KR101039864B1 - Apparatus for Searching Radio Frequency - Google Patents

Abstract

The present invention relates to a frequency detector capable of detecting a frequency by using a gain characteristic according to the frequency of the device.

To this end, the present invention provides a power distributor for distributing the input RF signal; A reference power detector for detecting power of a signal applied from the power divider; A first frequency signal gain variable unit which attenuates a signal applied from the power splitter so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A first power detector for detecting power of a signal applied from the first frequency signal gain variable part; A second frequency signal gain variable unit which attenuates a signal applied from the power splitter so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A second power detector for detecting power of a signal applied from the second frequency signal gain variable part; It provides a frequency detection device comprising a central processing unit for calculating the difference between the power value input from the reference power detector and the first and second power detector to set the frequency corresponding to the difference value of the pre-stored frequency.

Frequency, power divider, frequency signal gain variable, linearizer, frequency oscillator.

Description

Frequency Detection Device {Apparatus for Searching Radio Frequency}

The present invention relates to a frequency detecting device used in a base station or a repeater, and more particularly, to a frequency detecting device capable of detecting a frequency using a gain characteristic according to the frequency of an element without using a frequency generator in a frequency detecting process. It is about.

In general, a power amplifier used in a base station or a repeater is for power amplification of an input signal. In order to extract the maximum power, a transistor, which is a main active element, is operated in a saturation region having strong nonlinear characteristics.

However, due to the characteristics of the active device, intermodulation signals are generated due to the nonlinear characteristics near the saturation region, and these intermodulation (IMD) signals act as interference or noise, which degrades the transmission quality, thereby degrading communication quality. .

Accordingly, in order to remove the intermodulation signal in the power amplification process, a frequency of the input signal is detected and a linearization technique such as predistortion is used to cancel the intermodulation signal by using the frequency detected in the power amplification process. This results in a higher output signal with no intermodulation signal removed.

Figure 1 shows an example of a frequency detection device for detecting the frequency of the RF input signal.

As shown in FIG. 1, a conventional frequency detector includes a mixer 10 for downconverting a frequency of an RF signal into an intermediate frequency band, and a frequency generator 20 for supplying the mixer 10 with an LO frequency for frequency synthesis. ), Saw filters 30 and 31 for filtering out unnecessary frequencies among the frequencies output from the mixer 10 and the IF amplifier 41, IF amplifiers 40 and 41 for amplifying intermediate frequencies, and saw filters ( 31) to control the IF detector 50 and the frequency generator 20 to convert the intensity of the signal output from the power level signal to the central processing unit (CPU) according to the power level input from the IF detector 50 It is composed of a central processing unit 60 for setting the input RF frequency and outputs the frequency value set to the CPU of the linearizer.

However, such a conventional RF frequency detection device has many components such as a mixer 10, a frequency generator 20, a saw filter 30, an IF amplifier 41, an IF detector 50, and a separate central processing unit 60. As a result, the circuit structure is complicated and the manufacturing cost is greatly increased.

In addition, since the frequency is converted into a frequency lower than the input frequency (Down Converting), the generated frequency is converted into a sweep to find out the frequency of use. This causes problems in terms of complexity, such as slow response time.

In particular, the conventional RF frequency detection device must be sensitive to temperature because the oscillator (VCO) is essentially used in the frequency generator 20, which inevitably decreases the reliability of the detected signal, resulting in improved linearity of the power amplifier. There was a problem that can not be secured.

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems as described above, and an object of the present invention is to reduce unnecessary components due to frequency detection and to simplify the circuit, greatly reducing manufacturing cost and simplifying the circuit structure. It is to provide a detection device.

It is another object of the present invention to provide an RF frequency detection device capable of accurate frequency detection regardless of temperature change by excluding a frequency oscillator, thereby enabling more reliable linearization.

It is still another object of the present invention to provide an RF frequency detecting apparatus capable of detecting two frequencies from an input signal.

The above object of the present invention is a power distributor for distributing the input RF signal; A reference power detector for detecting power of a signal applied from the power divider; A first frequency signal gain variable unit which attenuates a signal applied from the power splitter so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A first power detector for detecting power of a signal applied from the first frequency signal gain variable part; A second frequency signal gain variable unit which attenuates a signal applied from the power splitter so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A second power detector for detecting power of a signal applied from the second frequency signal gain variable part; The difference between the reference power detector and the power values input from the first and second power detectors may be calculated, and may be achieved through a frequency detection device including a central processing unit for setting a frequency corresponding to the difference value among pre-stored frequencies. have.

