KR100412541B1 - Radio frequency receiver - Google Patents

Abstract

The present invention relates to a radio frequency receiver (RF receiver) for converting radio frequency (RF) into a baseband in phase signal and a quadrature phase signal. The present invention relates to a high frequency receiver capable of obtaining a baseband signal as well as an IF frequency from which an image signal has been removed by allowing a desired intermediate frequency to be obtained.

Description

Radio frequency receiver

The present invention relates to a high frequency receiver, and more particularly, to a high frequency receiver that can convert a radio frequency (RF) into a baseband in-phase signal and a quadrature signal, or can be used as a frequency converter.

Commonly used high frequency receivers include a superheterodyne receiver, a weaver receiver, and a wideband IF receiver.

The superheterodyne receiver is configured as shown in FIG. 2.

The signal received by the antenna 201 is input to the low noise amplifier 203 as a band signal via the band pass filter 202. The signal amplified by the low noise amplifier 203 is converted into a fixed intermediate frequency by the frequency converter 205. Since the frequency of the image band as well as the desired band is converted to the intermediate frequency during the conversion process, the signal of the image band is removed by passing through the filter 204 which is an external element.

In order to selectively receive a desired channel at a fixed intermediate frequency output from the frequency converter 205, only the desired channel is received using the filter 206 which is an external element. The output signal of the filter 206 is then amplified into a signal of constant magnitude through a variable gain amplifier (207), and is frequency-reduced from the intermediate frequency back to the baseband frequency by the frequency down mixers 208 and 211. Is converted. That is, the output frequency of the phase shifter 209 connected to the local oscillator 210 and the output frequency of the variable gain amplifier 207 become the input signals of the frequency down mixers 208 and 211 and output 90 ° to the output. In phase signal and quadrature phase signal having a phase difference of.

However, such a superheterodyne receiver has limitations in improving the integration of the circuit because it uses filters 204 and 206, which are external elements, to remove a signal of an image band and receive only a desired channel.

Therefore, a wideband IF receiver that can easily improve the integration of the circuit is used, which is configured as shown in FIG.

The signal received by the antenna 401 is input to the low noise amplifier 403 via the band pass filter 402. The signal amplified by the low noise amplifier 403 is converted to an intermediate frequency having a phase difference of 90 degrees by the frequency down mixers 404 and 416. That is, the output frequency of the phase shifter 411 which receives the frequency output from the oscillator 412 and the output frequency of the low noise amplifier 403 are converted by the frequency down mixers 404 and 416 to obtain a phase difference of 90 °. In-phase and quadrature signals are outputted.

In the broadband intermediate frequency receiver, switching means 413 and 417 are always short-circuited, and the in-phase signal output from the frequency down mixer 404 is input to the frequency converters 406 and 414, respectively, and the frequency down mixer 416 The quadrature signals outputted from the input signal are input to the frequency converters 418 and 419, respectively. The output of the frequency converter 406 connected to the oscillator 405 is the output and the adder of the frequency converter 418 connected to the oscillator 415. 407 is added to the A / D converter 410 through the variable gain amplifier 408 and the low pass filter 409, and the output of the frequency converter 419 connected to the oscillator 405 is the oscillator 415. The output of the frequency converter 414 coupled with the adder 420 is summed and then transferred to the A / D converter 423 through the variable gain amplifier 421 and the low pass filter 422.

As described above, the receiver of the in-phase and quadrature signals is converted into a baseband signal using a double quadrature conversion using four frequency converters 406, 414, 418, and 419. Because it has a canceling feature, it does not use an external filter to remove the image signal. However, such a wideband intermediate frequency receiver can obtain a baseband in-phase signal and a quadrature signal as an output, but cannot obtain an output of an intermediate frequency. That is, only the in-phase and quadrature components of the baseband can be obtained from the high frequency signal, and the intermediate frequency signal from which the image is removed cannot be obtained.

On the other hand, the receiver of the weaver structure can obtain the intermediate frequency from which the image has been removed. Then, the receiver of the weaver structure will be described with reference to FIG. 3.

The signal received by the antenna 301 is input to the low noise amplifier 303 via the band pass filter 302. The signal amplified by the low noise amplifier 303 is converted to an intermediate frequency having a phase difference of 90 degrees by the frequency down mixers 304 and 313. That is, the output frequency of the phase shifter 308 that receives the frequency output from the oscillator 309 and the output frequency of the low noise amplifier 303 are converted by the frequency down mixers 304 and 313 to obtain a phase difference of 90 °. In-phase and quadrature signals are outputted.

