KR20070040259A - Low noise amplifier circuit for dual band - Google Patents

Abstract

An object of the present invention is to provide a dual-band LNA circuit that can achieve miniaturization and manufacturing cost by implementing the LNA circuit in a dual band receiver such as a DMB band or a GPS band to use one dual antenna.

The dual band LNA circuit of the present invention is a LNA circuit applied to a dual band receiver employing a dual band antenna (ANT), wherein the signal from the dual band antenna (ANT) is converted into a first band signal and a second band signal. Signal separation unit 200 to separate; A first band pass filter 410 for passing the first band signal from the signal separation unit 200 to a preset first band; And a second band pass filter 420 for passing the second band signal from the signal separation unit 200 to a preset second band.

 DMB band, GPS band, dual band receiver, dual band LNA circuit

Description

LOW NOISE AMPLIFIER CIRCUIT FOR DUAL BAND}

1 is a conventional dual band LNA circuit diagram.

2 is a dual band LNA circuit diagram according to a first embodiment of the present invention;

3 is a diagram illustrating a first implementation of the signal separation unit of FIG. 2.

4 illustrates a second implementation of the signal separator of FIG. 2.

5 is a circuit diagram of an output side attenuation resonator of the signal separation unit of FIG.

FIG. 6 is an output side open stub circuit diagram of the signal separation unit of FIG. 2. FIG. Open stub.

7 is an exemplary diagram of a signal combiner of a dual band LNA circuit according to the present invention;

8 is a diagram illustrating a first implementation of the signal combiner of FIG. 7.

FIG. 9 illustrates a second implementation of the signal combiner of FIG. 7. FIG.

10 is an exemplary diagram of the ultra-low noise amplifier of FIG.

11 is a dual band LNA circuit diagram according to a second embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

ANT: dual band antenna 100: ultra-low noise amplifier

200: signal separation unit 210: first band selector

220: second band selector 310: first low noise amplifier

320: second low noise amplifier 410: first band pass filter

420: second band pass filter 510: third low noise amplifier

520: fourth low noise amplifier 600: signal coupling portion

700 output low noise amplifier

The present invention relates to a dual band LNA circuit applied to a dual band receiver such as a DMB band or a GPS band, and in particular, by implementing an LNA circuit so that one dual antenna can be used, the dual band LNA can achieve miniaturization and manufacturing cost reduction. It is about a circuit.

In general, GPS navigation may be implemented by installing a GPS antenna to perform navigation in a DMB receiver. In this case, a DMB antenna and a GPS antenna should be provided, respectively, and amplify the DMB signal and the GPS signal, respectively. A dual band LNA circuit is required, and this conventional LNA circuit will be described with reference to FIG.

1 is a conventional dual band LNA circuit diagram.

The conventional dual band LNA circuit shown in FIG. 1 includes a first amplifier 11 for amplifying the DMB signal from the DMB antenna ANT1 and a DMB band in which the DMB signal from the first amplifier 11 is preset. A first band pass filter 12 to be passed through, a second amplifier 13 for amplifying the DMB signal from the first band pass filter 12, and a GPS signal from the GPS antenna ANT2 The third amplifier 21, the second band pass filter 22 for passing the GPS signal from the third amplifier 21 to a predetermined GPS band, and the GPS from the second band pass filter 22 And a fourth amplifier 23 for amplifying the signal.

As described above, the conventional dual band LNA circuit of FIG. 1 uses two different GPS antennas and a DMB antenna, and in the case of using the two antennas as described above, the dual band receiver uses the two antennas. A dual band LNA circuit suitable for this is used.

Such a conventional dual band LNA circuit is connected to a GPS antenna (Microstrip Patch antenna) and an antenna for DMB (Digital Multimedia Broadcasting) or DAB (Digital Audio Broadcasting) separately to a receiver that performs GPS navigation and DMB / DAB reception functions. Apply.

