KR960013785B1 - Tunner - Google Patents

Abstract

a broad band filter(16) filtering a television broadcast frequency band; a broad band RF amplifying unit(18) amplifying a RF signal from the broad band filter(16); a first synchronization unit(17) applying a resonant frequency to the broad band filter(16) and the broad band RF amplifying unit(18); a first mixer(20) mixing the output signal from the broad band RF amplifying unit(18) and the oscillating frequency from a PLL circuit(14); a second synchronization unit(19) fitting the output synchronization of the broad band RF amplifying unit(18); a first IF amplifying unit(22) amplifying the mixed signal from the first mixer(20); a second mixer(26) mixing a reference local oscillating frequency and a RF signal from the first IF amplifying unit(22); and a second IF amplifying unit(28) amplifying an IF signal from the second mixer(26).

Description

Tuner

1 is a diagram showing the configuration of a general tuner.

2 is a block diagram of a tuner according to an embodiment of the present invention.

3 is a diagram showing a general configuration of the PLL circuit shown in FIG.

4 is a view showing an example of the first light unit shown in FIG.

5 is a view showing an example of the characteristic curve of the varactor diode shown in FIG.

* Explanation of symbols for main parts of the drawings

10: channel selector 12: controller

14: PLL circuit 16: broadband filter

18: wideband RF amplifier 20: the first mixer

22: first intermediate frequency amplifier 24: local oscillator

26: second mixer 28: second intermediate frequency amplifier

The present invention relates to a tuner, and more particularly, to an improved tuner that is common to the UHF / VHF frequency band and that excludes signal interference between the frequency bands.

In general, a tuner that selects a radio wave of a desired channel from the radio waves captured by the antenna, converts the radio wave into an intermediate frequency (hereinafter referred to as IF) signal, and then outputs the tuner as shown in FIG. The VHF filter (1a) and the UHF filter (1b) for separating and filtering the RF signal received by the VHF band and UHF band separately, and the VHF RF signal and UHF RF signal for filtering separately An amplifier 2 comprising a VHF RF amplifier 2a and a UHF RF amplifier 2b which amplifies a signal with a gain of about 10 dB and a low NF characteristic, and the VHF RF amplifier of the amplifier 2 ( The amplified signal from the UHF RF amplifier 2b of the first mixer 5 which outputs the IF signal by mixing the amplified signal from 2a) with the reference oscillation frequency output from the local oscillator 3 for VHF and outputting the IF signal. IF signal by mixing the reference oscillation frequency output from the local oscillator 4 And a second mixer 6 for outputting the? And an IF amplifier 7 for amplifying the IF signal output from the second mixer 6.

According to the above configuration, the frequency of the corresponding channel by the user's channel selection among the frequency of the VHF band (for example, 30 ~ 300MHz) and the UHF band (for example 300 ~ 3000MHz) received by the antenna (A) VHF filter Filtered through 1a or UHF filter 1b. At this time, when the channel of the VHF band is selected, the frequency output from the VHF filter 1a is amplified by the VHF RF amplifier 2a and then applied to the first mixer 5, and the first mixer 5 is VHF. The IF signal is output by mixing the reference local oscillation frequency output from the local oscillator 3 and the RF signal amplified by the VHF RF amplifier 2a, and the IF signal through the second mixer 6 is an IF amplifier ( In 7), it is amplified and output as the shortest signal of IF.

When the channel of the UHF band is selected, the frequency output from the UHF filter 1b is amplified by the UHF RF amplifier 2b and then applied to the second mixer 6 after being amplified by the UHF filter 1b. The second mixer 6 mixes the reference local oscillation frequency output from the UHF local oscillator 4 and the RF signal amplified by the UHF RF amplifier 2b and outputs an IF signal. That is, the IF signal) is amplified and output from the IF amplifier 7 to the very short signal of the IF.

However, in the conventional tuner configuration as described above, the band pass filter, the RF amplifier and the mixer are separated into the VHF / UHF bands, respectively, and output the signal by filtering, amplifying, and mixing the signals, respectively. Signal interference between the highest frequency band and the lowest frequency band of the UHF), which not only generates noise but also causes deterioration such as image quality.

