KR101868848B1 - Device for Canceling Passive Intermodulation Signal - Google Patents

Abstract

An intermodulation signal canceling apparatus is disclosed. The disclosed apparatus includes a first reception band filter for performing filtering on a reception band with respect to a reception signal from an antenna; A transmission band filter for performing filtering on a transmission band with respect to a transmission signal to the antenna; A second reception band filter for performing filtering on a reception band with respect to a transmission signal to the antenna; An intermodulation signal elimination module for receiving an output signal of the first reception band filter, an output signal of the second reception band filter, and a coupling signal for an output of the transmission band filter, An uplink intermodulation signal removal block for removing the uplink interleaved signal from the output signal of the first reception band filter using a coupling signal for the transmission band filter output as a first reference signal, And a downlink intermodulation signal canceling block for generating an anti-phase signal with respect to the downlink interleaved signal using the signal as a second reference signal. The intermodulation signal canceller of the present invention can be effectively used in an environment in which a plurality of repeaters or RRHs are connected to a local station.

Description

{Device for Canceling Passive Intermodulation Signal}

Embodiments of the present invention relate to an intermodulation signal rejection apparatus, and more particularly to an apparatus for eliminating intermodulation signal caused by passive intermodulation distortion.

In order to provide a mobile communication service, a base station apparatus and a repeater apparatus are used. These apparatuses transmit a downlink signal using a transmission frequency band for a specific allocated radio transmission / reception frequency band or a plurality of radio transmission / And the RF power is transmitted through an antenna through a passive element such as an RF feed cable and a router or a distributor.

In the base station or repeater installation operation of the mobile communication system, passive intermodulation distortion (nonlinearity) due to non-linearity, non-uniformity of the contact surface of a passive element such as a feeder cable, a feeder router, a distributor, Intermodulation signals generated by the PIMD are generated.

When the intermodulation signal due to the passive intermodulation distortion (PIMD) generated by the nonlinear characteristic of the passive element is generated within the allocated reception frequency band, the signal to noise ratio (SNR) of the uplink signal ) Of the base station or the repeater is deteriorated to cause a problem of degrading the communication quality and reducing the service coverage of the base station or the repeater.

A mobile communication transmitting and receiving device such as a base station, an RRH, and a repeater is coupled to the antenna.

In the past, an intermodulation signal canceller, such as a repeater connected to an antenna, was coupled to remove the intermodulation signal from the PIMD. Such a conventional structure has no problem in the structure in which one repeater is coupled to a single local station. However, in recent years, a system in which a plurality of repeaters and RRHs are connected to one antenna is used. In such a system, an intermodulation signal canceller should be installed for each repeater and each RRH.

Especially, when another repeater is added in the environment where one repeater is installed, an intermodulation signal canceller must be added to the newly added repeater, and there is a case where the intermodulation signal device of the existing repeater is removed.

Meanwhile, a conventional intermodulation signal cancellation apparatus is often used to distribute and detect intermodulation signals using a power divider, resulting in a loss of a divider. By using a power amplifier having a high output to compensate for the loss, There is a problem in that it is increased.

An aspect of the present invention is to provide an intermodulation signal canceling apparatus that can be effectively used in an environment where a plurality of repeaters or RRHs are connected to a local station.

Another aspect of the present invention is to provide an intermodulation signal canceling apparatus capable of minimizing loss.

According to an aspect of the present invention, there is provided an intermodulation signal apparatus provided between an antenna and a mobile communication transceiver, comprising: a first reception band filter for performing filtering on a reception band with respect to a reception signal from an antenna; A transmission band filter for performing filtering on a transmission band with respect to a transmission signal to the antenna; A second reception band filter for performing filtering on a reception band with respect to a transmission signal to the antenna; An intermodulation signal elimination module for receiving an output signal of the first reception band filter, an output signal of the second reception band filter, and a coupling signal for an output of the transmission band filter, An uplink intermodulation signal removal block for removing the uplink interleaved signal from the output signal of the first reception band filter using a coupling signal for the transmission band filter output as a first reference signal, Modulated signal cancellation block for generating a reverse-phase signal with respect to the down-mixed-modulated signal using the signal as a second reference signal.

