KR100960237B1 - IF repeater for wireless communication systems - Google Patents

Abstract

The present invention relates to a relay system of a radio signal, and more particularly, a relay system including one master unit and at least one remote unit for receiving a radio signal from a base station of a time division duplex communication system and serving a shadow area. In this case, the master unit detects the TDD control signal from the downlink signal of the base station and controls the path switches, and transmits and receives with the remote unit by varying the IF frequencies of the downlink path and the uplink path, and the remote unit is the same downlink as the master unit. The present invention relates to a distributed relay system for wireless communication that does not require a separate TDD control signal by transmitting and receiving each using a link and an uplink IF frequency.

To this end, the present invention receives a high frequency signal from a base station of a time division duplex communication system to service a shadow area, but detects a TDD control signal from a downlink signal of the base station to control path switches and to each other in a downlink path and an uplink path. At least one master unit transmitting and receiving to and from the remote unit using another IF frequency, and receiving a signal from the master unit to serve a shadow area, and at least one transmitting and receiving using the same downlink and uplink IF frequencies as the master unit, respectively. Consists of a remote unit, the remote units provide a distributed relay system for wireless communication that does not require a separate TDD control signal.

Description

Distributed repeater system for wireless communication {IF repeater for wireless communication systems}

1 is a block diagram showing a configuration of a repeater for a general time division duplex communication system.

2 is a view showing the overall configuration of a distributed relay system for wireless communication according to the present invention.

3 is a block diagram showing a configuration of a master unit of a distributed relay system for wireless communication according to the present invention.

4 is a block diagram showing a configuration of a remote unit of a distributed relay system for wireless communication according to the present invention.

5 is a diagram illustrating IF band filtering of a distributed relay system for wireless communication according to the present invention.

6 is a view showing a state of use of a distributed relay system for wireless communication according to the present invention.

7 is a view showing another embodiment of a distributed relay system for wireless communication according to the present invention.

[Description of Drawings]

110. base station 120. repeater

121, 201, 601. Link antenna 122, 205. First switch

123. Power amplifiers 124, 214. Second switch

125. Low noise amplifier 126, 313. Coverage antenna

127. Control unit 130, 400. Terminal

200. Master unit 202, 312. Bandpass filter

203. Couplers 204, 311. Circulators

206, 306, 603, 706. First transmit amplifier 207, 604. Reference clock generator

208, 307, 605, 707. Dividers 209, 308, 606, 708. First phase locked loop

209-1, 308-1, 606-1, 708-1. 2nd phase locked loop

210, 309, 607, 709. First mixer

210-1, 309-1, 607-1, 709-1. Second mixer

211, 310, 608, 714. Second transmit amplifier 212, 305, 609, 705. IF filter for transmission

213, 304, 610, 704. First attenuator 215, 303, 611, 703. IF duplexer

216, 302, 613, 702. Bias-T 217, 301, 612, 701. Power supply

218. Third switch 219, 317, 615, 716. Second attenuator

220, 316, 616, 715. Receive IF filter 221, 314, 617, 713, first receive amplifier

222, 315, 618, 714. Second receive amplifier 223, 614. Transmission line

224. TDD detection and control unit 300. Remote unit

602, 711. RF Duplexer

       The present invention relates to a wireless signal relay system, and more particularly, to a relay system comprising one master unit and at least one remote unit for receiving a high frequency signal from a base station of a time division duplex communication system and serving a shadow area. The master unit detects the TDD control signal from the downlink signal of the base station, controls the path switches, and transmits and receives with the remote unit by varying the IF frequencies of the downlink path and the uplink path, and the remote unit is the same downlink as the master unit. The present invention relates to a distributed relay system for wireless communication that does not require a separate TDD control signal by transmitting and receiving using uplink IF frequencies.

       In general, a time division duplex communication system uses the same transmission / reception frequency, but selects and processes a transmission and reception at a predetermined time period. To this end, a conventional time division system base station or repeater uses a method of switching a transmission path and a reception path by a switch. However, in the case of deploying a plurality of repeaters, the system needs to be equipped with a TDD control unit in all repeaters. The cost will rise, and there is a problem that the repeater can not be used efficiently when the small shaded areas are adjacent or the sizes of the shaded areas are different.

       FIG. 1 is a block diagram showing a configuration of a repeater for a general time division duplex communication system, in which a base station 110, a repeater 120, and a terminal 130 are illustrated. In FIG. 1, the repeater 120 includes a link antenna 121 for transmitting and receiving a radio signal to and from the base station 110, a first switch 122 for switching the path between the link antenna, and amplifying a downlink signal. A second switch 124 for switching the path between the first amplifier 123, the coverage antenna 126 to be described later, a second amplifier 125 for amplifying the uplink signal, a terminal 130 in the shaded area, A coverage antenna 126 for transmitting and receiving a radio signal, and a control unit 127 for controlling the first and second switches in response to the TDD control signal.

       SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art, and receives a high frequency signal from a base station of a time division duplex communication system to service a shaded area, but detects a TDD control signal from a downlink signal of the base station to switch a path. One master unit for transmitting and receiving to and from the remote unit by controlling the IF bands of the downlink path and the uplink path, and receiving a signal from the master unit to serve a shadow area, the same downlink and uplink IF as the master unit. It is a technical object of the present invention to provide a distributed relay system for wireless communication, which is composed of at least one remote unit transmitting and receiving each using a frequency, and the remote units do not require a separate TDD control signal.

