KR950001646Y1 - Tuning circuit for video if signal - Google Patents

Abstract

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Description

Video Intermediate Frequency Signal Tuning Circuit

1 is a circuit diagram of an embodiment according to the present invention.

* Explanation of symbols for main parts of the drawings

10: tuner portion 20: video intermediate frequency amplifier portion

30: first reference voltage setting unit 40: second reference voltage setting unit

50: third reference voltage setting unit 60: micom

The present invention relates to an image intermediate frequency signal tuning circuit in a heterodyne imaging device. In particular, an image intermediate frequency signal tuning is performed to automatically tune the image intermediate frequency signal by automatically controlling the oscillation frequency of the local oscillation circuit. It is about inquiry.

In general, a heterodyne type video apparatus has a variable oscillator capable of precisely adjusting the frequency inside a receiver to mix the output of the received signal with the oscillator, converts the received signal into a viewable frequency, and demodulates the output. This is a typical example. A television receiver is provided with a local oscillation circuit using a variable oscillator, and sets a local oscillation frequency for each reception channel. Fine tuning of the local oscillation frequency must always be performed accurately in order to watch an accurate reproduction picture.

Therefore, in the related art, a control voltage is applied to a variable capacitance diode in a local oscillator circuit of a tuner to automatically tune an image intermediate frequency signal by automatically fine tuning to a corresponding local oscillation frequency. That is, when the image intermediate frequency signal applied through the aerial is heavy and is mixed with the local oscillation frequency corresponding to the reception channel and outputted, if the local oscillation frequency deviates from the corresponding value, the image intermediate frequency becomes the prescribed value (generally NTSC method). Case is 45.75 MHz). This deviation is detected by phase detection (PWM (Pulse Width Modulation) detection) through a comparison circuit and a microcomputer, and the detection output (DC output voltage) is applied to the variable capacitance diode of the local oscillator circuit of the tuner as a control voltage. Automatically fine-tuning the value to tune the image intermediate frequency. However, there is a problem in that the range of the tuning adjustment is limited because the reference voltage of the comparison circuit is fixed during phase detection and the control voltage applied to the variable capacitance diode is limited.

Therefore, the purpose of the present invention is to superimpose the local intermediate voltage amplifier circuit of different power supply and the AFC (Auto Frequency Control (or Fine) Control) reference voltage of Micom for heterodyne imaging equipment. The AFC reference voltage of the oscillator circuit is constantly controlled so that the local oscillation frequency of the corresponding channel can be accurately generated to provide an image intermediate frequency signal tuning circuit for accurately tuning the image intermediate frequency signal.

In order to achieve the above object, the present invention is composed of a high frequency amplification circuit, a local oscillation circuit and a mixing circuit, and a tuner unit for tuning and outputting an image intermediate frequency signal introduced through an aerial to a local oscillation frequency of a corresponding channel, and an image intermediate frequency. An image intermediate frequency signal tuning circuit of an imaging apparatus having an amplifier and a microcomputer having a supply power different from that of the tuner unit and the image intermediate frequency amplifier 20; A first reference voltage setting unit for setting a reference voltage of the automatic frequency control signal output from the image intermediate frequency amplifier; A second reference voltage setting unit for setting a reference voltage of the AFC signal of the microcomputer according to the voltage value obtained by dividing the reference voltage set by the first reference voltage setting unit; The AFC reference voltage set in the first reference voltage setting unit and the AFC reference voltage set in the second reference voltage setting unit are superimposed according to the control of the microcomputer, so that the local oscillation frequency generated in the local oscillation circuit is always tuned. And a third reference voltage setting unit for setting a reference voltage of the AFC signal of the tuner unit to be a frequency.

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

1 is a circuit diagram of an embodiment of the present invention, and is an image intermediate frequency signal tuning circuit for an image signal introduced through an aerial line of a television receiver.

