KR20000005820U - Digital broadcast tuner - Google Patents

Abstract

The present invention is a DC power supply tuner (B ⁺ ) and automatic gain control (AGC) voltage in the tuner for receiving digital broadcasts to form a trap using the diode's capacitive component and mutual inductance in order to improve the reduction of gain reduction on the high frequency side. The present invention relates to a tuner for digital broadcast reception that effectively improves the amount of gain reduction by effectively changing the position of the trap to the corresponding frequency according to the channel.

The tuner for digital broadcast reception of the present invention for realizing this includes an automatic gain control circuit unit which automatically adjusts gain so that the output of the video signal is always constant even if the magnitude of the high frequency signal induced by the antenna changes, and outside the tuner. A local oscillation circuit section for generating an oscillation frequency by a located microcom, a phase lock loop (PLL) section for controlling the operation of the local oscillation circuit section by a signal obtained by comparing the oscillation frequency and the reference frequency of the local oscillation circuit section; A first mixer circuit unit for mixing a high frequency signal input through the automatic gain control circuit unit and an oscillation frequency of the local oscillation circuit unit to output a new intermediate frequency, and data inputted from the phase lock loop unit to the corresponding channel. Receives the data for the automatic gain control circuit Provided with a negative DC supply voltage (B ⁺⁾ and a voltage control circuit for automatically controlling the gain select control (AGC) voltage is characterized in that is made.

Description

Digital broadcast tuner

The present invention relates to a tuner (TUNER) for receiving digital broadcasting, and more particularly, to form a trap using a capacitance component and mutual inductance of a diode in order to improve a decrease in gain reduction on the high frequency side. ^{The present} invention relates to a tuner for digital broadcast reception, which effectively changes the gain by shifting the position of the trap to the corresponding frequency according to the channel by effectively varying the voltage and the automatic gain control (AGC) voltage.

In general, a tuner is a device that selects only one desired channel from among a plurality of TV channels being broadcast, converts it into an intermediate frequency IF, and supplies the set to an image intermediate amplifier.

Hereinafter, a conventional general digital broadcast tuner will be briefly described.

A conventional digital satellite broadcasting tuner (not shown) includes an automatic gain control (AGC) circuit that automatically adjusts gain so that the output of a video signal is always constant even when the magnitude of the high frequency signal induced by the antenna changes. A high frequency amplifying circuit for amplifying a high frequency signal passing through the automatic gain control (AGC) circuit, a high frequency tuning circuit for selecting a desired high frequency signal from the amplified high frequency signal by the high frequency amplifying circuit, and a microcom (external to the tuner) A local oscillation circuit interlocked by a frequency synthesizer controlled by a frequency synthesizer to output an oscillation frequency, a PLL clock circuit generating a clock signal of a predetermined period, a reference frequency output from the PLL clock circuit, and a local oscillation circuit; Compare the oscillation frequency with and determine whether it is higher or lower than the reference frequency It is composed of PLL (Phase Locked Loop) IC which controls the oscillation frequency of the true circuit to be lowered and, if it is low, controls it to the higher side.

And a first mixer circuit for outputting an intermediate frequency by mixing the high frequency signal selected through the high frequency tuning circuit and the oscillation frequency of the local oscillation circuit, and a first intermediate frequency amplifier circuit for amplifying the intermediate frequency of the first mixer circuit. And an intermediate frequency filter for filtering the intermediate frequency amplified by the first intermediate frequency amplifier circuit, and a second intermediate frequency amplifier circuit for amplifying the intermediate frequency filtered through the intermediate frequency filter.

And an intermediate frequency oscillator circuit controlled by an AFT (Automatic Fine Tunning) signal outside the tuner to generate an oscillation frequency shifted in phases of 0 ° and 90 °, and an intermediate frequency amplified by the second intermediate frequency amplifier circuit. A second mixer circuit for mixing the 0 ° phase shifted oscillation frequency output from the intermediate frequency oscillator circuit and outputting a demodulated baseband signal I, the intermediate frequency amplified by the second intermediate frequency amplifier circuit and the intermediate frequency; And a third mixer circuit for outputting a demodulated baseband signal Q by mixing the 90 ° phase shifted oscillation frequency output from the frequency oscillation circuit.

1 is an automatic gain control circuit diagram of a conventional tuner, FIG. 2 is an equivalent circuit diagram of FIG. 1, and FIG. 3 is an output waveform diagram showing a relationship between a frequency and a gain according to the conventional automatic gain control circuit.