Thereafter, the in-phase phase signal output from the frequency down mixer 304 is input to the frequency converter 307 through the variable gain amplifier 305 and the low pass filter 306, and is output from the frequency down mixer 313. The quadrature signal is input to the frequency converter 316 through the variable gain amplifier 314 and the low pass filter 315. The output frequency of the phase shifter 310 receiving the frequency output from the oscillator 311 and the output frequencies of the low pass filters 306 and 315 are summed in the frequency down mixers 307 and 316, respectively. The signals output from the frequency down mixers 307 and 316 are summed by an adder 312.

However, the receiver of the above-described weaver structure also has the following disadvantages.

First, the receiver output of the weaver structure is a signal of intermediate frequency, not baseband. Therefore, in the application of the receiver, the output signal of the intermediate frequency must be converted back to the baseband signal.

Secondly, since the baseband frequency cannot be the output of the receiver as described above, it cannot be a single receiver and is used only as a frequency conversion stage in the receiver.

Third, image removal can be limited by mismatches in phase and quadrature.

Accordingly, an object of the present invention is to provide a high frequency receiver capable of solving the above-mentioned disadvantages by allowing the baseband in-phase and quadrature signals to be obtained, as well as to obtain an intermediate frequency from which images are removed.

The present invention for achieving the above object is a low-noise amplifier for amplifying a signal received through the antenna, a first frequency mixer for receiving a signal output from the low noise amplifier and outputs the in-phase and quadrature signals of the intermediate frequency And a variable gain amplifier for amplifying the signals output from the first frequency mixer, and a plurality of frequency converters, respectively, and receiving the signals output from the variable gain amplifiers, respectively, for the baseband in phase and quadrature signals. A second frequency mixer section for outputting a signal, a plurality of switching means for selectively deactivating the frequency converter of the second frequency mixer section, and a phase-phase signal and a quadrature signal output from the activated frequency converter of the second frequency mixer section. Characterized in that it comprises an adder for.

1 is a structural diagram illustrating a high frequency receiver according to the present invention;

2 is a structural diagram for explaining a superheterodyne type receiver.

3 is a structural diagram for explaining a receiver of a weaver structure.

4 is a structural diagram for explaining a wideband IF receiver.

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

101, 201, 301, 401: antenna

102, 202, 204, 206, 302 402: Bandpass filter

106, 111, 119, 122, 306, 315, 409, 422: Low pass filter

103, 203, 303, 403: low noise amplifier

104, 109, 112, 114, 116, 117, 205, 208, 211, 304, 307, 313, 316, 404, 406, 414, 416, 418, 419: frequency converter

105, 110, 207, 305, 314, 408, 421: variable gain amplifier

107, 209, 308, 310, 411: phase shifter

108, 125, 127, 210, 309, 311, 405, 412, 415: oscillators

113, 115, 413, 417: switching means

118, 121, 124, 312, 407, 420: adder

120, 123, 410, 423: A / D Converter

The present invention configures a high frequency receiver to obtain not only the baseband signal but also the intermediate frequency from which the image signal is removed. To this end, the present invention allows the frequency converter to be selectively deactivated to obtain a desired intermediate frequency, thereby obtaining not only base phase in-phase and quadrature signals but also intermediate frequencies from which images are removed.

Next, the present invention will be described in detail with reference to the accompanying drawings.

1 is a structural diagram illustrating a high frequency receiver according to the present invention.

The signal received by the antenna 101 is input to the low noise amplifier 103 via the bandpass filter 102. The signal amplified by the low noise amplifier 103 is converted to an intermediate frequency having a phase difference of 90 degrees by the frequency down mixers 104 and 109. That is, the output frequency of the phase shifter 107 which receives the frequency output from the oscillator 108 and the output frequency of the low noise amplifier 103 are converted by the frequency down mixers 104 and 109 to obtain a phase difference of 90 °. In-phase and quadrature signals are outputted.

The output signals of the frequency down mixers 104 and 109 are amplified uniformly through the variable gain amplifiers 105 and 110, respectively, and then input to the low pass filters 106 and 111.

In this case, when the switching means 113 and 115 are short-circuited, the in-phase phase signal output from the low pass filter 106 is input to the frequency converters 112 and 114, respectively, and is a right angle output from the low pass filter 111. The phase signal is input to the frequency converters 116 and 117, respectively, and the output of the frequency converter 112 connected with the oscillator 125 is summed at the adder 118 with the output of the frequency converter 116 connected with the oscillator 127. The output of the frequency converter 117 connected to the A / D converter 120 through the low pass filter 119 and connected to the oscillator 125 is an output and an adder of the frequency converter 114 connected to the oscillator 127. After being combined at 121, the low pass filter 122 is transferred to the A / D converter 123. At this time, the frequency output from the oscillator 125 for supplying the signal to the frequency converters 112 and 117 and the frequency output from the oscillator 127 for supplying the signal to the frequency converters 114 and 116 have a phase difference of 90 °. Have It is also possible to substitute a signal having a phase difference of 90 ° from a single oscillator such as the oscillator 108 and the phase shifter 107.

