenna ANT1, and the RX1 signal is connected to the second antenna ANT2. Through the route setting unit 430 is applied.

The routing unit 430 distributes / combines the RX1 / RX2 signals applied from the first and second antennas ANT1 and ANT2 to the first and second line couplers 410 and 420. At this time, the routing unit 430 provides the RX1 signal applied from the second antenna ANT2 to the first line coupler 410, and the RX2 signal applied from the first antenna ANT1 is the second line coupler 420. ) Will be provided.

Subsequently, the first and second frequency band reverse signals applied to the first and second line couplers 410 and 420 are induced to the first signal line L1, respectively, to connect the first and second transmission lines P1 and P2. It is applied to the path processing unit 300 through.

The path processing unit 300 distributes the reverse signal applied from the terminating device 400 through the first and second transmission lines P1 and P2 for each of the first to third frequency bands, and thereby the first to third amplifying units 210, 220, and 230. ), And the reverse signal amplified by the first to third amplifiers 210, 220, and 230 are wirelessly transmitted to the corresponding base station through the first to third interfaces 110, 120, and 130.

Meanwhile, in the above embodiment, the TX2 / RX2 signals of 800 MHz to 900 MHz are transmitted and received through the first antenna ANT1 in the terminator, and the TX1 / RX1 signals of 1.9 GHz to 2.1 GHz and the TX3 signals of 2.6 GHz to 2.7 GHz Although it is configured to transmit and receive through the second antenna ANT2, it is possible to configure to transmit and receive the TX1 / RX1, TX2 / RX2, TX3 signals through one third antenna (ANT3) as shown in FIG. In this case, as shown in FIG. 10, the routing unit 430 receives the TX2 signal applied from the first duplexer 431 and the TX1 / TX3 signal applied from the second triplexer 434 in the third antenna ANT3. And the RX2 signal applied from the third antenna ANT3 to the first duplexer 432 and the RX1 signal applied from the third antenna ANT3 to the second triplexer 434. It is configured to further include three triplexer (800).

That is, according to the above embodiment, the radio relay processing is performed on the plurality of wireless communication systems by configuring signals of different frequency bands used in the plurality of wireless communication systems to be simultaneously processed by a terminal device which is multi-stage coupled to the amplifying means. By simply implementing the wireless relay device, the installation cost can be significantly reduced.

In addition, each terminal device is configured to branch a predetermined level of signal through magnetic coupling with the main signal line in branching the forward signal, thereby minimizing the occurrence of internal noise due to signal branching, thereby maintaining a stable signal quality. It becomes possible.

In addition, each terminal device is configured to display and output the power level of the forward signal, and to arbitrarily adjust the signal level of the forward signal branching from the transmission line, so that the administrator always forwards the constant signal level through the terminal device. It is easy to keep the signal sent out.

In addition, since a forward signal of a predetermined level is always transmitted from each terminal device, it is possible to stably provide a wireless communication service provided in a plurality of wireless communication systems to a user.

In addition, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the technical spirit of the present invention.

As described above, according to the present invention, it is possible to simply implement a wireless relay device that performs radio relay processing for a plurality of wireless communication systems, thereby significantly reducing the installation cost, and generating internal noise due to signal branching. By minimizing this, it is possible to keep the signal quality stable.

In addition, it becomes easy to manage such that the forward signal of a certain level is always sent from each end device, it is possible to provide a stable wireless communication service provided to a plurality of wireless communication system to the user.

