KR20150035043A - Energy dispersion consuming type hybrid radio communications repeater - Google Patents

Abstract

The present invention relates to an energy dispersion consuming type hybrid wireless communication repeater which dispersively depends with an RF signal through a first duplexer without totally depending on DC voltage of an AC/DC converter (10) in an MCU (20), in other words, makes the switch (70) use DC voltage converted through an RF/DC converter (60) after taking an RF power out from an RF signal in a coupler (50), thereby achieving maximization of energy efficiency.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an energy dispersive hybrid wireless communication repeater,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an energy dispersive hybrid wireless communication repeater, and more particularly, to an energy dispersive hybrid wireless communication repeater installed between a base station and a terminal for relaying radio signals.

Generally, a wireless repeater is installed in a building where a radio wave can not reach well or in a shaded area that is blocked from the outside such as a subway, and relays radio signals between a base station and a subscriber terminal.

Prior Art Document (10-2009-0052483; RF repeater) 1 is a block diagram showing a radio repeater of the RF scheme mentioned in the prior art document. As shown in FIG. 1, the RF repeater described in the prior art includes a first duplexer 110 for transmitting and receiving a radio signal to and from a base station, and a second duplexer 120 for transmitting and receiving a radio signal to and from the mobile station A forward low noise amplifier 210 for low-noise amplifying a forward signal between the first duplexer 110 and the second duplexer 120, a forward gain controller 220 for controlling a repeater to a constant output, A forward high band amplifier 240 for amplifying the forward signal to the required output, and a forward output detector 250 for detecting the intensity of the forward output level. A low noise amplifier 310 for low-noise amplifying a reverse signal is provided between the second duplexer 120 and the first duplexer 110, a reverse gain controller 320 for controlling a repeater to a constant output, A high-power amplifier 340 for amplifying a reverse signal to a required output, and an inverse output detector 350 for detecting the intensity of a reverse output level. In the RF repeater described in the prior art document, the duplexer includes a first duplexer 110 for transmitting and receiving a radio signal to and from a base station, and a second duplexer 120 for transmitting and receiving a radio signal to and from the terminal. The forward amplification includes a forward low noise amplifier 210 for low noise amplifying a forward signal, a forward gain controller 220 for controlling a repeater to a constant output, a forward bandpass filter 230 for selecting only a forward signal, A forward high power amplifier 240 for amplifying the forward signal to the required output and a forward detector 250 for detecting the strength of the forward output level. The backward amplification includes a low noise amplifier 310 for low noise amplifying the reverse signal, A reverse high pass amplifier 330 for amplifying the reverse signal to a required output, a reverse high pass filter 330 for outputting a signal having a reverse output level, And an inverse detector 350 for detecting the intensity. The signal link of the RF repeater described in the prior art document composed of two RF paths as described above will be described as follows. First, only the forward signal is selected through the first duplexer 110, and the selected forward signal is low-noise amplified by the forward low-noise amplifier 210 and then forward-amplified by the forward gain control unit 220 to an appropriate signal size And is then amplified to a desired output by the forward high power amplifier 240 after being removed by the forward bandpass filter 230 and then applied to the second duplexer 120 to remove the unwanted wave, . Meanwhile, the radio signal transmitted from the mobile station is received by the second duplexer 120, separated from the reverse signal, amplified by the low-noise amplifier 310, and then controlled by the reverse gain controller 320 to an appropriate level. And then amplified to a desired size by a reverse high-power amplifier 340. The first duplexer 110 removes unwanted waves, and then is transmitted to the base station. However, the radio repeater of the RF scheme mentioned in the prior art has no suggestion of power consumption at all.

It is an object of the present invention to provide an RF / DC converter that is independent of the DC voltage of an AC / DC converter in an MCU and is distributed dependent on the RF signal through the first duplexer, The present invention provides an energy-dispersive hybrid wireless communication repeater capable of maximizing energy efficiency by selectively using DC voltages converted through a switch in a switch.

An object of the present invention is to provide an energy dispersive hybrid wireless communication repeater capable of economically expanding various communication service coverage with high energy efficiency by selecting commercial power and RF power of AC 110 ~ 220V between a base station and a terminal .