On the other hand, when the switching means 113 and 115 are opened, the in-phase phase signal output from the low pass filter 106 is transmitted to the adder 124 via the frequency converter 112, the low pass filter 111 The quadrature signal outputted from is transmitted to the adder 124 via a frequency converter 117. Therefore, when the switching means 113 and 115 are opened, a signal having an intermediate frequency summed by the adder 124 is output.

At this time, the frequency of the signal in the desired reception band is called F1, and the oscillator 108 is supplied to the phase shifter 107 to obtain the frequencies of the in-phase and quadrature components from the first frequency converters 104 and 109. The supplied frequency is called LOF1, and the oscillator 125 provides the local oscillation signal in quadrature with the oscillator 125 and the frequency converters 114 and 116, which provide the local oscillation signal in phase to the frequency converters 112 and 117 of the second stage. If the output frequency of (127) is LOF2, the relation of desired intermediate frequency (IF) = F1-LOF1-LOF2 must be satisfied.

The present invention configures a high frequency receiver as described above, and controls the switching means 113 and 115 to selectively open, i.e., deactivate the frequency converters 114 and 116. Therefore, only the signals output from the frequency converters 112 and 117 that are not deactivated are summed in the adder 124.

In the present embodiment, the switching means 113 and 115 are used as described above to selectively deactivate the frequency converters 114 and 116, but operate the frequency converters 114 and 116 without using a separate switching means. The circuit can also be configured so that no power is supplied.

In another embodiment, the high frequency receiver of the present invention may be used instead of the image mixer frequency and the frequency mixer of the receiver of the heterodyne structure shown in FIG. In this case, it is possible to apply to a multi-band receiver by varying the oscillator frequency.

In the present invention, some of the frequency converters 114 and 116 are selectively deactivated by the operation of the switching means 113 and 115 so that the receiver itself can be operated as one image suppression frequency converter. Thus, an integrated receiver can be used as one image rejection frequency conversion device.

Conventional wideband intermediate frequency receivers have not been able to obtain intermediate frequency outputs. However, the receiver of the present invention outputs baseband in-phase and quadrature signals, and when used as a frequency converter for image removal, the intermediate image is removed. Output the frequency.

As described above, the present invention can not only obtain the baseband in-phase and quadrature signals by selectively deactivating some frequency converters, but also obtain an intermediate frequency from which images are removed when used as a frequency converter for image removal. Make sure

According to the present invention, a filter, which is an external element, is not used in the process of converting a signal of a high frequency band into an in-phase signal and a quadrature signal. In addition, when the high frequency receiver of the present invention is used as a frequency converter for outputting an intermediate frequency from which an image has been removed, it can take the role of a frequency converter used in a conventional superheterodyne structure. In this case, if the receiver of the present invention is connected to the output terminal of the low noise amplifier, it is not necessary to use an image removing filter, thereby effectively improving the circuit density.

Claims (5)

A low noise amplifier for amplifying the signal received through the antenna, A first frequency mixer unit which receives a signal output from the low noise amplifier and outputs an in-phase phase signal and a quadrature phase signal of an intermediate frequency; A variable gain amplifier for amplifying the signals output from the first frequency mixer, respectively; A second frequency mixer comprising a plurality of frequency converters, each receiving a signal output from the variable gain amplifier and outputting a baseband in-phase signal and a quadrature signal; A plurality of switching means for selectively deactivating the frequency converter of the second frequency mixer; And an adder for adding the in-phase and quadrature signals output from the activated frequency converter of the second frequency mixer. The method of claim 1, The first frequency mixer unit and a first frequency converter for outputting the in-phase phase signal by adding one of the output of the low noise amplifier and the output of the oscillator having a phase difference of 90 °, And a second frequency converter configured to output the quadrature signal by adding the output of the low noise amplifier and the other output of the oscillator. The method of claim 1, And a low pass filter connected between an output terminal of the variable gain amplifier and an input terminal of the second frequency mixer. The method of claim 1, Each frequency converter of the first frequency mixer part is supplied with a signal having a predetermined frequency having a phase difference of 90 ° from each oscillator or one oscillator, and each frequency converter of the second frequency mixer part is supplied from each oscillator or one oscillator. A high frequency receiver, wherein a signal of a predetermined frequency having a phase difference of 90 ° is supplied. The method of claim 1, The second frequency mixer comprises: a first frequency converter receiving the in-phase phase signal output from the variable gain amplifier; A second frequency converter which receives the in-phase phase signal output from the variable gain amplifier and is inactivated by the switching means; A third frequency converter receiving the quadrature signal output from the variable gain amplifier; And a fourth frequency converter receiving the quadrature signal output from the variable gain amplifier and being inactivated by the switching means.