Accordingly, the present invention has been made in view of the above circumstances, and an object thereof is to provide a tuner that simplifies the circuit configuration inside the tuner while eliminating signal interference and noise phenomenon by using a broadband filter and a wideband RF amplifier.

In order to achieve the above object, a tutor according to an embodiment of the present invention includes a channel selection unit capable of channel selection by a user, and outputting a predetermined oscillation frequency under the control of a control unit as an arbitrary channel is selected. A television with a PLL circuit, comprising: a wideband filter for filtering only a predetermined television broadcast frequency band, a wideband RF amplifier for amplifying a predetermined RF signal from the wideband filter, and a channel selected by the channel selector under the control of the control unit. A first mixer for applying a corresponding resonance frequency to the wideband filter and the wideband RF amplifier, a first mixer for mixing an output signal from the wideband amplifier and an oscillation frequency from the PLL circuit, A second cavity for generating a predetermined variable resonant frequency under control to match output tuning of the wideband RF amplifier; Part, by the first mixer, and, the prescribed value amplifies the IF signal from the second mixer is configured to further include a second intermediate frequency amplifying unit for applying to the IF stage.

According to a preferred embodiment of the present invention, the first and second tuning portions comprise a plurality of varactor diodes.

Preferably, the first tuning unit is further provided with a trap circuit for blocking the frequency band of the radio broadcast signal in order to pass only the frequency band of a predetermined television broadcast signal in the broadband filter.

According to the present invention configured as described above, according to the user's channel selection, the frequency signal of the corresponding channel is filtered by the wideband filter through the antenna, and then the RF signal amplified by the wideband RF amplifier is combined with the oscillation frequency from the PLL circuit. The IF signal mixed in the mixer and amplified by the first intermediate frequency amplifier by a predetermined value is mixed in the second mixer together with the reference oscillation frequency from the local oscillator and applied as an ultrashort signal of the IF stage through the second intermediate frequency amplifier.

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

2 is a block diagram of a tuner according to an embodiment of the present invention, where reference numeral 10 is a channel selection unit having a special selection key so that a user can select a desired television broadcasting channel, and 12 is a channel selection unit. A control unit for controlling the frequency signal of the channel in accordance with the channel selection signal output from the unit 10, 14 is a phase locked loop (PLL) for outputting a predetermined oscillation frequency under the control of the control unit 12 Loop) circuit. A reference oscillator 14a for oscillating a reference frequency, a voltage controlled oscillator 14b in which the oscillation frequency changes according to a control voltage (970 to 1810 MHz in the present invention), and the voltage controlled oscillator 14b under the control of the controller 12 The programmable divider 14c for dividing the oscillation frequency from the multiplier by a predetermined division ratio N, and the reference frequency generated by the reference oscillator 14a and the signal 1 / N of the programmable divider 14c are compared. A phase comparator 14d outputted as a control suppression of the voltage controlled oscillator 14b and a low pass filter for determining the synchronous or response characteristics of the PLL circuit as well as the effect of removing high frequency components of the control voltage output from the phase comparator. And a loop filter 14e.

Further, reference numeral 16 denotes a broadband filter for filtering only the corresponding television broadcasting frequency band among the television broadcasting signals received at the antenna A based on the variable resonance frequency from the first tuning unit 17, which will be described later. When the channel selector 10 selects a channel, the resonant frequency corresponding to the selected channel is output under the control of the controller 12 to enable the TV broadcasting frequency band filtering in the broadband filter 16. In addition, it is a first tuning section that uses the resonant frequency to match the input tuning of the wideband RF amplifier section 18 at the rear stage.

Here, an example of the first tuning unit 17 is composed of the selector diodes VD1 and VD2 so as to enable television broadcasting signal selection in the band 50 to 890 MHz, as shown in FIG. Coil L, resistor R and clamper 16a are additionally connected to block the frequency band (e.g., FM band) of the radio broadcast signal in band.