The intermodulation signal elimination module converts the output signal of the first reception band filter, the first reference signal, and the second reference signal into a baseband and a digital signal, removes the uplink intermodulation signal, Phase signal with respect to the signal.

The downlink interleaved signal removing block receives the downlink interleaved signal in the receiving band through a difference between the output signal of the second reception band filter converted into the baseband and digital signals and the output signal of the uplink interleaved signal removing block, .

The upstream intermodulation signal removing block may include an intermodulation signal regenerator for regenerating an upstream intermodulation signal, an intermodulation signal crosstalk calculator for calculating a covariance matrix for the regenerated intermodulation signal, an orthogonalization coefficient calculating unit for calculating an orthogonalization coefficient using the covariance matrix, An orthogonal modulator for orthogonalizing the regenerated orthogonal modulated signal and a second orthogonal orthogonal modulator for modulating the gain and phase of the output signal of the orthogonal modulator and the first reference signal, And an intermodulation signal canceller for removing the uplink intermodulation signal through the difference between the first reference signal whose gain is adjusted by the intermodulation signal gain controller and the intermodulation signal orthogonalized by the intermodulation signal gain controller.

The down-mix signal cancellation block generates an in-phase signal with respect to the intermodulation signal existing in the reception band, and the intermodulation signal elimination module adds up the output signal of the anti-phase signal and the up- And outputs it.

Further comprising a combiner for securing an isolation of the output signal of the intermodulation signal elimination module and the output signal of the second reception band filter transmitted in the direction of the antenna, Intermodulation signal remover.

The coupler includes a directional coupler and a circulator.

Wherein an output signal of the intermodulation signal elimination module is filtered by the second reception band filter via the combiner and transmitted in the direction of the mobile communication transceiver.

According to another aspect of the present invention, there is provided an intermodulation signal apparatus installed between an antenna and a mobile communication transceiver, comprising: a first reception band filter for performing filtering on a reception band with respect to a reception signal from an antenna; A first transmission band filter for performing a filtering on a first transmission band with respect to a first band transmission signal to the antenna; A second reception band filter for performing filtering on a reception band with respect to a second band transmission signal to the antenna; Receiving a coupling signal for an output of the first reception band filter, an output signal of the second reception band filter, a coupling signal for an output of the first transmission band filter, and a coupling signal for an output of the second transmission band filter, Wherein the intermodulation signal cancellation module is configured to receive a coupling signal for the first transmission band filter output as a first reference signal and a coupling signal for the second transmission band filter output as a second reference signal, And an uplink interleaved signal removing block for removing the uplink interleaved signal from the output signal of the first reception band filter as a reference signal and a downlink interleaved signal removing block using the output signal of the second reception band filter as a third reference signal, And a downstream intermodulation signal removal block for generating an anti-phase signal for the intermodulation signal elimination block.

The intermodulation signal canceller of the present invention can be effectively used in an environment in which a plurality of repeaters or RRHs are connected to a local station. In addition, the intermodulation signal removing apparatus of the present invention is advantageous in that intermodulation signal can be removed while minimizing loss.

1 illustrates a structure of a mobile communication system in which a macro cell and a small cell to which the present invention is applied are present together.
2 is a block diagram showing the structure of an intermodulation signal eliminator according to an embodiment of the present invention;
3 is a block diagram illustrating a schematic structure of a removal device according to an embodiment of the present invention;
4 is a block diagram illustrating a detailed structure of a forward intermodulation signal cancellation block according to an embodiment of the present invention;
5 is a block diagram showing a detailed structure of a down-mixed-modulated signal removing block according to an embodiment of the present invention;
6 is a diagram illustrating an intermodulation signal canceling apparatus according to another embodiment of the present invention.
FIG. 7 illustrates an intermodulation signal canceling apparatus according to another embodiment of the present invention. FIG.
FIG. 8 illustrates a conceptual structure of an intermodulation signal eliminator according to an embodiment of the present invention; FIG.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view showing an installation state of an intermodulation signal removing apparatus according to an embodiment of the present invention.

