KR100553434B1 - Apparatus for receiving rf signal - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to an RF receiving device.

2. The technical problem to be solved by the invention

SUMMARY OF THE INVENTION An object of the present invention is to provide an RF receiving apparatus capable of fundamentally blocking noise injected through an adjacent channel by blocking a frequency band corresponding to an adjacent channel of a selected channel before performing a mixing process.

3. Summary of Solution to Invention

An RF receiving apparatus mounted in a portable terminal, comprising: an adjacent channel canceling unit for acquiring a noise canceling RF receiving signal by canceling a frequency band corresponding to an adjacent channel of the RF receiving signal under control of a phase locked voltage; And receiving the noise canceling RF received signal from the adjacent channel canceling unit, converting the noise canceling RF received signal into a signal of a processable frequency band by a plurality of internal oscillating signals, and stabilizing the plurality of internal oscillating signals. And a reception signal processor configured to generate the phase lock voltage and output the phase lock voltage to the adjacent channel eraser.

4. Important uses of the invention

The present invention is used in the receiving device of the portable terminal.

Adjacent Channel, IND, STD, RF Receive

Description

RF receiver device {APPARATUS FOR RECEIVING RF SIGNAL}             

1 is a block diagram showing a conventional super heterodyne RF receiver;

2 is a block diagram showing a conventional RF conversion apparatus of a direct conversion method;

3 is a block diagram showing an RF receiving apparatus according to an embodiment of the present invention;

4 is a circuit diagram illustrating a high frequency block and a low frequency block of FIG. 3;

5a is a graph showing characteristics of an RF bandpass filter;

5b is a graph showing characteristics of an RF received signal;

Figure 5c is a graph showing the characteristics of the high frequency block and low frequency block,

6A is a graph illustrating a relationship between a selected channel frequency and a phase locked voltage;

6B is a graph illustrating a relationship between a phase locked voltage and capacitances of a first varistor diode and a second varactor diode;

6C is a graph illustrating a relationship between capacitances of the first varactor diode and the second varactor diode and the resonant frequencies of the high frequency blocking unit and the low frequency blocking unit.

* Explanation of symbols for the main parts of the drawings

310: adjacent channel cancellation unit 320: reception signal processing unit

The present invention relates to an apparatus and method for receiving RF, and more particularly, to an apparatus and method for receiving RF used in an RF transmission / reception system such as a portable terminal.

Recently, various portable terminals and wireless communication devices have been developed in the direction of miniaturization, light weight, and low cost, and thus, miniaturization, low power consumption, and high integration of components constituting these devices are required. In response to these demands, in the case of Bluetooth or a local area network (LAN) device based on the IEEEE 802.11b / a standard, which is emerging as a standard for a short-range wireless network, all components constituting the same In addition, researches are being actively conducted to reduce the size of a terminal by using a system on chip (SOC) technology integrated in two silicon chips.

A high frequency transceiver is one of several key components of such a wireless communication device, in which the receiver must consider various characteristics such as noise characteristics, linearity, stability or yield. The receiver, in addition to the heterodyne structure, which is known to be unsuitable for highly integrated radio SOCs because it requires filters such as image rejection filters, has a low-intermediate frequency and direct-conversion structure. It can be roughly divided into various structures such as.

The heterodyne structure provides several advantages. First, IF frequencies can be filtered to more easily filter out unwanted inter-modulation (IM) inter-modulation products resulting from nonlinearities in the RF and analog circuits used to modulate and downconvert the received signal. You can choose. Second, multiple filter and variable gain amplifier (VGA) stages can be provided at the RF and IF to provide the filtering and amplification required for the received signal. For example, the RF amplifier may be designed to provide a gain range of 40 dB, and the IF amplifier may be selected to provide a gain range of 60 dB, covering the dynamic range of 100 dB collectively for the received signal. In certain applications, such as cellular telephones, it is highly desirable to simplify the receiver design in order to save on size and cost. In addition, in mobile applications such as cellular telephones, it is highly desirable to reduce power consumption to extend battery life between recharges. In these applications, direct downconversion receivers (also known as heterodyne receivers or zero-IF receivers) can provide this desirable advantage, since the receiver uses only one stage to receive the received signal. This is because it directly downconverts from RF to the baseband.