Referring to FIG. 1, an automatic gain control (AGC) circuit of a tuner according to the related art includes a capacitor C1 connected between an antenna and a node N1, and a node N1 and a DC power supply voltage B ⁺ . A coil L1 connected between an input terminal, a resistor R1 and a diode D1 and a patterned mutual inductance P1 connected in series between the node N1 and the node N4, and the node N4. And a capacitor C4 and C5 connected in parallel between the ground terminal Vss and the ground terminal Vss. And a capacitor C2 connected between the node N1 and the node N2, a diode D3 connected between the node N2 and the node N3, and an automatic gain control AGC voltage. A coil L2 connected between the node N2, a resistor R3 and a diode D2 and a patterned mutual inductance P2 connected in series between the node N3 and the node N5, and the node Resistor R2 connected between N4 and node N5, capacitors C6 and C7 connected in parallel between node N5 and ground terminal Vss, and node N2 and ground terminal. Resistors R4 and R5 connected in series between Vss, and a capacitor C3 connected between the node N3 and the output terminal out.

In the conventional automatic gain control circuit of the tuner having the above configuration, the impedance decreases as the frequency increases with X _c = 1 / (jwc) due to the capacitance component of the series diode, thereby reducing the gain reduction amount.

To compensate for this, the automatic gain control circuit of the conventional terrestrial digital TV tuner is composed of a trap circuit with mutual inductances P1 and P2 formed in a pattern of the diode's capacitive component CsD ₁ , and the parallel trap is placed on the high frequency side. The reduction was compensated for.

At this time, the DC power supply voltage B ⁺ gives a constant voltage and varies the automatic gain control (AGC) voltage from 0 to 9V to fix the trap on the high frequency side, thereby holding overall gain reduction characteristics.

That is, referring to the equivalent circuit illustrated in FIG. 2, when the automatic gain control (AGC) voltage is set to 0V and the DC power supply voltage B ⁺ is _changed , C _SD2 and C _SD3 are _changed to form a trap. At this time, after placing the trap point using DC power supply voltage (B ⁺ ) at the high frequency side, the automatic gain control (AGC) voltage is changed from 0 to 9V, so that the automatic gain control has a uniform gain reduction curve over the high frequency frequency (50 to 800 MHz). It was made to work.

In the waveform showing the relationship between the gain and the frequency of the conventional tuner (FIG. 3), it can be seen that the gain reduction amount of the 800 MHz side is much smaller than 50 MHz in the high frequency frequency of 50 to 800 MHz.

However, in the conventional digital broadcast reception tuner configured as described above, the trap due to the capacitance component of the diode and the patterned mutual inductance has a fixed DC power supply voltage (B ⁺ ) and an automatic gain control (AGC) voltage of 0 to 9V. By varying up to, a trap was always fixed on the high frequency side. Therefore, the gain reduction of the middle band and the low frequency side rather than the high frequency side was smaller than the high frequency side.

That is, there is a problem in that the variable capacitance component of C _SD1 due to the automatic gain control (AGC) voltage and the variable capacity components of C _SD2 and C _SD3 due to the DC power supply voltage (B ⁺ ) cannot be used.

Therefore, the present invention has been made to solve the above problems, and an object of the present invention is to provide a DC power supply voltage when forming a trap using a capacitance component and mutual inductance of a diode in order to improve a decrease in gain reduction on the high frequency side. B ⁺ ) and automatic gain control (AGC) voltage is effectively changed to provide a digital broadcast reception tuner that greatly improves the gain reduction by moving the position of this trap to the corresponding frequency according to the channel.

1 is an automatic gain control circuit diagram of a conventional tuner.

2 is an equivalent circuit diagram of FIG.

3 is an output waveform diagram showing a relationship between a frequency and a gain according to a conventional automatic gain control circuit.

4 is a block diagram showing a part of a tuner for receiving digital broadcasts according to the present invention;

5 is an output waveform diagram showing the relationship between the frequency and the gain of the automatic gain control circuit of the present invention.

* Explanation of symbols for the main parts of the drawings

10: automatic gain control circuit 20: first mixer circuit

30 local oscillation circuit 40 PLL

50: voltage control circuit

C1 to C7: capacitors D1 to D3: diodes

R1 to R5: resistors L1 to L2: coils

In order to achieve the above object, the digital broadcast reception tuner according to the present invention,

An automatic gain control circuit for automatically adjusting gain so that the output of the video signal is always constant even if the magnitude of the high frequency signal induced by the antenna changes;

A local oscillation circuit unit generating an oscillation frequency by a microcom located outside the tuner;

A phase lock loop (PLL) portion for controlling the operation of the local oscillation circuit portion by a signal obtained by comparing the oscillation frequency and the reference frequency of the local oscillation circuit portion;

A first mixer circuit unit for mixing a high frequency signal input through the automatic gain control circuit unit and an oscillation frequency of the local oscillation circuit unit to output a new intermediate frequency;

The data for the corresponding channel is received from the data input to the phase lock loop (PLL), and the DC power supply voltage (B ⁺ ) and the automatic gain control (AGC) voltage of the automatic gain control circuit are selected based on the received data. It is characterized by comprising a voltage control circuit for controlling.

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

In addition, in all the drawings for demonstrating an embodiment, the thing with the same function uses the same code | symbol, and the repeated description is abbreviate | omitted.

