KR101054926B1 - Wireless repeater - Google Patents

Abstract

The present invention relates to a wireless relay apparatus capable of communicating with a plurality of base stations, and more particularly to a wireless relay apparatus capable of performing a smoother wireless relay process by performing communication with a base station having an optimal call quality.

The wireless relay apparatus according to the present invention is a base station antenna for performing wireless communication with a plurality of base stations fixedly installed at a predetermined position, a terminal antenna for performing wireless communication with a plurality of wireless terminals, a forward signal applied from the base station antenna is predetermined Level amplification is provided to the terminal antenna, and the reverse signal applied from the terminal antenna is amplified by a predetermined level and provided to the base station antenna, but the call quality information of each base station is calculated from the wireless terminal based on the forward signal applied from the base station antenna. And relay processing means for controlling the base station antenna to transmit an applied reverse signal to a base station having an optimal call quality.

Description

Wireless repeater {Wireless repeater}

1 is a view schematically showing a configuration of a general wireless relay device.

Figure 2 is a block diagram showing the functional separation of the internal configuration of the radio relay apparatus according to the present invention.

Figure 3 is a block diagram showing the functional separation of the internal configuration of the coupling means 140 shown in FIG.

Figure 4 is a block diagram showing the functional separation of the internal configuration of the amplifying means 150 shown in FIG.

5 is a diagram illustrating in more detail the configuration of the base station antenna 110 and antenna control unit 130 shown in FIG.

6 is a diagram illustrating the shape of the base station antenna 110 shown in FIG.

7 is a diagram illustrating another configuration of the base station antenna 500 and the antenna control unit 600 in more detail.

8 is a diagram illustrating the shape of the base station antenna 600 shown in FIG.

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

100: base station antenna, 200: terminal antenna,

300: relay processing means, 310: antenna control means,

320: coupling means, 330: amplification means,

340: control means.

The present invention relates to a wireless relay apparatus capable of communicating with a plurality of base stations, and more particularly to a wireless relay apparatus capable of performing a smoother wireless relay process by performing communication with a base station having an optimal call quality.

In general, a wireless communication system amplifies a forward signal received from a base station and transmits it to a wireless terminal in a communication shaded area to prevent degradation of the communication service caused by a shadow area such as an underground or a building, or from a wireless terminal in a communication shaded area. A wireless repeater that amplifies the received reverse 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 apparatus includes a base station antenna 11 performing wireless communication with the base station 1 and a terminal antenna 12 performing wireless communication with the wireless terminal 2. Relay processing means for amplifying a forward signal applied from the base station 1 and transmitting it through the terminal antenna 12, and amplifying a reverse signal applied from the radio terminal 2 and sending it to the base station through the base station antenna 11. It is comprised with 10.

In this case, the base station antenna 11 is configured such that the area A is configured to be able to communicate with a plurality of fixed bases, for example, the first to third base stations 1: 1a, 1b, 1c. The base station antenna 11 is generally composed of a directional antenna, and is installed to be directed to a specific base station having the highest power level, for example, the second base station 1b.

However, when the second base station 1b with which the base station antenna 11 communicates, the noise component increases due to the bursting of the call, etc., and the call quality with the base station antenna 11 falls below a certain level, the second base station 1b Due to the noise component mixed in the forward signal applied from), a problem arises that the service for the wireless terminal 2 is not possible.

Accordingly, the present invention has been made in view of the above circumstances, and by checking the call quality state for each base station based on forward signals provided from a plurality of base stations, it is possible to perform communication with the base station having the best call quality. The technical objective is to provide a wireless relay device that can provide a high quality wireless relay service.

Wireless relay apparatus according to the present invention for achieving the above object is a base station antenna for performing wireless communication with a plurality of base stations fixedly installed at a predetermined position, a terminal antenna for performing a wireless communication with a plurality of radio terminals, from the base station antenna Amplify the applied forward signal to the terminal antenna by a predetermined level and amplify the reverse signal applied from the terminal antenna to the base station antenna, and provide it to the base station antenna, based on the forward signal applied from the base station antenna. And relay processing means for controlling the base station antenna to calculate information and to transmit a reverse signal applied from a wireless terminal to a base station having an optimal call quality.

That is, according to the above, the communication quality of the wireless terminal is improved by confirming the call quality state of each base station based on the forward signals provided from the plurality of base stations to perform communication with the base station having the best call quality. Can be provided.

