KR20110071675A - Rf signal processing circuit - Google Patents

Abstract

PURPOSE: An RF(Radio Frequency) signal processing unit driving method is provided to reliaby process the radio frequency signal. CONSTITUTION: The first value, in which the image power corresponding to the harmonic component is measured, is saved in the first frequency(S2). The second value, in which the image power corresponding to the harmonic component is measured, is saved in the secondary frequency(S3). The third value, in which the image power corresponding to the harmonic component is measured, is saved in the third frequency(S4). The sizes of the first value to the third value are compared(S5-S7). A frequency corresponding to the great small value is selected as the IF(Intermediate Frequency)(S12).

Description

RF signal processing device driving method {RF SIGNAL PROCESSING CIRCUIT}

The present invention relates to an RF signal processing apparatus, and more particularly, to a method of driving an RF signal processing apparatus.

With the development of wireless communication technology, it is possible to transmit and receive audio and video signals far away. When transmitting audio signals and video signals, a communication frequency called an RF signal uses a signal of several hundred MHz to several Ghz. In the transmission equipment, the audio signal and the video signal are combined with the RF signal, and in the reception equipment, the RF signal and the audio signal and the video signal are separated. In this case, combining is called modulation and separating is called demodulation.

In general, an RF signal processing device amplifies an input RF signal, filters a signal of a desired frequency band, and then demodulates it. The RF signal processing apparatus does not separate a signal having data from the input RF signal, but converts the input RF signal into an intermediate frequency signal inside the RF signal processing apparatus and then demodulates the converted intermediate frequency signal. . Recently, due to noise introduced into the RF signal processing device, a problem that it is difficult to process the RF signal stably occurs.

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

The present invention provides a method of driving an RF signal processing apparatus for removing a harmonic component of an intermediate frequency, the method comprising: storing a first value of measuring an image power corresponding to the harmonic component at the first frequency; Storing a second value of measuring image power corresponding to the harmonic component at the second frequency; Storing a third value of measuring 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.

In addition, comparing the magnitudes of the first to third values and selecting a frequency corresponding to the smallest value as an intermediate frequency may include comparing the magnitudes of the first value and the second value; Comparing the magnitudes of the first and third values; And comparing the magnitudes of the third value and the first value.

In addition, the first frequency is 36Mhz, the second frequency is 34Mhz, the third frequency is characterized in that 38Mhz.

In addition, the RF signal processing apparatus is characterized in that it is driven in the ATSC method or NTSC method.

According to the present invention, since the RF signal processing apparatus can select an intermediate frequency having improved noise characteristics, the RF signal processing apparatus can process the RF signal 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.

Referring to FIG. 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, and signal selection. The unit 20 includes a modulating unit 30.

The input unit 5 amplifies the signals input through the antenna ANT to the input filter units 11, 12, 13. The input filter units 11, 12, and 13 transfer signals of a desired band among 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 signals amplified by the RF amplifiers 14, 15, and 16, respectively. The reason why there are three input filter units, three RF amplifiers, and three filter units is to process RF signals in the VHF Low, VHF High, and UHF bands, respectively.

In general, television stations can receive radio waves by transmitting radio waves of very high frequency (VHF) and ultra high frequency (UHF) to the viewer. In Korea, UHF television channels range from channel 13 (frequency 470-476 MHz) to channel 62 (frequency 764-770 MHz). Television broadcasts started using very high freqeuency (VHF) bands, or radio waves of 30 to 300 MHz (actually channel 1, ie from 90 to 96 MHz to channel 12, or 216 to 222 MHz). Due to the increase in the number of radio communication stations such as ships and ship stations, the radio waves cannot be handled by VHF alone.

In television broadcasting, a frequency band of 6 MHz, that is, an occupied bandwidth, is required, but in a radio communication that handles only an audio signal, a frequency bandwidth of 20 kHz is required. Therefore, the radio wave of the VHF band is used for radio communication other than the television, and the television has a high efficiency in radio wave assignment such that the radio wave of the UHF band can take a large number of channels. Therefore, television broadcasting is expected to move from VHF broadcasting to UHF broadcasting. As a transient state, the mixing of VHF broadcasting and UHF broadcasting is being performed. In order to receive UHF radio waves through the VHF receiver, UHF converter must be used for frequency conversion. However, an all-channel television product can receive both UHF and VHF broadcasting.