Referring to FIG. 1, an intermodulation signal canceller 601 according to an embodiment of the present invention is installed between an antenna 110 and a mobile communication transceiver 120 to remove intermodulation signals. Here, the mobile communication transceiver 120 is a device for performing signal processing on a reception signal of an antenna, and may include a repeater, an RRH, a base station, and the like.

In the intermodulation signal canceling apparatus of the present invention, even when a plurality of mobile communication transceivers are connected to an antenna, it is possible to remove intermodulation signals through a single intermodulation signal canceller.

Therefore, even if a new repeater or RRH is added to the antenna, it is possible to design an intermodulation canceling apparatus that can respond to a new environment comparatively easily.

1, the intermodulation signal generated by the PIMD generated between the antenna 110 or the antenna 110 and the intermodulation signal eliminator 601 is removed in the intermodulation signal elimination apparatus according to an embodiment of the present invention. The intermodulation signal generated between the intermodulation signal eliminator 601 and the mobile communication transceiver 120 can not be removed with the existing structure.

Hereinafter, the intermodulation signal cancellation apparatus according to an embodiment of the present invention may include a PIMD intermodulation signal generated between the antenna 110 or the antenna 110 and the intermodulation signal elimination apparatus 601, A structure for eliminating the intermodulation signal due to the PIMD generated between the mobile communication transceiver 120 and the mobile communication transceiver 120 will be described in detail.

2 is a block diagram illustrating the structure of an intermodulation signal eliminator according to an embodiment of the present invention.

2, the intermodulation signal canceling apparatus according to an embodiment of the present invention uses two transmission bands and two reception bands. When the transmission bands and the reception bands increase or decrease, As shown in FIG.

Referring to FIG. 2, the apparatus for removing intermodulation signals using a PIMD according to an embodiment of the present invention includes a first connection unit 616 and a second connection unit 617. The first connection part 616 is a connection part to be connected to the antenna direction and the second connection part 617 is a connection part to be connected to the direction of a mobile communication transmission and reception device such as a base station, an RRH or a repeater. The first connection part 616 and the second connection part 617 include RF connectors and various types of connectors such as an N-type connector and a DIN-type connector are used as the first connection part 616 and the second connection part 617 .

Passive elements such as a feeder line and a splitter are installed between the intermodulation signal canceller and the antenna. The nonlinear characteristics of these passive elements cause intermodulation components due to the PIMD. Also, intermodulation components due to PIMD are generated between the intermodulation signal canceller and the mobile communication transceiver such as the repeater, RRH or base station due to the non-linear characteristics of the passive components.

The intermodulation signal by the PIMD causes the distortion of the received signal when the intermodulation signal by the transmission signal occurs at the frequency of the reception band. In the embodiment shown in FIG. 2, the intermodulation signal by the PIMD of the first transmission band signal and the second transmission band signal is applied to the second reception band signal to remove the intermodulation signal. It will be appreciated by those skilled in the art that the intermodulation signal cancellation module for the first reception band may additionally be provided if it affects the first reception band signal.

The apparatus for removing intermodulation signals from a PIMD according to an embodiment of the present invention includes a duplexer 606 for filtering a first transmission band and a first reception band, two second reception band filters 604 and 605, Band filter 603.

 The received signal (uplink signal) of the second band is received through the first connection portion 616. The second reception band signal may be distorted by the intermodulation signal by the PIMD of the transmission signals of the two transmission bands (the first transmission band and the second transmission band), and the second reception band signal (uplink signal) Intermodulation signal.

The second reception band signal (uplink signal) is filtered in the second-1 reception band-pass filter 605.

The first transmission band signal (downlink signal) is filtered through the first transmission band filter of the duplexer 606 and then transmitted to the first connection unit 616 and provided to the antenna. Conversely, the first reception band signal (uplink signal) input through the antenna is filtered through the first reception band filter of the duplexer 606 and then transmitted to the repeater, the RRH, or the base station through the second connection unit 617. Although FIG. 2 illustrates a first transmission band filter and a first reception band filter implemented by the duplexer 606, the first transmission band filter and the first reception band filter may be implemented as a single filter module There will be.

The second transmission band signal (downlink signal) is filtered through the second transmission band filter 603 and then provided to the antenna via the first connection portion 616.