However, in the conventional dual band LNA circuit, when applied to a terminal in which GPS and DMB or DAB functions are combined, a GPS antenna and a DMB antenna (or DAB antenna) must be separately provided and connected to each other. There is a problem that it is expensive and the size is not suitable for mounting or moving the vehicle. That is, in the dual band receiver, when implementing the characteristics of the DMB, DAB, GPS antenna, the antenna must be used separately, there is a problem that the SET size is large, the manufacturing cost is expensive, and the characteristics deterioration due to ANT interference.

In addition, even when using a dual-band (DUAL BAND) antenna, there is a problem that the characteristics deterioration due to the mutual interference effect due to matching problems in the LNA circuit.

Accordingly, it is preferable to use a dual band antenna instead of using two antennas. However, when using a dual band antenna, mutually amplifying to a DMB signal and a GPS signal or a DAB signal and a GPS signal simultaneously There is a need for an LNA circuit that improves the ISOLATION characteristics of the LNA circuit to prevent interference.

The present invention has been proposed to solve the above problems, the object of which is applied to a dual-band receiver such as DMB band or GPS band, by implementing an LNA circuit to use a single dual antenna, to achieve miniaturization and manufacturing cost reduction It is to provide a dual band LNA circuit that can be.

In order to achieve the above object of the present invention, the dual-band LNA circuit of the present invention is a LNA circuit applied to a dual-band receiver employing a dual-band antenna, the signal from the dual-band antenna and the first band signal A signal separation unit separating the second band signal; A first band pass filter for passing the first band signal from the signal separation unit to a first band set in advance; And a second band pass filter for passing the second band signal from the signal separation unit to a preset second band.

The dual band LNA circuit may further include an ultra-low noise amplifier for amplifying a signal from the dual band antenna with a predetermined gain and outputting the signal to the signal separation unit.

The dual band LNA circuit may further include a first low noise amplifier for amplifying the first band signal from the signal separation unit with a predetermined gain and outputting the first band signal to the first band pass filter.

The dual band LNA circuit may further include a second low noise amplifier amplifying the second band signal from the signal separation unit with a predetermined gain and outputting the second band signal to the second band pass filter.

The dual band LNA circuit may further include a third low noise amplifier which amplifies the first band signal passed in the first band of the first band pass filter to a predetermined gain.

The dual band LNA circuit may further include a fourth low noise amplifier which amplifies the second band signal passed in the second band of the second band pass filter to a predetermined gain.

The signal separator may include: a first band selector for selecting a first band signal from the dual band antenna and outputting the first band signal to the first band pass filter; And a second band selector for selecting a second band signal from the dual band antenna and outputting the second band signal to the second band pass filter.

The first band selector includes a high pass filter, a low pass filter, a parallel resonator, a band pass filter, a band stop filter, a meander line, and an element for impedance matching to select a first band signal from the dual band antenna. Characterized in that any one selected from the group consisting of.

The second band selector includes a high pass filter, a low pass filter, a parallel resonator, a band pass filter, a band stop filter, a meander line, and an impedance matching element for selecting a second band signal from the dual band antenna. Characterized in that any one selected from the group consisting of.

The first band selector and the second band selector may include a diplexer or a duplexer including a filter for selecting the first band signal and a filter for selecting the second band signal. **

The dual band LNA circuit may further include an attenuation resonator connected to an output terminal of the first band selector of the signal separation unit to attenuate the second band signal from the signal separation unit.

The dual band LNA circuit may further include an attenuation resonator connected to an output terminal of the second band selector of the signal separation unit to attenuate the first band signal from the signal separation unit.

The dual band LNA circuit is connected to an output terminal of the first band selector of the signal separation unit, and (λ) / 4 open stub corresponding to 1/4 of the wavelength λ of the second band signal from the signal separation unit. It characterized in that it further comprises.

The dual band LNA circuit is connected to an output terminal of the second band selector of the signal separator to further add a lambda 1/4 open stub corresponding to 1/4 of the wavelength lambda 1 of the first band signal from the signal separator. It is characterized by including.

