KR101984809B1 - Pimd interference reducing apparatus in multiple frequency combination and mobile communications system having the same - Google Patents

Abstract

The mobile communication system includes a plurality of transceivers for transmitting and receiving signals using different frequency bands and a plurality of signal sources shared by the transceivers and input from the transceivers to the transmitting and receiving antennas, A plurality of signal sources input from the transceivers in order to reduce PIMD interference generated in the feeder router; and a plurality of signal sources for receiving signals from the transceivers, Wherein the nth-n included in the output signal of the feeder sharer includes an erasure source occurring around n times the frequency of the fundamental frequency of the plurality of signal sources among the at least three odd-numbered distortion signals, After the detection, the size and upper After controlling the application side of the transceiver and, a PIMD interference reducing device, to reduce the PIMD interference by canceling the interference source in a frequency band of the reception signals of the transceiver of the n th order distortion signal.

Description

TECHNICAL FIELD [0001] The present invention relates to a PIMD interference reduction apparatus and a mobile communication system including the PIMD interference reduction apparatus and a mobile communication system including the PIMD interference reduction apparatus.

The present invention relates to a PIMD interference reduction apparatus in a multi-band frequency combining and a mobile communication system including the PIMD interference reduction apparatus.

In installing a feeder line and an antenna for each mobile communication service to solve a shadow area, installation cost is excessively required when a separate antenna is installed for each communication service provider or for each mobile communication service. Therefore, a feeder router is used in terms of cost reduction and ease of installation. For example, since the frequencies of mobile communication services are different from each other in WCDMA and WiBro (Wirelss Broadband), it is possible to reduce the cost of laying a feeder line by using a feeder router that combines filter characteristics of the corresponding frequency band.

In this way, when a feeder router is used to reduce the cost of installing a feeder line, intermodulation distortion (IMD) becomes a problem. In particular, passive intermodulation distortion due to nonlinearity of passive elements, PIMD) is a problem. The IMD is an RF signal source that has two or more center frequencies (represented as 'two tones' with two center frequencies and 'three tones' with three center frequencies) It generates an undesired parasitic signal. If IMD appears in a passive device, it is called a PIMD. If it appears in an active device, it is called an AIMD.

Generally, a PIMD is caused by this nonlinear medium property when there is a nonlinear medium in the signal propagation path where there are 2 tone, 3 tone or more multitone RF signal sources. In the construction of the RF system, the PIMD level of the components is determined by the nonlinear signal transfer function, and the possibility of interference between communication systems using different frequency bands is very high. Such interference causes signal disconnection between the terminal and the system in the communication system, and causes a phenomenon such as call-drop.

Therefore, when a RF signal source having two, three, or more center frequencies is input in a feeder router in a mobile communication system, a nonlinear medium existing in the signal transmission path (which has contact nonlinearity or material non- There is a need in the art for a solution to reduce the passive intermodulation distortion (PIMD) that acts as an interferer of a communication signal due to the presence of the signal.

As one of the conventional solutions, a coupler is used in the output signal of the feeder router to detect only a signal component causing PIMD, and a separate harmonic signal for erasing the signal component is artificially generated Is being used. However, the mobile communication system is composed of CDMA (2G), WCDMA (3G), and LTE (4G) according to a multiple access scheme and combines various modulated and multiplexed signal sources using a feeder router Or a single transmission line to the antenna. In this case, since the amount of voice or data traffic is adaptively used for the transmission / reception signal sources according to the radio environment (channel environment), it acts as the same channel interference source The PIMD component having a complicated nature with time and a certain portion of the frequency band overlapping with the signal received on the frequency axis acts as a cochannel interference source and the noise signals are very difficult to be separated from each other .

Therefore, in a conventional method of artificially generating a harmonic signal to remove a PIMD by level and phase control, the PIMD acting as a co-channel interference source is completely different from its generating mechanism, A solution of the concept is required in the art.

Korean Patent Publication No. 10-2010-0104677 (published on September 29, 2010) Korean Patent Publication No. 10-2010-0117360 (published on November 3, 2010)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a PIMD interference reduction apparatus in a multi-band frequency combining and a mobile communication system including the PIMD interference reduction apparatus.

In order to reduce passive intermodulation distortion (PIMD) at triple-band frequencies (center frequencies f1, f2, f3 and f1 <f2 <f3 respectively) (Fifth order IMD) generated by a fifth order distortion signal (fifth order IMD) generated by the intermodulation of the fifth order distortion signal (fifth order IMD) in the reception signal band (center frequency f2) of the second transceiver, A third transmitter / receiver, a third transmitter, and a third transmitter / receiver using a fifth order distortion signal generated in the vicinity of a frequency 5 times the fundamental frequency of the transmission signal of the third transmitter / And a mobile communication system including the PIMD interference reduction apparatus.

According to an aspect of the present invention, there is provided a mobile communication system including a plurality of transceivers for transmitting and receiving signals using different frequency bands, a plurality of signal sources shared by the transceivers and input from the transceivers, A transmission line shaper for transmitting a plurality of signal sources to the transceivers via a transmission / reception antenna or a plurality of signal sources received through the transmission / reception antenna; and a control unit for receiving input from the transceivers in order to reduce PIMD Wherein n-th power of the n-th power signal generated by the plurality of signal sources, which are included in the output signal of the feeder router, Circulates the output signal of the feeder sharing device The PIMD interference can be reduced by controlling the magnitude and phase of the cancellation source and applying the same to the transceivers to cancel the n-order distortion signals with the interference sources in the frequency bands of the received signals of the transceivers. And an interference reduction device.

According to one embodiment, the transceivers include a first transceiver, a second transceiver, and a third transceiver, wherein the first transceiver, the second transceiver, and the third transceiver use different frequency bands, and the first transceiver, Wherein the center frequency for transmitting and receiving is f1, the center frequency for transmitting and receiving the second transceiver is f2, the center frequency for transmitting and receiving the third transceiver is f3, and f1 <f2 <f3, And an output of the feeder router, which is generated by three signal sources input from the transceivers and has a center frequency of 2f1 + 2f2 + f3 among fifth-order distortion signals included in the output signal of the feeder router, And controls the magnitude and phase of the cancellation source to be applied to the second transceiver side so that the frequency of the received signal of the second transceiver The interference source in the band - the interference source in the frequency band of the received signal of the second transceiver is offset by 2f1 + f3 - 2f2 as the center frequency.

According to one embodiment, the PIMD interference reduction apparatus comprises: a cancellation source detection unit for detecting the cancellation source; and a control unit for controlling the size and phase of the cancellation source detected by the cancellation source detection unit, 1 reference phase and a first reference magnitude wherein the first reference phase is a phase of an interferer in a frequency band of a received signal of the second transceiver and the first reference magnitude is within a frequency band of a received signal of the second transceiver Wherein the interference canceller comprises: an interference source information providing unit for determining an interference canceller size and providing the interference canceller to the canceller detecting unit; and an erasure source whose size and phase are controlled by the interference canceller, And a PIMD interference reduction coupler coupled to the receive link of the second transceiver for canceling the interference source in the band to reduce PIMD interference.

