KR100856327B1 - Double conversion type television tuner - Google Patents

Abstract

SUMMARY OF THE INVENTION An object of the present invention is to provide a double-conversion television tuner for removing unnecessary image frequencies included in a signal input to a secondary mixer in a double-conversion television tuner.

The present invention for achieving the above object, a low noise amplifier 31 for amplifying the input signal (Sin) of the television broadcast with low noise; Primary oscillator 32; Primary mixer 33; Band pass filter 34; An image tracking filter 35 for removing an unnecessary image frequency FIMG included in the signal S3 output from the band pass filter 34; Secondary oscillator 36; And a secondary mixer 37.

According to the present invention, by removing unnecessary image frequencies included in the signal input to the secondary mixer, there is an effect that can improve the reception performance, such as the ability to recover the signal for the double-conversion television tuner.

Television, tuner, image frequency

Description

Double conversion television tuner {DOUBLE CONVERSION TYPE TELEVISION TUNER}

1 is a block diagram of a conventional double conversion television tuner.

2 is a frequency characteristic diagram of a signal input to a conventional secondary mixer.

3 is a block diagram of a double conversion television tuner according to the present invention.

4 (a) to (b) is a frequency characteristic diagram of a signal input to the secondary mixer according to the present invention.

Explanation of symbols on the main parts of the drawings

31: low noise amplifier

32: primary oscillator

33: primary mixer

34: band pass filter

35: Image Tracking Filter

36: secondary oscillator

37: secondary mixer

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a television tuner applied to a television receiving system. In particular, in a double-conversion television tuner, it is possible to remove unnecessary image frequencies included in a signal input to a secondary mixer, thereby receiving performance such as a signal recovery capability. It is about a double conversion television tuner that can improve the performance.

In general, in a TV system, a tuner performs a channel selection function that enables a user to watch a desired channel. The tuner amplifies and selects a received signal to restore only a signal of a desired channel. In order to design a complex structure. Transceiver for mobile communication has a structure to process narrowband high frequency signal, but TV tuner system has to deal with wideband (40MHz-900MHz) signal that is distributed from low frequency to high frequency, so there is a difficulty in design and implementation do. Various tuner methods have been proposed and applied for a long time to solve these difficulties, and these tuner methods include single conversion, double conversion, and direct conversion. The most representative of these is the double conversion method.

1 is a block diagram of a conventional double conversion television tuner. The conventional double conversion television tuner shown in FIG. 1 includes a low noise amplifier 11 for amplifying the input signal Sin in the range of approximately 50-900 MHz with low noise. From the primary oscillator 12 for generating the primary oscillation frequency (FVCO1) necessary for up-conversion of the input signal, and the oscillation frequency (FVCO1) from the primary oscillator (12) and the low noise amplifier (11) The primary mixer 13 and the primary mixer 13 which generate a primary intermediate frequency signal IF1 up-converted to a higher frequency (approximately 1.2 GHz) than the input signal by mixing the signal S1 of Bandpass filter 14 for passing a band including the first intermediate frequency signal IF1 among the signals from the first and second secondary oscillation frequencies required for down-conversion of the upconverted primary intermediate frequency signal IF1. The secondary oscillator 15 generating VCO2 and the oscillation frequency FVC from the secondary oscillator 15 O2) and a second intermediate frequency signal (1) down-converting the first intermediate frequency signal IF2 to a preset frequency by mixing the first intermediate frequency signal IF2 from the band pass filter 14. A secondary mixer 16 producing IF2).

In the conventional double conversion television tuner, the first and second intermediate frequency signals, that is, two intermediate frequency signals, are first converted into a predetermined high frequency band, and then only a desired band can pass through the band pass filter. The bandpass signal is again converted into a second intermediate frequency signal by the second mixer.

