KR100209946B1 - Impulse noise reduction circuit - Google Patents

Abstract

Discloses a video signal processing circuit that removes pulsed noise present in a video signal and restores lost video information. Wherein a pulse noise and a movement degree of the screen are detected by a pulse noise sensing unit and a motion sensing unit, respectively, from a video signal inputted through an input terminal, and a video signal inputted through the input terminal is a horizontal low- Pass filter and are delayed for a predetermined time by a delay unit, and the selector selects the horizontal direction and the horizontal direction from the horizontal low-pass filter based on the motion detection of the motion detection unit and the pulse noise detection of the pulse noise detection unit A video signal from the temporal low-pass filter, and a video signal from the delay unit.

Description

Pulse noise canceling circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video signal processing circuit, and more particularly, to a pulse noise removing circuit that removes pulse noise existing in a video signal and restores lost video information.

In image processing systems such as televisions or video tape recorders, one of the major problems is to reproduce clean images free of noise components.

In general, a screen image provided by a broadcasting station or a video tape production company is likely to incorporate unnecessary noise due to a video transmission channel or repeated copying. Also, noise can be introduced into the image information signal during operation of the image signal processing system.

Noise can also occur when the image source contains noise or when low-quality film is used in an image processing system. Moreover, the image is also affected by weak electromagnetic waves while receiving the television video signal.

Noise is generally classified into impulse noise and line noise. Again, the impulse noise is classified into white noise and black noise. These noise components may exist simultaneously in the video signal. Therefore, various measures must be taken into consideration in order to effectively reduce such noise components.

FIG. 1 shows a conventional pulse noise removing circuit. The pulse noise removing circuit includes a pulse noise sensing unit 110, a low pass filter 120, a delay unit 130, and a switch unit 140.

The pulse noise sensing unit 110 senses pulse noise from an input video signal and controls the switching operation of the switch unit 140 according to whether pulse noise is sensed or not.

The low-pass filter 120 filters the input video signal to remove the noise included in the video signal, and then outputs the noise-eliminated video signal to the first terminal 141 of the switch unit 140.

The delay unit 130 delays the input video signal by a predetermined time and outputs the delayed video signal to the second terminal 142 of the switch unit 140.

The switch unit 140 is connected to the first terminal 141 and the second terminal 142 from the low pass filter 120 or the delay unit 130 under the control of the pulse noise sensing unit 110 And selectively outputs the video signal.

When the pulse noise sensing unit 110 senses pulse noise from an input video signal, the pulse noise sensing unit 110 controls the switch unit 140 so that a video signal interpolated by the low-pass filter 120 is output And controls the switch unit 140 so that the video signal outputted from the delay unit 130 is outputted through the second terminal of the switch unit 140 when the pulse noise can not be detected from the video signal, do.

However, in the above configuration, when the pulse noise is detected from the video signal, the interpolated video signal is simply output using the low-pass filter, and there is a problem that the video signal is not accurately interpolated.

An object of the present invention is to provide a pulse noise removing circuit capable of removing pulse noise included in a video signal.

It is another object of the present invention to provide a pulse noise canceling circuit capable of detecting a motion of a video signal and interpolating a video signal according to the motion level of the detected video signal when the pulse noise is removed from the video signal.

1 is a diagram showing a conventional pulse noise removing circuit.

2 is a diagram illustrating a pulse noise canceling circuit according to an embodiment of the present invention.

FIG. 3 is a diagram showing an example of a pulse noise detecting unit of the pulse noise removing circuit of FIG. 2. FIG.

FIG. 4 is a diagram illustrating an example of a motion sensing unit of the pulse noise removing circuit of FIG. 2. FIG.

5 is a circuit configuration diagram showing an example of the horizontal direction low-pass filter in Fig.

6 is a circuit diagram showing an example of the temporal low-pass filter of FIG. DESCRIPTION OF THE REFERENCE NUMERALS

110, 200: Pulse noise sensing unit 120: Low pass filter

130: delay unit 140: switch

300: Motion detection unit 400: Horizontal direction low pass filter

500: Time direction low pass filter 600:

700: first switch unit 800: second switch unit

201: Input terminal 210: Signal generator

220: first comparator 310: dynamic correlation adaptation unit

320: Absolute Value Circuit,

330: size conversion unit 340: second comparator

400: horizontal low-pass filter 410: first 1-pixel delay

420: second 1-pixel delay 430: third summing unit

440: second 1/2 amplifier 450: fourth summing unit

500: time direction low pass filter (500) 510: second 525H delay device

520: fifth adder 530: third 1/2 amplifier

The pulse noise removing circuit according to the present invention for realizing the above objects comprises pulse noise detecting means for detecting a pulse noise from a video signal input through an input terminal and generating a pulse noise detection signal according to whether or not pulse noise is detected, A movement sensing means for sensing the degree of motion of the screen in accordance with the variation of the image information of the video signal input through the input terminal, comparing the degree of motion of the screen with a predetermined reference signal, Pass filter for time-domain low-pass filtering a video signal input through a horizontal low-pass filter input terminal for low-pass filtering an image signal input through the input terminal, Is delayed by a predetermined time, A first switching means for selectively outputting an output signal of the horizontal direction low pass filter and an output signal of the time direction low pass filter in accordance with a motion detection signal of the motion sensing means, And a second switch unit for selectively outputting a video signal output from the first switch unit and a video signal output from the delay unit according to a pulse noise detection signal generated by the noise detection unit.