According to one embodiment, the cancellation detecting unit includes a first filter for filtering an output signal of the feed line sharer, a first amplifier for amplifying an output signal of the feed line sharer filtered by the first filter, A frequency mixer for mixing and down converting the center frequency of the cancellation source and the local oscillation frequency generated by the voltage controlled oscillator in a signal amplified by the first amplifier, A second filter for removing noise from an erasure source down-converted by the second filter, and a second filter for removing noise from the noise source by the second filter, An attenuator for attenuating the attenuator; and an attenuator for outputting the attenuator according to the first reference phase provided from the interferer information provider And a phase converter for converting the phase of the signal, and a second amplifier for amplifying the signal output from the phase converter.

According to one embodiment, the first filter may be located in the feeder router.

According to one embodiment, the interference source information providing unit includes a first detecting coupler coupled between the first amplifier and the frequency mixer, for detecting a signal amplified by the first amplifier, A first reference phase and a first reference phase in an interference source in a frequency band of a received signal of the second transceiver, in a signal amplified by the first amplifier, And a controller for providing the first reference phase and the first reference magnitude detected by the first level detector to the phase converter and the attenuator, respectively.

According to an embodiment, the interference source information providing unit may be configured such that, at a reception link of the second transceiver, a PIMD interference reduction is reduced by the PIMD interference reduction coupler at a rear end of a point where the PIMD interference reduction coupler is coupled And a second detection coupler for detecting a received signal of the second transceiver in a state of a second state.

According to an embodiment, the interference source information providing unit may include a third filter for filtering the signal detected by the second detecting coupler, and a third filter for filtering the first reference phase and the second reference signal, And a second level detector for detecting and providing to the controller side a second reference phase and a second reference magnitude corresponding to each of the first reference magnitudes.

According to one embodiment, the cancellation detecting section includes a third detecting coupler located between the feed line router and the transmitting / receiving antenna for detecting an output signal of the feed line router and transmitting the signal to the first filter side .

The PIMD interference cancellation apparatus according to an aspect of the present invention includes a plurality of signal sources shared by a plurality of transceivers transmitting and receiving using different frequency bands and outputting a plurality of signal sources input from the transceivers to a transmitting and receiving antenna side, A plurality of signal sources input from the transceivers for reducing PIMD interference generated in a feed line router transmitting a plurality of received signal sources to the transceivers, An n-th order-n signal included in the signal is directly detected from an output signal of the feeder router, and an erase source located at a frequency around n times the fundamental frequency of the plurality of signal sources among the at least three odd- After controlling the size and phase of the cancellation source, And outputs the n-th order distortion signal to the input devices, thereby canceling PIMD interference by canceling the n-order distortion signals with the interference sources in the frequency bands of the received signals of the transceivers, wherein the PIMD interference reduction device comprises: The first reference phase and the first reference phase from the output signal of the feed line shaper are controlled by the frequency of the received signal of the second transceiver, Wherein the first reference size is a size of an interference source in a frequency band of a received signal of the second transceiver and provides the signal to the cancellation detection unit side; An interference canceller whose size and phase are controlled by the interference source information providing unit and an interference source within the frequency band of the reception signal of the second transceiver, To include, receive link and coupling coupler, the interference reducing PIMD is a ring of said second transceiver to reduce the PIMD interference.

The present invention provides a PIMD interference reduction apparatus in a multi-band frequency combining, especially a triple-band frequency combining, and a mobile communication system including the PIMD interference reducing apparatus, a fifth order distortion signal (fifth order IMD (Center frequency f2) of the second transceiver in the 5th order distortion signal (5th order IMD) of the fundamental frequency of the transmission signals of the first transceiver, the second transmitter, and the third transceiver, The fifth order distortion signal generated in the vicinity of the harmonic frequency is used to control the magnitude and the phase to offset the PIMD interference, thereby reducing the PIMD interference.

FIG. 1 is a block diagram for explaining a basic structure of a feeder line sharing system of a communication system using a two-tone signal source (for example, WCDMA and WiBro)
FIG. 2 is a diagram for explaining the nonlinear characteristic of the feeder sharer 30 of FIG. 1,
FIG. 3 is a graph showing a third-order IM and a fifth-order IM generated when a feeder line is shared between the A system (yellow) and the B system (blue)
FIG. 4 is a graph in which linear characteristics and nonlinear characteristics of input and output are simplified,
5 is a graph showing a nonlinear characteristic of a frequency spectrum due to nonlinearity of a feed line router,
(Center frequency: 2f1-f2) ((a (a)) acting as an interference source in the received signal (center frequency: f3) band of the WCDMA transceiver among the third- (Center frequency: 2f1 + f2) ((b)) of the signal appearing near the frequency 3f1 corresponding to three times the center frequency f1 of the transmission signal of the WCDMA transceiver among the third-order distortion signals, Is a spectrum waveform for comparison,
FIG. 7 is a block diagram for explaining a PIMD interference reduction apparatus for reducing PIMD interference in a dual-band frequency combining and a mobile communication system including the PIMD interference reduction apparatus,
FIG. 8 is a block diagram illustrating a process of removing the left interferer from the left cancellation source in FIG. 7,
FIG. 9 is a block diagram illustrating a process of removing the right interferer from the right side canceller in FIG. 7,
FIG. 10 is a block diagram illustrating a process of removing a left interferer and a right interferer with the left eraser and the right eraser in FIG. 7, respectively.
11 is a frequency spectrum for explaining the PIMD in the triple-band frequency combining,
FIG. 12 is a diagram schematically showing a frequency spectrum of an interference source in a reception signal of a second transceiver among a cancellation source and a fifth-order distortion signal of a fifth-order distortion signal in a triple-band frequency combination,
13 is a view for explaining a PIMD interference reduction apparatus in a triple-band frequency combining and a mobile communication system including the PIMD interference reduction apparatus according to an embodiment of the present invention,
FIG. 14 is a diagram for explaining a PIMD interference reduction apparatus and a mobile communication system including the PIMD interference reduction apparatus in a triple-band frequency combining according to another embodiment of the present invention.

The present invention basically detects PIMD components in dual, triple, or more multi-band frequency combinals using a plurality of transceivers directly at the feed line router, so that n (n is an odd number of 3 or more) The present invention relates to a device for reducing PIMD interference by canceling an n-order distortion signal appearing near a drain harmonic with a component causing a PIMD interference at a receiving end in the transceivers, and a mobile communication system using the same.

 Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that the accompanying drawings and the embodiments described with reference to the same are simplified and illustrated to enable those of ordinary skill in the art to readily understand the present invention.

FIG. 1 is a block diagram for explaining a basic structure of a feeder line sharing system of a communication system using a two-tone signal source (for example, WCDMA and WiBro) and the PIMD generation according to the basic structure.