       In order to solve the above technical problem, a distributed relay system for wireless communication according to the present invention receives a high frequency signal from a base station 110 of a time division duplex communication system and serves a shadow area, but provides a TDD control signal from a downlink signal of the base station. One master unit 200 to control the path switches to control the path switches and to transmit and receive to and from the remote unit by varying the IF frequency of the downlink path and the uplink path; and receives a signal from the master unit 200 to service the shadow area At least one remote unit 300 for transmitting and receiving each using the same downlink and uplink IF frequency as the master unit; and a transmission line 223 for connecting the master unit 200 and the remote unit 300 by wire. It is configured to include.

       The master unit 200 may include: a link antenna 201 for transmitting and receiving downlink and uplink high frequency signals with the base station 110; and a bandpass filter for passing only a required band of high frequency signals transmitted and received by the link antenna; And a coupler 203 for branching the downlink signal passing through the bandpass filter; and a TDD detection for detecting a TDD control signal included therein from the downlink signal branched by the coupler and controlling the switches to be described later. And a circulator 204 for forwarding the downlink signal passing through the bandpass filter only in the forward direction; and receiving the control signal from the TDD detection and control unit and passing through the circulator 204. A first switch 205 for turning on / off a downlink signal; and a first transmission boost for amplifying the downlink high frequency signal passing through the first switch with a predetermined gain; An aeration 206; and a reference clock generator 207 for generating a predetermined reference clock and supplying the divided clock and the duplexer; and a divider for receiving a reference clock signal generated from the reference clock generator and dividing it into two phases and equal amplitudes. 208); and a first phase locked loop 209 for generating a first local frequency signal from a reference clock signal received from the splitter; and a downlink high frequency signal output from the first transmit amplifier and a first phase locked loop. A first mixer 210 for synthesizing the first local frequency signal to generate a predetermined downlink IF signal; and a second transmit amplifier 211 for amplifying the downlink IF signal output from the first mixer with a predetermined gain; And a transmission IF filter 212 for passing only a required band of the downlink IF signal output from the second transmission amplifier; and an output from the transmission IF filter. A first attenuator 213 for adjusting a downlink IF signal to a predetermined level; and receiving a control signal from the TDD detection and control unit to turn on / off a downlink IF signal output from the first attenuator; A second switch 214 turned on / off in conjunction with the second switch; and an IF receiving the reference clock from the reference clock generator by combining a downlink IF signal passing through the second switch and an uplink IF signal described later in one path; A duplexer 215 and a control signal received from the TDD detection and control unit to turn on / off an uplink IF signal input through the IF duplexer, but inversely coupled to the first and second switches, A third switch 218; and a second attenuator 219 for adjusting the uplink IF signal output from the third switch to a predetermined level; and an uplink IF signal output from the second attenuator. A receiving IF filter 220 for passing only a yaw band; and a first receiving amplifier 221 for amplifying an uplink IF signal output from the receiving IF filter with a predetermined gain; and a reference clock signal received from the divider. A second phase synchronization loop 209-1 for generating a second local frequency signal from the first phase; and an uplink IF signal output from the first receiver amplifier and a second local frequency signal received from the second phase synchronization loop; A second mixer 210-1 for generating an uplink high frequency signal of the second mixer; and a second receiver amplifier 222 for amplifying the uplink high frequency signal output from the second mixer with a predetermined gain and transmitting the amplified signal to the circulator 204. And powering the first to third switches, the first and second transmit amplifiers, the first and second receive amplifiers, the reference clock generator, the first and second phase locked loops, and the first and second mixers. Ha And a power supply unit 217 for supplying power to the bias tee 216 which will be described later; and a bias tee 217 connected to the IF duplexer and receiving power from the power supply unit and transferring the power through the transmission line. It is configured and connected to the remote unit 300 described later by the transmission line 223.

       The remote unit 300 includes: an IF duplexer 303 for separating the downlink and uplink IF signals transmitted by the transmission line and transmitting the reference clock received from the reference clock generator to the distributor 307; and the A first attenuator (304) for adjusting the downlink IF signal output from the IF duplexer to a predetermined level; and a transmission IF filter (305) for passing only a required band of the downlink IF signal output from the first attenuator; And a first transmission amplifier 306 for amplifying the downlink IF signal passing through the transmission IF filter with a predetermined gain; and a divider 307 that receives a reference clock signal from the IF duplexer and divides it into equal phase and equal amplitude. And a first phase locked loop 308 for generating a first local frequency signal from a reference clock signal received from the divider; and a downlink output from the first transmit amplifier. A first mixer 309 for synthesizing the high IF signal and the first local frequency signal received from the first phase synchronization loop to generate a predetermined downlink high frequency signal; and a downlink high frequency signal output from the first mixer. A second transmission amplifier 310 for amplifying the signal; and a circulator 311 for passing only the downlink signal passing through the second transmission amplifier in a forward direction; and a required band of a high frequency signal transmitted and received by a coverage antenna, which will be described later. A bandpass filter 312 for passing the bay; and a coverage antenna 313 for transmitting and receiving downlink and uplink high frequency signals with a terminal in a shaded area; and an uplink high frequency signal output from the circulator 311. A first receive amplifier 314 for amplifying the signal; and generating a second local frequency signal from the reference clock signal received from the splitter. The key combines a second phase locked loop 308-1 with an uplink high frequency signal output from the first receiver amplifier and a second local frequency signal received from the second phase locked loop to generate a predetermined uplink IF signal. A second mixer 309-1; and a second receiver amplifier 315 for amplifying the uplink IF signal output from the second mixer with a predetermined gain; and the uplink IF signal output from the second receiver amplifier. A receiving IF filter 316 for passing only a required band; and a second attenuator 317 for adjusting an uplink IF signal output from the receiving IF filter to a predetermined level and transferring the same to a IF duplexer; and the first And a power supply unit for supplying power to the second transmit amplifier, the first and second receive amplifiers, the first and second phase locked loops, the first and second mixers, and the bias-tee 302 to be described later. 301); and the IF duple Standing and are connected to receive the power supply from the power supply bias to pass it through the transmission line-T (302); and comprises a, it is connected with the master unit 200 by the above-described transmission line 223.