The intermodulation signal cancellation apparatus according to an embodiment of the present invention includes an intermodulation signal cancellation module 602. The filtered second reception band signal output from the 2-1 reception band filter 605 is input to the intermodulation signal elimination module 602.

A portion of the first transmission band signal filtered in the first transmission band filter of the duplexer 606 is also input to the intermodulation signal rejection module 602 and the second transmission band filtered in the second transmission band filter 603, A portion of the signal is also input to the intermodulation signal rejection module 602.

The filtered second reception band signal includes an intermodulation signal component and becomes a signal to be intermodulation canceled by the intermodulation rejection module 602. A portion of the first transmission band signal and a portion of the second transmission band signal serve as reference signals used to remove intermodulation signal components in the second reception band signal.

A part of the output signal of the first transmission band filter 650 of the duplexer 606 is input to the intermodulation signal elimination module 602 through coupling, and the signal is hereinafter defined as a first reference signal.

A part of the output signal of the second transmission band filter 603 is input to the intermodulation signal elimination module 602 via coupling, and the signal is hereinafter defined as a second reference signal.

The intermodulation signal rejection module 602 includes an amplifier 610 that amplifies the output signal of the 2 < nd > -1 receive bandpass filter 605. [ The signal output from the 2-1 reception band filter 605 has a very low signal level and it is necessary to amplify it to a certain level. In one example, the amplifier 610 may include a low noise amplifier.

The signal amplified by the amplifier 610 is input to the rejection unit 608 via the first conversion unit 611. The first conversion unit 611 includes a mixer and an A / D converter, and is converted into a digital signal through the first conversion unit 611.

The first reference signal is input to the removal unit 608 via the second conversion unit 612. The second conversion unit 612 includes a mixer and an A / D converter, and the first reference signal is converted into a digital signal through the second conversion unit 612.

The second reference signal is input to the removal unit 608 via the third conversion unit 613. The third conversion unit 613 includes a mixer and an A / D converter, and the second reference signal is converted into a digital signal through the third conversion unit 613.

The removing unit 608 removes the intermodulation signal of the second reception band signal (uplink signal) using the first reference signal and the second reference signal. At this time, the intermodulation signal removed in the demultiplexer 608 is an intermodulation signal generated in the second reception band between the antenna and the intermodulation signal eliminator 602.

Since the intermodulation signal eliminator 601 of the present invention is disposed between the antenna and the mobile communication transceiver (the repeater, the base station or the RRH), the intermodulation signal eliminator 601 is connected to the intermodulation signal eliminator 601, It is also necessary to remove the intermodulation signal generated between the transmitting and receiving devices. To this end, the intermodulation signal elimination device 601 of the present invention includes a 2-2 reception band filter 604, a combiner 607, an amplifier 609 and a fourth conversion unit 615.

The signal input through the second connection unit 617 includes a first transmission band signal and a second transmission band signal which are transmitted to the intermodulation signal eliminator 601 and the mobile communication transceiver . A part of the first transmission band signal and the second transmission band signal is input to the second -2 reception band filter 604 and the output signal of the second -2 reception band filter 604 is input to the second transmission band signal 604, Only the intermodulation signal component based on the PIMD of the second reception band is output from the transmission band signal.

The output signal of the second-second reception band-pass filter 604 is amplified through an amplifier 609, and is converted into a digital signal through the fourth conversion unit 615. The output signal of the 2 < nd > 2 reception band filter 604 acts as a third reference signal, and the third reference signal converted into a digital signal is input to a rejection unit 608.

The demultiplexer 608 generates an inverse phase signal based on the third reference signal and reflects it in the second reception band signal from which the intermodulation signal component generated between the antenna and the intermodulation signal elimination device is removed. The intermodulation signal generated between the intermodulation signal eliminator 601 and the mobile communication transceiver is an intermodulation signal that has not yet occurred in terms of the second reception band signal, Thereby compensating for the distortion caused by the distortion.

The removal unit 608 may be implemented with various types of digital processing modules, and may be implemented, for example, through an FPGA

An apparatus for canceling intermodulation signal according to an embodiment of the present invention includes an upper intermodulation signal and an intermodulation signal elimination device installed between an antenna and a mobile communication transceiver, The downlink intermodulation signal between the communication transmitting and receiving devices can be eliminated, and even if a mobile communication transmitting and receiving device is added in the future, it can be easily changed and replaced. In addition, since a 3 dB splitter or the like is not used as in the prior art, the intermodulation signal can be removed with a relatively low loss.