In addition, an object of the present invention is a power distributor for distributing the input RF signal; A reference frequency signal gain variable unit which attenuates the signal applied from the power divider and changes a gain of the signal according to a frequency; A reference power detector for detecting power of a signal applied from the reference frequency signal gain variable unit; A first frequency signal gain variable unit which attenuates a signal applied from the power splitter so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A first power detector for detecting power of a signal applied from the first frequency signal gain variable part; A second frequency signal gain variable unit which attenuates a signal applied from the power splitter so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A second power detector for detecting power of a signal applied from the second frequency signal gain variable part; The difference between the reference power detector and the power values input from the first and second power detectors may be calculated, and may be achieved through a frequency detection device including a central processing unit for setting a frequency corresponding to the difference value among pre-stored frequencies. have..

And an object of the present invention is a power distributor for distributing the input RF signal; A reference power detector for detecting power of a signal applied from the power divider; An RF switch for switching a signal applied from the power divider; A first frequency signal gain variable unit which attenuates the signal applied from the RF switch so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A first power detector for detecting power of a signal applied from the first frequency signal gain variable part; A second frequency signal gain variable unit which attenuates the signal applied from the RF switch so as to detect one of the two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A second power detector for detecting power of a signal applied from the second frequency signal gain variable part; The difference between the reference power detector and the power values input from the first and second power detectors may be calculated, and may be achieved through a frequency detection device including a central processing unit for setting a frequency corresponding to the difference value among pre-stored frequencies. have.

In addition, an object of the present invention is a power distributor for distributing the input RF signal; A reference power detector for detecting power of a signal applied from the power divider; A first RF switch for distributing a signal input from the power distributor; A first frequency signal gain variable unit which attenuates the signal applied from the first RF switch so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A second frequency signal gain variable unit which attenuates the signal applied from the first RF switch so as to detect another frequency band of two spaced apart frequencies, and whose gain is changed according to the frequency; A second RF switch for switching signals applied from the first and second frequency signal gain variable parts; A first power detector for detecting power of the attenuated signal applied from the first RF switch; The difference between the reference power detector and the first power detector may be calculated through a frequency detection device including a central processing unit for calculating a difference corresponding to the difference value among pre-stored frequencies.

The present invention having the problem solving means and the configuration as described above can greatly reduce the number of components in accordance with the frequency detection can simplify the circuit structure and significantly reduce the manufacturing cost.

According to the present invention, since two frequencies can be set through the first and second frequency signal gain variable parts and the first and second power detectors, multicarriers can be realized.

Since the present invention does not use a temperature-sensitive device such as a frequency oscillator, accurate frequency detection is possible, and thus there is a very useful effect of ensuring more reliable linearity.

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

First Embodiment

2 is a block diagram to which the frequency detecting device of the present invention is applied, and FIG. 3 is a block diagram showing the configuration of the frequency detecting device. As shown in FIGS. 2 and 3, the first embodiment of the present invention is largely a power divider. 100, the reference power detector 300, the first and second frequency signal gain variable parts 210 and 220, the first and second power detectors 310 and 320, and the central processing unit 400. .

First, the power divider 100 distributes the power of the input RF signal by distributing the power and outputs the power to the reference power detector 300 and the first and second frequency signal gain variable parts 210 and 220.

The reference power detector 300 detects the power level of the signal applied from the power divider 100 and outputs the power level value to the CPU 400.

The first frequency signal gain variable unit 210 attenuates a signal so as to detect a frequency of any one of two spaced apart frequencies included in the signal applied from the power divider 100, and the power divider 100. The signal applied from the attenuate and low pass (Low Path) is output to the first power detector 310.

The first power detector 310 detects the power level of the low pass signal by the first frequency signal gain variable unit 210 and outputs the power level value to the CPU 400.

The second frequency signal gain variable unit 220 attenuates a signal so as to detect a frequency of another band of two spaced apart frequencies included in the signal applied from the power divider 100, and the power divider 100. The signal applied from the attenuator and the high pass (High Path) is output to the second power detector 220.

The second power detector 320 detects the power level of the high pass signal by the second frequency signal gain variable unit 220 and outputs the power level value to the CPU 400.