The dual band LNA circuit includes a first band selector for selecting a first band signal from the first band pass filter and a second band selector for selecting a second band signal from the first band pass filter. The signal combiner may further include a signal combiner configured to combine a signal from the first band selector and a signal from the second band selector into one signal line.

The first band selector is for high pass filter, low pass filter, parallel resonator, band pass filter, band stop filter, meander line and impedance matching to select the first band signal from the first band pass filter. Characterized in that any one selected from the group consisting of devices.

The second band selector is for high pass filter, low pass filter, parallel resonator, band pass filter, band stop filter, meander line and impedance matching to select the second band signal from the first band pass filter. Characterized in that any one selected from the group consisting of devices.

The first band selector and the second band selector may include one duplexer including a filter for selecting the first band signal and a filter for selecting the second band signal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings referred to in the present invention, components having substantially the same configuration and function will use the same reference numerals.

2 is a dual band LNA circuit diagram according to a first embodiment of the present invention.

Referring to FIG. 2, the dual band LNA circuit according to the present invention is an LNA circuit applied to a dual band receiver employing a dual band antenna (ANT), which is configured to transmit a signal from the dual band antenna (ANT) to a first band. A signal separation unit 200 for separating the signal and the second band signal, a first band pass filter 410 for passing the first band signal from the signal separation unit 200 to a preset first band, And a second band pass filter 420 for passing the second band signal from the signal separation unit 200 to a preset second band.

The dual band LNA circuit, in order to amplify a signal having a size required at a later stage, ultra-low noise for amplifying a signal from the dual band antenna ANT with a predetermined gain and outputting the signal to the signal separation unit 200. The amplifier 100 may further include.

In addition, the dual band LNA circuit amplifies the first band signal from the signal separation unit 200 with a preset gain to compensate for signal loss in the signal separation unit 200. A first low noise amplifier 310 outputted to the pass filter 410 and a second band signal from the signal separation unit 200 are amplified to a predetermined gain and outputted to the second band pass filter 420 It may further include a second low noise amplifier 320.

In addition, the dual band LNA circuit amplifies the first band signal passed through the first band of the first band pass filter 410 with a predetermined gain in order to amplify the signal having a magnitude required at a later stage. The device may further include a third low noise amplifier 510 and a fourth low noise amplifier 520 that amplifies the second band signal passed in the second band of the second band pass filter 420 with a preset gain. .

The signal separator 200 of the present invention performs a function of separating the first band signal such as the DMB band and the second band signal such as the GPS band without affecting each other, which includes a high pass filter, a low pass filter, It may be performed in various ways such as a parallel resonator, a bandpass filter, a bandstop filter, a meander line, and an impedance matching element. Here, for example, the first band may be any one of a DMB band using a 2.6 GHz band, a GPS band using a 1.5 GHz band, a 900 band or a GPS band using a 1.9 GHz band, and the second band. The band may be a band different from the first band of the band.

As such, the signal separation unit may be implemented using a circuit or an element capable of separating different bands, which will be described with reference to FIGS. 3 and 4.

3 is a diagram illustrating a first implementation of the signal separation unit of FIG. 2.

Referring to FIG. 3, the signal separation unit 200 selects a first band signal from the dual band antenna ANT and outputs the first band selector 210 to the first band pass filter 410. And a second band selector 220 for selecting a second band signal from the dual band antenna ANT and outputting the second band signal to the second band pass filter 420.

4 is a diagram illustrating a second implementation of the signal separation unit of FIG. 2.

Referring to FIG. 4, the first band selector 210 may be implemented as a 90 degree phase shifter having a meander line structure to select a first band signal from the dual band antenna ANT.

In addition, the second band selector 220 may be implemented as a 90 degree phase shifter having a meander line structure in order to select a second band signal from the dual band antenna ANT.

In this case, the 90-degree phase shifter has a maximum impedance at a point λ / 4 with respect to the corresponding frequency, and the line is shown to be broken at the corresponding frequency, thereby blocking the frequency.

