KR910009317Y1 - Chroma noise removing circuit - Google Patents

Abstract

No content.

Description

Chroma Noise Reduction Circuit

1 is a conventional chroma noise removing circuit.

2 is a circuit diagram of the present invention.

3 is a circuit diagram of one embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

1: buffer stage 2: gain control unit

3: noise reduction circuit 4: control unit

5: micom 6: trap part

R1-R15: resistor Q1-Q5: transistor

L1: coil D1: diode

C1-C3: Capacitor

The present invention eliminates chroma noise included in the luminance signal of a large-sized television, and controls the flow of the luminance signal mixed with the chroma noise and the pure luminance signal from which the noise is removed by using a microcomputer to insert the noise of the luminance signal. The present invention relates to a chroma noise removing circuit capable of preventing loss.

Referring to FIG. 1, which is a conventional chroma noise removing circuit, the buffer stage 1 is configured such that the luminance signal Y input from the luminance signal input terminal is applied to the base of the transistor Q1 connected to the resistors R1-R4. The luminance signal Y output to the collector of the transistor Q1 of the buffer stage 1 is removed through the filter circuit 7 to remove chroma noise (3.58 MHz), and then connected to the emitter of the buffer transistor Q2. It is configured to be output from the signal output terminal (Yout).

However, regardless of the presence or absence of chroma noise included in the luminance signal (Y) input from the luminance signal input terminal, it is necessary to pass through the filter circuit 7 at all times, so that the loss and noise of the luminance signal (Y) may be inserted. .

In view of the above, the present invention recognizes the chroma noise signal included in the luminance signal, and then the input luminance signal is selectively passed through the chroma noise removing filter circuit according to the presence or absence of chroma noise. ) To prevent loss and noise insertion.

As such, the present invention passes the filter circuit only when the luminance signal including chroma noise is input, and does not pass through the filter circuit when the luminance signal including chroma noise is not included to prevent loss of luminance signal and noise insertion. According to the description in detail as follows.

2 is a circuit diagram of the present invention, and a gain adjusting unit 2 for adjusting the gain of the luminance signal buffered and amplified in the buffer stage 1, and selecting the flow of the gain-adjusted luminance signal in the gain adjusting unit 2 and chroma. A noise removing circuit 3 for removing noise and a control unit 4 for supplying a control signal for selecting a luminance signal flow in accordance with the control signal of the microcomputer 5 to the noise removing circuit 3.

The noise removing circuit 3 passes through the luminance signal applied by the gain adjusting unit 2 as it is, and is driven by the control signal of the control unit 4 and the transistor 03 applied by the gain adjusting unit 2. It consists of a trap part 6 which removes chroma noise contained in a luminance signal.

At this time, the driving of the trap part 6 of the noise removing circuit 3 may be configured to be selected by the control switch SW operated by the control signal of the control part 4. That is, according to the present invention, the luminance signal Y input from the luminance signal input terminal configures the buffer stage 1 to be buffered and amplified by the transistor Q1 connected to the resistors R1-R4, and the luminance passed through the buffer stage 1 is obtained. The signal Y is configured by the gain adjusting unit 2 so that the gain is adjusted by the transistor Q2 connected to the variable resistor R5, and the noise removing circuit 3 is connected through the resistor R7 of the gain adjusting unit 2. ), The luminance signal is input.

Then, the control signal (high level, roll level) of the microcomputer 5 controls the transistor Q5 of the control unit 4 composed of the resistors R14, R15 and the diode D1, thereby removing the noise. It is configured to control the driving of.

In this case, the luminance signal Y applied to the noise removing circuit 3 is output through the transistor Q3 and the buffer transistor Q4 controlled by the microcomputer 5 applied through the controller 4. After the chroma noise (3.58 MHz) is removed from the trap part 6 composed of the resistors R9-R11, the capacitors C1, the C2, the coil L1, and the variable resistor R12, only the luminance signal Y The noise removing circuit 3 is configured to be output through the luminance signal output terminal Yout of the buffer transistor Q4.