In addition, one of the characteristic curves of the selector diode VD1 is operable at V _{1 to} V ₂ as shown in FIG. 5 (a), so that the capacitance is 10 [pF] to 190 [pF]. It will have a value. In addition, an example of the characteristic of the varistor diode VD2 may be operated at V _{3 to} V ₄ as shown in FIG. 5 (b), and thus the capacitance is set to 3.587 [pF] to 4.375 [pF]. Have.

In addition, when the selector diode VD1 is in operation, the selector diode VD2 has a predetermined value of 3.587 [pF] to 4.375 [pF], and when the selector diode VD2 is operating, The selector diode VD1 has a certain value of 10 [pF] to 190 [pF].

The reference subfield 18 is a wideband RF amplifier for amplifying the RF signal from the wideband filter 16 to a predetermined level (for example, gain of 18 dB, NF 3 dB or less in the wideband filter). Amplifonix Co., Ltd. model name AX0686. Reference numeral 19 denotes a second tuning unit for generating a predetermined variable resonant frequency under the control of the control unit 12 so as to match the output tuning in the wideband RF amplifier 18. 19), it is preferable that the second tuning portion is composed of a varistor diode.

On the other hand, reference numeral 20 is a combination of the RF signal output from the wideband RF amplifier 18 and the oscillation frequency output from the low-voltage control oscillator 14b of the PLL circuit 14 by mixing a predetermined IF signal (that is, 920MHz Signal) is a first mixer 20, 22 is a first intermediate frequency amplifier for amplifying the IF signal output from the first mixer 20, 24 is a predetermined reference oscillation frequency (e.g., about 876MHz) It is a local oscillator that oscillates.

Reference numeral 26 denotes a first IF unit (i.e., a 44 MHz signal) by mixing a frequency signal output from the first intermediate frequency amplifier section 22 and a reference oscillation frequency oscillated by the local oscillator 24 to convert a predetermined IF signal (ie, a signal of 44 MHz). The second intermediate frequency amplifier outputs a signal.

Referring to the channel tuning operation by the tuner according to an embodiment of the present invention configured as described above are as follows.

In FIG. 2, once a user turns on a television and then tunes in a desired channel, for example, the user may select channel 1 (e.g., the frequency band corresponding to channel 1 in the inventive signal is 50 MHz ±). When [alpha] ([alpha]: allowable error frequency)] is selected, the channel tuning signal is applied from the channel selector 10 to the controller 12. Accordingly, the control unit 12 controls the first tuning unit 17 and the second tuning unit 19 as well as the PLL circuit 14.

Thus, the first tuning unit 17 issues a resonance frequency corresponding to 50 MHz ± α by the selector diodes VD1 and VD2, whereby the broadband filter 16 receives the television received at the antenna A. In the broadcast signal, only the frequency band corresponding to 50 MHz ± α is filtered. Subsequently, in the wideband RF amplifier 18 in which the input tuning is adjusted by the first tuning unit 17, the RF signal (that is, the signal corresponding to channel 1) is amplified and the second tuning unit 19 is amplified. The amplified RF signal is applied to the first mixer 20 in the state where the output tuning is adjusted.

At the same time, a predetermined frequency is applied from the PLL circuit 14 to the first mixer 20. When the reference frequency generated by the reference oscillator 14a is 10 MHz, the control unit 12 of the programmable divider 14c The division ratio N is set to 97. Accordingly, the voltage controlled oscillator 14b generates a frequency of 970 MHz and outputs it to the first mixer 20. Subsequently, the first mixer 20 mixes a frequency of about 50 MHz and the frequency of 970 MHz applied by the wideband RF amplification ratio 18 to output a predetermined IF signal (ie, a signal of 920 MHz). The frequency of 920 MHz amplified by the intermediate frequency amplifier 22 is applied to the second mixer 26.

Accordingly, the second mixer 26 mixes a frequency of 920 MHz and a reference oscillation frequency (ie, 876 MHz) output from the local oscillator 24 to apply a predetermined IF signal (ie, a signal of 44 MHz). It is applied to the intermediate frequency amplifier 28. Thereafter, the second intermediate frequency amplifier 28 amplifies the IF signal (ie, a signal of 44 MHz) and outputs the ultra short signal in IF units.