FIG. 3 is a block diagram illustrating a schematic structure of an eliminator according to an embodiment of the present invention. In this embodiment, the intermodulation signal generated between the antenna and the intermodulation signal elimination device 601 is defined as the upward intermodulation signal, and the intermodulation signal generated between the intermodulation signal elimination device 601 and the mobile communication transceiver Is defined as a down-mix signal.

3, the remover 608 according to an embodiment of the present invention includes an upper intermodulation signal rejection block 701, a downstream intermodulation signal rejection block 702, a processor 703, and a combining block 704, .

The first reference signal and the second reference signal are input to the uplink intermodulation canceling block 701 and the third reference signal is input to the downlink intermodulation canceling block 702. [

Processor 703 performs digital signal processing operations to remove intermodulation signals.

The upstream intermodulation signal canceling block 701 removes the upstream intermodulation signal existing in the second reception band using the second reception band signal including the first reference signal, the second reference signal, and the upstream intermodulation signal component .

The down-interleaved signal removing block 702 extracts only the down-interleaved signal and reproduces the down-interleaved signal of the opposite phase.

The combining block 704 combines the output signal of the upstream intermodulation signal rejection block 701 with the output signal of the downstream intermodulation signal rejection block 702.

4 is a block diagram illustrating a detailed structure of a forward intermodulation signal cancellation block according to an embodiment of the present invention.

4, the uplink interleaved signal removal block 701 includes a first down converter 705, a second down converter 711, an inter-modulation signal first synchronizer 706, The intermodulation signal regenerator 707, the intermodulation signal crosstalk calculator 708, the intermodulation signal orthogonalizer 709, the intermodulation signal gain adjuster 710, the plurality of delayers 712, 713, and 714, And a signal first remover 715.

A more detailed description of the upward intermodulation signal rejection block 701 shown in FIG. 4 may be found in the applicant's patent application No. 2016-0022819.

The processor 703 calculates a value for adjusting the time synchronization between the down-converted baseband signals for the second reception band signal including the first reference signal, the second reference signal, and the upstream intermodulation signal component, The first synchronizer 706 and the plurality of delay units 712, 713, and 714 receive the computed value of the time delay from the processor 703 and perform time synchronization.

The intermodulation signal regenerator 707 multiplies the N passive intermodulation components using the Taylor series or the Boltera series for the first reference signal and the second reference signal synchronized with the signal including the upward intermodulation signal component Playback.

The intermodulation signal crosstalk calculator 708 for the regenerated passive intermodulation signals performs a correlation operation on the intermodulation regeneration signal output through the intermodulation signal regenerator 707. The intermodulation signal covariance calculator 708 performs autocorrelation and inter-correlation calculations on intermodulation signals, respectively. Specifically, the intermodulation signal covariance calculator 708 calculates an N X N covariance matrix using an autocorrelation function and a cross-correlation function.

The covariance matrix computed by the intermodulation-signal covariance calculator 708 is input to the processor, and the processor 703 outputs the N X N coefficient value that computes the orthogonal coefficient to the input covariance matrix. The intermodulation signal orthogonalizer 709 receives the N X N coefficient values from the processor 703 and performs orthogonalization by applying orthogonalization coefficients to the N regenerated intermodulation signal components. By the orthogonalization operation, only the autocorrelation value exists for the diagonal component, and other cross-correlation values have a zero value. That is, an operation is performed in the intermodulation signal orthogonalizer 709 to make the regenerated intermodulation signal components orthogonal to each other.

The intermodulation signal gain adjuster 710 receives the N orthogonal intermodulation signal component signals and the signals including the uplink intermodulation signal components (the second reception band including the intermodulation signal) by the intermodulation signal orthogonalizer 709, Signal) is input to the processor, and the processor receives the output information extracted through the gain and phase calculations to compensate the gain and phase information for the orthogonal intermodulation signal components. That is, the gain adjustment is performed so that the power of the orthogonal passive intermodulation signal component signals is similar to the power of the signal including the upward intermodulation signal.