According to an aspect of the present invention,

An AC / DC converter for converting a commercial power of AC 110 to 220 V to a DC voltage; an MCU for receiving a DC voltage from the AC / DC converter; The RF signal is amplified, attenuated, filtered, and re-amplified to a forward line while receiving the RF signal through the first duplexer, and then transmitted to the terminal through the second duplexer and the second antenna, Filtering, attenuating, and re-amplifying the signal by a reverse line while receiving the signal through the second duplexer, and transmitting the signal to the base station through the first duplexer and the first antenna, the hybrid wireless communication repeater comprising:

A coupler for extracting RF power from the RF signal through the first duplexer,

An RF / DC converter for converting the RF power drawn from the coupler into a DC voltage;

And a switch for variably selecting a DC voltage of the AC / DC converter and the RF / DC converter and supplying the DC voltage to the MCU.

The present invention is based on the fact that the MCU does not depend entirely on the DC voltage of the AC / DC converter, but relies on the RF signal through the first duplexer to make the dispersion dependent, i.e., RF power from the RF signal is extracted from the coupler, DC voltage can be distributed and selectively used together in the switch, thereby maximizing the energy efficiency.

The present invention has the effect of economically expanding various communication service coverage with high energy efficiency by allowing commercial power and RF power of 110 V to 220 V to be selected and used between the base station and the terminal.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram illustrating a wireless repeater of the RF scheme mentioned in the prior art document. FIG.
2 is a block diagram illustrating a wireless communication relay system to which an energy dispersive hybrid wireless communication repeater according to the present invention is applied.
3 is a detailed block diagram illustrating an energy dispersive hybrid radio communication repeater according to the present invention;

The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which exemplary embodiments of the invention are shown. These and other objects, features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings, I can understand them better.

Due to the development of communication technology, various wireless communication services through wireless are being provided. In addition to the development of communication technology, various wireless communication devices for transmitting and receiving voice information and image information of voice communication terminals, video communication terminals, and the like are rapidly becoming popular.

In recent years, as the number of subscribers of wireless communication services has increased, the number of base stations has been significantly increased for smooth operation of services.

However, since the environment of the wireless communication service is very unstable, it is true that there is a relatively shaded area that is blocked from the outside, such as inside a building or a subway where radio waves can not reach.

In such a shaded area, there is a problem that the receiving strength is weak and the communication is instantaneously disconnected or the communication is unstable, so that high quality wireless communication service is not smoothly performed.

The success or failure of wireless communication service providers is determined by the fact that the shaded area is more effectively removed at low cost.

On the other hand, the most efficient way to remove shadow areas is to use a wireless communication repeater that can relay signals between the network and the user.

2 is a block diagram illustrating a wireless communication relay system to which an energy dispersive hybrid wireless communication repeater according to the present invention is applied.

The wireless communication relay system is configured such that the energy dispersive hybrid wireless communication repeater 100 of the present invention is installed between the base station B and the subscriber terminal T in accordance with the traffic density for expanding the service area as shown in FIG. Lt; / RTI >

The base station B is installed at an optimal position that satisfies the service quality required in the wireless communication network with respect to the terminal T distributed in the service area in an area with high traffic density.

The energy dispersive hybrid wireless communication repeater 100 according to the present invention is to economically expand service coverage to an ultra small relay device installed in an area with relatively low subscriber density.

The energy dispersive hybrid wireless communication repeater 100 according to the present invention can expand the service coverage by relaying to the service area by applying wireless equipment or optical transmission equipment for transmitting and receiving wireless signals from the base station B. [

Accordingly, it is installed in various places such as an apartment, a building, a basement of a building, a subway, a farming and fishing village, and a mountainous area in which radio signals are difficult to reach from the base station B on the ground while the subscriber density is low.