That is, when the low level signal is applied from the microcomputer 5, the transistors Q3 and Q5 are " turned off " so that the luminance signal Y applied to the noise removing circuit 3 is luminance through the trap unit 6. After removing the chroma noise (3.58MHz) included in the signal (Y) is output through the transistor (Q4), when the high level is applied from the microcomputer 5, transistors (Q3), (Q5) 'turn on' to remove the noise The luminance signal Y applied to the circuit 3 is output directly through the transistors Q3 and Q4 without passing through the trap section 6.

At this time, if the chroma signal is included in the luminance signal, the microcomputer 5 detects it and outputs the low level. If the chroma signal is not included in the luminance signal, the microcomputer 5 detects it and outputs the high level.

3 is a circuit diagram of an embodiment of the present invention to control the driving of the control switch SW to the output of the control unit 4 controlled by the microcomputer 5 so that the luminance signal Y passes through the trap unit 6 or Or it is configured not to pass.

In other words, while the driving of the transistor Q3 is controlled by the coat roll section 4 in this paper, the switching of the control switch SW is controlled in one embodiment.

Such an effect of the present invention is as follows.

The luminance signal Y, which is applied at the luminance signal input terminal and buffer-amplified in the transistor Q1 to which the bias resistors R1 to R4 are connected, varies the resistance value of the variable resistor R5 connected to the emitter of the transistor Q1. The gain is adjusted accordingly and output to the collector of transistor Q2, and then to the node point A connected to the emitter of transistor Q3 of the noise canceling circuit 3 and the resistor R9 of the trap section 6. Is approved.

In this case, when chroma noise is included in the luminance signal applied to the luminance signal input terminal, the microcomputer 5 detects this and outputs a low level. In this case, when the lower level is output from the microcomputer 5, the bias resistor R14 is output. , The low level signal of the microcomputer 5 is applied to the base of the transistor Q5 of the control unit 4 through R15, so that the transistor Q5 is 'turned off' and the transistor 'Q5' is turned off. Since the transistor Q3 connected to the low diode D1 is 'turned off', the luminance signal Y input from the luminance signal input terminal through the buffer stage 1 is a node to which the transistor Q3 and the trap section 6 are connected. The luminance signal Y is applied to the base of the transistor Q4 through the trap part 6, which is applied to the point A, and then the characteristic of the filter is adjusted by the variable resistor R12, to the collector of the buffer transistor Q4. Is output and the luminance applied to the node point A in the operation Chroma noise (3.58㎒) included in the call (Y) is so removed are trapped in the trap portion 6, the luminance signal (Y) only to be output via the transistor (Q4) for the buffer.

That is, when the chroma signal (3.58MHz) is included in the luminance signal, the microcomputer 5 outputs a low level, so that the transistor Q5 of the controller 4 is turned off and the transistor of the noise removing circuit 3 is turned off. Since Q3 is 'turned off', the luminance signal applied through the buffer stage 1 is adjusted by the gain adjusting unit 2, and after the chroma unit of 3.58 MHz is removed through the trap unit 6, the transistor ( Through Q4), a luminance signal from which chroma noise has been removed is output.

However, when the chroma signal is not included in the luminance signal applied to the luminance signal input terminal, the microcomputer 5 detects it and outputs a high level. Therefore, the resistor R14 is applied to the base of the transistor Q5 of the controller 4. When the high level signal of the microcomputer 5 is applied through R15, the transistor Q5 is 'turned on' and a low level is also applied to the transistor Q3 through the diode D1 to turn on the transistor Q3. Thus, the luminance signal Y applied to the node point A is applied directly through the emitter and the collector of the transistor Q3 to the base of the buffer transistor Q4 without passing through the trap section 6 and then to the transistor ( By outputting to the emitter of Q4), even when chroma noise is not included in the luminance signal, the trap portion 6 is passed through to prevent the loss of the luminance signal or the insertion of noise.