1, a WCDMA transceiver 10 and a WiBro transceiver 20 share one feeder line 37 and are commonly connected to a transmitting and receiving antenna ANT. The feeder router 30 is used for sharing the feeder line 37 and the feeder router 30 is a passive device of a cavity type and filters 31, 32, and 33 are accommodated in filter banks (not shown) and combined using T-junctions. 1, reference numeral 34 denotes a T-junction, 35 a connector on the feeder sharer 30, and 36 a connector on the transmitting and receiving antenna (ANT). A feed line (37) is connected between the transmission / reception antenna (ANT) and the feeder router (30). The transmission frequency of the WCDMA transceiver 10 is f1 and the reception frequency thereof is f3. The transmission link (downlink) is provided with a transmission amplifier 11 and the reception link (uplink) A credit amplifier 12 is provided. The uplink and the downlink may be changed according to the reference, but in the present description, a link transmitted through the antenna ANT is referred to as a downlink, and vice versa, that is, a receive link is referred to as an uplink . In the case of the WiBro transceiver 20, a circulator 24 for discriminating an upstream signal from a downstream signal and a switch 23 for switching and receiving the upstream signal and the downstream signal are included do. An amplifier 21 for transmitting and an amplifier 12 for receiving are also provided in the WiBro transceiver 20, respectively. The amplifiers 11, 12, 21 and 22 are all low noise amplifiers (LNAs). Among the filters provided in the feeder router 30, reference numerals 31 and 32 denote filters for a WCDMA transceiver, and reference numeral 33 denotes filters for a WiBro transceiver.

In the feed line sharing system as shown in FIG. 1, the WCDMA and WiBro communication systems are different from each other in terms of the communication system (CDMA vs. TDMA) as well as using different frequency bands.

However, as shown in FIG. 1, the feeder sharer 30 is a passive element of a cavity type and must be operated in a T-junction manner to ideally operate linearly. However, due to contact nonlinearity and material nonlinearity, The router 30 has a nonlinear characteristic. Intermodulation distortion (IMD), particularly passive intermodulation distortion (PIMD), occurs when there is a medium having a non-linear characteristic on the signal transmission path in which a multi-tone RF signal source of 2 tons or more exists. Thereby increasing the possibility of interference between communication systems using different frequency bands. 1, the point at which the PIMD occurs is the connector 36 for the transmission / reception antenna, the connector 35 for the feeder router, the transmission / reception antenna ANT itself, and the T-junction 34. In view of the trend of continuous increase in capacity and improvement of service quality in mobile communication, the interference problem due to PIMD causes a decrease in reception sensitivity in a communication system operating in the range of -100 to -130 dBm. As a result, There is a problem that it causes deterioration and call drop phenomenon. The above-mentioned contact nonlinearity is caused by incomplete contact between the metal and the surface state of the connection point between metals. This is due to a change in the constriction resistance, tunneling effect, microdischarge appear. On the other hand, material nonlinearity is caused by ferromagnetic hysteresis, magneto-resistance, etc. appearing in materials such as nickel, iron and cobalt.

The nonlinear characteristics of the feeder sharer 30 are such that when a multi-tone signal source (having fundamental frequencies f1 and f2) is input to a system having non-linear characteristics, as modeled in Fig. 2, As shown, an IMD occurs. It can be seen that the transmission frequency used in the WCDMA transceiver of FIG. 1 is f1 in FIG. 2 and the frequency of the Wibro transceiver is f2 in FIG.

FIG. 3 is a graph showing the third-order IM and the fifth-order IM that occur when a feeder line is shared between the A system (yellow) and the B system (blue). Referring to FIG. 3, when a two-tone signal source is input to the feeder router, a third order IMD (red) and a fifth order IMD (orange) are generated over a wide range. Each of the A system and the B system may be two different systems selected from, for example, a WCDMA system, a WiBro / Wi-Fi system, and a PCS system. In the case of sharing them, The fifth IMD is generated and directly or indirectly influences the system.

The PIMD interference reduction device and the wireless communication system using the same include a plurality of transceivers for transmitting and receiving using different frequency bands, a feeder router, and a PIMD interference reduction device.

The feeder router transmits a plurality of signal sources shared by the transceivers and input from the transceivers to the transceiver antenna or transmits a plurality of signal sources received through the transceiver antenna to the transceivers.

The PIMD interference reduction apparatus includes an n-th power source generated by a plurality of signal sources input from the transceivers and included in an output signal of the power line sharing device to reduce PIMD interference generated in the power line sharing device, And an erase source having a center frequency of n times the fundamental frequency of the plurality of signal sources among the odd-numbered signal sources is directly detected from the output signal of the feeder router, and then the magnitude and phase of the erase source are controlled And then reduces the PIMD interference by applying the n-th order distortion signal to the transceivers, thereby canceling the n-th order distortion signal with the interference source in the frequency band of the reception signal of the transceivers.

The most notable part in relation to PIMD interference is the method of canceling the interferer with the canceller in relation to the third order distortion signal in the dual band frequency combination and the method of canceling the interferer in the case of the fifth order distortion signal in the triple band frequency combination And the interference source is canceled by the cancellation source. In the following, these are described in order.

&Lt; &lt; PIMD  Interference Abatement >

First, referring to Figs. 5 to 10, a description will be given of a technique for eliminating an interference source using an erasure source related to a third-order distortion signal in a dual-band frequency combining.

In order to model the nonlinear characteristic of the input vs. output, a polynomial is generally used. When the output voltage having a nonlinear characteristic as shown in FIG. 4 is expressed as V ₀ , As shown in Fig.

이고, 이를 상기 수학식 1에 대입한 후의 다항식을 세제곱항까지 풀어서 전개하면 이하의 수학식 2가 된다.
When a two tone signal is applied as an input,

, And the polynomial after substituting it into the equation (1) is solved to the cubic term and developed, the following equation (2) is obtained.

If the input signal source is the transmission signal of the WCDMA transceiver 10 (FIG. 1) and the transmission signal of the WiBro transceiver 20 (FIG. 1) and the respective center frequencies are f1 and f2, Due to the characteristic, various frequency spectra may be generated in the output (V _O ) as shown in Equation (2). This can be represented graphically with respect to the frequency axis as shown in FIG. As shown in FIG. 5, PIMD is generated by the center frequencies f1 and f2 of the input two-tone signal, and among these, third-order distortion signals occur near f1 and f2, and around 3f1 and 3f2. In particular, the third order distortion signal having 2f1 - f2 in the third order distortion signal generated near the transmission frequency f1 of the WCDMA and the WiBro frequency f2 is generated in the frequency band corresponding to the reception signal of the WCDMA having the center frequency f3 Thereby acting as a co-channel interference source. The same is true for the third-order distortion signal having the center frequency of 2f2 - f1. As described above, in the WCDMA transmission / reception system, the terminal acts as a direct interference source of a call signal to the uplink system, which causes a signal disconnection between the terminal and the system. Thus, a so-called call-drop ). Therefore, in order to reduce the interference due to the PIMD, the interference sources are removed by using the third-order distortion signals having frequencies of 2f1 + f2 and f1 + 2f2 generated in the vicinity of 3f1 and 3f2 of the third-order distortion signal, A feedforward method is employed which approximates the linear characteristic to the linear characteristic.