In other words, the CDMA (Code Division Multiple Access => frequency range: TX; 869 to 894 MHz, RX: 824 to 849 MHz, Bandwidth: 1.25 MHz), PCS and LTE 1820 MHz, RX: 1710 to 1785 MHz, PCS Bandwidth: 1.25 MHz, LTE Bandwidth: 5 MHz, 10 MHz: 20 MHz), WCDMA (Wideband CDMA => frequency range: TX: 2110 to 2170 MHz, RX: 1920 to 1980 MHz The energy dispersive hybrid wireless communication repeater 100 of the present invention can be applied to economically expand the coverage of various communication services such as bandwidth, 5 MHz, WiBro, and DMB (Digital Multimedia Broadcasting).

The energy dispersive hybrid wireless communication repeater 100 of the present invention relays radio signals between a base station B that provides a communication service and a terminal T that receives a communication service.

That is, the energy dispersive hybrid wireless communication repeater 100 repeats the signal from the base station B to the terminal T and relays the signal from the terminal T to the base station B.

3 is a detailed block diagram illustrating an energy dispersive hybrid radio communication repeater according to the present invention.

As shown in FIG. 3, the energy dispersive hybrid wireless communication repeater 100 according to the present invention includes an AC / DC converter 10 for converting a commercial power source of 110 to 220 V AC into a DC voltage, an AC / DC converter 10 receives an RF signal from the base station B via the first antenna A1 under the control of the MCU 20 and a second duplexer D1, and then amplifies, attenuates, filters and re-amplifies the received signal to the forward line 30 and then transmits the amplified signal to the terminal T through the second duplexer D2 and the second antenna A2, Filters, attenuates, and re-amplifies the RF signal received from the terminal T via the second duplexer D2 via the reverse line 40 via the first duplexer D1 and the first duplexer D2, To the base station (B) through the base station (A1).

The energy dispersive hybrid wireless communication repeater 100 according to the present invention receives the DC voltage of the AC / DC converter 10 from the MCU 20 and receives the forward voltage from the base station B to the terminal T, And a reverse line 40 extending from the terminal T to the base station B to control wireless signals so as to economically expand various communication service coverage such as CDMA, PCS & LTE, WCDMA, WiBro, and DMB .

More preferably, the energy dispersive hybrid radio communication repeater 100 according to the present invention includes a coupler 50 for extracting RF power from an RF signal through the first duplexer D1, an RF An RF / DC converter 60 for converting electric power into a DC voltage and a switch 70 for distributing and selecting DC voltages of the AC / DC converter 10 and the RF / DC converter 60 to the MCU 20 .

The RF power from the RF signal is extracted from the coupler 50, that is, from the RF signal, depending on the RF signal through the first duplexer D1 without depending entirely on the DC voltage of the AC / DC converter 10 in the MCU 20. [ The DC voltage converted through the RF / DC converter 60 is selectively distributed and utilized in the switch 70, thereby maximizing the energy efficiency.

More specifically, the AC / DC converter 10 converts a commercial power of AC 110 to 220 V to a DC 3 to 5.5 V voltage, and the RF / DC converter 60 converts RF power drawn from the coupler 50 to DC 3 So that the DC voltage can be applied to the MCU 20 in accordance with the RF signal environment such as CDMA, PCS & LTE, WCDMA, WiBro, and DMB.

The forward line 30 includes a first forward amplifier 31 for amplifying the RF signal through the first duplexer D1 and a forward attenuator 31 for adjusting the gain of the RF signal amplified by the first forward amplifier 31 A second forward amplifier 34 for re-amplifying the RF signal filtered in the forward BPF 33, and a second forward amplifier 34 for re-amplifying the RF signal filtered in the forward BPF 33. The forward BPF 33 filters the unnecessary RF signal among the RF signals gain-adjusted by the forward attenuator 32, And a third forward amplifier (35).

The RF signal through the first antenna A1 may be CDMA, PCS & LTE, WCDMA, WiBro, DMB, etc., amplified by the first forward amplifier 31, then adjusted through the forward attenuator 32, 33 to amplify the signals through the second forward amplifier 34 and the third forward amplifier 35 while filtering the signals to the required band and then transmit them to the second duplexer D2 and the second antenna A2.