       Hereinafter, a preferred embodiment of a distributed relay system for wireless communication according to the present invention will be described in detail with reference to the drawings. In the following description, the same or corresponding members will be denoted by the same reference numerals and detailed description thereof will be omitted.

       2 is a diagram showing the overall configuration of a distributed wireless relay system according to the present invention, as shown in the present invention is largely composed of one master unit 200 and at least one remote unit 300. First, the master unit 200 receives a high frequency signal from a base station 110 of a time division duplex communication system to service a shadow area, and detects a TDD control signal from a downlink signal of the base station to control path switches and downlink paths. Transmitting / receiving with the remote unit using different IF frequencies in the uplink path, the remote unit 300 receives a signal from the master unit 200 to service the shadow area, but the same downlink and uplink IF frequency as the master unit Send and receive using each. In addition, the master unit 200 and the remote unit 300 are connected by a transmission line 223.

       3 is a block diagram showing a configuration of a master unit of a distributed relay system for wireless communication according to the present invention. As described above, the master unit 200 according to the present invention includes a link antenna 201 for transmitting and receiving downlink and uplink high frequency signals with the base station 110, and a band required among high frequency signals transmitted and received with the link antenna. A bandpass filter 202 for passing only a signal of a signal, a coupler 203 for branching a downlink signal passing through the bandpass filter, and a TDD control signal included therein from a downlink signal branched by the coupler, A TDD detection and control unit 224 for controlling on / off of the first to third switches, a circulator 204 for passing the downlink signal passing through the bandpass filter in only one direction, and the TDD detection and control unit A first switch 205 for receiving a control signal and turning on / off a downlink signal passing through the circulator 204 and a downlink high frequency signal passing through the first switch A first transmission amplifier 206 for amplifying a signal with a predetermined gain, a reference clock generator 207 for generating a predetermined reference clock signal, and receiving a reference clock signal generated from the reference clock generator and dividing the signal into two equal phases and dynamic amplitudes. A splitter 208, a first and second phase locked loops 209 and 209-1 for generating first and second local frequency signals from reference clock signals received from the splitter, respectively, and output from the first transmit amplifier. A first mixer 210 for synthesizing the downlink high frequency signal and the first local frequency signal received from the first phase locked loop to generate a predetermined downlink IF signal, and a predetermined gain for the downlink IF signal output from the first mixer; A second transmission amplifier 211 for amplifying a signal, a transmission IF filter 212 for passing only a required band of the downlink IF signal output from the second transmission amplifier, and the transmission signal A first attenuator 213 for adjusting a downlink IF signal output from an IF filter to a predetermined level, and receiving a control signal from the TDD detection and control unit to turn on / off the downlink IF signal output from the first attenuator; A second switch 214, which is turned on / off in conjunction with a first switch, combines a downlink IF signal passing through the second switch and an uplink IF signal to be described later into one path and receives a reference clock from the reference clock generator. An IF duplexer 215 and a control signal received from the TDD detection and control unit to turn on / off an uplink IF signal input through the IF duplexer, and inversely coupled to the first and second switches to turn off / on A third switch, a second attenuator 219 for adjusting the uplink IF signal output from the third switch to a predetermined level, and an uplink IF signal output from the second attenuator A receiving IF filter 220 for passing only a yaw band, a first receiving amplifier 221 for amplifying an uplink IF signal output from the receiving IF filter with a predetermined gain, and an up output from the first receiving amplifier A second mixer 210-1 for synthesizing a link IF signal and a second local frequency signal received from the second phase locked loop 209-1 to generate a predetermined uplink high frequency signal; an up output from the second mixer A second receive amplifier 222, the first to third switches, the first and second transmit amplifiers, the first and second receive amplifiers, the reference, amplifying a link high frequency signal to a circulator 204 and amplifying the link high frequency signal; A power supply 217 for supplying power to a clock generator, first and second phase locked loops, first and second mixers and to a bias-tee 216, which will be described later, connected to the IF duplexer and from the power supply. Power ball It is composed of a bias-tee 217 that is urgently received and delivered through the transmission line.