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

Figure 2 is a block diagram showing the functional separation of the internal configuration of the wireless repeater according to the present invention.

As shown, the wireless relay apparatus according to the present invention includes a base station antenna 100 for wireless transmission and reception with a base station, a terminal antenna 200 for wireless transmission and reception with a wireless terminal, and a forward signal applied from the base station antenna 100. Amplifies a predetermined level to provide the terminal antenna 200, and amplifies a reverse signal applied from the terminal antenna 200 to the base station antenna 100, and provides a forward signal applied from the base station antenna 100. A relay processing means 300 for controlling the base station antenna 100 to calculate the call quality information of each base station and to transmit the reverse signal applied from the wireless terminal to the base station having the optimal call quality. .

Here, the base station antenna 100 is configured to perform wireless communication with a plurality of base stations as shown in FIG.

In addition, the relay processing means 300 performs a forward signal receiving process applied from the base station antenna 100 and also controls the base station antenna 100 to transmit a reverse signal to the base station in an optimal state. And a forward signal applied from the antenna control means 310 at a predetermined ratio and sent to the amplifying means 330 and the control means 340 to be described later, and a reverse applied from the amplifying means 330. Coupling means 320 for synthesizing the signal and a predetermined antenna control signal applied from the control means 340 to the antenna control means 310, by a predetermined level amplification of the forward signal applied from the coupling means 320 In addition to providing to the terminal antenna 200, amplification means 330 for amplifying a reverse signal applied from the terminal antenna 200 to the coupling means 320 to provide a predetermined level And controlling overall operation of the wireless relay apparatus, calculating call quality information for each base station based on a forward signal applied from the coupling means 320, and identifying a base station having an optimal call quality. It comprises a control means 340 for providing an antenna control signal to the antenna control means 310 through the coupling means 320.

Here, the control means 340 is a call for the forward signal for each base station by using the data memory 341 for storing the base station registration information and the selected base station information, and the forward signal applied from the coupling means 320 A first modem 342 for calculating quality information, a second modem 343 for performing antenna control signal transmission / reception processing with the antenna control means 310, and for each base station applied from the first modem 342 And a processor 344 which selects a base station having the best call quality based on the call quality information and provides a second antenna 342 with a predetermined antenna control signal including the selected base station information. At this time, the base station registration information stored in the data memory 341 includes identification codes of each base station, for example, PN code information, and location information such as distance and direction. The first modem 342 performs CDMA demodulation processing on the forward signal applied from the coupling means 320 using the PN codes of the base stations stored in the data memory 341. In addition, the first modem 342 calculates the call quality information of the demodulated forward signal, for example, a reception sensitivity level, a signal-to-noise ratio, and an amplification adjustment value, by using a digital monitoring (DM) function to provide the processor 344 to the processor 344. do. In addition, the second modem 343 modulates a predetermined antenna control signal applied from the processor 344 to the coupling means 320. In addition, the processor 344 compares the call quality information of the forward signal of each base station provided from the first modem 342, selects the base station determined to be the best call quality state, and selects the base station in the data memory 341. In addition to storing the information, a predetermined antenna control signal including the identification information and the location information of the selected base station is generated and provided to the second modem 343. In this case, the processor 344 periodically performs a series of antenna control signal generation processing, checks the selection base station information stored in the data memory 341, and transmits the antenna control signal to the second modem (only when the base station information is changed. 343).

In addition, the coupling means 320 is composed of a multiplexer 321 and a line coupler 322 as shown in FIG. The multiplexer 321 provides the forward signal applied from the antenna control means 310 to the line coupler 322, and the reverse signal applied from the line coupler 322 and the second modem 343 of the control means 340. The antenna control signal applied from the synthesized and transmitted to the antenna control means (310). The line coupler 322 divides the forward signal applied from the multiplexer 321 by a predetermined ratio to provide the first modem 343 and the amplifying means 330 of the control means 340, and from the amplifying means 330. The applied reverse signal is provided to the multiplexer 321. At this time, one end of the line coupler 322 is grounded through an impedance matching resistor (R).

