KR100742993B1 - Front end unit device of base station for interference signal suppression - Google Patents

Abstract

The present invention relates to a FEU device of a base station for suppressing an interference signal to suppress an interference signal, comprising: an HPA for high power amplification of an RF signal for transmission to a mobile station along a transmission path, and an RF signal amplified by the HPA The first duplexer comprising a channel BPF for filtering the signal according to the corresponding channel, two TX_BPF (4M), TX_BPF (11M) for separating the interference signal by separating the RF signal passing through the channel BPF for each channel, and the first A second duplexer comprising TX_BPF (4M) for filtering the RF signal passing through TX_BPF (4M) in one duplexer according to the transmission band and RX_BPF (25M) for filtering the RF signal received from the mobile station according to the reception band, and a transmission / reception path A first coupler for coupling and outputting an RF signal, a first LNA for low noise amplifying the RF signal passing through the RX_BPF 25M in the second duplexer, and TX_ in the first duplexer according to a reception path. A third duplexer comprising a TX_BPF (11M) for filtering the RF signal passing through the BPF (11M) according to the transmission band, and an RX_BPF (25M) for filtering the RF signal received from the mobile station according to the reception band; A second coupler for coupling and outputting a signal, and a second LNA for low-noise amplifying the RF signal passing through the RX_BPF (25M) in the third duplexer according to the receiving path.

Description

Front end unit device of base station for interference signal suppression {FRONT END UNIT OF BASE STATION FOR INTERFERENCE SIGNAL CONTROL}

1 is a block diagram of a front end unit of a conventional base station;

2 is a block diagram of a front end unit apparatus of a base station for interference signal suppression according to a first embodiment of the present invention;

3 is a block diagram of a front end unit device of a base station for interference signal suppression according to a second embodiment of the present invention;

<Description of the symbols for the main parts of the drawings>

11,22-1,2: HPA, 1st, 2 HPA 12,23-1,2: Channel BPF, Channel BPF

13,21: first duplexer 14,24: second duplexer

15,25: first coupler 16,26: third duplexer

17,27: second coupler 18,28: first LNA

19,29: 2nd LNA

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a front end unit (hereinafter referred to as a 'FEU') device of a base station for interference signal suppression. In particular, a plurality of duplexers, channels BPF (Band Pass Filter), and HPA (High) Interference that separates the transmission channel using Power Amplifier, etc. to suppress interference signals caused by active IMD (Inter Modulation Distortion) and passive IMD components that occur during transmission channel operation A FEU apparatus of a base station for signal suppression.

In general, the mobile communication system of the DCS (Digital Cellular System) method uses a frequency band of 800MHz band, in particular, the base station is provided with a FEU device as shown in Figure 1 RF signal received from the mobile station according to the receiving path Filter and low noise amplification, and a high power or low power amplification and filtering of the RF signal for transmission to the mobile station according to the transmission path.

That is, FIG. 1 is a block diagram of a conventional FEU apparatus of a base station, which corresponds to an HPA 1 for high power amplification of an RF signal for transmission to a mobile station along a transmission path, and an RF signal amplified by the HPA 1. A channel BPF 2 for filtering according to a channel, a TX_BPF 25M for filtering an RF signal passing through the channel BPF 2 for a transmission band, and an RX_BPF for filtering an RF signal received from a mobile station according to a reception band ( 25M) and the RF signal passing through the TX_BPF (25M) in the duplexer (3) to the mobile station through the first antenna (Ant1) or transmitted from the mobile station through the first antenna (Ant1) A first coupler 4 for coupling and outputting an RF signal according to a transmission / reception path, such as receiving an incoming RF signal and transmitting it to the RX_BPF 25M in the duplexer 3, and the duplexer 3 according to the reception path First LNA for low noise amplification of RF signal passing through RX_BPF (25M) (5), a second coupler 6 for coupling to receive an RF signal transmitted from a mobile station through a second antenna Ant2, and an RF signal coupled by the second coupler 6; RX_BPF (25M) (7) for filtering according to the band, and a second LNA (8) for low noise amplification of the RF signal passing through the RX_BPF (25M) (7).

