KR101620640B1 - Rf signal processing circuit - Google Patents

Abstract

The present invention relates to a method of driving an RF signal processing apparatus for removing an harmonic component of an intermediate frequency, the method comprising the steps of: Storing a first value that measures a corresponding image power; Storing a second value that measures an image power corresponding to the harmonic component at the second frequency; Storing a third value measuring an image power corresponding to the harmonic component at the third frequency; And comparing the magnitudes of the first to third values to select a frequency corresponding to the smallest value as an intermediate frequency.

RF Signal, Noise, Demodulator, Power, Ripple.

Description

TECHNICAL FIELD [0001] The present invention relates to an RF signal processing apparatus,

Field of the Invention [0002] The present invention relates to an RF signal processing apparatus, and more particularly, to a driving method of an RF signal processing apparatus.

With the development of wireless communication technology, it is possible to transmit and receive voice signals and video signals remotely. When a voice signal and a video signal are transmitted, a signal having a communication frequency of several hundred Mhz to several Ghz is used as an RF signal. The transmitting equipment combines the voice signal and the video signal with the RF signal, and the receiving equipment separates the RF signal, the voice signal and the video signal. At this time, coupling is called modulation and demodulation is called separation.

Generally, an RF signal processing apparatus amplifies an inputted RF signal, filters it by a signal of a desired frequency band, and then performs demodulation. The RF signal processing apparatus does not separate the signal having data from the input RF signal but converts the RF signal inputted thereto into an intermediate frequency signal in the RF signal processing apparatus and demodulates the converted intermediate frequency signal . In recent years, there is a problem that it is difficult to stably process an RF signal due to noise introduced into the RF signal processing apparatus.

The present invention provides a method of driving an RF signal processing apparatus having a noise characteristic.

According to an aspect of the present invention, there is provided a driving method of an RF signal processing apparatus for removing an harmonic component of an intermediate frequency, the method comprising: storing a first value obtained by measuring an image power corresponding to the harmonic component at the first frequency; Storing a second value that measures an image power corresponding to the harmonic component at the second frequency; Storing a third value measuring an image power corresponding to the harmonic component at the third frequency; And comparing the magnitudes of the first to third values to select a frequency corresponding to the smallest value as an intermediate frequency.

The step of comparing the magnitudes of the first to third values and selecting the frequency corresponding to the smallest value as the intermediate frequency may include comparing magnitudes of the first and second values; Comparing magnitudes of the first and third values; And comparing the magnitude of the third value with the magnitude of the first value.

The first frequency is 36 MHz, the second frequency is 34 MHz, and the third frequency is 38 MHz.

In addition, the RF signal processor is driven by an ATSC system or an NTSC system.

According to the present invention, since the RF signal processing apparatus can select the intermediate frequency with improved noise characteristics, the RF signal can be processed more reliably.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention. do.

1 is a block diagram showing an RF signal processing apparatus for explaining the present invention.

1, the RF signal processing apparatus includes an input unit 5, input filter units 11, 12 and 13, RF amplifiers 14, 15 and 16, filter units 17, 18 and 19, (20), and a modulating unit (30).

The input unit 5 amplifies the signal input through the antenna ANT by the input filter units 11, 12, and 13. The input filter units 11, 12, and 13 transmit signals of a desired band among the RF signals input through the antenna. The RF amplifiers 14, 15, and 16 amplify the signals transmitted from the input filter units 11, 12, and 13, respectively. The filter units 17, 18, and 19 filter the amplified signals from the RF amplifiers 14, 15, and 16, respectively. The input filter section, the RF amplifier section, and the filter section are provided for processing the RF signals of the VHF Low, VHF High, and UHF bands, respectively.

Generally, in a television broadcasting station, reception is possible by transmitting a radio wave of a VHF or a UHF to a viewer. In Korea, UHF television channels range from channel 13 (frequency 470 to 476 MHz) to channel 62 (frequency 764 to 770 MHz). Television broadcasting started with very high freqeuency (VHF) band, that is, radio waves of 30 to 300 MHz (actually, channel 1, ie, 90 to 96 MHz to channel 12, ie 216 to 222 MHz) Due to the increase of wireless communication stations such as ship stations and VHF band can not be processed only by radio waves.

In television broadcasting, a frequency band of 6 MHz, that is, an occupied bandwidth is required, but only a frequency band of 20 kHz is required in wireless communication in which only voice signals are handled. Therefore, the radio waves of the VHF band are used for radio communication other than the television, and the radio waves of the UHF band are used for the television, so that the efficiency of radio wave allocation is good. Therefore, it is expected that TV broadcasting will be transferred from VHF to UHF, and VHF broadcasting and UHF broadcasting are mixed as transient state. To receive UHF radio waves using a VHF receiver, the UHF converter must be used for frequency conversion, but all channel television receivers can receive both UHF and VHF broadcasts.

The signal selector 20 selects an RF signal of a predetermined frequency band among the input signals, and generates and transmits the intermediate frequency signal IF. The signal selection unit 20 includes a phase locked loop circuit 29, mixing circuits 22 and 23, OSC units 25 and 26, an amplifier 24, a signal transmission unit 28, an RF amplification control unit 27, To select and transmit RF signals in a predetermined frequency band. In recent years, it is common to implement these circuits by including them in one chip.