6 shows a left side waveform (center frequency: 2f1 - f2) ((a)) acting as an interference source in a reception signal (center frequency: f3) band of a WCDMA transceiver among a third order distortion signal (Center frequency: 2f1 + f2) ((b)) of the signal appearing near the frequency 3f1 corresponding to three times the center frequency f1 of the transmission signal of the WCDMA transceiver among the third-order distortion signals It is the spectrum waveform.

The left signal (center frequency 2f1 - f2) serving as the interference source of the received signal of the WCDMA transceiver for the discrimination in the 3rd PIMD is hereinafter referred to as a 'left interferer' and the right signal (center frequency 2f2 - f1) 'Right interferer'. To distinguish them from each other, the left signal (center frequency 2f1 + f2) of the signal appearing near the frequency 3f1 corresponding to three times the center frequency of the transmission signal of the WCDMA transceiver among the third-order distortion signals is referred to as' And the right signal (center frequency f1 + 2f2) is referred to as the 'right erase source'.

As shown in FIG. 6, since the left interferer and the left canceller differ only in magnitude and phase, the left interferer is eliminated using the left canceller. Likewise, the right interferer is eliminated using the right interferer. Although only WCDMA and WiBro are described as examples in the drawings, they may be applied to sharing of feeder lines of 3G and WiBro. In the case of inputting a three-tone signal source as described later, It can also be applied to the case of establishing feeder line sharing with multitone signal source as input.

FIG. 7 is a block diagram for explaining a PIMD interference reduction apparatus for reducing PIMD interference in a dual-band frequency combining and a mobile communication system including the PIMD interference reduction apparatus according to the present invention. Referring to FIG. 7, a transmission / reception antenna ANT, a plurality of transceivers 110 and 120, a feeder router 130, and a PIMD interference reduction device 210, 220, and 230 are illustrated. In FIG. 8, only two examples of the plurality of transceivers 110 and 120 are illustrated, but they may be configured to be more commonly shared through the feeder router 130.

First, the transceivers 110 and 120 include a first transceiver 110 and a second transceiver 120. The first transceiver 110 and the second transceiver 120 communicate using different frequency bands. The central frequency for transmission of the first transceiver 110 is defined as f1, the center frequency for reception of the first transceiver 110 is defined as f3 and the center frequency for transmission and reception of the second transceiver 120 is defined as f2 . The center frequency and the frequency bandwidth of the mobile communication can be referred to FIG. Also, the first transceiver 110 may be a WCDMA transceiver and the second transceiver may be a WiBro transceiver. 1, the first transceiver 110 includes a transmitting amplifier 111 and a receiving amplifier 112, and the second transceiver 120 includes a transmitting amplifier 121, And further includes a circulator 124 and a switch 123 in addition to the receiving amplifier 122. [

The feeder sharer 130 may receive signal sources shared by the transceivers 110 and 120 and having different frequency bands from the transceivers 110 and 120 or signal sources having different modulation schemes And transmits the two or more different signal sources received by the transmission / reception antenna ANT via the feeder line 137 to the transceivers 110 and 120 side via the transmission line 137 It plays a role. As mentioned above, there has been a problem in that PIMD interference occurs due to contact nonlinearity or material nonlinearity with respect to a feeder router, and this problem can be solved by the PIMD interference reduction apparatus.

The PIMD interference cancellation apparatuses 210, 220 and 230 basically transmit the two-tone signal input from the transceivers 110 and 120 in order to reduce PIMD interference generated in the feeder router 130, (C3) of the third-order distortion signal generated by the source and included in the output signal of the feeder router 130, i.e., a third-order distortion signal having a center frequency of 2f1 + (A green arrow of the rightmost group in the frequency spectrum in C3), which is a third-order distortion signal having a center frequency f1 + 2f2, is detected, and the left erasure source or the right erasure source The frequency and phase of the first and second transceivers 110 and 110 are provided to the first transceiver 110 so that the first and second transceivers 110 and 110 receive the interference signal By color (L interferer), or green (right interferers)) and the offset reduces the interference PIMD. 8, the output signal of the feeder router 130 indicates the signal on the feeder line in the feeder router 130. The output signal of the feeder router 130 includes the first transceiver 110 having f1 as the center frequency for transmission and the second transceiver 110 as f2 The second transceiver 120 having the center frequency is shared via the T-junction 134, and accordingly, the PIMD interference is generated and transmitted to the first transceiver, the second transceiver, or the transmission / reception antenna ANT side Signal. An example of an output signal of the feeder router 130 is represented by C3 in Fig.

The PIMD interference cancellation apparatuses 210, 220 and 230 include a cancellation detection unit 210 (211, 212, 213, 214, 215, 216, 217) 228, 229, 229, and 229, and a PIMD interference reduction coupler 230. The PIMD interference reduction coupler 230 may include a plurality of PIMD interference reduction units 220, 221, 222, 223, 224,

The cancellation detecting section 210 is a component for detecting the left cancellation source (third-order distortion signal having 2f1 + f2 as the center frequency) or the right cancellation source (second-order distortion signal having the center frequency 2f2 + f1) (2f1 - f2 or 2f2 - f1) serving as an interference source of the reception signal of the first transceiver 110 (the signal whose center frequency is f3). The canceller detection unit 210 includes a first filter 211, a first amplifier 212, a frequency mixer 214, a second filter 215, an attenuator 216, a phase shifter 217, And a second amplifier 218. The first filter 211 receives the output signal C3 of the feeder router 130 from the left canceling source 2f1 + f2 as a third-order distortion signal, 2f2 + f1, which is the third-order distortion signal, and the green arrow of the rightmost group). The first filter 211 may be connected to the T-junction 134 together with the filters 131, 132 and 133 in the feeder router 130. The first amplifier 212 amplifies the left cancellation source or the right cancellation source extracted by the first filter 211. The frequency mixer 214 receives the center frequency 2f1 + f2 of the left cancellation source amplified by the first amplifier 212 or the center frequency 2f2 + f1 of the right cancellation source amplified by the first amplifier 212, And a local oscillation frequency generated by the voltage controlled oscillator VCO 213. The second filter 215 performs frequency conversion on the noise from the left side canceling source or the right side canceling source which is downconverted by the frequency mixer 214, (Center frequency 2f1 - f2) or a signal having the same center frequency as the right interferer 2f2 - f2 is extracted by the second filter 215. The attenuator 216 eliminates the noise by the second filter 215 And attenuates the size according to the first reference size provided from the interferer information providing part 220 for the right side cancellation source whose noise has been removed by the left side cancellation source or the second filter 215. [ Will be described below with reference to the interferer information providing part 220 The phase converter 217 converts the phase of the signal output from the attenuator 216 according to the first reference phase provided from the interferer information providing unit 220. The left interferer and the left interferer Since the relationship of the circles or the relationship of the right interferer and the left interferer can be canceled by having magnitude and opposite phase to each other, the phase converter 217 generally inverts the phase.