However, in the conventional double conversion type tuner, an image problem caused by the relationship between the oscillation frequency and the intermediate frequency should be considered, which is a secondary intermediate frequency signal (IF1) in the primary intermediate frequency signal IF1. When converting to IF2), the image frequency existing on the opposite side of the primary intermediate frequency centered on the secondary oscillation frequency is converted into the band of the secondary intermediate frequency signal as an interference signal, which eventually adversely affects the restoration of the desired signal. There is a problem.

In detail, FIG. 2 is a frequency characteristic diagram of a signal input to a conventional secondary mixer, and as shown in FIG. 2, positioned with a frequency interval ΔF around the secondary oscillation frequency FVCO2. An image frequency positioned at the same frequency interval ΔF on the opposite side to the desired secondary intermediate frequency signal IF2 is also generated in the band of the secondary intermediate frequency signal. Accordingly, there is a problem that difficulty in restoring a desired signal.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above problems, and an object thereof is to provide a double conversion television tuner for removing unnecessary image frequencies included in a signal input to a secondary mixer in a double conversion television tuner. .

In order to achieve the above object of the present invention, the double conversion television tuner of the present invention                     

A low noise amplifier for amplifying the input signal of the television broadcast with low noise;

A primary oscillator generating a primary oscillation frequency determined according to a primary tuning voltage in a predetermined primary oscillation frequency range;

A primary mixer for mixing the oscillation frequency from the primary oscillator and the signal from the low noise amplifier to provide a primary intermediate frequency signal;

A band pass filter including a first intermediate frequency signal among the signals output from the primary mixer and passing a predetermined band;

An image tracking filter for removing unnecessary image frequencies included in a signal output from the band pass filter;

A secondary oscillator generating a secondary oscillation frequency determined according to a secondary tuning voltage in a preset secondary oscillation frequency range; And

A secondary mixer that provides a second intermediate frequency signal by mixing a second oscillation frequency from the secondary oscillator and the signal passing through the image tracking filter.

Characterized in having a.

In addition, the image tracking filter may preset a frequency to be removed in advance, and alternatively, the image tracking filter may be configured to vary the frequency to be removed based on the second tuning voltage.

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

In the drawings referred to in the present invention, components having substantially the same configuration and function will use the same reference numerals.

3 is a block diagram of a double conversion television tuner according to the present invention.

Referring to FIG. 3, the double conversion television tuner according to the present invention includes a low noise amplifier 31 for amplifying the input signal Sin of a television broadcast with low noise, and a first tuning voltage within a predetermined first oscillation frequency range. A first oscillation unit 32 for generating a primary oscillation frequency FVCO1 determined according to VT1), an oscillation frequency FVCO1 from the primary oscillation unit 32, and a signal from the low noise amplification unit 31; A primary mixer 33 that mixes S1 to provide a primary intermediate frequency signal IF1, and a primary intermediate frequency signal IF1 of the signal S2 output from the primary mixer 33; A band pass filter 34 for passing a predetermined band, an image tracking filter 35 for removing an unnecessary image frequency FIMG included in the signal S3 output from the band pass filter 34, and a preliminary 2 determined according to the secondary tuning voltage (VT2) in the secondary oscillation frequency range set in The second oscillator 36 generates the second oscillation frequency FVCO2, the second oscillation frequency FVCO2 from the second oscillator 36 and the signal S4 passed through the image tracking filter 35 are mixed. And a secondary mixer 37 for providing a secondary intermediate frequency signal IF2.                     

The image frequency FIMG is based on the secondary oscillation frequency VCO2 among the upper and lower frequencies separated from the secondary oscillation frequency FVCO2 by the frequency ΔF of the secondary intermediate frequency signal IF2. Corresponds to the frequency opposite to the difference intermediate frequency signal IF1.

When the secondary oscillation frequency FVCO2 and the secondary intermediate frequency signal IF2 are fixed, the image tracking filter 35 also fixes the image frequency FIMG accordingly. can do.