The intermodulation signal first eliminator 715 multiplies the N regenerated passive intermodulation signal component signals by the intermodulation signal gain adjuster 710 with the sum of the signals for which the gain and the weft information are compensated and the sum of the upward intermodulation signal components And a second reception band signal in which the intermodulation signal has been removed is removed from the output signal of the second reception band through the difference between the signal (the second reception band signal including the intermodulation signal) do.

5 is a block diagram illustrating a detailed structure of a down-mixed-modulated signal removal block according to an embodiment of the present invention.

5, the downlink intermodulation signal cancellation block according to an embodiment of the present invention includes a third down converter 716, two delay units 717 and 719, an intermodulation signal second synchronizer 718, An intermodulation signal second remover 720, an inverse modulator 721, and a combiner 722.

The intermodulation signal second synchronizer 718 and the two delay units 717 and 719 receive the output signal of the upstream intermodulation signal rejection block 701 and the downmodulation signal (A computation value for a time delay) for synchronizing the baseband signals of the baseband signals of the baseband signals from the processor 703 and adjusting the time synchronization.

The intermodulation signal second eliminator 720 receives the difference signal between the output signal of the upstream intermodulation signal rejection block and the signal including the downstream intermodulation signal component (the signal passing through the 2-2 reception band filter) Only the downstream intermodulation signal present in the received signal is extracted. If the isolation degree of the coupler 607 to be described later is perfect, the removal operation may not be performed but the isolation degree of the coupler 607 may not be perfect. Therefore, the removal operation is performed through the intermodulation signal second remover 720 do.

The inverse phase signal 721 generates an inverse phase signal with respect to the output signal of the intermodulation signal second canceller 720.

The combiner 722 performs a sum operation on the output signal of the uplink intermodulation canceling block and the anti-phase signal.

The output signal of the demultiplexer 608 is a signal obtained by adding an anti-phase signal to the block of the upstream intermodulation signal. The output signal of the demultiplexer 608 is converted into a signal of a high frequency band and an analog signal .

The signal of the fifth conversion unit 614 is input to the second -2 reception filter 604 via the combiner 607. [

The coupler 607 has an isolation diagram for the output signal of the second -2 reception band filter 604 and the output signal of the rejection 608, which is a signal in the direction of the second connection portion, And transmits the signal. Since signals in different directions are transmitted via the coupler 607, it is necessary to secure isolation thereof. A directional coupler or circulator may be used as such a coupler, and various RF devices capable of securing isolation may be used.

The intermodulation signal canceller according to the embodiment of the present invention can be implemented in various forms. FIG. 6 is a diagram illustrating an apparatus for canceling an intermodulation signal according to another embodiment of the present invention. FIG. 6 illustrates an example of an intermodulation signal elimination apparatus existing on a MIMO (Multiplexed Input Multiple Output) path to be. It can be confirmed that the two intermodulation signal elimination apparatuses shown in FIG. 2 are combined to support MIMO.

FIG. 7 is a block diagram of an intermodulation signal canceling apparatus according to another embodiment of the present invention. The intermodulation signal canceller is applicable to each mobile communication transceiver when a power supply unit is shared between mobile communication providers in a building or the like. An example is shown in Fig.

In addition to the embodiments shown in FIGS. 2, 5 and 6, it will be apparent to those skilled in the art that various types of intermodulation signal equalization devices may be implemented while maintaining the essential features of the present invention.

FIG. 8 is a diagram illustrating a conceptual structure of an intermodulation signal eliminator according to an embodiment of the present invention. Referring to FIG.

The embodiment of FIG. 2 is a diagram showing an apparatus for canceling an intermodulation signal when two transmission bands and two reception bands are used, and FIG. 8 is a conceptual view of such a structure. In Figure 8, one transmission band filter 810 and two reception band filters 812 and 814 are shown, wherein the pass band of the filters 810, 812, 814 is not limited to a single band It may be understood as a set of filters capable of filtering for multiple bands.

Referring to FIG. 8, a received signal is input through the first connection unit 800, and the received signal is a signal including an upward intermodulation signal generated between the intermodulation signal canceller and the antenna.