       Referring to FIG. 3, the high frequency transmission signal from the base station received by the link antenna 201 to the terminal, i.e., the downlink high frequency signal, is filtered by the band pass filter 202 so that the required frequency band is filtered. Is transmitted in one direction only. The downlink high frequency signal passing through the circulator is amplified by the first transmit amplifier 206 by the required gain via the first switch 205, which is coupled to the coupler 203 and the TDD detection and control unit 224. On / off is controlled according to the TDD control signal detected by

       In addition, in order to achieve the object of the present invention, a predetermined reference clock signal is generated by the reference clock generator 207, and the reference clock signal is divided into two phases and equal amplitudes by the divider 208, respectively, to thereby first And after the first and second local frequency signals are generated through the second phase synchronization loops 209 and 209-1, the downlink high frequency signals output from the first transmission amplifier and the first phase synchronization loops are output. One local frequency signal is synthesized by the first mixer 210 to produce a predetermined downlink IF signal.

       The downlink IF signal output from the first mixer is amplified by the second transmit amplifier 211 to a predetermined gain and passes only the required band by passing through the transmission IF filter 212, and is output from the transmission IF filter. The downlink IF signal is adjusted to a predetermined level by the first attenuator 213 and is controlled by the second switch 214 by receiving a control signal from the TDD detection and control unit. In this case, the second switch is interlocked with the first switch, and the downlink IF signal passing through the second switch is combined in one path by the IF duplexer 215 together with the uplink IF signal which will be described later. After receiving the reference clock from the clock generator is transmitted to the remote unit 300 through the transmission line 223.

       On the contrary, the uplink IF signal transmitted from the remote unit 300 through the transmission line 223 is input through the IF duplexer, receives the control signal from the TDD detection and control unit, and passes the path by the third switch. The third switch is interlocked with the first and second switches in reverse. That is, when the first and second switches are turned on and a downlink signal is connected, the third switch is turned off to block an uplink signal, and the third switch is turned on to uplink. When the signal is connected, the first and second switches are turned OFF to block the downlink signal.

       The uplink IF signal output from the third switch is adjusted to a predetermined level by the second attenuator 219 and passes through the receiving IF filter 220 so that only the required band of the uplink IF signal is passed. Amplified by the amplifier 221 to a predetermined gain.

       Then, in order to achieve the object of the present invention, the second local signal of a predetermined frequency generated by the reference clock generator and distributed and divided by the divider and the second phase locked loop and the uplink output from the first receive amplifier. The IF signal is synthesized by the second mixer 210-1, converted into a predetermined uplink high frequency signal, and then amplified by the second receive amplifier 222 with a predetermined gain to be delivered to the circulator 204, and the bandpass. It is transmitted to the base station through a filter and a link antenna.

       In addition, the power supply unit 217 includes the first to third switches, the first and second transmit amplifiers, the first and second receive amplifiers, the reference clock generator, the first and second phase-locked loops, and the first and the second. A power supply is supplied to components that require power, such as a mixer, and a bias-tee 216 is connected to the IF duplexer and receives power from the power supply unit and transmits the power through the transmission line.

       4 is a block diagram showing the configuration of a remote unit of a distributed relay system for wireless communication according to the present invention. As described above, the remote unit 300 according to the present invention separates the downlink and uplink IF signals transmitted by the transmission line 223 and divides the reference clock received from the reference clock generator into the distributor 307. An IF duplexer 303 for transmitting, a first attenuator 304 for adjusting the downlink IF signal output from the IF duplexer to a predetermined level, and for passing only a required band of the downlink IF signal output from the first attenuator A transmission IF filter 305, a first transmission amplifier 306 for amplifying a downlink IF signal passing through the transmission IF filter with a predetermined gain, and receiving a reference clock signal transmitted by the transmission line in phase, A divider 307 that divides in equal amplitude, and a first and second phase locked loop 308 for generating first and second local frequency signals from a reference clock signal received from the divider. 308-1), a first mixer 309 for synthesizing a downlink IF signal output from the first transmission amplifier and a first local frequency signal received from a first phase locked loop to generate a predetermined downlink high frequency signal; A second transmit amplifier 310 for amplifying the downlink high frequency signal output from the first mixer with a predetermined gain, a circulator 311 for passing only the downlink signal passing through the second transmit amplifier in a forward direction, and A bandpass filter 312 for passing only a required band of a high frequency signal transmitted to and received from a coverage antenna to be described later and a circulator, and connected to the bandpass filter to transmit and receive downlink and uplink high frequency signals with a terminal in a shadow area A coverage antenna 313, for amplifying an uplink high frequency signal output from the circulator with a predetermined gain; A first mixer 309 combines an uplink high frequency signal output from the first receive amplifier and a second local frequency signal received from a second phase locked loop to generate a predetermined uplink IF signal. -1), a second receiving amplifier 315 for amplifying the uplink IF signal output from the second mixer with a predetermined gain, and for receiving only the required band of the uplink IF signal output from the second receiving amplifier An IF filter 316, a second attenuator 317 for adjusting the uplink IF signal output from the receiving IF filter to a predetermined level and transferring it to the IF duplexer, the first and second transmit amplifiers, first and second A power supply unit 301 for supplying power to a second receiver amplifier, first and second phase locked loops, first and second mixers and to a bias-tee 302 which will be described later; in And a bias-tee 302 that receives power from the transmission line and transmits the same through the transmission line.