Therefore, when the chroma signal (3.58 MHz) is included in the luminance signal Y applied to the node point A, the microcomputer 5 outputs a low level signal to turn off the transistors Q3 and Q5. Thus, the luminance signal Y applied to the node point A removes the chroma noise (3.58 MHz) included in the luminance signal Y by the trap unit 6 and then outputs the luminance signal output terminal through the transistor Q4 ( If the luminance signal is not included in chroma signal (3.58MHz), the microcomputer 5 outputs a high level signal to 'turn off' the transistors Q3 and Q5. The luminance signal Y applied to the node point A is immediately output from the luminance signal output terminal Yout connected to the emitter of the transistor Q4 via the collector and the emitter of the transistor Q3. Control signal output from the microcomputer 5 according to the presence of noise (high level, To control the flow of the luminance signal by the right level).

Therefore, the flow of the luminance signal Y is selected according to the signal state of the luminance signal Y recognized by the microcomputer 5 (that is, whether or not there is chroma noise (3.58 MHz)). By preventing loss or noise insertion, only the pure luminance signal is output to the luminance signal output terminal Yout.

3 is an embodiment of the present invention, the gain adjusting unit 2 and the trap unit 6 so that the control switch (SW) can be selected without selecting the flow of the luminance signal using the above-described transistor (Q3). The control switch SW is connected between the selector terminals ② when the high level is applied from the control unit 4 and the selector terminal ① when the low level is applied.

Therefore, when the roll level is applied from the microcomputer 5, the low level signal of the microcomputer 5 'turns off' the transistor Q5 of the control unit 4 through the resistors R14 and R15. The luminance signal (Y) applied to the node (A) by being applied to the control switch (SW) and connected to the selector terminal (②) is included in the luminance signal (Y) through the trap part (6). After the chroma noise (3.58 MHz) is removed, the luminance signal Y from which the chroma noise is removed is output through the buffer transistor Q4.

However, when the microcomputer 5 outputs a high level, the transistor Q5 of the control unit 4 is 'turned on' so that a lower level is applied to the control switch SW, so that it is connected to the control switch SW selector terminal ①. Therefore, the luminance signal Y applied to the node point A is output to the signal output terminal Yout through the resistor R6 and through the buffer transistor Q4 without passing through the trap section 6.

In other words, when the high level is applied from the control unit 4, the control switch SW is connected to the selector terminal ②, and when the roll level is applied to the selector terminal ①, the luminance signal passes through the trap unit 6. The control unit 4 is controlled by the control unit 4 and the control unit 4 is controlled by the microcomputer 5 so that the control switch SW is switched to the microcomputer 5 so that the luminance signal passes through the trap unit 6. You will control what you do.

As described above, according to the present invention, when the luminance signal Y input from the luminance signal input terminal 1 is applied to the noise removing circuit 3 through the buffer stage 1 and the gain adjusting unit 2, the luminance is reduced in the microcomputer 5. Outputs a control signal according to the state of the signal (i.e., whether or not the luminance signal has chroma noise (3. 58MHz)) (when there is no chroma noise: high level output, the luminance signal (Y) contains chroma noise) Case: roll level output] to output the luminance signal through the trap unit 6 only when there is chroma noise, thereby controlling the flow of the luminance signal including chroma noise and the luminance signal without chroma noise. By controlling the signal, the luminance signal is lost and noise can be prevented from being inserted.

Claims (3)

A gain controller 2 for adjusting the gain of the luminance signal buffered and amplified in the buffer stage 1, and a noise removing circuit for removing chroma noise by selecting a flow of the luminance signal gain-adjusted in the gain controller 2; 3) and a control unit (4) which selects the luminance signal flow of the noise removing circuit (3) and is driven by the control signal of the microcomputer (5). The noise canceling circuit (3) according to claim 1, comprising a resistor (R9-R11), capacitors (C1), (C2), coils (L1), and variable resistors (R12). To the output side of the gain control section 2 and to the transistor Q3 in which the drive is selected by the output of the control section 4 in parallel to the trap section 6. Chroma Noise Reduction Circuit. The noise canceling circuit (3) according to claim 1 or 2, wherein the noise canceling circuit (3) is switched by the output of the control section (4) and has a control switch (SW) for selecting passage of the trap section (6) of the luminance signal. A chroma noise elimination circuit formed by connecting between 2) and the trap part 6.