On the other hand, when the secondary oscillation frequency FVCO2 is varied according to the secondary tuning voltage VT2, the image tracking filter 35 changes the image frequency FIMG according to the secondary oscillation frequency FVCO2. In this case, the frequency to be removed is varied based on the secondary tuning voltage VT2.

The image tracking filter 35 is a filter for removing a specific frequency, that is, an image frequency. The frequency rejection filter may be configured using at least one L element and a C element.

4 (a) to (b) is a frequency characteristic diagram of the signal input to the secondary mixer according to the present invention, Figure 4 (a) is the pass frequency band characteristics by the band pass filter 34 of the present invention 4 (b) is a characteristic diagram of elimination frequency bands of the image tracking filter 35 of the present invention, and FIG. 4 (c) shows the band pass filter 34 and the image tracking filter 35 of the present invention. ) Is the overall frequency band characteristic diagram with

Hereinafter, the operation and effects of the present invention will be described in detail with reference to FIGS. 3 and 4.

First, referring to FIG. 3, the television input signal Sin in the range of approximately 50 MHz to 900 MHz including various broadcast channels is amplified to low noise by the low noise amplifier 31 and then provided to the primary mixer 33.

The primary oscillator 32 of the present invention generates a primary oscillation frequency FVCO1 determined according to the primary tuning voltage VT1 in a predetermined primary oscillation frequency range (about 1.175 GHz to 1.975 GHz). Provided to the primary mixer 33, the primary oscillation frequency FVCO1 is determined to be a frequency corresponding to a television broadcast channel selected within the range of approximately 1.175 GHz to 1.975 GHz of the primary oscillation frequency range.

Next, the primary mixer 33 mixes the oscillation frequency FVCO1 from the primary oscillator 32 and the signal S1 from the low noise amplifier 31 and bands the output signal S2. Provided to the pass filter 34, the signal (S2) output through this mixing process includes the sum of the first oscillation frequency (FVCO1) and the signal (S1), the difference frequency "FVCO1 ± FS1" ( Here, "FS1" means the frequency of the signal (S1), typically the sum of the signals included in the signal S2 output from the primary mixer 33, the desired signal of the difference frequency "FVCO1 ± FS1" is the sum signal " FVCO1 + FS1 "or the difference frequency" FVCO1-FS1 ". In the present invention, when the desired signal is set to the difference frequency" FVCO1-FS1 ", this difference signal becomes the primary intermediate frequency signal IF1.

For example, when the primary oscillation frequency FVCO1 is "1.89 GHz" and the signal S1 input to the primary mixer 33 is "700 MHz", the primary mixer 33 has a sum frequency. "1.89GHz + 700MHz = 2.69GHz" and the difference frequency "1.89GHz-700MHz = 1.19GHz" are output. In this case, when the difference frequency "1.19 GHz" is set as the primary intermediate frequency signal IF1, only the primary intermediate frequency signal IF1 of "1.19 GHz" is passed to the rear end by the band pass filter 34. desirable.

By the way, the band pass filter 34 is usually composed of at least one L element and C element, because the selection characteristics are not good due to the characteristics of the filter element, so that only the desired frequency band can be selected, so that the band pass filter is larger than the desired band. The band is set. Accordingly, the band passed by the band pass filter 34 includes other frequency components, such as an image frequency, in addition to the desired first intermediate frequency signal IF1.

The signal S4 from which the unwanted frequency included in the band passed by the band pass filter 34, that is, the unnecessary image frequency FIMG, is removed by the image tracking filter 35 and the image frequency FIMG is removed. ) Is provided to the secondary mixer 37.

On the other hand, the secondary oscillator 36 of the present invention generates a secondary oscillation frequency (FVCO2) determined according to the secondary tuning voltage (VT2) in the preset second oscillation frequency range (about 1.064 GHz-1.176 GHz) Provided to the secondary mixer 37, wherein the secondary oscillation frequency FVCO2 is determined to be any frequency within the range of approximately 1.064 GHz to 1.176 GHz, which is the secondary oscillation frequency range, which is described below. The secondary frequency IF2 output from the mixer 37 can be set differently, for example, 36 MHz, 40 MHz, 44 MHz, 48 MHz, etc. for each region-applied product in consideration of the reception state. The secondary oscillation frequency is determined to generate the frequency IF2.