       Referring to FIG. 4, the downlink IF signal transmitted from the master unit received by the transmission line 223 to the remote unit is divided by the IF duplexer 303 and predetermined by the first attenuator 304. Only the required band is passed by adjusting to the level and passing through the transmission IF filter 305, and amplified by the first transmission amplifier 306 to a predetermined gain.

       Then, in order to achieve the object of the present invention, the first local signal and the first transmission of a predetermined frequency generated by the reference clock generator and distributed and generated by the divider 307 and the first phase locked loop 308. The downlink IF signal output from the amplifier is synthesized by the first mixer 309, converted into a predetermined downlink high frequency signal, and then amplified by a predetermined gain by the second transmit amplifier 310 and transmitted in only one direction. After passing through the radar 311, only the required band is filtered by the band pass filter 312 and transmitted to the shaded area through the antenna 313.

       Alternatively, the uplink high frequency signal from the terminal received by the coverage antenna 313 is input to the first receive amplifier 314 via the circulator 311 and amplified with a predetermined gain, and from the first receive amplifier A predetermined uplink IF signal is generated in the second mixer 309-1 by combining the output uplink high frequency signal and the second local frequency signal received from the second phase locked loop 308-1. The uplink IF signal output from the second mixer is amplified by the second receiving amplifier 315 to a predetermined gain, and only the required band is passed by the receiving IF filter 316, and the second attenuator 317 The uplink IF signal output from the receiving IF filter is adjusted to a predetermined level and transferred to the master unit 200 via the IF duplexer 303.

       In addition, the power supply unit 301 is a component that requires power, such as the first and second transmit amplifiers, the first and second receive amplifiers, the first and second phase locked loops, the first and second mixers, and the like. And a bias-tee 302 is connected to the IF duplexer and receives power from the power supply unit and transfers the power through the transmission line.

       3 and 4, components corresponding to each other and having the same function are as follows. First, the bandpass filters 202 and 312 filter only the high frequency downlink and uplink signal bands, and the circulators 204 and 311 have three terminals and adjacent terminals along the arrow direction indicated by the symbol. It outputs a signal only.

       Further, the first transmit amplifier 206 of the master unit and the second transmit amplifier 310 of the remote unit are the same as amplifying the downlink high frequency signal, and the first receive amplifier 314 of the remote unit and the master unit The second receive amplifier 222 amplifies the uplink high frequency signal and is the same as each other, and the second transmit amplifier 211 of the master unit and the first transmit amplifier 306 of the remote unit amplify the downlink IF signal. The same as each other, the second receiving amplifier 315 of the remote unit and the first receiving amplifier 221 of the master unit is to amplify the uplink IF signal to perform the same function.

       Then, the reference clock signal generated by the reference clock generator 207 of the master unit is distributed in the same amplitude and phase by the dividers 208 and 307, respectively, and these divided reference clock signals are respectively phase locked loops. The same is true for the first and second local frequency signals generated by 209, 209-1, 308, and 308-1. In addition, the transmitting IF filters 212 and 305 pass only the downlink IF frequency band, and the receiving IF filters 220 and 316 pass only the uplink IF frequency band, respectively. In addition, the first attenuators 213 and 304, the second attenuators 219 and 317, the IF duplexers 215 and 303, the power supplies 217 and 301, the bias-tees 216 and 302 of the master unit and the remote unit. ) Correspond to each other to have the same function.

       5 is a diagram illustrating IF band filtering of a distributed relay system for wireless communication according to the present invention. FIG. 5 omits unnecessary components from FIG. 3 and FIG. 4 to illustrate the filtering function of the IF band, which is a main part of the present invention, and shows only main components.

       First, the downlink high frequency (RF) signal from the base station is synthesized with the first local signal from the first phase locked loop 209 in the first mixer 210 of the master unit and converted into a downlink IF signal for transmission. Only the downlink IF signal IFdn whose center frequency is f1 is output by the IF filter 212 and input to the IF duplexer 215 of the master unit. The downlink IF signal IFdn is refiltered by the downlink IF signal IFdn whose center frequency is f1 by the transmission IF filter 305 via the transmission line 223 through the IF duplexer 303 of the remote unit. The first mixer 309 then combines the first local signal from the first phase locked loop 308 and converts it into a downlink high frequency (RF) signal.

       Alternatively, the uplink high frequency (RF) signal from the terminal is synthesized with the second local signal from the second phase locked loop 308-1 in the second mixer 309-1 of the remote unit to be an uplink IF signal. Only the uplink IF signal IFup whose center frequency is f2 is output by the receiving IF filter 316 and input to the IF duplexer 303 of the remote unit. The uplink IF signal IFup is likewise passed down through the transmission line 223 via the IF duplexer 215 of the master unit by the receiving IF filter 220 with a downlink IF signal IFup having a center frequency of f2. After filtering, the second mixer 210-1 is synthesized with a second local signal from the second phase locked loop 209-1 and converted into an uplink high frequency (RF) signal.