In the FEU apparatus of the conventional base station configured as described above, when the RF signal along the transmission path passes through the HPA 1 during the operation of the transmission channel, the IMD component 3rd, 5th is active by the high power amplification operation of the HPA 1. , 7th order IMD) interference signals are generated.

Thereafter, the channel BPF (2) is passed, where the interference signal is suppressed to some extent by the channel BPF (2), but again passes through the TX_BPF (25M) in the duplexer (3), passive IMD component (3rd, 5th, 7th order IMD) interference signals are generated.

In addition, an interference signal of a passive IMD component is generated while passing through the first antenna Ant1 again.

The interference signal generated during the operation of the transmission channel as described above exists in the reception band, which adversely affects the quality of the reception signal, thereby degrading the overall reception performance.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to separate active transmission channels using multiple duplexers, channel BPFs, HPAs, etc. The present invention provides an FEU apparatus of a base station for suppressing an interference signal.

The FEU apparatus of the base station for interference signal suppression according to the first embodiment of the present invention for achieving the above object is a HPA for high power amplification of the RF signal for transmission to the mobile station along the transmission path, by the HPA A first duplexer comprising a channel BPF for filtering the amplified RF signal according to a corresponding channel, and two TX_BPF (4M) and TX_BPF (11M) for separating interference signals by separating the RF signal passing through the channel BPF for each channel. And a second duplexer comprising a TX_BPF (4M) for filtering the RF signal passing through the TX_BPF (4M) in the first duplexer for the transmission band and an RX_BPF (25M) for filtering the RF signal received from the mobile station for the reception band. And transmitting the RF signal passing through the TX_BPF (4M) in the second duplexer to the mobile station through the first antenna or receiving the RF signal transmitted from the mobile station through the first antenna. A first coupler for coupling output to transmit to the internal RX_BPF 25M, a first LNA for low noise amplifying the RF signal passing through the RX_BPF 25M in the second duplexer, and TX_BPF in the first duplexer according to a reception path A third duplexer comprising a TX_BPF (11M) for filtering the RF signal passing through the (11M) to the transmission band and an RX_BPF (25M) for filtering the RF signal received from the mobile station to the reception band, and TX_BPF in the third duplexer Coupling and outputting the RF signal passed through the (11M) to the mobile station through the second antenna or the RF signal transmitted from the mobile station through the second antenna to transmit to the RX_BPF (25M) in the third duplexer. And a second coupler and a second LNA for low noise amplifying the RF signal passing through the RX_BPF 25M in the third duplexer according to the reception path.                     

The FEU apparatus of the base station for interference signal suppression according to the second embodiment of the present invention, two TX_BPF (4M), TX_BPF for removing the interference signal by separating the RF signal for transmission to the mobile station according to the transmission path for each channel A first duplexer (11M), first and second HPAs for high power amplifying RF signals passing through the TX_BPF (4M) and the TX_BPF (11M) in the first duplexer, and the first and second HPAs, respectively. The first and second channel BPFs for filtering the RF signal amplified by the corresponding channel, and the TX_BPF (4M) for filtering the RF signal passing through the first channel BPF according to the transmission band and the RF signal received from the mobile station. Transmits a second duplexer consisting of RX_BPF (25M) for filtering to a reception band and an RF signal passing through TX_BPF (4M) in the second duplexer to a mobile station through a first antenna or at a mobile station through a first antenna. Receives the received RF signal A first coupler for coupling output to transmit to the RX_BPF (25M) in a second duplexer, a first LNA for low noise amplifying the RF signal passing through the RX_BPF (25M) in the second duplexer according to a receiving path, and the second A third duplexer comprising a TX_BPF (11M) for filtering the RF signal passing through the channel BPF according to the transmission band, and an RX_BPF (25M) for filtering the RF signal received from the mobile station according to the reception band, and TX_BPF (in the third duplexer); RF signal transmitted through 11M) to a mobile station through a second antenna or an RF signal transmitted from a mobile station through a second antenna to be transmitted to RX_BPF (25M) in the third duplexer according to a transmission / reception path And a second coupler for coupling and outputting a second LNA for low noise amplifying the RF signal passing through the RX_BPF 25M in the third duplexer according to a reception path.                     

