KR0132065Y1 - A noise removing circuit of monitor using a low pass filter - Google Patents

Abstract

The present invention relates to a noise reduction circuit of a monitor using a low pass filter, comprising: an output driver IC for amplifying a low voltage level RGB image signal to a constant voltage level, each RGB bias circuit amplified by the output driver IC, A low pass filter for removing a high frequency signal at each of the image output terminals connected between the output driver IC and the RGB bias circuit, and connecting a low pass filter for removing the high frequency signal to a bias power supply terminal of the output driver IC, This prevents the high frequency video signal from flowing back to the bias power supply stage, thereby completely eliminating unnecessary high frequency noise signals flowing through the power line, and also significantly blocks the increase of electromagnetic waves caused by the inflow of high frequency signals. It will also be significantly improved.

Description

Noise Reduction Circuit of Monitor Using Low Pass Filter

1 is a circuit diagram illustrating a conventional image output circuit,

2 is a circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: Preamplifier IC 2: Output Drive IC

3: low pass filter 4: cathode ray tube

5a-c: R.G.B bias circuit 6: Power supply stage

R1-R7: Resistor L1-L3: Coil

C1, C2: Capacitor L1-L3: Coil

The present invention relates to a noise reduction circuit of a monitor using a low pass filter. In particular, a low pass filter for removing a high frequency signal is connected to a bias power supply terminal of an output driver IC, whereby a high frequency image signal is applied to a bias power supply terminal. As it prevents the reverse flow, the present invention relates to a noise reduction circuit of a monitor using a low pass filter, which significantly blocks unnecessary high frequency noise signals flowing through the power line, thereby improving the functionality of the system.

In general, a monitor is provided with an image signal output terminal for amplifying an image signal and displaying the same on a CRT screen. The image signal output terminal is amplified by various operating voltages rather than amplifying the image signal with the same bias voltage. In addition, referring to FIG. 1, one of the image output circuits of such a monitor first amplifies an RGB image signal having a low voltage level, for example, about 0.7 [V], to a constant voltage level, for example, 4-5 [V]. A preamplifier IC 70, an output driver IC 70 that receives the RGB video signal amplified by the preamplifier IC 70 and amplifies it to a predetermined voltage level, for example, about 60-70 [V], and this output drive An RGB bias circuit 73a-c biases the video signal of each RGB amplified by the IC 70 to be transmitted to the cathode end of the monitor CRT.

A bias voltage of, for example, 12 [V] is connected to pin 22 of the preamplifier IC 70. In addition, port 1 of the output driver IC 71 to which a red (R) image signal is output through a resistor R1 and coils L1 and L2 is connected to pin 23 of the preamplifier IC 70. Pin 8 of the preamplifier IC 70 is connected to port 8 of the output driving IC 71 through which the green (G) image signal is output through the resistor R2 and the coils L3 and L4. Pin 18 of the preamplifier IC 70 is connected to port 6 of the output driver IC 71 through which the blue (B) image signal is output through the resistor R3 and the coils L5 and L6.

A pin 11 of the output driver IC 71 is connected to a power supply terminal 74 for supplying an operating voltage of each R.G.B bias circuit 73a-c, for example, a voltage of about 80 [V].

On the other hand, referring to the operation of the conventional image output circuit having the above configuration, first, the RGB output signal of a relatively low voltage level, for example, 0.7 [V] to pins 5, 8, 11 of the preamplifier IC 70. When inputted respectively, the RGB video signals inputted from the preamplifier IC 70 are amplified to a voltage level of, for example, 4-5 [V].

Then, the amplified RGB video signal is inputted to pins 1, 8, and 6 of the output driver IC 71, and accordingly, the output driver IC 71 outputs an output voltage level of 60-70 [V]. It is applied to each RGB bias circuit 73a-c. Then, this R.G.B bias circuit 73a-c applies an R.G.B video signal having a relatively high voltage level to the cathode end of the CRT 72. Therefore, the screen is displayed on the monitor screen by the video signal applied to this cathode end.

However, in the video output circuit of the conventional monitor as described above, a power supply line for supplying operating power through the video signal output terminal of the output driver IC 71, that is, the signal lines of the 3, 4, 10 ports and the 11 port is provided with a diode. Since it is directly connected through (D1-D3), a high frequency video signal flows back to the power line connected to port 11 through (D1-D3). Therefore, the power line inflow of the high frequency image signal is mixed with the noise signal in the power line to increase the electromagnetic wave emitted from the monitor, and also has the drawback that the function of the system is also degraded due to the noise.

In order to solve the above-mentioned shortcomings, the present invention is designed to connect a low-pass filter that removes a high frequency signal to a bias power supply terminal of an output driver IC, whereby a high frequency image signal is applied to the bias power supply stage. As it prevents backflow, it eliminates unnecessary high frequency noise signals flowing through the power line, and also blocks the increase of electromagnetic waves due to the inflow of high frequency signals. It is an object of the present invention to provide a noise canceling circuit.