The configuration of FIG. 1 includes a tuner portion 10 composed of a high frequency amplification circuit (not illustrated) and a local oscillation circuit (not illustrated) and a mixing circuit (not illustrated) and a tuner portion 10. A first reference voltage setting unit connected to an input terminal of an output terminal connected to an output terminal of an output terminal, and having an input terminal connected to the other output terminal of the image intermediate frequency amplifier 20 30, between the microcomputer 60 having one output terminal connected to the VT (Voltage Tuning) input terminal of the tuner unit 10, between the output terminal of the first reference voltage setting unit 30 and the AFC input / output terminal of the microcomputer 60. Between the second atmospheric voltage setting unit 40 connected to the connection point A, and the connection point A at which the reference voltages set by the first and second reference voltage setting units 30 and 40 overlap, and the AFC input terminal of the tuner unit 10. And a third reference voltage setting section 50 connected to the third reference voltage setting section.

In particular, the first reference voltage setting unit 30 includes a ripple cancellation capacitor C1 and voltage divider resistors R1 and R2 to set the reference voltage of the AFC signal output from the image intermediate frequency amplifier 20. . The second reference voltage setting unit 40 includes a ripple removing capacitor C2 and voltage divider resistors R3 and R4 to set the reference voltage of the AFC signal of the microcomputer 60. The third reference voltage setting unit 5 overlaps the reference voltages set by the first reference voltage setting unit 30 and the second reference voltage setting unit 40 to set the reference voltage of the AFC signal of the tuner unit 10. It is composed of a courtesy resistor (R5), voltage divider (R6, R7) and a ripple removing capacitor (C2).

The operation of FIG. 1 is as follows.

First, when a local oscillation frequency is increased due to external influence or temperature drift of an image intermediate frequency signal introduced through an aerial line, the voltage of the intermediate frequency of the tuner unit 10 applied to the image intermediate frequency amplifier 20 is a reference voltage. Lower and higher frequency. Therefore, the voltage of the AFC output terminal of the image intermediate frequency amplifier 20 drops so that the reference voltage (about 6V) applied to the connection point B between the voltage divider resistors R1 and R2 of the first reference voltage setting unit 30 is reduced. Drop it. The first reference voltage setting unit 30 supplies the power supply V _DD of the image intermediate frequency amplifier 20. 12V) is divided by the voltage dividing resistors R1 and R2 through the high frequency component removing capacitor C4 and the smoothing capacitor C5. At this time, since the ratio of the divided resistors R1 and R2 is about 1: 1 ratio, the voltage applied to the connection point B becomes 6V as described above. However, as the voltage at the AFC output terminal of the image intermediate frequency amplifier 20 decreases, the voltage at the connection point B is influenced by the ripple cancellation capacitor C1, so that the voltage at the connection point B is reduced. The second reference voltage setting unit 40 is applied to the second reference voltage setting unit 40 with the lowered value. The applied voltage of the first reference voltage setting unit 30 is divided by the voltage dividing resistors R3 and R4 and applied to the AFC terminal of the microcomputer 60 through the ripple removing capacitor C3. At this time, since the voltage divided by the second reference voltage setting unit 40 is a value at which the voltage of the connection point A is lower than the AFC reference voltage, a voltage less than the AFC reference voltage (2.5V) of the microcomputer 60 is less than the microcomputer 60. Is applied to the AFC terminal.

Since the voltage applied to the AFC terminal of the microcomputer 60 is lower than the reference voltage (2.5V), the voltage is increased and adjusted to match the reference voltage to output the adjusted voltage through the AFC terminal and the VT (Voltage Tuning) terminal. . The voltage output from the AFC terminal is applied to the second reference voltage setting section 40 to convert the voltage of the contact point C between the voltage divider resistors R2 and R4 through the ripple removing capacitor C3 to the reference voltage (2.5V). The voltage at the connection point A is increased to 6V. On the other hand, the control voltage applied to the tuner unit 10 through the VT stage is applied to the local oscillation circuit so as to generate a local oscillation frequency of the corresponding channel by the voltage combining method.