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the FEU device of the base station for interference signal suppression according to the present invention.

2 is a block diagram of an FEU apparatus of a base station for interference signal suppression according to a first embodiment of the present invention, which HPA 11 performs high power amplification of an RF signal for transmission to a mobile station along a transmission path, and the HPA A channel BPF 12 for filtering the RF signal amplified by 11 according to a corresponding channel, and two TX_BPFs 4M for removing interference signals by separating the RF signal passing through the channel BPF 12 for each channel. ), A first duplexer (13M) consisting of TX_BPF (11M), TX_BPF (4M) for filtering the RF signal passing through the TX_BPF (4M) in the first duplexer 13 to the transmission band and RF received from the mobile station A second duplexer (14) consisting of RX_BPF (25M) for filtering the signal according to the reception band, and the RF signal passing through the TX_BPF (4M) in the second duplexer (14) to the mobile station through the first antenna (Ant1) The number of RF signals transmitted or transmitted from the mobile station through the first antenna Ant1. A first coupler 15 for coupling and outputting an RF signal according to a transmission / reception path, for example, transmitting the signal to the RX_BPF 25M in the second duplexer 14, and the second duplexer 14 according to the reception path. The first LNA 18 for low noise amplifying the RF signal passed through the RX_BPF 25M and the TX_BPF 11M for filtering the RF signal passed through the TX_BPF 11M in the first duplexer 13 according to a transmission band. And a third duplexer 16 including an RX_BPF 25M for filtering the RF signal received from the mobile station according to a reception band, and an RF signal passing through the TX_BPF 11M in the third duplexer 16 through a second antenna ( An RF signal is transmitted according to a transmission / reception path, such as an RF signal transmitted to the mobile station through Ant2) or an RF signal transmitted from the mobile station through the second antenna Ant2 and transmitted to the RX_BPF 25M in the third duplexer 16. A second coupler 17 for coupling and outputting, and R in the third duplexer 16 according to the reception path And a second LNA 19 for low noise amplifying the RF signal passing through the X_BPF 25M.

FIG. 3 is a block diagram of an FEU apparatus of a base station for suppressing interference signals according to a second embodiment of the present invention, wherein two signals for removing interference signals by separating RF signals for transmission to a mobile station according to a transmission path for each channel are shown in FIG. A first HPA for high power amplification of the first duplexer 21 including the TX_BPFs (4M) and the TX_BPFs (11M) and the RF signals passing through the TX_BPFs (4M) and the TX_BPF (11M) in the first duplexer 21, respectively. First and second filters 22-1 and 2 HPA 22-2 and RF signals amplified by the first HPA 22-1 and second HPA 22-2 according to the corresponding channel, respectively. Received from the mobile station and TX_BPF (4M) for filtering the RF signal passing through the channel BPF 23-1 and the second channel BPF 23-2, the first channel BPF 23-1 according to the transmission band. A second duplexer 24 made of RX_BPF 25M for filtering an RF signal according to a reception band, and an RF signal passing through TX_BPF 4M in the second duplexer 24 through a first antenna Ant1. Coupling the RF signal according to the transmission and reception path, such as transmitting to the mobile station or receiving the RF signal transmitted from the mobile station through the first antenna Ant1 to the RX_BPF 25M in the second duplexer 24, An output first coupler 25, a first LNA 28 for low noise amplifying the RF signal passing through the RX_BPF 25M in the second duplexer 14, and the second channel BPF 23 according to a reception path. A third duplexer 26 comprising TX_BPF 11M for filtering the RF signal passing through -2) according to the transmission band, and RX_BPF 25M for filtering the RF signal received from the mobile station according to the reception band; The RF signal passing through the TX_BPF 11M in the duplexer 26 is transmitted to the mobile station through the second antenna Ant2 or the RF signal transmitted from the mobile station through the second antenna Ant2 to receive the third duplexer ( 26) The RF signal is increased according to the transmission / reception path, such as transmission to RX_BPF (25M). It consists of the second coupler 27, a second LNA (28) for low-noise amplifying the RF signal passing through the third duplexer 26 in RX_BPF (25M) according to the reception path to the output ring.