4 is a block diagram showing a part of a digital broadcast reception tuner according to the present invention, and FIG. 5 is an output waveform diagram showing the relationship between the frequency and the gain of the automatic gain control circuit of the present invention. Here, the curve a is a characteristic graph of gain versus frequency when the trap is placed on the high frequency side, and the curve b is a characteristic graph of gain vs. frequency when the trap is placed at the intermediate frequency.

In FIG. 4, reference numeral 10 denotes an automatic gain control (AGC) circuit, which automatically adjusts gain so that the output of the video signal is always constant even when the magnitude of the high frequency signal induced by the antenna changes.

Reference numeral 30 denotes a local oscillation circuit, which is interlocked by a frequency synthesizer controlled by a microcom (located outside of the tuner) and outputs an oscillation frequency.

Reference numeral 40 denotes a phase locked loop (PLL) circuit that compares the reference frequency output from a PLL clock circuit (not shown) with the oscillation frequency of the local oscillation circuit to determine whether it is higher or lower than the reference frequency. The oscillation frequency should be lowered, and in the lower case, it should be controlled upward to obtain the correct oscillation frequency.

Reference numeral 20 denotes a first mixer circuit that mixes the high frequency signal selected through the high frequency tuning circuit and the oscillation frequency of the local oscillation circuit to output a new intermediate frequency.

Between the automatic gain control circuit 10 and the first mixer circuit 20, a high frequency amplification circuit for amplifying a high frequency signal passed through the automatic gain control (AGC) circuit, and a high frequency signal amplified by the high frequency amplification circuit. Among them, a high frequency tuning circuit for selecting a desired high frequency signal is omitted.

Reference numeral 50 is a voltage control circuit, which receives data for a corresponding channel from data input to the PLL 40 and selects an appropriate DC power supply voltage (B ⁺ ) and an automatic gain control (AGC) voltage from the received data. By controlling, the capacitance component of each diode is varied and the gain frequency is adjusted by changing the trap frequency to the corresponding frequency.

In the figure, reference symbol a denotes a control signal for varying the DC power supply voltage B ⁺ , and reference symbol b denotes a control signal for varying the automatic gain control (AGC) voltage.

The present invention, unlike the conventional automatic gain control (AGC) circuit is provided with a voltage control circuit 50 that can vary the DC power supply voltage (B ⁺ ) and automatic gain control (AGC) voltage.

Then, the operation of the present invention by the above configuration will be briefly described.

First, the data input to the PLL 40 is input to the voltage control circuit 50 to vary the DC power supply voltage B ⁺ and the automatic gain control AGC voltage of the automatic gain control circuit 10 to correspond to the corresponding channel. Gain can be controlled by placing a trap at the frequency to increase the gain reduction.

In other words, the variable capacitance component of C _SD1 by the automatic gain control (AGC) voltage and the variable capacitance components of C _SD2 and C _SD3 by the DC power supply voltage (B ⁺ ) are appropriately used to correlate with the inductance value of the fixed mutual inductance. It is possible to move the frequency of the trap freely without

Therefore, the present invention can easily realize a wide range of automatic gain control (AGC) required by the terrestrial digital TV tuner, thereby reducing the two-step automatic gain control (AGC) circuit to one stage and having a relatively constant voltage. There is an advantage that the gain reduction at each channel frequency can be increased than the automatic gain control circuit at the DC power supply voltage (B ⁺ ).

As described above, according to the tuner for digital broadcast reception according to the present invention, the DC power supply voltage (B) is used to form a trap using the capacitive component and the mutual inductance of the diode in order to improve the reduction of the gain reduction amount on the high frequency side. ⁺ ) And the automatic gain control (AGC) voltage can be effectively changed, and the position of the trap to the corresponding frequency according to the channel can be effectively improved the gain reduction amount.

In addition, preferred embodiments of the present invention are disclosed for the purpose of illustration, those skilled in the art will be possible to various modifications, changes, substitutions and additions through the spirit and scope of the present invention disclosed in the appended utility model registration claims.

Claims (1)

In the tuner for digital broadcast reception, An automatic gain control circuit for automatically adjusting gain so that the output of the video signal is always constant even if the magnitude of the high frequency signal induced by the antenna changes; A local oscillation circuit unit generating an oscillation frequency by a microcom located outside the tuner; A phase lock loop (PLL) portion for controlling the operation of the local oscillation circuit portion by a signal obtained by comparing the oscillation frequency and the reference frequency of the local oscillation circuit portion; A first mixer circuit unit for mixing a high frequency signal input through the automatic gain control circuit unit and an oscillation frequency of the local oscillation circuit unit to output a new intermediate frequency; The data for the corresponding channel is received from the data input to the phase lock loop (PLL), and the DC power supply voltage (B ⁺ ) and the automatic gain control (AGC) voltage of the automatic gain control circuit are selected based on the received data. Tuner for receiving digital broadcasting, characterized in that it comprises a voltage control circuit for controlling.