Here, the first and second frequency signal gain variable parts 210 and 220 allow the low pass and high pass of the input signals, respectively, but may change the functions to make the high pass and the low pass.

In addition, the first and second frequency signal gain variable parts 210 and 220 may use a band pass filter, a low pass filter, and a high pass filter to attenuate the applied signal. It is preferable to use a filter such as), but in addition to the filter, a general passive element as shown in FIG. 8 or a general active element which may have a desired loss and gain depending on frequency as shown in FIG. 9 or as shown in FIG. As described above, it is also possible to use the passive element and the active element together.

The CPU 400 calculates a difference between power values input from the reference power detector 300 and the first and second power detectors 310 and 320 to set a frequency corresponding to the difference value among pre-stored frequencies. In this case, it is preferable to use a lookup table to set the frequency according to the difference in power values.

The central processing unit 400 may simply use a central processing unit having a reader function, but it is preferable to use a linearizing central processing unit (CPU) for simple circuit configuration and cost reduction.

FIG. 4 is a diagram illustrating first and second lookup tables illustrating differences between power values of the reference power detector 300 and the first and second power detectors 310 and 320 and corresponding frequencies when a specific frequency signal is input. An example is shown.

That is, when a specific frequency signal is input, the power value of the first power detector 310 low pass by the first frequency signal gain variable unit 210 and the power value of the reference power detector 300 have a difference. . Therefore, when the central processing unit 400 calculates the difference between the two power values and obtains -8.92, the central processing unit 400 sets 2110MHz corresponding to -8.92 in the first lookup table as the frequency and uses the frequency for predistortion linearization.

In addition, the CPU 400 calculates a difference between the power value of the second power detector 320 and the power value of the reference power detector 300 that are high pass by the second frequency signal gain variable unit 220. When -10.8 is obtained, 2170MHz corresponding to -10.8 is set as the frequency in the second lookup table and used as the frequency for predistortion linearization.

As described above, when the input signal includes two frequencies spaced apart from each other, as in the example of 2110 MHz and 2170 MHz, the present invention detects each of the signals through low pass and high pass, thereby realizing multi-carrier by setting two frequency bands. Nonlinear components resulting from linearization can also be efficiently removed.

Furthermore, the present invention, unlike the prior art, because the frequency oscillator is not used, not only reduces the manufacturing cost, but also simplifies the circuit, and can perform stable and accurate frequency detection even if the power or temperature is changed, such as busy or short time. Therefore, call quality can be improved through more reliable linearization.

Second Embodiment

5 shows a second embodiment of the present invention, which is substantially the same as the first embodiment, except that the first and second frequency signal gain variable parts 210 and 220 have different attenuation characteristics. There is a difference in that the variable unit 200 is installed at the input terminal of the reference power detector 300.

As described above, in the present invention, since the reference frequency signal gain variable part 200 and the first and second frequency signal gain variable parts 210 and 220 have different gain characteristics, the reference power detector 300 and the first and second values are different. The power level values output from the two power detectors 310 and 320 are different, and the CPU 400 calculates the difference value and sets the frequency of the corresponding lookup table.

The frequency stored in the lookup table and a value corresponding to each frequency are values of the first embodiment based on gain characteristics of the reference frequency signal gain variable unit 200 and the first and second frequency signal gain variable units 210 and 220. A different value from can be stored, but the effect is the same since the way it works is the same.

Third Embodiment

6 shows a third embodiment of the present invention, which is substantially the same as the configuration of the first embodiment, except that the first and second frequency signals are switched by switching the output signal of the power distributor 100 through the RF switch 500. There is a difference in that it is input to the gain variable section (210, 220).

Fourth Embodiment

FIG. 7 illustrates a fourth embodiment of the present invention, which is substantially the same as the configuration of the third embodiment. However, since the first RF switch 510 and the second RF switch 520 are used, the number of power detectors is reduced. There is a difference.

As described above, according to the present invention, since the second RF switch 520 switches both signals of the first and second frequency signal gain variable parts 210 and 220, the first power detector 310 adjusts the power level of each signal. This reduces the number of power detectors, further simplifying circuit structure and reducing costs.

The various embodiments of the present invention described above are merely illustrative of preferred examples, and the scope of the present invention is not limited thereto, and may be appropriately changed within the scope of the same concept.

1 is a block diagram showing a conventional frequency detection device.

Figure 2 is a block diagram to which the frequency detection device of the present invention is applied.