In addition, the amplifying means 330 is the first and second duplexers (331,332) and the first duplexer for setting the signal transmission and reception paths between the coupling means 320 and the terminal antenna 200 as shown in FIG. A first amplifier 333 for a predetermined level amplification of the forward signal applied from the 331 and a high power amplified forward signal from the first amplifier 333 are provided to the terminal antenna 200 through the second duplexer 332. A predetermined level amplification of the reverse signal applied from the low noise amplifier 335 (LNA) and the low noise amplifier 335 which low-amplifies the reverse signal applied from the first high power amplifier 334 (HPA), the second duplexer 332 A second high output amplifier 337 (HPA) that provides a high output amplification of the second amplifier 336 and the reverse signal applied from the second amplifier 336 to the coupling means 320 through the first duplexer 331. It is configured to include).

In addition, the base station antenna 100, as shown in Figure 5 from one transmitting antenna 110 for transmitting a reverse signal to the base station and from each base station, such as the first to third base stations (1a, 1b, 1c) The first to third receiving antennas 120: 121, 122, and 123 for receiving an applied forward signal are included. The receiving antenna 120 is arranged to have a directivity for each base station installed at a location capable of communicating with the wireless relay device according to the present invention.

5 shows an internal configuration of the antenna control means 310 for controlling the base station antenna 100 having the above configuration.

That is, the antenna control unit 310 is coupled to correspond one-to-one with the first to third reception antennas 121, 122, and 123 so as to filter the frequency band of the forward signal applied from the reception antenna. 311a, 311b, 311c and the first to third filters 311a, 311b, and 311c are combined in a one-to-one correspondence to perform the low noise amplification processing for the forward signal applied from the filter 311. Combiner 313 for synthesizing respective forward signals applied from low noise amplifiers 312: 312a, 312b, 312c, and LNA, first to third low noise amplifiers 3312a, 312b, and 312c, and the combiner ( A duplexer 314 and the duplexer 314 for transmitting the forward synthesis signal applied from the 313 to the multiplexer 315 to be described later, or for transmitting the reverse signal applied from the multiplexer 315 to the transmission antenna 110. Forward Synthesis Approved by Is transmitted to the coupling means 320, and the signal applied from the coupling means 320 is divided into frequency bands to provide the reverse signal to the duplexer 314, and the antenna control signal to the antenna drive control unit 316. An antenna driving control unit 316 for controlling the antenna driver 317 to change the signal transmission direction of the transmission antenna 110 based on the multiplexer 315 and the antenna control signal applied from the multiplexer 315. And an antenna driver 317 which is combined with the transmission antenna 110 to change the directing direction of the transmission antenna 110 based on a control signal applied from the antenna driver control unit 316. Here, the antenna driver control unit 316 provides the antenna driver 317 with information corresponding to the difference between the base station position information of the antenna control signal provided from the multiplexer 315 and the position information of the currently set base station.

That is, Figure 6 illustrates the configuration of the base station antenna 100 shown in Figure 5, Figure 6a is an external perspective view of the base station antenna 100, Figure 6b is a side view, showing a front case open state. will be. As shown, the base station antenna 100 is configured such that the first to third receiving antennas 121, 122, and 123 are spaced apart by a predetermined angle so as to have directivity characteristics for respective base stations installed at different positions inside the predetermined case C. . In addition, the transmission antenna 110 is configured to be coupled to the antenna driver 317 for adjusting the direction of the transmission antenna 110 installed below. The antenna driver 317 rotates on the basis of a control signal applied from the antenna driver controller 316, a motor shaft 317b fixedly coupled to the motor 317a, and the transmission antenna 110. The rear and one end of the support plate 317d, the other end is fixedly coupled to the antenna shaft 317c, the first and second reduction gears 317e and 317f between the antenna shaft 317c and the motor shaft 317a. Is axially coupled through the fixed shaft (317g) is configured. That is, as the motor 317a rotates, the output direction of the transmission antenna 110 coupled by the first and second reduction gears 317e and 317f is changed.

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

First, in the wireless relay apparatus according to the present invention, communicable peripheral station information is registered in advance in the data memory 341 of the control means 340. For example, the manager may directly input distance, direction angle, and PN information of a plurality of base stations located nearby or automatically register the corresponding base station information in the data memory 341 through communication with the base station.