       Here, the downlink and uplink IF signals have different center frequencies, and the master unit and the remote unit use the same reference clock signal generated by the reference clock generator 207, but divide each of them by two. The first mixers 210, 309 and the second mixers 210-1, after generating the first and second local frequency signals by the phase locked loops 209, 209-1, 308, 308-1, 309-1) obtains a downlink IF signal IFdn having a center frequency f1 and an uplink IF signal IFup having a center frequency f2, respectively.

       As described above, in the distributed relay system for wireless communication according to the present invention, the TDD detection and control unit are unnecessary in the remote unit, and the downlink and uplink IF signals have different frequencies. Since it increases the reliability of communication. In addition, although not separately shown in the drawings of the present invention, the transmission line 223 may be a variety of lines such as a high frequency coaxial cable, an optical line, a UTP cable, and a plurality of remotes, especially in a large building. If the unit is installed in a distributed manner, a wired telephone line or a CATV public hearing network using VDSL communication may be used.

       6 is a view showing a state of use of the distributed relay system for wireless communication according to the present invention. FIG. 6A shows that signals branched by a plurality of branching means 501 from a transmission line 223 connected to one master unit 200 are connected to remote units 300. FIG. 6 (b) shows that the signal distributed by the distribution means 502 from the transmission line 223 connected to one master unit 200 is connected to the remote unit 300 and another distribution means 502. Indicates.

       FIG. 7 is a diagram showing another embodiment of a distributed relay system for wireless communication according to the present invention. FIG. 7A illustrates a master unit and FIG. 7B illustrates a remote unit. First, the master unit includes a link antenna 601 for transmitting and receiving downlink and uplink high frequency signals with a base station, an RF duplexer 602 for separating a transmission and reception path of high frequency signals transmitted and received by the link antenna, and a down through the RF duplexer. A first transmission amplifier 603 for amplifying a link high frequency signal with a predetermined gain, a reference clock generator 604 for generating a predetermined reference clock signal, and a reference clock signal generated from the reference clock generator to receive in-phase and dynamic amplitudes The divider 605 divides into two, the first and second phase locked loops 606 and 606-1, and the first transmit amplifier which generate first and second local frequency signals from reference clock signals received from the divider, respectively. Generating a predetermined downlink IF signal by synthesizing the downlink high frequency signal outputted from the first local frequency signal received from the first phase synchronization loop A first mixer 607, a second transmit amplifier 608 that amplifies the downlink IF signal output from the first mixer with a predetermined gain, and passes only a required band of the downlink IF signal output from the second transmit amplifier A transmission IF filter 609, a first attenuator 610 for adjusting a downlink IF signal output from the transmission IF filter to a predetermined level, a downlink IF signal passing through the first attenuator, and an uplink IF to be described later An IF duplexer 611 which combines the signals in one path and receives a reference clock from the reference clock generator, a second attenuator 615 for adjusting the uplink IF signal output from the IF duplexer to a predetermined level, and the second A receiving IF filter 616 for passing only a required band of the uplink IF signal output from the attenuator, and amplifying the uplink IF signal output from the receiving IF filter with a predetermined gain The first receive amplifier 617 to combine the uplink IF signal output from the first receive amplifier and the second local frequency signal received from the second phase synchronization loop 606-1 to obtain a predetermined uplink high frequency signal. A second mixer 607-1 to generate; a second receiver amplifier 618 that amplifies an uplink high frequency signal output from the second mixer to a predetermined gain and transfers it to the RF duplexer 602; Powering the two transmit amplifiers, the first and second receive amplifiers, the reference clock generator, the first and second phase locked loops, the first and second mixers, and the bias-tee 613 described below. A power supply unit 612 is connected to the IF duplexer and is provided with a bias-tee 613 that receives power from the power supply unit and transfers it through the transmission line.

       In addition, the remote unit, the IF duplexer 703 for separating the downlink and uplink IF signals transmitted by the transmission line 614 and transmits the reference clock received from the reference clock generator to the distributor 707, the A first attenuator 704 for adjusting a downlink IF signal output from an IF duplexer to a predetermined level, a transmission IF filter 705 for passing only a required band of the downlink IF signal output from the first attenuator, and A first transmission amplifier 706 for amplifying the downlink IF signal passing through the transmission IF filter with a predetermined gain, and a divider 707 which receives a reference clock signal transmitted by the transmission line and divides it into equal phase and equal amplitude. First and second phase locked loops 708 and 708-1 for generating first and second local frequency signals from a reference clock signal received from the splitter, and the first transmit amplifier section. A first mixer 709 for synthesizing the downlink IF signal outputted from the first output signal and the first local frequency signal received from the first phase synchronization loop to generate a predetermined downlink high frequency signal, and a downlink high frequency signal output from the first mixer A second transmit amplifier 710 for amplifying a predetermined gain, an RF duplexer 711 for combining a downlink high frequency signal passing through the second transmit amplifier and an uplink high frequency signal, which will be described later, into one path, and the RF duplexer A coverage antenna 712 connected to a terminal for transmitting and receiving downlink and uplink high frequency signals with a terminal in a shadow area, a first receiving amplifier 713 for amplifying an uplink high frequency signal output from the RF duplexer with a predetermined gain, and The uplink high frequency signal output from the first receive amplifier and the second local frequency signal received from the second phase locked loop are summed. A second mixer 709-1 for generating a predetermined uplink IF signal, a second receiver amplifier 714 for amplifying the uplink IF signal output from the second mixer with a predetermined gain, and the second receiver amplifier. A receiving IF filter 715 for passing only a required band of the uplink IF signal output from the second attenuator for adjusting the uplink IF signal output from the receiving IF filter to a predetermined level and transmitting the same to the IF duplexer ( 716), powering the first and second transmit amplifiers, the first and second receive amplifiers, the first and second phase locked loops, and the first and second mixers, to a bias-tee 702 described below. A power supply unit 701 for supplying power and a bias-tee 702 connected to the IF duplexer and receiving power from the power supply unit and transferring the power through the transmission line.