The direct conversion structure has the advantage that there is no image problem and most signal processing such as channel selection and modulation and demodulation can be performed in the programmable baseband, and accordingly, the software defined radio (SDR) will be It has been spotlighted as a technology that can be implemented in a short time. However, when used in a narrowband system where the signal bandwidth is not wide such as Bluetooth, the main signal processing such as amplification is performed in the low frequency region where the 1 / f noise of the device is very large, and thus the Signal Noise Ratio (SNR) There is a problem that the ratio becomes worse.

1 is a block diagram illustrating a conventional super heterodyne RF receiver, which will be described below.

First, the duplexer 110 serves to provide a path for transmitting an RF reception signal received through an antenna and a path for transmitting an RF transmission signal generated by a transmitter (not shown). In addition, the low noise amplifier (LNA) 115 receives an RF reception signal from the duplexer 110 and outputs the low noise amplifier to the RF band pass filter (BPF) 120. . Meanwhile, the RF band pass filter (BPF) 120 receives a signal amplified from the low noise amplifier 115 and serves to pass only a predetermined RF band. In addition, the dual phase locked loop (PLL) 125 detects a phase difference between the plurality of standard signals and the oscillation outputs of the plurality of voltage controlled oscillators 130 and 135, respectively, and thus the frequencies of the plurality of voltage controlled oscillators 130 and 135, respectively. And a phase locked voltage for stabilizing the phase to the plurality of voltage controlled oscillators 130 and 135. Meanwhile, the plurality of voltage controlled oscillators 130 and 135 receive a phase locked voltage from the dual PLL 125 and output an oscillation signal having a frequency and a phase determined according to the phase locked voltage. In addition, the first mixer 140 receives a signal of the RF band filtered from the RF bandpass filter 120, receives an oscillation signal from the voltage controlled oscillator 130, and mixes the oscillation signal with the signal of the RF band. As a result, an intermediate frequency band signal is generated, and the intermediate frequency band signal is output to the intermediate frequency (IF) band pass filter (BPF) 145. Meanwhile, the IF BPF 145 receives an intermediate frequency band signal from the first mixer 140 and passes only the intermediate frequency band. In addition, the variable amplifier 150 receives the filtered signal from the IF BPF 145, amplifies the filtered signal by a gain according to an external control (not shown), and converts the amplified signal into the second mixer 160. ) And the third mixer 165. On the other hand, the phase shifter 155 receives an oscillation signal from the voltage controlled oscillator 135, transmits the oscillation signal to the second mixer 160, and simultaneously applies an orthogonal oscillation signal obtained by applying a phase shift of 90 ° to the oscillation signal. And outputs the quadrature oscillation signal to the third mixer 165. In addition, the second mixer 160 receives the amplified signal from the variable amplifier 150, receives the oscillation signal through the phase shifter 155, and mixes the amplified signal and the oscillation signal to receive and process a frequency. It generates a signal of the band, and outputs a signal of the reception processable frequency band to the first amplifier 170. Meanwhile, the third mixer 165 receives the amplified signal from the variable amplifier 150, receives the quadrature oscillation signal through the phase shifter 155, and mixes the amplified signal and the quadrature oscillation signal to receive processing. It generates a signal of a possible frequency band, and outputs a signal of the reception processable frequency band to the second amplifier 175. In addition, the first amplifier 170 receives a mixed signal from the second mixer 160, amplifies the mixed signal to generate an I signal, and outputs the I signal to the ADC 180. The second amplifier 175 receives a mixed signal from the third mixer 165, amplifies the mixed signal to generate a Q signal, and outputs the Q signal to the ADC 180. In addition, the ADC 180 receives an I signal and a Q signal from the first amplifier 170 and the second amplifier 175, respectively, and converts the I signal and the Q signal into digital signals.

2 is a block diagram showing a conventional RF conversion apparatus of a direct conversion method, which will be described below.