In addition, the first band selector 210 and the second band selector 220 may include one diplexer or one including a filter for selecting the first band signal and a filter for selecting the second band signal. It may be made of a duplexer.

5 is a circuit diagram of an output side attenuation resonator of the signal separation unit of FIG. 2.

Referring to FIG. 5, the dual band LNA circuit is connected to an output terminal of the first band selector of the signal separator, and an attenuation resonator 610 for attenuating a second band signal from the signal separator 200. And an attenuation resonator 620 connected to an output terminal of the second band selector of the signal separation unit to attenuate the first band signal from the signal separation unit 200.

Here, the attenuation resonator 610 may be implemented as a series resonator connected between the output terminal of the signal separation unit 200 and the ground. In this case, the series resonator is tuned to the second band to turn the second band signal to ground. Bypass may attenuate the second band signal. The attenuation resonator 620 may be implemented as a series resonator connected between the output terminal of the signal separation unit 200 and a ground. In this case, the series resonator is tuned to a first band to bypass the first band signal to ground. The first band signal can be attenuated.

In addition, the attenuation resonator 610 may be implemented as a parallel resonator on the output line of the signal separation unit 200, in which the parallel resonator is tuned to the second band to block the second band signal to the second The band signal can be attenuated. The attenuation resonator 620 may be implemented as a parallel resonator connected on an output end line of the signal separation unit 200. In this case, the parallel resonator may be tuned to a first band to block the first band signal so that the first The band signal can be attenuated.

FIG. 6 is a diagram illustrating an output side open stub of the signal separation unit of FIG. 2.

Referring to FIG. 6, the dual band LNA circuit is connected to an output terminal of the first band selector of the signal separation unit and is connected to 1/4 of the wavelength? Of the second band signal from the signal separation unit 200. A corresponding (λ) / 4 open stub 710 and an output terminal of the second band selector of the signal separation unit, and 1/4 of the wavelength λ1 of the first band signal from the signal separation unit 200. It may further include a λ 1/4 open stub 720 corresponding to. Here, the λ / 4 open stub acts like a parallel resonant circuit with respect to the frequency, thereby attenuating the first band signal or the second band signal, respectively.

FIG. 7 is an exemplary diagram of a signal combiner of a dual band LNA circuit according to the present invention, FIG. 8 is an exemplary diagram illustrating a first implementation of the signal combiner of FIG. 7, and FIG. 9 is an exemplary diagram of a second implementation of the signal combiner of FIG. 7. .

7 to 9, the dual band low noise amplifier circuit includes a first band selector 610 for selecting a first band signal from the first band pass filter 410 of FIG. The signal combiner 600 further includes a second band selector 620 for selecting the second band signal from the two band pass filter 420.

Here, the signal combiner 600 is configured to combine the signal from the first band selector 610 and the signal from the second band selector 620 into one signal line.

The first band selector 610 may include a high pass filter, a low pass filter, a parallel resonator, a band pass filter, a band stop filter, and a US to select a first band signal from the first band pass filter 410. The second band selector 620 may be configured to select a second band signal from the second band pass filter 420. , A high pass filter, a low pass filter, a parallel resonator, a band pass filter, a band stop filter, a meander line, and an impedance matching element.

The first band selector 610 and the second band selector 620 may include one duplexer including a filter for selecting the first band signal and a filter for selecting the second band signal.

10 is an exemplary diagram of the ultra-low noise amplifier of FIG. 2.

Referring to FIG. 10, the ultra-low noise amplifier 100 may include one LNA, and may include first and second LNAs 110 and 120 to increase signal amplification.

11 is a dual band LNA circuit diagram according to a second embodiment of the present invention.

Referring to FIG. 11, a dual band LNA circuit according to a second embodiment of the present invention, in an LNA circuit applied to a dual band receiver employing a dual band antenna, pre-signals a signal from the dual band antenna ANT. An ultra-short low noise amplifier 100 for amplifying with a gain set in the following, a signal separation unit 200 for separating a signal from the ultra-low noise amplifier 100 into a first band signal and a second band signal, and the signal separation unit ( And a signal combiner 600 which combines the two signals separated by 200.