       Another embodiment of the present invention as described above relates to a relay apparatus that does not use a TDD control signal, and is configured as shown in FIGS. 7A and 7B, and the operation thereof is described with reference to FIGS. 3 and 4. Same thing as That is, since FIG. 7A corresponds to FIG. 3 and FIG. 7B corresponds to FIG. 4, detailed description thereof will be omitted.

       The present invention as described above has been described and illustrated with respect to the preferred embodiment, but the present invention is not limited to the above-described embodiment of the present invention described in the claims by those of ordinary skill in the art Various changes and modifications can be made without departing from the spirit.

       As described above, the present invention, while receiving a high frequency signal from the base station of the time division duplex communication system to service the shadow area, while detecting the TDD control signal from the downlink signal of the base station to control the path switches and downlink path and uplink path At least one master unit transmitting and receiving to and from the remote unit at different IF bands, and receiving and receiving a signal from the master unit to serve a shadow area, using at least one of the same downlink and uplink IF frequencies as the master unit. The remote unit has the effect that the remote units do not need a separate TDD control signal.

Claims (8)

delete An apparatus for relaying a high frequency signal of a communication system or a base station, The master unit detects a TDD control signal from a downlink high frequency signal received from a base station of a time division duplex communication system and operates path switches for controlling the downlink and uplink paths according to the control signal. Distributing reference clock signals generated by one reference clock generator to generate downlink IF signals and uplink IF signals having different center frequencies by phase-locked loops having different center frequencies, and transmitting them respectively. Filter with and IF filter for reception, Transmitting the downlink and uplink IF signals and the reference clock signals coupled by an IF duplexer to at least one remote unit by a transmission line, The remote unit is connected to the master unit by a transmission line, An IF duplexer separates the downlink IF signal and the uplink IF signal and filters them with a transmission IF filter and a reception IF filter, respectively, Wireless to provide a downlink high frequency signal and an uplink high frequency signal by using a phase locked loop having a different center frequency by distributing a reference clock signal transmitted from the IF duplexer of the master unit and the IF duplexer of the remote unit. Distributed relay system for communication. The method of claim 2, wherein the master unit, A link antenna for transmitting and receiving downlink and uplink high frequency signals with the base station; A bandpass filter for passing only a required band of a high frequency signal transmitted and received by the link antenna; A coupler for branching the downlink high frequency signal passing through the bandpass filter; A TDD detection and control unit for detecting a TDD control signal included therein from the downlink signal branched by the coupler and controlling the switches to be described later; A circulator for passing a downlink signal passing through the bandpass filter only in a forward direction; A first switch which receives a control signal from the TDD detection and control unit and turns on / off a downlink signal passing through the circulator; A first transmit amplifier for amplifying the downlink high frequency signal passing through the first switch with a predetermined gain; A reference clock generator for generating a predetermined reference clock signal; A divider which receives a reference clock signal generated from the reference clock generator and divides the signal into two phases of equal phase and equal amplitude; First and second phase locked loops for generating first and second local frequency signals from a reference clock signal received from the splitter, respectively; A first mixer for synthesizing a downlink high frequency signal output from the first transmit amplifier and a first local frequency signal received from a first phase locked loop to generate a predetermined downlink IF signal; A second transmit amplifier for amplifying the downlink IF signal output from the first mixer with a predetermined gain; A transmission IF filter for passing only a required band of the downlink IF signal output from the second transmission amplifier; A first attenuator for adjusting a downlink IF signal output from the transmitting IF filter to a predetermined level; A second switch receiving a control signal from the TDD detection and control unit and turning on / off a downlink IF signal output from the first attenuator, in association with the first switch; An IF duplexer combining the downlink IF signal passing through the second switch and the uplink IF signal described later in one path and receiving a reference clock from the reference clock generator; A third switch which receives a control signal from the TDD detection and control unit and turns on / off an uplink IF signal input through the IF duplexer, but is inversely coupled to the first and second switches; A second attenuator for adjusting the uplink IF signal output from the third switch to a predetermined level; A reception IF filter for passing only a required band of an uplink IF signal output from the second attenuator; A first receiving amplifier for amplifying an uplink IF signal output from the receiving IF filter with a predetermined gain; A second mixer for synthesizing the uplink IF signal output from the first receiving amplifier and the second local frequency signal received from the second phase locked loop to generate a predetermined uplink high frequency signal; A second receiver amplifier for amplifying an uplink high frequency signal output from the second mixer with a predetermined gain and transmitting the amplified signal to the circulator; Power and bias the first to third switches, first and second transmit amplifiers, first and second receive amplifiers, reference clock generators, first and second phase locked loops, and first and second mixers. A power supply for supplying power to the tee; And And a bias-tee connected to the IF duplexer and receiving power from a power supply unit and transmitting the power through the transmission line. The method of claim 2, wherein the remote unit, An IF duplexer that separates the downlink and uplink IF signals transmitted