First, the duplexer 210 serves to provide a path for transmitting an RF reception signal received through an antenna and a path for transmitting an RF transmission signal generated by a transmitter (not shown). In addition, the low noise amplifier (LNA) 215 serves to receive an RF received signal from the duplexer 210 and to amplify the low noise and output the RF noise to the RF band pass filter (BPF) 220. . Meanwhile, the RF band pass filter (BPF) 220 receives a signal amplified from the low noise amplifier 215 and passes only a predetermined RF band. In addition, the variable amplifier 225 receives the filtered signal from the RF BPF 220, amplifies the filtered signal by a gain according to an external control (not shown), and converts the amplified signal into the first mixer 245. ) And the second mixer 250. In addition, the phase locked loop (PLL) 230 detects a phase difference between the standard signal and the oscillation output of the voltage controlled oscillator 235, respectively, and voltage-controls a phase locked voltage that stabilizes the frequency and phase of the voltage controlled oscillator 235. It serves to apply to the oscillator 235. The voltage controlled oscillator 235 receives a phase locked voltage from the PLL 230 and outputs an oscillation signal having a frequency and a phase determined according to the phase locked voltage. In addition, the phase shifter 240 receives an oscillation signal from the voltage controlled oscillator 235, transmits the oscillation signal to the first mixer 245, and simultaneously applies an orthogonal oscillation signal obtained by applying a phase shift of 90 ° to the oscillation signal. It generates and outputs the quadrature oscillation signal to the second mixer 250. In addition, the first mixer 245 receives the amplified signal from the variable amplifier 225, receives the oscillation signal through the phase shifter 240, and mixes the amplified signal and the oscillation signal to receive and process a frequency. It generates a signal of the band, and outputs a signal of the reception processable frequency band to the first LPF (255). Meanwhile, the second mixer 250 receives the amplified signal from the variable amplifier 225, receives the quadrature oscillation signal through the phase shifter 240, and mixes the amplified signal and the quadrature oscillation signal for reception processing. It generates a signal of a possible frequency band, and outputs a signal of the reception processable frequency band to the second LPF (260). In addition, the first LPF 255 receives a mixed signal from the first mixer 245 and performs a low pass filtering on the mixed signal. Meanwhile, the second LPF 260 receives a mixed signal from the second mixer 250 and performs low pass filtering on the mixed signal. The first amplifier 265 receives the filtered signal from the first LPF 255, amplifies the filtered signal to generate an I signal, and outputs the I signal to the ADC 280. Meanwhile, the second amplifier 270 receives the filtered signal from the second LPF 260, amplifies the filtered signal to generate a Q signal, and outputs the Q signal to the ADC 280. In addition, the ADC 280 receives an I signal and a Q signal from the first amplifier 265 and the second amplifier 270, respectively, and converts the I signal and the Q signal into digital signals.

However, according to the conventional technology described above, since the RF received signal is input to the RF BPFs 120 and 220 without removing noise of an adjacent channel, Single Tone Desensitization (STD) or InterModulation Distortion (IMD) is performed through a mixing process. There is a problem that a distortion of a signal such as) may occur.

The present invention has been proposed to solve the above problems, and provides an RF receiving apparatus capable of fundamentally blocking the noise injected through the adjacent channel by blocking the frequency band corresponding to the adjacent channel of the selected channel before performing the mixing process. The purpose is.

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

The apparatus of the present invention for achieving the above object is, in the RF receiving apparatus mounted in the portable terminal, the noise canceling RF reception signal by canceling the frequency band corresponding to the adjacent channel of the RF reception signal under the control of the phase locked voltage Adjacent channel cancellation unit to obtain a; And receiving the noise canceling RF received signal from the adjacent channel canceling unit, converting the noise canceling RF received signal into a signal of a processable frequency band by a plurality of internal oscillating signals, and stabilizing the plurality of internal oscillating signals. And a reception signal processor configured to generate the phase lock voltage and output the phase lock voltage to the adjacent channel eraser.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a block diagram showing an RF receiving apparatus according to an embodiment of the present invention. The RF receiving apparatus of the present invention includes an adjacent channel canceling unit 310 and a receiving signal processing unit 320.

The adjacent channel cancellation unit 310 obtains a noise canceling RF reception signal by canceling a frequency band corresponding to an adjacent channel of the RF reception signal according to the control of the phase locked voltage input from the reception signal processing unit 320. do. Here, the adjacent channel eraser 310 will be described in detail as follows.

The duplexer 311 mounted in the adjacent channel canceling unit 310 may include a path through which an RF reception signal received through an antenna is transmitted to the high frequency cutout 312 and an RF transmission signal input from a transmitter (not shown). It serves to provide a path respectively transmitted through the antenna.