The reverse line 40 includes a first reverse amplifier 41 for amplifying the RF signal through the second duplexer D2 and a backward attenuator for adjusting the gain of the RF signal amplified by the first reverse amplifier 41 A second reverse amplifier 44 for re-amplifying the RF signal filtered in the reverse BPF 43, and a second reverse amplifier 44 for re-amplifying the RF signal filtered in the reverse BPF 43, And a third reverse amplifier (45).

The RF signal through the second antenna A2 may be CDMA, PCS & LTE, WCDMA, WiBro, DMB, etc., amplified by the first reverse amplifier 41 and then adjusted by the reverse attenuator 42, 43 to amplify the signals through the second reverse amplifier 44 and the third reverse amplifier 45 and then transmit the amplified signals to the first duplexer D1 and the first antenna A1.

As described above, the energy dispersive hybrid wireless communication repeater 100 according to the present invention can select and use commercial power and RF power of AC 110 to 220 V between the base station B and the terminal T, And to enable economical expansion of various communication service coverage.

INDUSTRIAL APPLICABILITY The present invention can be applied to an industrial field installed in a building where radio wave can not reach well or in a shaded area blocked from the outside such as a subway, and relaying a radio signal between a base station and a subscriber terminal.

B: base station T: terminal
100: Energy dispersive hybrid type wireless communication repeater
10: AC / DC converter 20: MCU
A1: first antenna D1: first duplexer
30: forward line 31: first forward amplifier
32: Forward attenuator 33: Forward BPF
34: second forward amplifier 35: third forward amplifier
D2: second duplexer A2: second antenna
40: reverse line 41: first reverse amplifier
42: Reverse attenuator 43: Reverse BPF
44: second reverse amplifier 45: third reverse amplifier
50: coupler 60: RF / DC converter
70: Switch

Claims (4)

An AC / DC converter 10 for converting a commercial power source of AC 110 to 220 V into a DC voltage, an MCU 20 receiving a DC voltage from the AC / DC converter 10, Filters and re-amplifies the RF signal received from the base station B via the first antenna A1 through the first duplexer D1 while amplifying, attenuating, filtering, and re-amplifying the RF signal through the forward line 30, To the terminal T through the second antenna D2 and the second antenna A2 while the RF signal received from the terminal T via the second antenna A2 is transmitted through the second duplexer D2 And transmits the signal to the base station B via the first duplexer D1 and the first antenna A1 after amplifying, filtering, attenuating, and re-amplifying the received signal by the reverse line 40 while receiving the signal, In this case,
A coupler 50 for drawing RF power from the RF signal through the first duplexer D1,
An RF / DC converter 60 for converting the RF power drawn from the coupler 50 to a DC voltage,
And a switch (70) for distributing and supplying DC voltage of the AC / DC converter (10) and the RF / DC converter (60) to the MCU (20) . The method according to claim 1,
The AC / DC converter 10 converts a commercial power source of AC 110 to 220 V to a DC 3 to 5.5 V voltage,
Wherein the RF / DC converter (60) converts the RF power drawn from the coupler (50) to a DC voltage of 3 to 5.5 V. 3. The method according to claim 1 or 2,
The forward line (30)
A first forward amplifier 31 for amplifying an RF signal through the first duplexer D1,
A forward attenuator 32 for adjusting a gain of the RF signal amplified by the first forward amplifier 31,
A forward BPF 33 for filtering unnecessary bands among RF signals gain-controlled by the forward attenuator 32,
And a second forward amplifier (34) and a third forward amplifier (35) for re-amplifying the filtered RF signal in the forward BPF (33). 3. The method according to claim 1 or 2,
The reverse line (40)
A first reverse amplifier 41 for amplifying an RF signal through the second duplexer D2,
A reverse attenuator 42 for adjusting the gain of the RF signal amplified by the first reverse amplifier 41,
A reverse BPF 43 for filtering unnecessary bands among the RF signals gain-controlled by the backward attenuator 42,
And a second reverse amplifier (44) and a third reverse amplifier (45) for re-amplifying the filtered RF signal in the reverse BPF (43).

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