The present invention for achieving the above object is an output driver IC for amplifying a low voltage level RGB video signal to a constant voltage level, and outputs the video signal of each RGB amplified by the output driver IC to the cathode end of the CRT. And a low pass filter for removing a high frequency signal at each of the image output terminals connected between the output driver IC and the RGB bias circuit.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

The circuit of the present invention includes a preamplifier IC 1 which amplifies an RGB video signal having a low voltage level, for example, about 0.7 [V], to a constant voltage level, for example, 4-5 [V], as shown in FIG. An output driver IC 2 that receives the RGB video signal amplified by the preamplifier IC 1 and amplifies it to a predetermined level, for example, about 60 to 70 [V], and a power input port of the output driver IC 1; And a low pass filter (3) connected between the video output port and the high frequency video signal to block the inflow of high frequency video signals, and the cathode of the cathode ray tube (4) of the monitor of the RGB video signals amplified by the output driver IC (2). And RGB bias circuits 5a-c to be output.

A bias voltage of, for example, 12 [V] is connected to pin 22 of the preamplifier IC 1. In addition, port 1 of the output driver IC 2 through which the red (R) image signal is output through the resistor R1 and the coils L1 and L2 is connected to pin 23 of the preamplifier IC 1. Pin 8 of the preamplifier IC 1 is connected to port 8 of the output driver IC 2 through which the green (G) image signal is output through the resistor R2 and the coils L3 and L4. Pin 6 of the preamplifier IC 1 is connected to port 6 of the output driver IC 2 through which the blue (B) image signal is output through the resistor R3 and the coils L5 and L6.

A power supply terminal 6 for supplying an operating voltage of each R.G.B bias circuit 5a-c, for example, about 80 [V], is connected to pin 11 of the output driver IC 2.

In addition, the anode terminal of the diode D1 of the red (R) bias circuit 5a to which the red (R4) video signal is output through the resistor R4 is connected to the third port of the output driver IC 2. The anode terminal of the diode (D2) of the green (G) bias circuit 56, through which the green (G) image signal is output, is connected to the port 10 of the output driver IC 2 through the resistor R5. The anode terminal of the diode D3 of the blue (B) bias circuit 5c, through which the blue (B) image signal is output, is connected to port 11 of the driving IC 2 through the resistor R6.

On the other hand, the low pass filter 3 is a resistor (R7) connected to a common point between the port 11 and the power supply terminal 6 of the output driver IC (2), and a capacitor connected in parallel to both ends of the resistor (R7), respectively It consists of (C1, C2).

One end of the capacitor C2 is connected to a connection point at which the cathode ends of the diodes D1-D3 of the R.G.B bias circuits 5a-c are commonly connected.

Next, the operation and effects of the present invention having the above configuration will be described.

First, when an RGB video signal having a relatively low voltage level, for example, 0.7 [V] conduction is input to pins 5, 8, and 11 of the preamplifier IC 70, the image of the RGB input from the preamplifier IC 1 is input. The signal is amplified to, for example, a voltage level of 4-5 [V] conduction.

Then, the amplified RGB video signal is inputted to pins 1, 8, and 6 of the output driver IC 2, and thus amplified again to the output voltage level by the output driver IC 2, for example, 60-70. Amplified into a video signal having [V] to be input to each of the RGB bias circuits 5a-c via resistors R4-R6.

Then, this R.G.B bias circuit 5a-c forms an R.G.B video signal at a relatively high voltage level and applies it to the casing end of the CRT 4. Therefore, the screen appears on the monitor screen by the video signal applied to this cathode end.

However, the high frequency video signals input to the RGB bias circuits 5a-c during the operation may flow through the diodes D1-D3 to the common line, and at port 11 of the output driver IC 2, respectively. Since the inflow to the power line is blocked by the connected low pass filter 3, the high frequency image signal cannot flow to the power line.

Therefore, since the high frequency video signal does not flow to the power line, noise due to the inflow of the high frequency signal is not generated.

As described above, the present invention connects a low pass filter that removes the high frequency signal to the bias power supply terminal of the output driver IC, thereby preventing the high frequency video signal from flowing backward to the bias power supply terminal. In addition to completely eliminating unnecessary high frequency noise signals flowing through the line, it also significantly blocks the increase of electromagnetic waves due to the influx of high frequency signals, thereby improving the functionality of the system.

Claims (1)

The output driver IC 2 and the R.G.B. In a video output circuit of a monitor provided with a bias circuit 5a-c, a low pass filter for removing a high frequency signal at each of the video output terminals connected between the output driver IC 2 and the RGB bias circuits 5a-c. And (3), wherein the noise reduction circuit of the monitor using a low pass filter.