Referring to the operation of the FEU device of the base station for interference signal suppression of the present invention configured as described above are as follows.

First, when the operation of the FEU device of the base station for the interference signal suppression according to the first embodiment shown in FIG. 2 is described, the HPA 11 high-power amplifies the RF signal for transmission to the mobile station along the transmission path, The BPF 12 filters the RF signal amplified by the HPA 11 according to the corresponding channel.

At this time, the filtering of the channel BPF 12 suppresses the interference signal of the active IMD components 3rd, 5th, and 7th order IMD generated while the RF signal passes through the HPA 11.

Subsequently, the first duplexer 13 including two TX_BPFs 4M and TX_BPFs 11M removes the interference signal by separating and filtering the RF signal passing through the channel BPF 12 for each channel.

That is, the first duplexer 13 separates and filters the channels that are likely to cause interference in the reception band through the TX_BPF 4M and the TX_BPF 11M, respectively, to remove the remaining interference by the channel BPF 12. The interference signal of the passive IMD components 3rd, 5th, and 7th order IMD which will be generated while passing through the signal and the second duplexer 14 and the third duplexer 16 which are the next stages is removed in advance.

Thereafter, the second duplexer 14 and the third duplexer 16 pass through the TX_BPF 4M and the TX_BPF 11M in the first duplexer 13 through the TX_BPF 4M and the TX_BPF 11M, respectively. After filtering each of the suppressed RF signal according to the transmission band, and outputs to the first and second antennas (Ant1, Ant2) via the first and second couplers (15, 17) to transmit to the mobile station.

On the other hand, in the case of the reception path, RF signals received from the mobile station through the first and second antennas Ant1 and Ant2 are coupled by the first and second couplers 15 and 17, respectively, and then second and third, respectively. Output to duplexers 14 and 16.

Subsequently, the second duplexer 14 and the third duplexer 16 filter the RF signals received from the mobile station through the RX_BPF 25M and the RX_BPF 25M, respectively, according to the reception bands, so that the first and second LNAs 18, 19)

Then, the first and second LNAs 18 and 19 low noise amplify RF signals passing through the RX_BPF 25M in the second duplexer 14 and the RX_BPF 25M in the third duplexer 16, respectively.

Next, referring to the operation of the FEU device of the base station for interference signal suppression according to the second embodiment shown in Figure 3, the first duplexer 21 consisting of two TX_BPF (4M) and TX_BPF (11M) is transmitted The RF signal for transmission to the mobile station along the path is separated and filtered for each channel to remove the interference signal.

That is, the first duplexer 21 separates and filters channels that may cause interference in the reception band through TX_BPF (4M) and TX_BPF (11M), respectively. The interference signals of the active IMD components (3rd, 5th, 7th order IMD) to be generated while passing through 1,2 are removed in advance.

In addition, after passing through the first and second channel BPFs 23-1 and 2, the passive IMD components 3rd, 5th, and 7th to be generated while passing through the second and second duplexers 24 and 26. The interference signal of order IMD) is also removed in advance.

Subsequently, the first HPA 22-1 and the second HPA 22-2 high power amplify RF signals passing through the TX_BPF 4M and the TX_BPF 11M in the first duplexer 21, respectively, The channel BPF 23-1 and the second channel BPF 23-2 filter the RF signals amplified by the first HPA 22-1 and the second HPA 22-2 according to the corresponding channel, respectively. .

Thereafter, the second duplexer 24 and the third duplexer 26 suppress the noise signals passing through the first and second channel BPFs 23-1 and 2 through TX_BPF 4M and TX_BPF 11M, respectively. Each RF signal is filtered according to the transmission band, and then output to the first and second antennas Ant1 and Ant2 through the first and second couplers 25 and 27 to be transmitted to the mobile station.

On the other hand, in the case of the reception path, RF signals received from the mobile station through the first and second antennas Ant1 and Ant2 are coupled by the first and second couplers 25 and 27, respectively, and then second and third, respectively. Output to duplexers 24 and 26.