The interference source information providing unit 220 may determine the size and phase of the left cancellation source detected by the cancellation source detection unit 210 or the size and phase of the right cancellation source detected by the cancellation source detection unit 210, The first reference phase and the first reference magnitude are determined from the output signal of the feeder router 130 and provided to the cancellation detector 210 side. The first reference phase is equal to the phase of the interferer in the frequency band of the received signal (center frequency f3) of the first transceiver 110 and the first reference amplitude is the frequency of the received signal of the first transceiver 110 Is equal to the size of the interference source in the band. Therefore, in the case of the left interferer (center frequency 2f1 - f2), the first reference phase is the phase of the signal with center frequencies 2f1 - f2, and in the case of the right interferer (center frequency 2f2 - f1) It is the phase of the signal with frequency 2f2 - f1. The same is true of size.

The interference source information providing unit 220 includes a first detecting coupler 221, a third filter 222, a third amplifier 223, a first level detector 224, and a controller 225. The first detecting coupler 221 couples with the feeder router 130 to detect the output signal of the feeder router 130 including the third order distortion signals. The third filter 222 is connected to the left interferer (center frequency 2f1 - f2) or the right interferer (center frequency 2f2 - f1), that is, the first transceiver (Center frequency f3) of the received signal of the mobile station 110. [ The third amplifier 223 outputs an interference source (center frequency 2f1 - f2 or 2f2 - f1) within the frequency band (center frequency f3) of the reception signal of the first transceiver 110 extracted by the third filter 222 Amplified. The first level detector 224 detects a first reference phase at an interference source (center frequency 2f1 - f2 or 2f2 - f1) in the frequency band of the reception signal of the first transceiver 110 amplified by the third amplifier 223, And a first reference size. The controller 225 provides the first reference phase and the first reference magnitude detected by the first level detector 224 to the phase shifter 217 and the attenuator 216, The left or right cancellation source is substantially equal to each of the left or right interference sources of the interference canceller 220.

The PIMD interference reduction coupler 230 is a left side cancellation source whose size and phase are controlled by the interference source information providing unit 220 or a right side cancellation source whose size and phase is controlled by the interference source information providing unit 220 The interference sources in the frequency band (center frequency f3) of the received signal of the first transceiver 110 (i.e., the left interferer or the center frequency 2f2 - f1, which is the center frequency 2f1 - f2) Is coupled to the receive link of the first transceiver (110) so as to be reduced.

In addition, the interferer information providing unit 220 may further include a second detecting coupler 226 coupled to a receiving link of the first transceiver 110. The second detecting coupler 226 is configured such that the PIMD interference is reduced by the PIMD interference reducing coupler at a downstream side of the point where the PIMD interference reducing coupler 230 is coupled at the receiving link of the first transceiver 110 (The center frequency f3) of the first transceiver 110. [0050] FIG.

The interference source information providing unit 220 may further include a fourth filter 227, a fourth amplifier 228, and a second level detector 229. The fourth filter 227 is a portion for filtering the signal detected by the second detecting coupler 226, that is, the signal after the PIMD interference is reduced. The fourth amplifier 228 is a portion for amplifying the signal filtered by the fourth filter 227. The second level detector 229 detects a second reference phase and a second reference amplitude corresponding to the first reference phase and the first reference amplitude in the signal amplified by the fourth amplifier 228, . To compare and track phases and sizes before and after PIMD interference cancellation, i.e., a first reference phase and a second reference phase, and a first reference magnitude and a second reference magnitude to control the phase and magnitude in real time to be.

8 to 10 are block diagrams illustrating PIMD interference reduction using an erasure source and an interference source with reference to a center frequency. FIG. 8 is a block diagram illustrating a process of removing a left interferer using a left erasure source, 9 is a block diagram illustrating a process of removing the right interferer from the right canceller, and FIG. 10 is a block diagram illustrating a process of removing the left interferer and the right interferer from the left canceller and the right canceller, respectively. Hereinafter, these drawings are referred to with reference to FIG. In the drawings, only the center frequency is shown as an arrow to increase the discrimination power, but the signals indicated by the respective arrows are signals having a certain range of bandwidth.

7 and 8, a transmission signal C1 (center frequency f1) of the first transceiver 110 and a transmission signal C2 (center frequency f2) of the second transceiver 120 are input as an input source The PIMD interference occurs in the output signal C3 of the feeder router 130 when the two tone signal is applied to the feeder router 130. [ C3 has a left interferer (center frequency 2f1 - f2) (indicated in red) which is a PIMD near the center frequencies f1 and f2, and a PIMD near the center frequencies 3f1 and 3f2, (Center frequency 2f1 + f2) (indicated in red). That is, the left side interference source is canceled by using the left side cancellation source to reduce the PIMD interference. The signal with the center frequency 2f1 + f2 is extracted from the first filter 211 of the canceller detection unit 210, as shown in Fig. Then, down-conversion and filtering by amplification and frequency mixing are performed to filter signals having center frequencies 2f1 - f2, as indicated by C5. However, since the signal denoted by C5 is different in magnitude and phase from the actual interference source, the first reference phase and the first reference size are provided from the side of the interference source information providing unit 220 as described with reference to FIG. And controls the signal through the phase converter 217 and the attenuator 216 and amplifies the amplified signal through the second amplifier 218. Thereafter, the PIMD interference reduction coupler 230 is used to reduce the PIMD interference. The phases of the upper left cancellation sources 2f1 - f2 are reversed by the phase shifter 217 as indicated by C6. C7 represents the size of the left interferer 2f1 - f2 before PIMD interference reduction and C8 represents the size of the left interferer 2f1 - f2 after PIMD interference reduction. When comparing C7 and C8, it can be confirmed that the left interference source in the frequency band of the reception signal of the first transceiver 110 is greatly reduced by the PIMD interference reduction apparatus.

7 and 9, the transmission signal C 1 (center frequency f 1) of the first transceiver 110 and the transmission signal C 2 (center frequency f 2) of the second transceiver 120 are input to the input / The PIMD interference is generated in the output signal C3 of the feeder router 130. In this case, C3 is the right interferer (center frequency 2f2 - f1) (indicated in green) near the center frequencies f1 and f2, and the PIMD near the center frequencies 3f1 and 3f2, (Center frequency 2f2 + f1) (indicated in green). That is, the right side interference source is canceled by using the right side cancellation source to reduce the PIMD interference. As shown in C14, the first filter 211 of the canceller detection unit 210 extracts a signal having a center frequency of 2f2 + f1. After down-conversion and filtering by amplification and frequency mixing, a signal having a center frequency of 2f2 - f1 is filtered as indicated by C15. However, since the signal denoted by C15 is different in magnitude and phase from the actual interferer, the first reference phase and the first reference size are provided from the side of the interferer information provider 220 as described with reference to FIG. And controls the signal through the phase converter 217 and the attenuator 216 and amplifies the amplified signal through the second amplifier 218. Thereafter, the PIMD interference reduction coupler 230 is used to reduce the PIMD interference. The phase of the upper right cancellation source 2f2 - f1 is inverted by the phase shifter 217 as indicated by C16. C17 shows the size of the right interferer 2f2 - f1 before PIMD interference reduction and C18 shows the size of the right interferer 2f2 - f1 after PIMD interference reduction. When comparing C17 and C18, it can be confirmed that the right interference source in the frequency band of the reception signal of the first transceiver 110 is greatly reduced by the PIMD interference reduction apparatus.