The signal selector 20 selects an RF signal of a predetermined frequency band among the input signals, generates and transmits the intermediate frequency signal IF. The signal selector 20 includes a phase locked loop circuit 29, a mixing circuit 22 and 23, an OSC unit 25 and 26, an amplifier 24, a signal transfer unit 28, an RF amplification control unit 27, and the like. Including, and selects and delivers the RF signal of a predetermined frequency band, recently, it is common to implement these circuits in one chip.

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

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

However, in the tuner using the IF specific demodulator, the intermediate frequency is set to 36 MHz to process the broadcast signal of the ATSC / NTSC system. The ATSC / NTSC scheme uses an intermediate frequency of 44 MHz. Accordingly, N + 12 characteristics (36MHZ * 2 = 72MHz Image frequency, N + 12 = 6MHz * 12 = 72MHz) among the other CH Interference characteristics with the standard (A-74) set based on the intermediate frequency as 44MHz. ) Gets worse.

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 + 12th channel and the image frequency overlap in the case where the interval of one channel is 6 MHz, the RF signal processing apparatus uses such a frequency. It should work to rule out this.

The Upper Heterodyne method used in the RF signal processing circuit has a relationship of fIF = fosc-fRF. Where fosc is the frequency provided by the internally provided oscillator, fRF is the frequency of the input RF signal, and fIF is the intermediate frequency. Even if a frequency higher than fIF, that is, Fimage = Fosc + fIF, is input to the mixing circuit of the RF signal processing apparatus, Fimage-fosc = fIF acts as an interference signal and should be removed.

The degree of exclusion of this disturbance signal is called an image rejection characteristic and is represented by the difference between the desired signal at the output of the RF signal processing circuit and the beat force due to the disturbance signal due to the image.

It is related to the Q factor of each tuning stage of the RF signal processing device, and also improves the rejection capability by increasing the Q factor of each tuning stage or adding a fixed trap or a variable trap circuit. However, the higher the Q aspect of the input tuning stage, the better the rejection of the disturbance signal due to the image, but the narrower operating bandwidth causes additional problems.

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

Referring to FIG. 2, the method for driving the RF signal processing apparatus according to the present embodiment first receives an N + 12 interference signal (S1). Subsequently, the power for the image at the intermediate frequency of 36 MHz is measured and stored as a p0 value (S2). The image here refers to an N + 12 disturbance signal.

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

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

Subsequently, if the p1 value is smaller in the comparison step between the p0 value and the p1 value, the p1 value and the p2 value are compared (S7). If the p1 value is smaller, the intermediate frequency signal is 33 MHz (S10). If the p2 value is smaller, the intermediate frequency signal is set to 39 MHz (S11). Here, the intermediate frequency is not 34Mhz and 38Mhz, 33Mhz and 39Mhz in consideration of the margin of the actual operation, 34Mhz and 38Mhz may be.

As described above, when the intermediate frequency is set to a specific frequency, when the frequency with the smallest N + 12 interference signal is set to the intermediate frequency, the harmonic component of the intermediate frequency can prevent the degradation of the RF signal processing characteristics.

Although the present invention has been described in detail with reference to exemplary embodiments above, those skilled in the art to which the present invention pertains can make various modifications to the above-described embodiments without departing from the scope of the present invention. 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.

Explanation of symbols on the main parts of the drawings

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

S3: second image power measurement S4: third image power measurement

Claims (4)

In the driving method of the RF signal processing apparatus for removing the harmonic component of the intermediate frequency, Storing a first value of measuring image power corresponding to the harmonic component at the first frequency; Storing a second value of measuring image power corresponding to the harmonic component at the second frequency; Storing a third value of measuring image power corresponding to the harmonic component at the third frequency; And Comparing the magnitudes of the first to third values and selecting a frequency corresponding to the smallest value as an intermediate frequency; Method of driving an RF signal processing apparatus comprising a. The method of claim 1, Comparing the magnitudes of the first to third values and selecting a frequency corresponding to the smallest value as an intermediate frequency; Comparing the magnitudes of the first and second values; Comparing the magnitudes of the first and third values; And And comparing the magnitudes of the third value and the first value. The method of claim 1, Wherein the first frequency is 36Mhz, the second frequency is 34Mhz, and the third frequency is 38Mhz. The method of claim 1, The RF signal processing apparatus is a method of driving an RF signal processing apparatus which is driven by the ATSC method or NTSC method.

Images