The dual band LNA circuit may further include an output low noise amplifier 700 which amplifies the signal from the signal combiner 600 with a predetermined gain.

In addition, a band pass filter of a frequency band for each of the first band and the second band may be added between the signal separator 200 and the signal merger 600. In this case, the signal separator 200 may be added. It can improve the isolation between the two signals separated by.

Hereinafter, the operation and effects of the present invention will be described in detail with reference to the accompanying drawings.

The dual band LNA circuit of the present invention is applied to a dual band receiver employing a dual band antenna (ANT) to amplify the dual band signal with low noise, which will be described with reference to FIGS. 2 to 6.

First, referring to FIG. 2, the ultra-low noise amplifier 100 of the dual band LNA circuit of the present invention amplifies a signal from the dual band antenna ANT with a preset gain and outputs the signal to the signal separation unit 200. do.

The signal separator 200 separates a signal from the dual band antenna ANT into a first band signal and a second band signal and outputs the first and second low noise amplifiers 310 and 320. .

The first low noise amplifier 310 amplifies the first band signal from the signal separation unit 200 with a preset gain and outputs the first band signal to the first band pass filter 410, and the second low noise amplifier 320. ) Amplifies the second band signal from the signal separation unit 200 to a preset gain and outputs the second band signal to the second band pass filter 420.

Here, the front and rear positions of the first low noise amplifier 310 and the first band pass filter 410 may be changed from each other, and the second low noise amplifier 320 and the second band pass filter 420 may be moved forward and backward. The positions can be changed from one another.

Next, the first band pass filter 410 passes the first band signal from the signal separation unit 200 to a first predetermined band, and outputs the first band signal to the third low noise amplifier 510. The band pass filter 420 passes the second band signal from the signal separation unit 200 to a second predetermined band and outputs the second band signal to the fourth low noise amplifier 520.

Thereafter, the third low noise amplifier 510 amplifies the first band signal passed in the first band of the first band pass filter 410 with a preset gain, and the fourth low noise amplifier 520 The second band signal passed through the second band of the second band pass filter 420 is amplified with a preset gain and output.

Here, the front and rear positions of the first band pass filter 410 and the third low noise amplifier 510 may be changed from each other, and the second band pass filter 420 and the fourth low noise amplifier 510 may be moved forward and backward. The positions can be changed from one another.

Referring to FIG. 3, when the signal separation unit 200 includes a first band selector 210 and a second band selector 220, the first band selector 210 may include the dual band antenna ANT. Selects a first band signal from and outputs the signal to the first low noise amplifier 310.

The second band selector 220 selects a second band signal from the dual band antenna ANT and outputs the second band signal to the second low noise amplifier 320.

The first band selector 210 may include a high pass filter, a low pass filter, a parallel resonator, a band pass filter, a band stop filter, to select a first band signal from the dual band antenna ANT. It may be implemented by any one selected from the group consisting of meander line and impedance matching element.

Similarly, the second band selector 220 may include a high pass filter, a low pass filter, a parallel resonator, a band pass filter, and a band stop to select a second band signal from the dual band antenna ANT. One of the filter, the meander line, and the impedance matching device may be implemented.

As an example, a case in which the first and second band selectors 210 and 220 are implemented as a 90 degree phase shifter will be described with reference to FIG. 4.

Referring to FIG. 4, when the first and second band selectors 210 and 220 are implemented with a 90 degree phase shifter having a length of λ / 4, the impedance is maximized at the λ / 4 point for each band. The line appears to be broken at that frequency, which can cut off that frequency.

Referring to FIG. 5, when the dual band LNA circuit includes an attenuation resonator connected to an output terminal of the first band selector of the signal separation unit, the attenuation resonator may include a second signal from the signal separation unit 200. Attenuate the band signal.