10 shows a process of canceling each of the left interferer and the right interferer using a left cancellation source and a right cancellation source. The PIMD interference cancellation device includes an cancellation source detection unit and a PIMD The interference reduction coupler may be separately arranged to remove each of the left interference source and the right interference source. Reference numerals 211a to 218a denote an erasure source detection unit for canceling the left interference source, and reference numerals 211b to 218b denote an erasure source detection unit for canceling the right interference source. Couplers for reducing PIMD interference are also provided at 230a and 230b, respectively. The description of the portion canceling the left interference source using the left cancellation source is substantially the same as that described with reference to Fig. 9, and the description of the portion for canceling the right interference source using the right cancellation source is the same as that described with reference to Fig. 9 And thus redundant description will be omitted.

The PIMD interference cancellation apparatus may further include a plurality of transceivers, wherein the transceivers include a first transceiver and a second transceiver, wherein the first transceiver and the second transceiver use different frequency bands, 1 transmission / reception center frequency f1 and a reception center frequency f3, and a center frequency for transmitting / receiving the second transceiver is f2, so that two or more signal sources input from the transceivers are shared by the transmission / (PIMD) interference generated in a feeder router (130) that transmits two or more signal sources received through the transmission / reception antenna to the transceivers, the method comprising the steps of: (a) Which is a third-order distortion signal having a center frequency of 2f1 + f2 among the third-order distortion signals contained in the output signal of the (B) detecting a left cancellation source detected in the step (a) as a center-frequency canceling signal, which is a third-order distortion signal having a center frequency f1 + 2f2 as a center frequency, , Or down-converting the right cancellation source detected in step (a) to a signal having a center frequency of 2f2 - f1; and (c) outputting the output of the feeder router (D) detecting a left interference source having 2f1 - f2 as a center frequency or a right interference source having 2f2 - f1 as a center frequency from the signal, and (d) The phase and magnitude are controlled by comparing with the left interference source detected in the step (c), or the right and left interference sources detected in the step (b) are compared with the right interference source detected in the step (E) repeating steps (d) and The phase and magnitude control the left or the right interferer interferer comprises the step of coupling to the incoming links of the first transceiver. As described above, the two or more signal sources may be signal sources for different center frequencies, or may be signal sources for different modulation schemes. Also, the PIMD interference may occur in a communication system in which a modulation scheme is the same but a frequency interval is separated and a feeder router is shared. In this case, the PIMD interference reduction method having the steps (a) to (e) Can be applied. In this case, the PIMD interferer may include controlling and coupling the left canceller or the right canceller to the receive link of the system acting as a co-channel interferer.

In this way, in the third-order distortion signal, the magnitude and the phase are controlled by using the third-order distortion signal generated near the third frequency of the fundamental frequency of the transmission signal of the first transceiver and the second transceiver, By canceling interference sources occurring within the band of the received signal of the transceiver, passive intermodulation distortion (PIMD) can be reduced.

&Lt; PIMD  Interference Abatement >

Next, with reference to FIG. 11 to FIG. 14, description will be made on a technique for eliminating an interference source using an erasure source associated with a fifth-order distortion signal in a triple-band frequency combining. The transceivers used for the triple-band frequency combining are referred to as a first transceiver, a second transceiver, and a third transceiver, respectively, and their center frequencies are referred to as f1, f2, and f3, respectively.

FIG. 11 is a frequency spectrum for explaining PIMD in the triple-band frequency combining, and FIG. 12 is a diagram for explaining the PIMD in the triple-band frequency combining in the case of the triple- FIG. 13 is a view for explaining a PIMD interference reduction apparatus and a mobile communication system including the PIMD interference reduction apparatus in a triple-band frequency combining according to an embodiment of the present invention, and FIG. Is a view for explaining a PIMD interference reduction apparatus and a mobile communication system including the PIMD interference reduction apparatus in a triple-band frequency combining according to another embodiment of the present invention.

Similar to the above-described two-band frequency coupling, the output voltage having a non-linear characteristic can be expressed as Equation (3) below with a formula of V _o .

가 인가되는 경우, 이를 수학식 3에 대입한 후 다항식을 풀어서 전개하여, 출력 V_o 에서 간섭원 및 소거원으로서 유의미한 부분을 표시하여 보면 이하의 수학식 4와 같이 나타난다.
Triple-band frequency combining, i. E., Three-tone signal as input Vi,

The polynomial is solved and expanded to display a significant portion as the interference source and the cancellation source at the output V _o , as shown in Equation (4) below.

Where a is a coefficient consisting of the sum, product and combination of Ea, Eb and Ec, and f1, f2 and f3 are the center frequencies in the triple band frequency combination.

For example, assuming that the center frequencies of the input signal sources are 1800 MHz, 2140 MHz, and 2630 MHz (respectively referred to as f1, f2, and f3, respectively), in the frequency spectrum appearing at the output, It can be seen that the coefficient indicating the characteristic of the PIMD having the center frequency of 2f1 + 2f2 + f3 as the center frequency and the characteristic of the PIMD having the center frequency of 2f1 - 2f2 + f3 as the same.

When the center frequency f2 of the second transceiver is 2140 MHz and the bandwidth of the uplink (reception link) is 1940 MHz to 1960 MHz in consideration of the bandwidth, as shown in FIG. 11, It can be seen that the 5th order PIMD having 2f1 - 2f2 + f3 as the center frequency acts as an interference source (part (A) of FIG. 11). As described above, this causes a direct interferer of the call signal to the uplink system, which causes a signal disconnection between the terminal and the system, and a so-called call-drop occurs. Accordingly, in the present invention, as shown in Equation (4), the cancellation source having the same characteristics as the interference source in the 5th PIMD appears at the center frequency 2f1 + 2f2 + f3 of the 5th PIMD, A feedforward system is adopted so that the operating characteristics of the system are generally close to linear characteristics.

11B is an uplink (reception link) frequency band of the first transceiver (center frequency f1 = 1820 MHz), and C is an uplink (reception link) frequency of the third transceiver (center frequency f3 = 2630 MHz) Band.

Fig. 12 is a graph showing the relationship between an erasure source having a center frequency fpim (2f1 + 2f2 + f3) of a center frequency fifth order PIMD and interference having center frequency f4 (2f1 - 2f2 + f3) serving as an interference source in a reception link of a second transceiver As shown in the figure, in the present invention, the cancellation source fpim appearing near the fifth frequency of the fundamental frequency in the fifth PIMD is directly detected, so that f4, which acts as an interference source in the reception link of the second transceiver, The interference source having the frequency is erased. As described above, since the canceller having the fpim as the center frequency in the fifth PIMD has the same characteristics as the interference source having the center frequency f4, it can be effectively removed without generating artificially generated cancellation sources . As mentioned above, since the amount of voice or data traffic is adaptively used in the channel environment according to the radio environment (channel environment), the PIMD component acting as a co-channel interference source is a complex noise And the signal received on the frequency axis overlaps with a certain portion of the frequency band and acts as a cochannel interference source. Since the noise signals are very difficult to separate from each other, artificially generated harmonics signals are generated, In the conventional method of removing the PIMD by phase control, it is difficult to efficiently remove the PIMD since the PIMD acting as a co-channel interference source is completely different from the generation mechanism thereof.