On the other hand, when the user switches the channel currently being watched to the second (for example, the additional number band corresponding to channel 2 in the specification of the present invention is set to 600MHz ± α) the channel selection signal is selected by the channel selector 10 Is applied from the control unit 12 to the control unit 12. Accordingly, the controller 912 controls the PLL circuit 14 as well as the first and second tuning units 17 and 19.

Subsequently, an operation similar to the channel 1 channel selection operation is performed. The broadband filter 16 transmits a signal corresponding to 600 MHz ± α by the first tuning unit 17 to the first mixer 20. Is approved.

At the same time, a predetermined frequency is applied from the PLL circuit 14 to the first mixer 20. When the reference frequency generated by the reference oscillator 14a is 10 MHz as in the channel 1 tuning operation, the controller Numeral 12 sets the division ratio N of the programmable divider 14c to 98. Accordingly, the voltage controlled oscillator 14b generates a frequency of 980 MHz and outputs it to the first mixer 20. Then, similar to the channel 1 channel operation, the first mixer 20 outputs a predetermined IF signal (ie, a signal of 920 MHz), and the frequency of 920 MHz amplified by the first intermediate frequency amplifier 22 is The second mixer 26 is applied to the second mixer 26, and the second mixer 26 applies a predetermined IF signal (ie, a signal of 44 MHz) to the second intermediate frequency amplifier 28.

Accordingly, the second intermediate frequency amplifier 28 amplifies the IF signal (ie, a signal of 44 MHz) and outputs it as an ultra-short signal of the IF stage.

On the other hand, the tuner according to an embodiment of the present invention can be directly applied to the NTSC type tuner currently being implemented, and also applicable to HD-TV (High Definition Television), which is called Hi-Vision. Do.

As described above, according to the present invention, when the user selects a channel, the frequency signal of the corresponding channel is filtered by the broadband filter, and then the predetermined IF signal, which is subjected to a predetermined mixing and amplification process, is constantly output as the ultra-short signal of the IF stage. Compared to the conventional method using a plurality of filters and RF amplifiers, not only the circuit design is simpler but also the number of components is low, which leads to an advantage of low production cost.

In addition, the use of a single wideband filter eliminates signal interference and noise, thereby greatly improving the quality of the image.

Claims (3)

In a television having a channel selector 10 which enables channel selection by a user and a PLL circuit 14 for outputting a predetermined oscillation frequency under the control of the control unit 12 as an arbitrary channel is selected, A wideband filter 16 for filtering only television broadcast frequency bands; a wideband RF amplifier 18 for amplifying a predetermined RF signal from the wideband filter 16; and the channel selector under the control of the control unit 12. A first tuning unit 17 and the wideband RF amplifier 18 for applying a resonant frequency corresponding to the channel selected in step 10 to the wideband filter 16 and the wideband RF amplifier 18, respectively The first mixer 20 mixing the output signal from the PLL circuit 14 and the oscillation frequency from the PLL circuit 14 generates a predetermined variable resonant frequency under the control of the control unit 12 to generate the wideband RF amplifier 18. 2nd tuning unit to match the output tuning of 19), the first intermediate frequency amplifier 22 amplifying the mixed signal from the first mixer 20, the predetermined local oscillation frequency output from the local oscillator 24 and the first intermediate frequency amplifier ( A second mixer 26 for mixing the RF signal from 22) and a second intermediate frequency amplifier 28 for amplifying the IF signal from the second mixer 26 by a predetermined value and applying it to the IF stage. Tuner, characterized in that provided with. 2. Tuner according to claim 1, characterized in that the first and second tuning sections (17, 19) consist of a plurality of varactor diodes. The first tuning unit 17 is further provided with a trap circuit for blocking the frequency band of the radio broadcast signal in order to pass only the frequency band of the predetermined television broadcast signal in the broadband filter (1). Tuner, characterized in that configured.