Figure 3 is a block diagram showing a frequency detection apparatus according to the present invention.

4 is a table showing an example of a lookup table according to the present invention;

5 to 7 are block diagrams showing another embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: power divider 200: reference frequency signal gain variable part

210,220: first and second frequency signal gain variable part

300: reference power detector

310,320: first and second power detector

400: central processing unit

500,510,520: RF Switch

Claims (10)

A power distributor 100 for distributing the input RF signal; A reference power detector (300) for detecting power of a signal applied from the power divider (100); A first frequency signal gain variable unit 210 for attenuating a signal applied from the power splitter 100 so as to detect one of two frequency bands spaced apart from each other, but having a gain of the signal changed according to a frequency; A first power detector (310) detecting power of a signal applied from the first frequency signal gain variable unit (210); A second frequency signal gain varying unit 220 which attenuates the signal applied from the power splitter 100 so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A second power detector 320 for detecting power of a signal applied from the second frequency signal gain variable unit 220; The CPU 400 calculates a difference between power values input from the reference power detector 300 and the first and second power detectors 310 and 320 and sets a frequency corresponding to the difference value among pre-stored frequencies. ); Frequency detection device comprising a. A power distributor 100 for distributing the input RF signal; A reference frequency signal gain variable unit 200 which attenuates the signal applied from the power divider 100 and whose gain is changed according to frequency; A reference power detector (300) for detecting power of a signal applied from the reference frequency signal gain variable unit (200); A first frequency signal gain variable unit 210 for attenuating a signal applied from the power splitter 100 so as to detect one of two frequency bands spaced apart from each other, but having a gain of the signal changed according to a frequency; A first power detector (310) detecting power of a signal applied from the first frequency signal gain variable unit (210); A second frequency signal gain varying unit 220 which attenuates the signal applied from the power splitter 100 so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A second power detector 320 for detecting power of a signal applied from the second frequency signal gain variable unit 220; The CPU 400 calculates a difference between power values input from the reference power detector 300 and the first and second power detectors 310 and 320 and sets a frequency corresponding to the difference value among pre-stored frequencies. ); Frequency detection device comprising a. A power distributor 100 for distributing the input RF signal; A reference power detector (300) for detecting power of a signal applied from the power divider (100); An RF switch 500 for switching a signal applied from the power splitter 100; A first frequency signal gain variable unit 210 attenuating the signal applied from the RF switch 500 so as to detect any one of two frequency bands spaced apart from each other, and having a gain of the signal changed according to the frequency; A first power detector (310) detecting power of a signal applied from the first frequency signal gain variable unit (210); A second frequency signal gain variable unit 220 which attenuates the signal applied from the RF switch 500 so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; A second power detector 320 for detecting power of a signal applied from the second frequency signal gain variable unit 220; The CPU 400 calculates a difference between power values input from the reference power detector 300 and the first and second power detectors 310 and 320 and sets a frequency corresponding to the difference value among pre-stored frequencies. ); Frequency detection device comprising a. A power distributor 100 for distributing the input RF signal; A reference power detector (300) for detecting power of a signal applied from the power divider (100); A first RF switch (510) for distributing a signal input from the power splitter (100); A first frequency signal gain variable unit 210 which attenuates the signal applied from the first RF switch 510 so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; ; A second frequency signal gain variable unit 220 which attenuates the signal applied from the first RF switch 510 so as to detect one of two frequency bands spaced apart from each other, but whose gain is changed according to the frequency; ; A second RF switch 520 for switching signals applied from the first and second frequency signal gain variable parts 210 and 220; A first power detector (310) for detecting power of the attenuated signal applied from the second RF switch (520); A central processing unit (400) for calculating a difference between power values input from the reference power detector (300) and the first power detector (310) and setting a frequency corresponding to the difference value among pre-stored frequencies; Frequency detection device comprising a. The method according to any one of claims 1 to 4, wherein the first and second frequency signal gain variable parts 210 and 220 are any one of a passive element and an active element so as to have different gain characteristics at a desired frequency. Or a combination of a passive element and an active element. delete delete According to any one of claims 1 to 4, wherein the first frequency signal gain variable unit 210 is any one of a high pass filter or a low pass filter, the second frequency signal gain variable unit 220 is And a low pass filter or a high pass filter corresponding to the first frequency signal gain variable unit (210). delete delete

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