Referring to FIG. 13, a mobile communication system in a triple-band frequency combining according to an embodiment of the present invention includes a plurality of transceivers (not shown), a plurality of signal sources shared by the transceivers, And a PIMD interference reduction device 1200. The PIMD interference reduction device 1200 includes a transmission line sharing device 1130 that transmits a plurality of signal sources, which are transmitted to a transmission / reception antenna ANT side or a plurality of signal sources received via a transmission / reception antenna ANT, The PIMD interference reduction apparatus 1200 includes a plurality of signal sources that are generated by a plurality of signal sources input from transceivers and included in an output signal of the feed line router 1130 in order to reduce PIMD interference generated in the feed line router 1130 An erase source generated around the frequency five times the fundamental frequency of the plurality of signal sources in the fifth order distortion signal is directly detected from the output signal of the power supply line sharing device 1130 and then the magnitude and phase of the erase source are controlled To the transceivers, thereby reducing the PIMD interference by canceling the fifth-order distortion signal with the interference source in the frequency band of the received signal of the transceivers.

In FIG. 13, the transceivers are not shown directly. Typically, the transceivers include a transceiver 1131 of a first transceiver, a transceiver 1133 of a second transceiver, and a transceiver 1133 of a second transceiver. The transceiver includes a first transceiver, a second transceiver, and a third transceiver. ) And a transmission / reception filter 1135 of the third transceiver. For example, the transmission / reception filter 1131 of the first transceiver is a filter that passes the band of 1710 MHz to 1830 MHz, the transmission / reception filter 1133 of the second transceiver is a filter that passes the band of 1930 MHz to 2150 MHz, ) May be a filter that passes a band of 2500 MHz to 2670 MHz. Accordingly, the first and second transceivers, the second and third transceivers use different frequency bands, the center frequency f1 for transmitting and receiving the first transceiver is 1820 MHz, and the center frequency f2 for transmitting and receiving the second transceiver is 2040 MHz, and the center frequency f3 for transmission and reception of the third transceiver may be 2630 MHz. That is, f1 < f2 < f3.

13, the PIMD interference cancellation apparatus 1200 generates a fifth order distortion signal (hereinafter referred to as a &quot; fifth order distortion signal &quot;) generated by three signal sources input from each of the three transceivers, The erase source having the center frequency of 2f1 + 2f2 + f3 in the 5th PIMD is directly detected from the output signal of the feeder router 1130 to control the size and phase of the erasure source and applied to the second transceiver side, As shown in Fig. 11 (A), an interference source in the frequency band of the reception signal of the second transceiver with the center frequency of 2f1 - 2f2 + f3 as an interferer in the frequency band of the reception signal of the second transceiver, Lt; / RTI &gt;

The PIMD interference reduction apparatus 1200 includes an elimination source detection unit (not shown) for detecting an erasure source having a center frequency of 2f1 + 2f2 + f3 in the 5th order distortion signal 5th PIMD included in the output signal of the feeder router 1130 1215, 1213, 1214, 1215, 1216, 1217, and 1218 of the erase source detectors 1211, 1212, 1213, 1214, 1212, 1213, 1214, 1215, 1216, 1217, 1218 side to determine the first reference phase and the first reference magnitude from the output signal of the feeder router 1130, The interference canceller 1221, 1224, and 1225 and the interference source in the frequency band of the received signal of the second transceiver and the cancellation source whose size and phase are controlled by the interference source information providing units 1221, 1224, and 1225, A PIMD interference reduction couple coupled to the receive link (i.e., uplink) of the second transceiver to reduce the PIMD interference by offsetting the circle It comprises 1230. The first reference phase and the first reference size are respectively the phase of the interference source in the frequency band of the received signal of the second transceiver and the size of the interference source in the frequency band of the received signal of the second transceiver.

The elimination source detection units 1211, 1212, 1213, 1214, 1215, 1216, 1217 and 1218 are provided with a first filter 1211 and a first filter 1211 for filtering the output signal of the feeder router 1130, A center frequency 2f1 + 2f2 + f3 of the erasure source in the signal amplified by the first amplifier 1212 and a center frequency 2f1 + 2f2 + f3 of the erase source in the signal amplified by the first amplifier 1212, A frequency mixer 1214 for mixing and downconverting the local oscillation frequency generated by the frequency synthesizer 1213, a second mixer 1214 for removing noise from the down- The size of the cancellation source is attenuated in accordance with the first reference size provided from the interference source information providing units 1221, 1224, and 1225 for the cancellation source that has been noise-canceled by the filter 1215 and the second filter 1215 An attenuator 1216 for providing interference information, and an interference source information providing unit 1221, 1224, A phase shifter 1217 for converting the phase of the signal output from the attenuator 1216 and a second amplifier 1218 for amplifying the signal output from the phase shifter 1217 according to the first reference phase . The first filter 1211 may be located in the feeder router 1130 as shown in FIG. 13, but may further include a feeder router 2230 (FIG. 14) and an antenna (not shown) The first filter 2211 (FIG. 14) may be located outside the feed line router 2230 (FIG. 14) when the third detecting coupler 2235 (FIG.

The interference source information providing units 1221, 1224 and 1225 are coupled between the first amplifier 1212 and the frequency mixer 1214 to perform a first detection for detecting a signal amplified by the first amplifier 1212 (I.e., 2f1 - 2f1) in the frequency band of the received signal of the second transceiver in the signal amplified by the first amplifier 1212 detected by the first coupler 1221 and the first detection coupler 1221, A first reference detector 1224 for detecting the first reference phase and the first reference magnitude in the first reference phase and the second reference phase in an interference source having a center frequency of 2f2 + f3, And a controller 1225 that provides the first reference magnitude to a phase shifter 1217 and an attenuator 1216, respectively.

13, the interference source information providing unit is provided with a PIMD interference reduction coupler 1230 at the rear end of the point where the PIMD interference reduction coupler 1230 is coupled at the reception link of the second transceiver, as shown in FIG. 13 And a second detection coupler 1226 for detecting a reception signal of the second transceiver in a state where the PIMD interference is reduced. In addition, the interference source information providing unit may include a third filter 1227 for filtering the signal detected by the second detecting coupler 1226, a second filter 1227 for filtering the signal detected by the second detecting coupler 1226, And a second level detector 1229 for detecting a second reference phase and a second reference magnitude corresponding to each of the first reference magnitudes and providing the second reference phase and the second reference magnitude to the controller 1225 side.