In addition, the high frequency blocker 312 mounted in the adjacent channel canceling unit 310 receives an RF reception signal from the duplexer 311 and receives a high frequency band corresponding to the adjacent channel according to the control of the phase locked voltage. Acquires the canceled signal, and outputs the obtained signal to the low noise amplifier 313.

On the other hand, the low noise amplifier 313 mounted in the adjacent channel canceling unit 310 receives a signal obtained by canceling a high frequency band from the high frequency blocking unit 312 and amplifies a low noise, and amplifies the low frequency blocking unit ( 314).

In addition, the low frequency blocking unit 314 mounted in the adjacent channel canceling unit 310 receives a signal amplified from the low noise amplifying unit 313, and receives a signal amplified from the reception signal processing unit 320. The control unit acquires a signal in which a low frequency band corresponding to an adjacent channel is canceled as the noise canceling RF reception signal, and outputs the obtained noise canceling RF reception signal to the reception signal processor 320.

Meanwhile, the reception signal processing unit 320 receives the noise canceling RF reception signal from the adjacent channel cancellation unit 310 and converts the noise canceling RF reception signal into a signal of a processable frequency band by a plurality of internal oscillation signals. And converts the phase synchronization voltage to stabilize the plurality of internal oscillation signals, and outputs the phase synchronization voltage to the adjacent channel eraser 310. Here, the reception signal processing unit 320 will be described in detail as follows.

The RF band pass filter (BPF) 321 mounted in the reception signal processing unit 320 receives the noise canceling RF reception signal from the low frequency blocking unit 314 and passes only a predetermined RF band.

In addition, the dual phase locked loop (PLL) 322 mounted in the reception signal processor 320 may adjust a phase difference between a plurality of standard signals (not shown) and the oscillation outputs of the plurality of voltage controlled oscillators 323 and 324. A phase synchronizing voltage for detecting and stabilizing frequencies and phases of the plurality of voltage controlled oscillators 323 and 324, respectively, is applied to the plurality of voltage controlled oscillators 323 and 324 and the adjacent channel eraser 310.

On the other hand, the plurality of voltage controlled oscillators 323 and 324 mounted in the reception signal processing unit 320 receive the phase synchronization voltage from the dual PLL 322 and have a frequency and phase determined according to the phase synchronization voltage. Outputs the oscillation signal.

In addition, the first mixer 325 mounted in the reception signal processor 320 receives a signal of the RF band filtered by the RF bandpass filter 321 and receives an oscillation signal from the voltage controlled oscillator 323. It receives the input, generates an intermediate frequency band signal by mixing the oscillation signal to the RF band signal, and outputs the intermediate frequency band signal to the IF (Intermediate Frequency) bandpass filter (BPF) (326).

The IF BPF 326 mounted in the reception signal processor 320 receives an intermediate frequency band signal from the first mixer 325 and passes only the intermediate frequency band.

In addition, the variable amplifier 327 mounted in the reception signal processor 320 receives the filtered signal from the IF BPF 326 and amplifies the filtered signal by a gain according to an external control (not shown). And outputs the amplified signal to the second mixer 329 and the third mixer 331.

On the other hand, the phase shifter 328 mounted in the reception signal processor 320 receives an oscillation signal from the voltage controlled oscillator 324, transmits the oscillation signal to the second mixer 329, and simultaneously transmits the oscillation signal to the oscillation signal. Generates an orthogonal oscillation signal applying a phase shift of 90 °, and outputs the orthogonal oscillation signal to the third mixer 331.

In addition, the second mixer 329 mounted in the reception signal processor 320 receives an amplified signal from the variable amplifier 327, receives an oscillation signal through the phase shifter 328, and amplifies the signal. By mixing the received signal and the oscillation signal to generate a signal of the receive processable frequency band, and serves to output the signal of the receive processable frequency band to the first amplifier 332.

On the other hand, the third mixer 331 mounted in the reception signal processor 320 receives the amplified signal from the variable amplifier 327, receives the quadrature oscillation signal through the phase shifter 328, By mixing the amplified signal and the quadrature oscillation signal, a signal of a receive processable frequency band is generated, and a signal of the receive processable frequency band is output to the second amplifier 333.

In addition, the first amplifier 332 mounted in the reception signal processor 320 receives a mixed signal from the second mixer 329, amplifies the mixed signal to generate an I signal, and generates an I signal. Output to the ADC 334.