Claims (9)

A wireless relay device comprising an interface for communicating with a base station and a terminal device for communicating with a wireless terminal, and an amplifying means coupled between the interface and the terminal device to perform signal amplification processing for a forward signal and a reverse signal. The interface and the amplifying means are respectively provided to correspond to the first to third systems using different frequency bands, Between the terminating device and the amplifying means, the forward signal applied from each amplifying means is separated / synthesized by frequency so as not to be affected by the harmonics between frequencies, and provided to the terminating device through the first and second transmission lines. 2 is a path processing means for separating the reverse signal applied from the terminal device through the transmission line and providing each of the amplification means, The termination device is coupled to the path processing means through the first and second transmission lines in multiple stages, and the first and second couplings for branching a forward signal of a predetermined level through magnetic coupling with the first and second transmission lines. And forwarding forward signals of the first to third frequency bands applied from the first and second coupling means to the antenna, branching the forward signal to a predetermined level, and applying a reverse signal from the antenna. And power detecting means for displaying and outputting a signal power level for the forward signals of the first to third frequency bands applied from the routing means, and routing means for transmitting to the second coupling means. Wireless repeater. delete The method of claim 1, The first and second coupling means may include a first metallic signal line connected to a transmission line in a rectangular housing and a second metallic signal line arranged in parallel with the first signal line. Both ends of the signal line are fixed to the plate by pins protruding in a direction perpendicular to the first signal line, and the plate is screwed with the central portion of the shaft of the knob installed on the front of the housing so that the plate is rotated on the shaft as the knob rotates. And a screw move to transfer the second signal line in a forward and backward direction. The method of claim 3, And the distance information between the first signal line and the second signal line corresponding to the amount of rotation of the knob is marked on the knob. The method of claim 1, The power sensing means has a first signal line connected to a main signal line and a second signal line metallic in parallel with the first signal line, and a forward signal having a predetermined level from the first signal line through magnetic coupling. Branching means configured to branch to a second signal line, attenuation circuit for attenuating the signal provided from the second signal line by a predetermined level, and a rectifying diode, the attenuation circuit being coupled to its anode end and applied from the attenuation circuit. Signal converting means for converting the alternating AC signal into a direct current signal, a smoothing circuit for flattening and outputting an inputted DC signal by combining a resistor and a capacitor in parallel with the cathode terminal of the rectifying diode, and a signal applied from the smoothing circuit And power display means for displaying and outputting a signal power level corresponding to The radio relay apparatus as. The method of claim 5, And an impedance matching inductor having one end grounded in parallel between an output end of the attenuation circuit and an input end of the signal conversion means. The method of claim 1, The first system provides a forward signal and a reverse signal in the 1.9 GHz to 2.1 GHz band, the second system provides a forward signal and a reverse signal in the 800 MHz to 900 MHz band, and the third system provides a 2.6 2.7 to 2.7 GHz band. Configured to provide a forward signal, The path processing means transmits and receives a forward signal and a reverse signal in the 1.9 GHz to 2.1 GHz band and a 800 MHz to 900 MHz forward signal with the terminating device through the first transmission line, and the 800 MHz to 900 MHz reverse signal and the 2.6 GHz to the amplification means. And a 2.7 GHz forward signal performs frequency-specific path processing to transmit and receive a terminal device through a second transmission line. The method of claim 7, wherein The terminator transmits 800 MHz to 900 MHz forward signal and 1.9 GHz to 2.1 GHz forward signal and 2.6 GHz to 2.7 GHz forward signal branched from the second transmission line through the antenna through the first coupling means. In addition to the radio transmission box, characterized in that it comprises a routing means for branching a forward signal provided through the first and second coupling means to a predetermined level through magnetic coupling to the power sensing means. Repeater. The method of claim 7, wherein The terminator wirelessly transmits a 800 MHz to 900 MHz forward signal branched from the first transmission line through the first coupling means to the first antenna, and 1.9 GHz to 2.1 branched from the first transmission line through the first coupling means. The 2.6 GHz to 2.7 GHz forward signal branched from the second transmission line through the GHz forward signal and the second coupling means is wirelessly transmitted through the second antenna. The 800 MHz to 900 MHz reverse signal applied from the first antenna is provided to the second transmission line through the second coupling means, and the reverse signal of 1.9 GHz to 2.1 GHz band applied from the second antenna provides the first coupling means. Wireless repeater comprising a routing setting means to be provided to the first transmission line through.

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