In the above state, when a forward signal is received from the base station through each receiving antenna 120 of the radio relay apparatus, each forward signal is synthesized by the antenna controller 310 and the forward synthesized signal is amplified by the coupling means 320. Means 330 and control means 340 are provided. That is, the antenna controller 310 provides each forward signal applied from the plurality of reception antennas 120 to the combiner 313 through the filter 311 and the low noise amplifier 312. The combiner 313 synthesizes a plurality of forward signals and provides them to the coupling means 320 through the duplexer 314 and the multiplexer 315. The coupling means 320 branches the forward synthesis signal applied from the antenna controller 310 at a predetermined ratio to provide the amplification means 330 and the control means 340.

Here, the forward synthesis signal applied to the amplifying means 330 is amplified by a predetermined level based on the control signal of the control means 340 and wirelessly transmitted to the wireless terminal through the terminal antenna 200.

Meanwhile, the forward synthesized signal applied to the control means 340 is applied to the first modem 342. The first modem 342 performs CDMA demodulation on the forward synthesized signal using a PN code, and calculates call quality information, that is, reception level, signal-to-noise ratio, and amplification control value, based on the demodulated forward signal for each base station. Provided at 344. The processor 344 controls the amplification level of the amplifying means 330 based on the call quality information for each base station applied from the first modem 342, selects a base station in an optimal call quality state, and selects the selected base station information, That is, a predetermined antenna control signal including the base station location information is generated, modulated by the second modem 343, and then provided to the coupler 320. Herein, the second modem modulates the antenna control signal at a frequency different from the reverse signal frequency band.

On the other hand, the reverse signal applied from the terminal antenna 200 is amplified by a predetermined level through the amplifying means 330 is applied to the coupling means 320, the multiplexer 321 of the coupling means 320 and the reverse signal After synthesizing the antenna control signal, it is provided to the antenna controller 310. In addition, the multiplexer 315 of the antenna controller 310 divides the signal applied from the coupling means 320 for each frequency band to provide the reverse signal to the duplexer 314 and the antenna control signal to the antenna drive controller 316. to provide. Subsequently, the antenna driver control unit 316 controls the antenna driver 317 based on the received antenna control signal to adjust its directing direction so that the transmission antenna 110 is directed to the selected base station. Accordingly, the reverse signal applied to the duplexer 314 is wirelessly transmitted to the base station through the transmission antenna 111 which is oriented in a state in which the call quality is optimal.

That is, according to the above embodiment, the base station information in the optimal call quality state is extracted based on the forward signals applied from the multiple base stations, and the antenna transmission direction is adjusted so that the transmitting antenna is directed to the base station, thereby applying the reverse signal applied from the radio terminal. It can be provided to the base station of the optimal call quality.

However, in the above embodiment, the transmission antenna is configured to transmit a reverse signal toward one base station, so that the signal relay service is interrupted when handoff processing is performed between the base stations due to the change in the call quality state for each base station during the service. Will be.

Therefore, there is a need to implement a wireless relay apparatus such that service interruption does not occur during handoff processing between base stations.

7 shows the internal configuration of the base station antenna 500 and the antenna control unit 600 of the radio relay apparatus configured in view of the above.

That is, as shown in FIG. 7, the base station antenna 500 includes first to fourth transmit / receive antennas 510, 520, 530, and 540 arranged to face each of the communicable base stations, and the antenna controller 600 includes a control unit 340. The reverse signal is controlled to be wirelessly transmitted to the base station through one or more transmission / reception antennas among the first to fourth transmission / reception antennas 500 based on the provided antenna control signal.

Here, the base station antenna 500 may be configured as shown in FIG. Here, FIG. 8A is an external perspective view of the base station antenna 500, and FIG. 8B is a side view illustrating the open front case. That is, as illustrated in FIG. 8, the first to fourth transmission / reception antennas 510, 520, 530, and 540 are spaced apart from each other to face different directions.