The second amplifier 333 mounted in the reception signal processor 320 receives a mixed signal from the third mixer 331, amplifies the mixed signal to generate a Q signal, and generates a Q signal. Output to the ADC 334.

In addition, the ADC 334 mounted in the reception signal processor 320 receives an I signal and a Q signal from the first amplifier 332 and the second amplifier 333, respectively, and receives the I signal and the Q signal. It converts into digital signal.

Here, although the present invention is applied to a heterodyne receiver, the present invention is not limited thereto. It is obvious that the present invention may be applied to a direct conversion receiver.

FIG. 4 is a circuit diagram illustrating the high frequency block 312 and the low frequency block 314 of FIG. 3.

The first capacitor 405 mounted in the high frequency breaker 312 has a first terminal connected to an output terminal of the duplexer 311 to provide a predetermined capacitance.

In addition, a first inductor 410 mounted in the high frequency breaker 312 may have a first terminal connected to a second terminal of the first capacitor 405 and a second terminal grounded to provide a predetermined inductance. It plays a role.

Meanwhile, the second capacitor 415 mounted in the high frequency breaker 312 may have a first terminal connected to the first terminal of the first capacitor 405 to provide a predetermined capacitance.

In addition, the first resistor 420 mounted in the high frequency breaker 312 may have a first terminal forming an input terminal of the phase-lock voltage, and a second terminal of the second terminal of the second capacitor 415. It is connected to and serves to provide a resistance value. Here, the first resistor 420 sets a bias voltage applied to the first varactor diode 435.

Meanwhile, the second inductor 425 mounted in the high frequency breaker 312 may have a first terminal connected to a second terminal of the first capacitor 405 to provide a predetermined inductance.

In addition, the third capacitor 430 mounted in the high frequency breaker 312 may have a first terminal connected to a second terminal of the second inductor 425 to provide a predetermined capacitance. Here, the third capacitor 430 stabilizes the bias voltage applied to the first varactor diode 435.

On the other hand, the first varistor diode 435 mounted in the high frequency blocking unit 312, the cathode is connected to the second terminal of the first resistor 420 to provide a capacitance value according to the voltage applied to the cathode Play a role. In this case, the first varistor diode 435 adjusts the resonance frequency so that the band cut filter operation can be performed in a desired frequency band by providing a variable capacitance.

In addition, the third inductor 440 mounted in the high frequency blocking unit 312 has a first terminal connected to the anode of the first varactor diode 435 and a second terminal grounded to provide a predetermined inductance. It plays a role.

On the other hand, the fourth capacitor 445 mounted in the high frequency blocking unit 312, the first terminal is connected to the anode of the first varistor diode 435 serves to provide a predetermined capacitance.

In addition, the second resistor 450 mounted in the high frequency breaker 312 has a first terminal forming an input terminal of the phase locked voltage, and a second terminal of the second terminal of the fourth capacitor 445. It is connected to and serves to provide a resistance value. Here, the second resistor 450 sets the bias voltage applied to the second varactor diode 460.

Meanwhile, in the fourth inductor 455 mounted in the high frequency breaker 312, a first terminal is connected to a second terminal of the third capacitor 430 and an anode of the first varactor diode 435. It serves to provide a predetermined inductance.

In addition, the second varistor diode 460 mounted in the high frequency blocking unit 312 may have a cathode connected to a second terminal of the second resistor 450 to provide a capacitance value according to a voltage applied to the cathode. Play a role. Here, the second varactor diode 460 adjusts the resonance frequency to provide a variable capacitance so that the band cut filter operation can be performed in a desired frequency band.

Meanwhile, in the fifth capacitor 465 mounted in the high frequency breaker 312, a first terminal is connected to a second terminal of the fourth inductor 455, and a second terminal is connected to the second varistor diode ( It is connected to the anode of 460 serves to provide a predetermined capacitance. Here, the fifth capacitor 465 stabilizes the bias voltage applied to the second varactor diode 460.

In addition, the fifth inductor 470 mounted in the high frequency breaker 312 may have a first terminal connected to the anode of the second varactor diode 460 and the second terminal may be grounded to provide a predetermined inductance. It plays a role.

Meanwhile, a sixth capacitor 475 mounted in the high frequency breaker 312 may have a first terminal connected to a first terminal of the fifth inductor 470 and a second terminal input of the LNA 313. It is connected to the terminal to serve to provide a predetermined capacitance.