In addition, when the dual band LNA circuit includes an attenuation resonator connected to an output terminal of the second band selector of the signal separation unit, the attenuation resonator attenuates the first band signal from the signal separation unit 200. Let's do it.

Referring to FIG. 6, when the dual band LNA circuit includes a (λ) / 4 open stub connected to an output terminal of the first band selector of the signal separation unit, the (λ) / 4 open stub is the signal separation. Corresponding to one quarter of the wavelength? Of the second band signal from the unit 200, the second band signal from the signal separation unit 200 is attenuated.

In addition, when the dual band LNA circuit includes a lambda 1/4 open stub connected to an output terminal of the second band selector of the signal separation unit, the lambda 1/4 open stub is a first signal from the signal separation unit 200. Corresponding to one quarter of the wavelength? 1 of the band signal, the first band signal from the signal separation unit 200 is attenuated.

On the other hand, when the dual band LNA circuit of the present invention includes the signal combiner 600 as shown in Figs. 7 to 9, the first band selector 610 of the signal combiner 600, The first band signal from the first band pass filter 410 is selected, and the second band selector 620 of the signal combiner 600 is configured to select the second band signal from the second band pass filter 420. Select the signal.

In addition, the signal combiner 600 combines and outputs the signal from the first band selector 610 and the signal from the second band selector 620 into one signal line.

In this case, the signal combiner 600 of the present invention selects each of the band signals to improve the isolation between the first band signal and the second band signal, and also to match impedance between the signal lines that are signal-coupled with the respective band signal lines. By combining, each band signal is combined and output through one output port without signal loss.

Referring to FIG. 10, the dual band low noise amplifier circuit is configured to increase the signal amplification degree in the structure of the ultra short low noise amplifier 100, the signal separator 200, and the signal combiner 600. , Two stages of the first and second low noise amplifiers 110 and 120. In this case, the low noise amplifier and cable used for dual band amplification and output can be reduced.

Referring to FIG. 11, in the dual band LNA circuit according to the second embodiment of the present invention, the signal through the ultra-low noise amplifier 100 is separated by the signal separation unit 200, and then the signal combiner 700 is again. Are combined and output via the output low noise amplifier 700.

In this case, a dual band signal is output through one output port, thereby saving cable.

In addition, a band pass filter of a frequency band for each of the first band and the second band may be added between the signal separator 200 and the signal merger 600. In this case, the signal separator 200 may be added. It can improve the isolation between the two signals separated by.

As described above, the signal coupling unit can save signal lines, and has advantages in installation and maintenance, compared to transmitting each band signal by using a separate signal line so that each band signal is combined and transmitted to the receiver. .

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, but is defined by the claims, and the apparatus of the present invention may be substituted, modified, and modified in various ways without departing from the spirit of the present invention. It is apparent to those skilled in the art that modifications are possible.

According to the present invention as described above, in a dual band LNA circuit applied to a dual band receiver such as a DMB band or a GPS band, the LNA circuit is implemented so that one dual antenna can be used to process some circuits for dual band signals. Since it can be shared, miniaturization and manufacturing cost can be achieved.

Claims (21)