Next, the secondary mixer 37 mixes the secondary oscillation frequency FVCO2 from the secondary oscillator 36 and the signal S4 that has passed through the image tracking filter 35 so as to mix the secondary intermediate frequency signal. A signal S5 including IF2 is output.

For example, when the primary intermediate frequency signal IF1 is "1.19 GHz" and the secondary intermediate frequency signal IF2 is "40 MHz," the secondary oscillation frequency FVCO2 is set to "1.15 GHz". The secondary mixer 37 outputs the sum signal "1.19 GHz + 1.15 GHz = 2.24 GHz" and the difference frequency "1.19 GHz-1.15 GHz = 40 MHz". In this case, the secondary frequency " 40 MHz " secondary intermediate frequency signal IF2 is subjected to subsequent signal processing.

The image tracking filter 35 will be described in detail. In the above description, the secondary intermediate frequency signal IF2 output from the secondary mixer 37, that is, the secondary intermediate frequency signal IF2 of " 40 MHz " It is also generated by the first intermediate frequency signal IF1, which is the desired signal, "1.19 GHz," but without the image tracking filter 35 of the present invention, as shown in FIG. 1.11 GHz ". For example, when the secondary oscillation frequency FVCO2 is "1.15 GHz", "40 MHz" is also generated by "1.15 GHz-1.11 GHz". Accordingly, the second intermediate frequency signal IF2 includes both a desired signal (1.19 GHz) and an undesired signal (1.11 GHz).

In order to solve this problem, the image tracking filter 35 of the present invention removes the unwanted image frequency (for example, 1.11 GHz) as described above, and a desired signal is output to the signal S5 output from the secondary mixer 37. Although only the second intermediate frequency signal IF2 is included, the image frequency is removed, thereby facilitating subsequent signal recovery.

According to the present invention as described above, in the double-conversion television tuner, by removing the unnecessary image frequency included in the signal input to the secondary mixer, it is possible to improve the reception performance, such as the signal recovery ability There is.

The above description is only a description of specific embodiments of the present invention, and the present invention is not limited to these specific embodiments, and various changes and modifications of the configuration are possible from the above-described specific embodiments of the present invention. It will be apparent to those skilled in the art to which the present invention pertains.

Claims (3)

A low noise amplifier 31 for amplifying the input signal Sin of the television broadcast with low noise; A primary oscillator 32 generating a primary oscillation frequency FVCO1 determined according to a primary tuning voltage VT1 in a predetermined primary oscillation frequency range; A primary mixer (33) for mixing the oscillation frequency (FVCO1) from the primary oscillator (32) and the signal (S1) from the low noise amplifier (31) to provide a primary intermediate frequency signal; A band pass filter 34 including a first intermediate frequency signal IF1 among the signals S2 output from the primary mixer 33 and passing a predetermined band; An image tracking filter 35 for removing an unnecessary image frequency FIMG included in the signal S3 output from the band pass filter 34; A secondary oscillator 36 for generating a secondary oscillation frequency FVCO2 determined according to the secondary tuning voltage VT2 in a preset secondary oscillation frequency range; And Secondary mixer 37 for mixing the secondary oscillation frequency FVCO2 from the secondary oscillator 36 with the signal S4 passing through the image tracking filter 35 to provide a secondary intermediate frequency signal IF2. ), The image tracking filter 35 varies the frequency to be removed based on the secondary tuning voltage VT2. Double conversion television tuner. The method of claim 1, wherein the image tracking filter 35 A double conversion television tuner, which presets the frequencies to be removed. delete

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