On the other hand, the AFC reference voltage of the microcomputer compensated by the second reference voltage setting unit 40 under the control of the microcomputer 60 and the AFC terminal of the image intermediate frequency amplifier 20 of the first reference voltage setting unit 30 are controlled. The AFC reference voltage of the image intermediate frequency amplifier 20 set under the influence is superimposed through the connection point A and the overlapping resistor R5. The superimposed voltage is applied to the connection point A between the voltage divider resistors R6 and R7 and the voltage obtained by dividing the supply power supply V _CC by the voltage divider resistors R6 and R7 is applied by the voltage applied through the resistor R5. Since the voltage of the AFC terminal of the tuner unit 10 rises to the reference voltage (6V), the tuner unit 10 adjusts the image intermediate frequency signal by the control voltage applied to the VT and AFC terminals.

However, when the local oscillation frequency output from the local oscillation circuit is lower than the reference frequency, the voltage of the AFC terminal of the tuner unit 10 rises above the reference voltage, and thus the voltage of the AFC terminal of the image intermediate frequency amplifier 20 is also increased. As a result, the voltage at the connection point B of the first reference voltage setting unit 30 rises above the reference voltage of 6V.

Therefore, the voltage of the connection point B of the second reference voltage setting unit 40 also rises above the reference voltage (2.5V) of the microcomputer 60, so that the microcomputer 60 lowers the voltage of the connection point C to the reference voltage. Output control voltage to AFC terminal and VT terminal simultaneously.

The third reference voltage setting unit 50 lowers the voltage at the connection point D to the AFC reference voltage of the tuner by the voltage applied through the overlap resistor R5 to apply the AFC voltage of the tuner unit 10. After the application to the AFC terminal and the VT terminal is as described above.

As described above, the present invention accurately generates a local oscillation frequency by superimposing the AFC reference voltages of the image intermediate frequency amplifier 20 and the microcomputer 20 having a phase difference power supply in a television receiver which is a heterodyne type video device. As a result, there is an advantage in that the image intermediate frequency signal applied through the aerial can always output the image intermediate frequency signal that is tuned.

Claims (4)

The tuner unit 10 is composed of a high frequency amplification circuit, a local oscillation circuit, and a mixed circuit to tune and output an image intermediate frequency signal introduced through an aerial to a local oscillation frequency of a corresponding channel, and an image intermediate frequency amplifier 10. A video intermediate frequency signal tuning circuit of an imaging apparatus having a microcomputer (60) having a supply power different from that of the tuner unit (10) and the image intermediate frequency amplifier unit (20); A first reference voltage setting unit 30 for setting a reference voltage of an automatic frequency control (AFC) signal output from the image intermediate frequency amplifier 20; A second reference voltage setting unit 40 for setting a reference voltage of the AFC signal of the microcomputer 60 according to the voltage value obtained by dividing the reference voltage set by the first reference voltage setting unit 30; The local oscillation circuit is generated by overlapping the AFC reference voltage set by the first reference voltage setting unit 30 and the AFC reference voltage set by the second reference voltage setting unit 40 under the control of the microcomputer 60. And a third reference voltage setting unit 50 for setting a reference voltage of the AFC signal of the tuner unit 10 so that the local oscillation frequency is always the frequency of the tuned channel. As your inquiry. The method of claim 1, wherein the second reference voltage setting unit 40 maintains a constant AFC reference voltage applied from the first reference voltage setting unit 30 to the third reference voltage setting unit 50 at all times. A video intermediate frequency signal tuning circuit, characterized in that the AFC reference voltage of the microcomputer 60 is set. The microcomputer 60 of claim 2, wherein the divided microcomputer 60 receives the divided voltage of the reference voltage set by the first reference voltage setting unit 30 through the second reference voltage setting unit 40 to the AFC terminal. And the resultant signal is output as the oscillation frequency control voltage of the local oscillation circuit. The control circuit of claim 3, wherein the microcomputer 60 simultaneously outputs a control voltage output to the local oscillation circuit to voltage tuning stages of the second reference voltage setting unit 40 and the tuner unit 10. Image intermediate frequency signal tuning circuit, characterized in that the output box.