The demodulating unit 30 includes a digital SAW filter 31, analog SAW filters 32 and 33, an amplifier 34, a video signal demodulator 35 and a voice signal demodulator 36. The analog SAW filters 32 and 33 filter and output the signal output from the signal selector 20 and the demodulators 35 and 36 respectively demodulate the signals output from the analog SAW filters 32 and 33 And outputs the video signal V and the audio signals A and SIF. The digital SAW filter 31 filters and outputs a signal output from the signal selection unit 20. [ The amplifier 34 amplifies and outputs a signal transmitted from the digital SAW filter 31, and a digital demodulator (not shown) demodulates the amplified signal.

A television tuner, which is one of the RF signal processing apparatuses, uses the intermediate frequency (Ifc) = 36 MHz or 44 MHz according to the regional broadcasting system.

However, the tuner using the IF-specific demodulator processes the ATSC / NTSC broadcast signal at an intermediate frequency of 36 MHz. The ATSC / NTSC method uses an intermediate frequency of 44MHz. Accordingly, the N + 12 characteristic (36 MHZ * 2 = 72 MHz Image frequency, N + 12 = 6 MHz * 12 = 72 MHz) among the Taboo CH Interference characteristics having the intermediate frequency of 44 MHz as the standard (A- ).

Here, the image frequency is a frequency at which the harmonic component of the intermediate frequency acts as noise. Since the frequency of the (N + 12) th channel overlaps with the image frequency in a situation where the interval of one channel is 6 MHz, Lt; / RTI >

In the Upper Heterodyne method used in the RF signal processing circuit, there is a relation of fIF = fosc - fRF. Where fosc is the frequency provided internally by the oscillator, fRF is the frequency of the incoming RF signal, and fIF is the intermediate frequency. Even when the frequency corresponding to FIM higher than fosc, that is, Fimage = Fosc + fIF, is input to the mixing circuit of the RF signal processing apparatus, Fimage-fosc = fIF is generated and acts as an interference signal.

The degree of rejection of this interference signal is called the image rejection characteristic and is expressed as the difference between the desired signal at the output of the RF signal processing circuit and the beat caused by the image interference signal.

It is related to the Q factor of each tuning end of the RF signal processing device and improves the exclusion ability by increasing the Q-factor of each tuning end or adding a fixed trap or a variable trap circuit. However, the higher the Q-factor of the input tuning stage is, the more advantageous it is to exclude the interference signal due to the image, but the operation bandwidth becomes narrower, thereby causing another additional problem.

2 is a block diagram illustrating a method of driving an RF signal processing apparatus according to a preferred embodiment of the present invention.

Referring to FIG. 2, in the driving method of the RF signal processing apparatus according to the present embodiment, an N + 12 disturbance signal is received (S1). Next, the power for the image when the intermediate frequency is 36 MHz is measured and stored as the p0 value (S2). The image here refers to the N + 12 interfering signal.

Then, the power of the image when the intermediate frequency is 34 MHz is measured and stored as the value p1 (S3). Next, the power for the image when the intermediate frequency is 38 MHz is measured and stored as the p2 value (S4).

Then, the p0 value is compared with the p1 value. If the p0 value is smaller, the p0 value is compared with the p2 value (S6). If the p0 value is smaller, the intermediate frequency signal is set to 36 MHz (S8). If the value of p2 is smaller, the intermediate frequency signal is set to 39 MHz (S9).

If the p1 value is smaller than the p1 value in the step of comparing the p0 value with the p1 value, the p1 value is compared with the p2 value (S7). If the p1 value is smaller, the intermediate frequency signal is set to 33 MHz (S10). If the value of p2 is smaller, the intermediate frequency signal is set to 39 MHz (S11). In this case, the intermediate frequencies are not set to 34 MHz and 38 MHz, and 33 MHz and 39 MHz are taken into account for the actual operation margin, and 34 MHz and 38 MHz are acceptable.

As described above, when the intermediate frequency is a specific frequency, if the N + 12 interfering signal sets the smallest frequency as the intermediate frequency, it is possible to prevent degradation of RF signal processing characteristics due to the harmonic component of the intermediate frequency.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, I will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the scope of the appended claims, as well as the appended claims.

1 is a block diagram showing an RF signal processing apparatus for explaining the present invention.

2 is a block diagram showing a method of driving an RF signal processing apparatus according to a preferred embodiment of the present invention.

Description of the Related Art [0002]

S1: frequency recognition step; S2: First image power measurement

S3: Second image power measurement S4: Third image power measurement

Claims (4)

A driving method of an RF signal processing apparatus for removing a harmonic component of an intermediate frequency, Storing a first value that measures an image power corresponding to the harmonic component at a first frequency; Storing a second value that measures an image power corresponding to the harmonic component at a second frequency; Storing a third value measuring an image power corresponding to the harmonic component at a third frequency; And Comparing magnitudes of the first to third values and selecting a frequency corresponding to the smallest value as an intermediate frequency Lt; / RTI > The RF signal processing apparatus includes: It is driven by the ATSC system or the NTSC system using a frequency of 44 MHz, The image power, And the power of the frequency of the N + 12 interfering signal overlapping the frequency of the (N + 12) th channel in a situation where the interval of one channel is 6 MHz. The method according to claim 1, The step of comparing the magnitudes of the first to third values and selecting the frequency corresponding to the smallest value as the intermediate frequency Comparing a magnitude of the first value with a magnitude of the second value; Comparing magnitudes of the first and third values; And And comparing the third value with a magnitude of the first value. The method according to claim 1, Wherein the first frequency is 36 MHz, the second frequency is 34 MHz, and the third frequency is 38 MHz. delete

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