In addition, the antenna controller 600 is coupled to correspond to the first to fourth transmit and receive antennas (510, 520, 530, 540 one-to-one) so that a forward signal applied from the transmit and receive antenna 500 is output to the first output terminal, and is applied from the second input terminal. The reverse signal is combined with the first to fourth circulators 610: 611, 612, 613 and 614 output to the corresponding transmission / reception antenna 500 and the first to fourth circulators 610 in a one-to-one correspondence to the frequency band of the reverse signal. First to fourth transmission filters 621: 621a, 621b, 621c, and 621d that are filtered and provided to the second input terminal of the circulator 610, and a forward signal applied from the first output terminal of the circulator 610. A filter unit 620 including first to fourth reception filters 622: 622a, 622b, 622c, and 622d for filtering a frequency band of the first and fourth reception filters 622a, 622b, 622c, and 622d. One-to-one correspondence to forward A first to fourth low noise amplifiers 630: 631, 632, 633 and 634 performing a low noise amplification process on the call; a combiner 640 for synthesizing a forward signal applied from the first to fourth low noise amplifiers 630; The forward synthesized signal applied from the binner 640 is provided to the multiplexer 660, and the reverse signal applied from the multiplexer 660 is applied to the duplexer 650 and the duplexer 650 provided to the switching unit 580. The forward synthesis signal is provided to the coupling means 320, the signal applied from the coupling means 320 is divided into frequency bands, and the reverse signal is provided to the switching unit 680, and the antenna control signal is the antenna control unit ( The multiplexer 660 provided to the 670 and the antenna control unit 670 for controlling the output path of the switching unit 680 based on the antenna control signal applied from the multiplexer 660, and applied from the antenna control unit 670 It is formed by a switching unit 680 provided to a transmit filter corresponding to the selected base station of the reverse signal applied to a predetermined control signal from the duplexer 650, the first to fourth transmit filter 223.

Here, the switching unit 680 is configured to route the reverse signal input under the control of the antenna controller 670 to be output through one or a plurality of transmission / reception antennas 510.

That is, according to the above configuration, when the first base station is selected as the transmitting base station, it is determined that the call quality of the third base station is better than that of the first base station, and thus a handoff from the first base station to the third base station should be performed. The means 340 provides the first base station and the third base station information to the antenna controller 600 through the coupling means 320. In addition, the antenna controller 670 of the antenna controller 600 controls the reverse signal input through the switching unit 680 to be transmitted to both transmit and receive antennas 510 and 530 corresponding to the first and third base stations. In other words, service interruption due to handoff between base stations does not occur.

Therefore, according to the above embodiment, communication quality of the wireless terminal is better by confirming the call quality state of each base station based on the forward signals provided from the plurality of base stations to perform communication with the base station having the best call quality. To provide services.

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 check the call quality state of each base station based on a forward signal provided from a plurality of base stations to perform communication with the base station having the best call quality. The communication service can be provided.

Claims (6)

A base station antenna performing wireless communication with a plurality of base stations fixedly installed at a predetermined position; A terminal antenna performing wireless communication with a plurality of wireless terminals, A predetermined level of the forward signal applied from the base station antenna is provided to the terminal antenna, and a reverse level applied from the terminal antenna is provided to the base station antenna, and provided to the base station antenna, based on the forward signal applied from the base station antenna. And relay processing means for controlling the base station antenna to calculate the call quality information of the base station and to transmit the reverse signal applied from the wireless terminal to the base station having the optimal call quality. The method of claim 1, The relay processing apparatus includes an antenna controller for controlling the base station antenna to perform forward signal reception processing applied from the base station antenna and to transmit the reverse signal to the base station in an optimal state based on a predetermined control signal; Coupling means for separating and outputting the forward signal applied from the antenna controller at a predetermined ratio, and providing the reverse signal and the predetermined selected base station information to the antenna controller; Amplification means for amplifying a forward signal applied from the coupling means to a terminal antenna and amplifying a reverse signal applied from the terminal antenna to a coupler by a predetermined level; And a processor for demodulating the forward signal applied from the coupling means to calculate call quality information for each base station, and comparing the call quality information to provide the selected optimal base station information to the coupling means. Wireless repeater. The method according to claim 1 or 2, And the call quality information of the base station includes a reception level of the forward signal, a signal-to-noise ratio, and an amplification adjustment value. The method of claim 1, The base station antenna is composed of one transmitting antenna for transmitting a reverse signal to the base station, and a plurality of receiving antennas arranged to direct different base stations to receive a forward signal from the base station, And the relay processing means is configured to adjust an output direction of the transmission antenna to direct an optimal base station. The method of claim 1, The base station antenna is configured to be directed to different base stations are composed of a plurality of transmission and reception antennas for receiving a forward signal from the base station and a reverse signal transmission process to the base station, And the relay processing means controls to transmit a reverse signal through a transmission / reception antenna aimed at an optimal base station. The method of claim 5, And the relay processing means controls to transmit a reverse signal to two base stations at the same time.

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