Subsequently, the second duplexer 24 and the third duplexer 26 filter the RF signals received from the mobile station through the RX_BPF 25M and the RX_BPF 25M, respectively, according to the reception bands, so that the first and second LNAs 28, 29).                     

Then, the first and second LNAs 28 and 29 low noise amplify RF signals passing through the RX_BPF 25M in the second duplexer 24 and the RX_BPF 25M in the third duplexer 26, respectively.

As described above, in the present invention, when transmitting a channel capable of generating an interference signal of an IMD component between channels, each channel is separated from each other and amplified so that an interference signal of an IMD component that exists in a reception band and affects reception performance is transmitted. It is supposed to be suppressed in advance.

As described above, by separating the transmission channel using a plurality of duplexers, channel BPF, HPA, etc., it is possible to suppress the interference signal caused by the active IMD component and the passive IMD component generated during operation of the transmission channel. There is an effect that can be improved.

Claims (2)

A channel BPF for filtering the RF signal amplified by the HPA according to the corresponding channel; A first duplexer comprising two TX_BPFs (4M) and TX_BPFs (11M) for separating interference signals by separating the RF signals passing through the channel BPF for each channel; A second duplexer comprising a TX_BPF (4M) for filtering the RF signal passing through the TX_BPF (4M) in the first duplexer according to the transmission band and an RX_BPF (25M) for filtering the RF signal received from the mobile station according to the reception band; The RF signal passing through the TX_BPF (4M) in the second duplexer is transmitted to the mobile station through the first antenna or the RF signal transmitted from the mobile station through the first antenna is transmitted to the RX_BPF (25M) in the second duplexer. A first coupler for coupling output to A first LNA for low noise amplifying the RF signal passing through the RX_BPF (25M) in the second duplexer according to a reception path; A third duplexer including a TX_BPF (11M) for filtering the RF signal passing through the TX_BPF (11M) in the first duplexer according to the transmission band and an RX_BPF (25M) for filtering the RF signal received from the mobile station according to the reception band; The RF signal passing through the TX_BPF (11M) in the third duplexer is transmitted to the mobile station through the second antenna or the RF signal transmitted from the mobile station through the second antenna is received and transmitted to the RX_BPF (25M) in the third duplexer. A second coupler for coupling output to And a second LNA for low noise amplifying the RF signal passing through the RX_BPF (25M) in the third duplexer according to a reception path. A first duplexer comprising two TX_BPFs (4M) and TX_BPFs (11M) for separating interference signals by channel-by-channel RF signals for transmission to a mobile station according to a transmission path; First and second HPAs for high power amplifying RF signals passing through the TX_BPF (4M) and the TX_BPF (11M) in the first duplexer, respectively; First and second channel BPFs for filtering the RF signals amplified by the first and second HPAs according to respective channels; A second duplexer comprising a TX_BPF (4M) for filtering the RF signal passing through the first channel BPF according to a transmission band and an RX_BPF (25M) for filtering the RF signal received from a mobile station according to a reception band; The RF signal passing through the TX_BPF (4M) in the second duplexer is transmitted to the mobile station through the first antenna or the RF signal transmitted from the mobile station through the first antenna is transmitted to the RX_BPF (25M) in the second duplexer. A first coupler for coupling output to A first LNA for low noise amplifying the RF signal passing through the RX_BPF (25M) in the second duplexer according to a reception path; A third duplexer including a TX_BPF (11M) for filtering the RF signal passing through the second channel BPF according to the transmission band and an RX_BPF (25M) for filtering the RF signal received from the mobile station according to the reception band; The RF signal passing through the TX_BPF (11M) in the third duplexer is transmitted to the mobile station through the second antenna or the RF signal transmitted from the mobile station through the second antenna is received and transmitted to the RX_BPF (25M) in the third duplexer. A second coupler for coupling and outputting an RF signal according to a transmission / reception path so as to And a second LNA for low noise amplifying the RF signal passing through the RX_BPF (25M) in the third duplexer according to a reception path.

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