The received signal is filtered through the first receive bandpass filter 812 and input to the intermodulation signal rejection module 820.

The transmission signal is input through the second connection unit 802. The transmission signal is divided into the transmission band pass filter 810 and the signal is filtered by the transmission band filter 810 and then transmitted through the first connection unit 800, . A portion of the signal filtered by the transmit bandpass filter 810 is input to intermodulation signal rejection module 820 via coupling. Since the filtered signal is filtered by the transmission band-pass filter 810, the signal is not included in the intermodulation signal component, and the corresponding signal is used in the intermodulation signal removal module 820 as the first reference signal.

A transmission signal of the transmission signal divided in the direction of the second reception band filter 814 is filtered by the second reception band filter 812. The signal filtered by the second reception band filter 814 is a signal including only the intermodulation signal component that affects the reception band of the transmission signal and the intermodulation signal is a signal between the intermodulation signal eliminator and the mobile communication transceiver Lt; / RTI >

The signal filtered by the second reception band filter 814 is input to the intermodulation signal removal module 820 and the output signal of the second reception band filter 814 is used as a second reference signal in the intermodulation signal module do.

The output signal of the first reception band-pass filter 812 is amplified by the first amplifier 830, converted into baseband and digital signals by the first conversion unit 840, and input to the rejection unit 850.

The coupled signal of the output signal of the transmission band filter 810 is converted into a baseband signal and a digital signal by the second conversion unit 842 and input to the rejection unit 850.

The demultiplexer 850 removes the uplink interleaved signal included in the received signal using the received signal including the first reference signal and the uplink interleaved signal. The operation of removing the uplink intermodulation signal at the demultiplexer 850 has been described in detail with reference to FIG. 2 and FIG.

The signal filtered by the second reception band-pass filter is amplified by a second amplifier 832 via a combiner 860 and converted into a band-blank and a digital signal via a third converter 844.

The demultiplexer 850 generates an anti-phase signal corresponding to the second reference signal, and adds the anti-phase signal to the received signal from which the uplink intermodulation signal has been removed, and this signal becomes the final output signal of the demodulation.

The output signal of the removal unit 850 is output through the second connection unit 802 via the combiner 860.

As described above, the present invention has been described with reference to particular embodiments, such as specific elements, and specific embodiments and drawings. However, it should be understood that the present invention is not limited to the above- And various modifications and changes may be made thereto by those skilled in the art to which the present invention pertains. Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, belong to the scope of the present invention .

Claims (16)