In the LNA circuit applied to a dual band receiver employing a dual band antenna, A signal separator for separating the signal from the dual band antenna into a first band signal and a second band signal; A first band pass filter for passing the first band signal from the signal separation unit to a first band set in advance; And A second band pass filter configured to pass a second band signal from the signal separation unit to a second predetermined band; Dual band LNA circuit comprising a. The method of claim 1, wherein the dual band LNA circuit, And a very short low noise amplifier for amplifying the signal from the dual band antenna with a predetermined gain and outputting the signal to the signal separation unit. The method of claim 1, wherein the dual band LNA circuit, And a first low noise amplifier for amplifying the first band signal from the signal separation unit to a predetermined gain and outputting the first band signal to the first band pass filter. The method of claim 1, wherein the dual band LNA circuit, And a second low noise amplifier for amplifying the second band signal from the signal separation unit with a preset gain and outputting the second band signal to the second band pass filter. The method of claim 1, wherein the dual band LNA circuit, And a third low noise amplifier for amplifying the first band signal passed into the first band of the first band pass filter with a predetermined gain. The method of claim 1, wherein the dual band LNA circuit, And a fourth low noise amplifier for amplifying the second band signal passed into the second band of the second band pass filter with a predetermined gain. The method of claim 1, wherein the signal separation unit, A first band selector for selecting a first band signal from the dual band antenna and outputting the first band signal to the first band pass filter; And A second band selector for selecting a second band signal from the dual band antenna and outputting the second band signal to the second band pass filter; Dual band LNA circuit comprising a. The method of claim 7, wherein the first band selector and the second band selector In order to select the first band signal from the dual band antenna, one selected from the group consisting of a high pass filter, a low pass filter, a parallel resonator, a band pass filter, a band stop filter, a meander line and an impedance matching element Dual band LNA circuit, characterized in that. The method of claim 7, wherein the first band selector and the second band selector And a duplexer including a filter for selecting the first band signal and a filter for selecting the second band signal. The method of claim 1, wherein the dual band LNA circuit, And an attenuation resonator connected to an output of the first band selector of the signal separation unit to attenuate the second band signal from the signal separation unit. The method of claim 1, wherein the dual band LNA circuit, And an attenuation resonator coupled to an output of the second band selector of the signal separator, for attenuating the first band signal from the signal separator. The method of claim 1, wherein the dual band LNA circuit, And a (λ) / 4 open stub connected to an output terminal of the first band selector of the signal separator and corresponding to a quarter of a wavelength λ of the second band signal from the signal separator. Dual band LNA circuit. The method of claim 1, wherein the dual band LNA circuit, And a lambda 1/4 open stub connected to an output terminal of the second band selector of the signal separator and corresponding to a quarter of the wavelength lambda 1 of the first band signal from the signal separator. Band LNA circuit. The method of claim 1, wherein the dual band LNA circuit, A signal combiner including a first band selector for selecting a first band signal from the first band pass filter, and a second band selector for selecting a second band signal from the first band pass filter, And the signal combiner is configured to combine the signal from the first band selector and the signal from the second band selector into one signal line. 15. The apparatus of claim 14, wherein the first band selector Any one selected from the group consisting of a high pass filter, a low pass filter, a parallel resonator, a band pass filter, a band stop filter, a meander line, and an impedance matching element for selecting a first band signal from the first band pass filter. Dual band LNA circuit, characterized in that implemented in one. 15. The apparatus of claim 14, wherein the second band selector Any one selected from the group consisting of a high pass filter, a low pass filter, a parallel resonator, a band pass filter, a band stop filter, a meander line, and an impedance matching element to select a second band signal from the first band pass filter. Dual band LNA circuit, characterized in that implemented in one. 15. The apparatus of claim 14, wherein the first band selector and the second band selector And a duplexer including a filter for selecting the first band signal and a filter for selecting the second band signal. The method of claim 2, wherein the ultra-low noise amplifier 100, A first LNA (110) for amplifying the signal from the dual band antenna with a preset gain; And And a second LNA (120) for amplifying the signal from the first LNA (110) with a predetermined gain. In the LNA circuit applied to a dual band receiver employing a dual band antenna, An ultra-low noise amplifier (100) for amplifying a signal from the dual band antenna (ANT) with a preset gain; A signal separation unit 200 for separating the signal from the ultra-low noise amplifier 100 into a first band signal and a second band signal; And Dual band LNA circuit including a signal combiner 600 for combining two signals separated by the signal separator 200, The method of claim 19, wherein the dual band LNA circuit, The dual band LNA circuit further comprises an output low noise amplifier (700) for amplifying the signal from the signal combiner (600) to a predetermined gain. The method of claim 19, wherein the dual band LNA circuit, Dual band LNA circuit further comprises a band pass filter of each of the frequency band for the first band and the second band between the signal separation unit (200) and the signal merger (600).

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