by the transmission line and receives a reference clock from the reference clock generator; A first attenuator for adjusting a downlink IF signal output from the IF duplexer to a predetermined level; A transmission IF filter for passing only a required band of the downlink IF signal output from the first attenuator; A first transmit amplifier for amplifying the downlink IF signal passing through the transmission IF filter with a predetermined gain; A divider configured to receive a reference clock signal transmitted by the transmission line and divide the signal into two phases of equal phase and equal amplitude; First and second phase locked loops for generating first and second local frequency signals from a reference clock signal received from the splitter, respectively; A first mixer for synthesizing a downlink IF signal output from the first transmit amplifier and a first local frequency signal received from a first phase locked loop to generate a predetermined downlink high frequency signal; A second transmit amplifier for amplifying a downlink high frequency signal output from the first mixer with a predetermined gain; A circulator for passing a downlink signal passing through the second transmit amplifier only in a forward direction; A bandpass filter for passing only a required band of a high frequency signal transmitted and received by a coverage antenna; A coverage antenna for transmitting and receiving downlink and uplink high frequency signals with a terminal in a shaded area; A first receiver amplifier for amplifying an uplink high frequency signal output from the circulator with a predetermined gain; A second mixer for synthesizing an uplink high frequency signal output from the first receiving amplifier and a second local frequency signal received from a second phase locked loop to generate a predetermined uplink IF signal; A second receiver amplifier for amplifying the uplink IF signal output from the second mixer with a predetermined gain; A reception IF filter for passing only a required band of an uplink IF signal output from the second reception amplifier; A second attenuator for adjusting the uplink IF signal output from the receiving IF filter to a predetermined level and transferring the uplink IF signal to the IF duplexer; A power supply unit for supplying power to the first and second transmit amplifiers, first and second receive amplifiers, first and second phase locked loops, and first and second mixers and to supply bias-tees; And And a bias-tee connected to the IF duplexer and receiving power from a power supply unit and transmitting the power through the transmission line. An apparatus for relaying a high frequency signal of a communication system or a base station, The master unit transmits and receives downlink and uplink high frequency signals with the communication system or the base station, Distributing reference clock signals generated by one reference clock generator to generate downlink IF signals and uplink IF signals having different center frequencies by phase-locked loops having different center frequencies, and transmitting them respectively. Filter with and IF filter for reception, Transmitting the downlink and uplink IF signals and the reference clock signals coupled by an IF duplexer to at least one remote unit by a transmission line, The remote unit is connected to the master unit by a transmission line, An IF duplexer separates the downlink IF signal and the uplink IF signal and filters them with a transmission IF filter and a reception IF filter, respectively, Wireless to provide a downlink high frequency signal and an uplink high frequency signal by using a phase locked loop having a different center frequency by distributing a reference clock signal transmitted from the IF duplexer of the master unit and the IF duplexer of the remote unit. Distributed relay system for communication. The method of claim 5, wherein the master unit, A link antenna for transmitting and receiving downlink and uplink high frequency signals with the communication system or the base station; An RF duplexer for combining downlink and uplink high frequency signals transmitted and received by the link antenna in one path; A first transmit amplifier for amplifying a downlink high frequency signal passing through the RF duplexer with a predetermined gain; A reference clock generator for generating a predetermined reference clock signal; A divider which receives a reference clock signal generated from the reference clock generator and divides the signal into two phases of equal phase and equal amplitude; First and second phase locked loops for generating first and second local frequency signals from a reference clock signal received from the splitter, respectively; A first mixer for synthesizing a downlink high frequency signal output from the first transmit amplifier and a first local frequency signal received from a first phase locked loop to generate a predetermined downlink IF signal; A second transmit amplifier for amplifying the downlink IF signal output from the first mixer with a predetermined gain; A transmission IF filter for passing only a required band of the downlink IF signal output from the second transmission amplifier; A first attenuator for adjusting a downlink IF signal output from the transmitting IF filter to a predetermined level; An IF duplexer combining the downlink IF signal passing through the first attenuator and the uplink IF signal described later in one path and receiving a reference clock from the reference clock generator; A second attenuator for adjusting an uplink IF signal output from the IF duplexer to a predetermined level; A reception IF filter for passing only a required band of an uplink IF signal output from the second attenuator; A first receiving amplifier for amplifying an uplink IF signal output from the receiving IF filter with a predetermined gain; A second mixer for synthesizing the uplink IF signal output from the first receiving amplifier and the second local frequency signal received from the second phase locked loop to generate a predetermined uplink high frequency signal; A second receiver amplifier for amplifying an uplink high frequency signal output from the second mixer with a predetermined gain and transferring the amplified signal to a circulator; A power supply unit supplying power to the first and second transmit amplifiers, first and second receive amplifiers, a reference clock generator, first and second phase locked loops, and first and second mixers ; And And a bias-tee connected to the IF duplexer and receiving power from a power supply unit and transmitting the power through the transmission line. delete delete

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