An intermodulation signal eliminating device installed between an antenna and a mobile communication transceiver,
A first reception band filter for performing a filtering on a first reception band with respect to a reception signal from an antenna;
A transmission band filter for performing filtering on a transmission band with respect to a transmission signal to the antenna;
A second reception band filter for performing a filtering on a second reception band with respect to a reception signal from the antenna;
And an intermodulation signal elimination module receiving an output signal of the first reception band filter, an output signal of the second reception band filter, and a coupling signal to an output of the transmission band filter,
The intermodulation signal elimination module may include an uplink intermodulation signal rejection block for removing the uplink intermodulation signal from the output signal of the first reception band filter using a coupling signal for the transmission band filter output as a first reference signal, And a downlink intermodulation signal canceling block for generating an anti-phase signal for the downlink interleaved signal using the output signal of the second reception band filter as a second reference signal,
Wherein the intermodulation signal elimination module sums and outputs the anti-phase signal and the output signal of the uplink intermodulation signal rejection block.
The method according to claim 1,
The intermodulation signal elimination module converts the output signal of the first reception band filter, the first reference signal, and the second reference signal into a baseband and a digital signal, removes the uplink intermodulation signal, And generates an anti-phase signal with respect to the signal.
3. The method of claim 2,
The downlink interleaved signal removing block receives the downlink interleaved signal in the receiving band through a difference between the output signal of the second reception band filter converted into the baseband and digital signals and the output signal of the uplink interleaved signal removing block, And extracting only the intermodulation signal.
3. The method of claim 2,
The upstream intermodulation signal removing block may include an intermodulation signal regenerator for regenerating an upstream intermodulation signal, an intermodulation signal crosstalk calculator for calculating a covariance matrix for the regenerated intermodulation signal, an orthogonalization coefficient calculating unit for calculating an orthogonalization coefficient using the covariance matrix, An orthogonal modulator for orthogonalizing the regenerated orthogonal modulated signal and a second orthogonal orthogonal modulator for modulating the gain and phase of the output signal of the orthogonal modulator and the first reference signal, And an intermodulation signal canceller for removing the uplink intermodulation signal through the difference between the first reference signal whose gain is adjusted by the intermodulation signal gain controller and the intermodulation signal orthogonalized by the intermodulation signal gain controller. Lt; / RTI >
delete The method according to claim 1,
Further comprising a combiner for securing an isolation of the output signal of the intermodulation signal elimination module and the output signal of the second reception band filter transmitted in the direction of the antenna, Intermodulation signal remover.
The method according to claim 6,
Wherein the coupler comprises a directional coupler and a circulator.
The method according to claim 6,
Wherein an output signal of the intermodulation signal elimination module is filtered by the second reception band filter via the combiner and transmitted in the direction of the mobile communication transceiver.
An intermodulation signal eliminating device installed between an antenna and a mobile communication transceiver,
A first reception band filter for performing a filtering on a first reception band with respect to a reception signal from an antenna;
A first transmission band filter for performing a filtering on a first transmission band with respect to a first band transmission signal to the antenna;
A second reception band filter for performing a filtering on a second reception band with respect to a reception signal from the antenna;
A second transmission band filter for performing a filtering on a second transmission band with respect to a second band transmission signal to the antenna; And
Receiving a coupling signal for an output of the first reception band filter, an output signal of the second reception band filter, a coupling signal for an output of the first transmission band filter, and a coupling signal for an output of the second transmission band filter, An intermodulation signal cancellation module,
Wherein the intermodulation signal elimination module uses the coupling signal for the output of the first transmission band filter as a first reference signal and the coupling signal for the output of the second transmission band filter as a second reference signal, An uplink intermodulation signal removing block for removing the uplink intermodulation signal from the output signal of the band pass filter and a downlink modulating signal removing block for generating an inverse phase signal for the downlink intermodulation signal using the output signal of the second reception band filter as the third reference signal, An intermodulation signal cancellation block,
Wherein the intermodulation signal elimination module sums and outputs the anti-phase signal and the output signal of the uplink intermodulation signal rejection block.
10. The method of claim 9,
The intermodulation signal elimination module converts the output signal of the first reception band filter, the first reference signal, the second reference signal, and the third reference signal into a baseband and a digital signal, And generates an anti-phase signal for the downlink interleaved signal.
11. The method of claim 10,
The downlink interleaved signal removing block receives the downlink interleaved signal in the receiving band through a difference between the output signal of the second reception band filter converted into the baseband and digital signals and the output signal of the uplink interleaved signal removing block, And extracting only the intermodulation signal.
11. The method of claim 10,
The upstream intermodulation signal removing block may include an intermodulation signal regenerator for regenerating an upstream intermodulation signal, an intermodulation signal crosstalk calculator for calculating a covariance matrix for the regenerated intermodulation signal, an orthogonalization coefficient calculating unit for calculating an orthogonalization coefficient using the covariance matrix, An orthogonal modulator for orthogonalizing the regenerated orthogonal modulated signal and a second orthogonal orthogonal modulator for modulating the gain and phase of the output signal of the orthogonal modulator and the first reference signal, An intermodulation signal canceller for eliminating the uplink intermodulation signal through the difference between the first reference signal whose gain is adjusted by the intermodulation signal gain controller and the second reference signal and the intermodulation signal orthogonalized by the intermodulation signal gain controller, And the intermodulation signal cancellation device.
delete 10. The method of claim 9,
Further comprising a combiner for securing an isolation of the output signal of the intermodulation signal elimination module and the output signal of the second reception band filter transmitted in the direction of the antenna, Intermodulation signal remover.
15. The method of claim 14,
Wherein the coupler comprises a directional coupler and a circulator.
15. The method of claim 14,
Wherein an output signal of the intermodulation signal elimination module is filtered by the second reception band filter via the combiner and transmitted in the direction of the mobile communication transceiver.

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