In the case of the low frequency blocking unit 314, a first terminal of the first capacitor 405 is connected to an output terminal of the LNA 313, and a second terminal of the sixth capacitor 475 is a reception signal processor. Except that connected to the input terminal of (320) has the same structure, but the inductance and capacitance of each element is only different in order to set the resonant frequency for low frequency cutoff, detailed description thereof will be omitted.

FIG. 5A is a graph showing the characteristics of the RF bandpass filter (BPF) 321, FIG. 5B is a graph showing the characteristics of the RF reception signal, and FIG. 5C is a diagram of the high frequency blocking unit 312 and the low frequency blocking unit 314. As a graph showing the characteristics, the operation of the RF receiving apparatus of the present invention will be described with reference to the following.

First, when the reverse bias is applied to the first and second varistor diodes 435 and 460 by the phase synchronization voltage applied from the dual PLL 322, the predetermined capacitance is determined by the reverse capacitance characteristics of the varactor diodes. It will have a value.

In this case, the first varactor diode 435 is operated as a series capacitor together with the second capacitor 415 connected in series with the first varactor diode 435, and the second varactor diode 460 is connected to the second varistor diode 460. The fourth capacitor 445 connected in series with the varactor diode 460 is operated as a series capacitor.

Through this, the resonant frequencies of the high frequency cutout 312 and the low frequency cutout 314 are determined, and even if the reception frequency band changes, the adjacent channel can be continuously blocked.

FIG. 6A is a graph showing a relationship between a selected channel frequency and a phase locked voltage, and FIG. 6B is a graph showing a relationship between a phase locked voltage and capacitance of the first varactor diode 435 and the second varactor diode 460. 6C is a graph illustrating a relationship between the capacitance of the first varactor diode 435 and the second varactor diode 460 and the resonant frequencies of the high frequency breaker 312 and the low frequency breaker 314. It can be seen that the level of the phase locked voltage is generally 0.5 to 2.5V and the phase locked voltage value and the resonance frequency are proportional to each other.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

The present invention as described above, by blocking the frequency band corresponding to the adjacent channel of the selected channel before the mixing process, there is an advantage that can fundamentally block the noise injected through the adjacent channel.

Claims (5)

In the RF receiving apparatus mounted in the portable terminal, An adjacent channel cancellation unit for acquiring a noise canceling RF received signal by canceling a frequency band corresponding to an adjacent channel of the RF received signal according to the control of the phase locked voltage; And Receiving the noise canceling RF received signal from the adjacent channel canceller, converting the noise canceling RF received signal into a signal of a processable frequency band by a plurality of internal oscillating signals, and stabilizing the plurality of internal oscillating signals A reception signal processing unit generating a phase synchronization voltage and outputting the phase synchronization voltage to the adjacent channel eraser; RF receiving device comprising a. The method of claim 1, wherein the adjacent channel cancellation unit, A duplexer for providing a path for transmitting an RF received signal received through an antenna and a path for transmitting an RF transmission signal; A high frequency blocker receiving an RF received signal from the duplexer and acquiring a signal in which a high frequency band corresponding to an adjacent channel is canceled under the control of the phase locked voltage; A low noise amplifier for low noise amplification by receiving a signal from which the high frequency band is canceled from the high frequency block; And A low frequency blocker which receives the amplified signal from the low noise amplifier and obtains a signal obtained by canceling a low frequency band corresponding to an adjacent channel according to the control of the phase locked voltage as the noise canceling RF reception signal; RF receiving apparatus comprising a. The method of claim 2, wherein the high frequency cutoff part, It is a resonant circuit in which a fundamental resonant frequency is set by an internal inductance and an internal capacitance, and the internal capacitance value is changed by the phase locked voltage to set a resonant frequency for high frequency cancellation. RF receiving device, characterized in that. The method of claim 2, wherein the low frequency blocking unit, It is a resonant circuit in which a fundamental resonant frequency is set by an internal inductance and an internal capacitance, and the internal capacitance value is changed by the phase locked voltage to set a resonant frequency for low frequency cancellation. RF receiving device, characterized in that. The method of claim 3 or 4, wherein the resonant circuit, A varactor diode that provides a capacitance value inversely proportional to the level of the phase locked voltage. RF receiving apparatus comprising a.

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