Referring to FIG. 14, a mobile communication system in a triple-band frequency combining according to another embodiment of the present invention includes a plurality of transceivers (not shown), a plurality of signal sources shared by the transceivers, And a PIMD interference reduction device 2200. The PIMD interference cancellation device 2200 includes a transmission line sharing device 2230 that transmits a plurality of signal sources to the transceiver ANT side or a plurality of signal sources received through the transmission / reception antenna ANT to the transceivers side. The PIMD interference reduction apparatus 2200 includes a plurality of PIMD interference reduction apparatuses 2200 and 2234. The PIMD interference reduction apparatus 2200 includes a PIMD interference reduction apparatus 2200. The PIMD interference reduction apparatus 2200 includes a plurality of signal sources, An erase source generated around the frequency five times the fundamental frequency of the plurality of signal sources in the fifth order distortion signal is directly detected from the output signal of the power feeder 2230 and then the magnitude and phase of the erase source are controlled To the transceivers, thereby reducing the PIMD interference by canceling the fifth-order distortion signal with the interference source in the frequency band of the received signal of the transceivers.

Comparing the embodiment shown in FIG. 14 with the embodiment shown in FIG. 13, it can be seen that the first filter 2211 in the PIMD interference reduction device 2200 is not located in the feed line router 2230, and the feed line router 2230 In that the output signal of the first detecting coupler 2335 is detected between the feeder shaper 2230 and the antenna ANT, that is, in the middle of the feeder line 2137 using the third detecting coupler 2335, Substantially the same.

110: first transceiver
120: second transceiver
130, 1130: feeder router
210:
220: Interference source information providing unit
230: PIMD interference reduction coupler
1200: PIMD interference reduction device

Claims (10)

A mobile communication system,
A plurality of transceivers for transmitting and receiving using different frequency bands;
A feeder sharer shared by the transceivers to transmit a plurality of signal sources input from the transceivers to the transceiver antenna or to transmit a plurality of signal sources received through the transceiver antenna to the transceivers; And
(N) -n (n) included in the output signal after being generated by a plurality of signal sources input from the transceivers and passing through the feeder router to reduce PIMD (Passive Intermodulation Distortion) interference generated in the feeder router, After detecting an erasure source occurring around the frequency n times the fundamental frequency of the plurality of signal sources among the odd-numbered or more than three signal sources directly from the output signal after passing through the feeder router, And a PIMD interference cancellation device for reducing PIMD interference by applying a control signal to the reception line of the transceivers after controlling the size and phase of the n-th order distortion signal, thereby canceling the interference with the interference source in the frequency band of the reception signal of the transceivers. And the mobile communication system. The method according to claim 1,
Wherein the first and second transceivers, the first transceiver, the second transceiver, and the third transceiver use different frequency bands, and the center frequency for transmitting and receiving the first transceiver is f1 Wherein the center frequency for transmission and reception of the second transceiver is f2, the center frequency for transmission and reception of the third transceiver is f3, and f1 <f2 <f3,
The PIMD interference reduction apparatus includes an erasure source generated by three signal sources input from the transceivers and having a center frequency of 2f1 + 2f2 + f3 among fifth-order distortion signals included in an output signal of the feeder router, And an interference source in a frequency band of a received signal of the second transceiver, and a receiving unit for receiving an interference signal from the second transceiver, And the interference source in the frequency band of the signal is 2f1 - 2f2 + f3 as a center frequency. The PIMD interference reduction apparatus of claim 2,
An erasure-source detecting unit for detecting the erase source,
Wherein the first reference phase and the first reference phase from the output signal of the feed line shaper are controlled so that the magnitude and phase of the received signal of the second transceiver And the first reference size is a size of an interference source in a frequency band of a received signal of the second transceiver and provides the interference signal to the cancellation detection unit side;
Receiver coupled to the receive link of the second transceiver so as to reduce PIMD interference by canceling the interference source in the frequency band of the received signal of the received signal of the second transceiver, , And a PIMD interference reduction coupler. 4. The image pickup apparatus according to claim 3,
A first filter for filtering the output signal of the feeder router,
A first amplifier for amplifying an output signal of the feed line router filtered by the first filter,
A frequency mixer for mixing and down converting the center frequency of the cancellation source and the local oscillation frequency generated by the voltage controlled oscillator in a signal amplified by the first amplifier,
A second filter for removing noise from an erasure source down-converted by the frequency mixer,
An attenuator for attenuating a size of an erasure source whose noise has been removed by the second filter in accordance with the first reference size provided from the interference source information providing unit;
A phase converter for converting a phase of a signal output from the attenuator according to the first reference phase provided from the interference source information providing unit;
And a second amplifier for amplifying a signal output from the phase shifter. The mobile communication system according to claim 4, wherein the first filter is located in the feed line router. The apparatus of claim 4,
A first detecting coupler coupled between the first amplifier and the frequency mixer for detecting a signal amplified by the first amplifier;
The first reference phase and the first reference magnitude in the interference source in the frequency band of the received signal of the second transceiver are detected in the signal amplified by the first amplifier detected by the first detecting coupler A first level detector for detecting a first level,
And provides the first reference phase and the first reference amplitude detected by the first level detector to the phase shifter and the attenuator, respectively. 7. The apparatus of claim 6,
And for detecting a reception signal of the second transceiver in a state where PIMD interference is reduced by the PIMD interference reducing coupler at a rear end of a point where the PIMD interference reducing coupler is coupled at the reception link of the second transceiver , And a second detecting coupler. The apparatus of claim 7,
A third filter for filtering the signal detected by the second detecting coupler,
And a second level detector for detecting and providing to the controller side a second reference phase and a second reference amplitude corresponding to the first reference phase and the first reference amplitude in the signal filtered by the third filter, And the mobile communication system. 5. The wireless communication system according to claim 4, wherein the cancellation detecting section includes a third detecting coupler positioned between the feed line router and the transmitting / receiving antenna for detecting an output signal of the feeder router and transmitting the signal to the first filter The mobile communication system comprising: A plurality of transceivers for transmitting and receiving using different frequency bands, wherein the transceivers comprise: a first transceiver having a center frequency f1 for transmitting and receiving; a second transceiver having a center frequency f2 for transmitting and receiving; and a third transceiver having a center frequency f3 for transmitting and receiving, A plurality of signal sources shared by f1 < f2 < f3, which are input from the transceivers, to a transmitting / receiving antenna side, and / or a plurality of signal sources received through the transmitting / In order to reduce PIMD (Interference Distortion) interference generated in the router, the nth-n generated by the plurality of signal sources input from the transceivers and included in the output signal after passing through the feeder router is 3 Of the fundamental frequency of the plurality of signal sources And a controller for controlling the magnitude and phase of the cancellation source and applying the cancellation source to the reception lines of the transceivers, A PIMD interference cancellation apparatus for reducing PIMD interference by canceling a distortion signal with an interference source in a frequency band of a received signal of the transceivers,
An erasure-source detecting unit for detecting the erase source,
Wherein the first reference phase and the first reference phase from the output signal of the feed line shaper are controlled so that the magnitude and phase of the received signal of the second transceiver And the first reference size is a size of an interference source in a frequency band of a received signal of the second transceiver and provides the interference signal to the cancellation detection unit side;
Receiver coupled to the receive link of the second transceiver so as to reduce PIMD interference by canceling the interference source in the frequency band of the received signal of the received signal of the second transceiver, And a PIMD interference reduction coupler.

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