According to the above configuration, when the pulse noise is removed from the video signal, the motion of the video signal is sensed and the video signal can be interpolated according to the motion of the sensed video signal.

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

2 is a block diagram showing a pulse noise removing circuit according to an embodiment of the present invention.

2, the pulse noise removing circuit includes a pulse noise sensing unit 200, a motion sensing unit 300, a horizontal low-pass filter 400, a temporal low-pass filter 500, a delay unit 600, (700), and a second switch unit (800).

The pulse noise sensing unit 200 senses whether or not a pulse noise is included in the video signal input through the input terminal 201 and outputs a switching operation of the second switch unit 260 according to whether the pulse noise is detected .

3 is a circuit diagram showing an example of the pulse noise sensing unit 200. As shown in FIG.

The pulse noise sensing unit 200 includes a signal generator 210 for processing a video signal input through the input terminal 201 and generating a reference signal and a comparison signal, And a first comparator 220 for comparing the reference signal and the comparison signal.

The signal generator 210 may include a first delay unit 211, a second delay unit 212, a first summer 213, a first 1/2 amplifier, (214), and a second summer (215).

The first delay 211 delays the input video signal by a predetermined time and outputs a first delayed video signal 2111 generated by a delay of the video signal. The first delayed video signal 2111 is output to the first comparator 220 as a reference signal. The second delay unit 212 delays the first delayed video signal 2111 generated by the first delay unit 211 by a predetermined time to generate a second delayed video signal 2121, 1 summation unit 213. [ The first summing unit 230 sums the second delayed video signal 2121 input from the second delay unit 212 and the video signal 2011 currently input through the input terminal 201, And outputs the generated summed video signal 2131 to the first 1/2 amplifier 214. The first summed video signal 2131 is input to the first half amplifier 214,

The first 1/2 amplification unit 214 amplifies the first summed video signal 2131 input from the first summing unit 213 by 1/2 and outputs the first 1/2 amplified video signal 2141 And provides the generated first 1/2 amplified video signal 2141 to the second summer 215. [ The second summer 215 adds an externally supplied alpha level signal to the first 1/2 amplified video signal 2141 input from the first 1/2 amplification unit 240 to generate a second summed video signal 2141. [ And outputs the generated second summed video signal to the first comparator 220 as a comparison signal. The first comparator 220 compares the level of the reference signal 2101 from the first delay 211 with the level of the comparison signal 2151 from the second summer 215, And supplies the result to the second switch unit 800 to control the switching operation of the second switch unit 800. [

3, the signal generator 210 of the pulse noise sensing unit 200 receives the video signal input through the input terminal 201 from the first delay unit 211, the second delay unit 211, A second delayed video signal 2121 delayed by a predetermined time is generated using the second delayed video signal 212 and the generated second delayed video signal 2121 is provided to the first summer 213. Then, the first summer 213 adds the second delayed video signal 2121 to the current video signal 2011 inputted through the input terminal 201 to adaptively adapt the video signal, The first summing video signal 2131, which is an adaptation signal, is supplied to the first 1/2 amplifier 214 to amplify the first summed video signal 2131, which is adapted for correlation, by 1/2. The first summed video signal 2131 half-amplified by the first 1/2 amplifier 214 is supplied to the second summer 215 as a first 1/2 amplified video signal 2141 Level signal is added to the first comparator 220 and is provided to the first comparator 220 as a comparison signal 2102. Accordingly, the comparison signal 2102 is provided to the first comparator 220 as a signal level corresponding to the level of the pulse noise of the video signal. The first comparator 220 compares the comparison signal 2102 with the reference signal 2101 from the first delay 210 so that the pulse noise included in the video signal input through the input terminal 201 And provides the comparison result to the second switch unit 800 to control the switching operation of the second switch unit 800. [

Referring to FIG. 2 again, the motion sensing unit 300 senses the degree of motion of the screen according to the variation of the image information of the image signal input through the input terminal 201, And controls the switching operation of the first switch unit 260 by providing the comparison result to the first switch unit 260. [

FIG. 4 is a circuit diagram showing an example of the motion sensing unit 300. Referring to FIG.

4, the motion sensing unit 300 includes a dynamic correlation adaptation unit 310, an absolute value circuit 320, a magnitude transformation unit 330, and a second comparator 340.

The dynamic correlation adaptation unit 310 includes a first 525H delay unit 311 and a subtractor 312 for dynamic correlation adaptation of the image signal. The first 525H delay 311 delays the video signal input from the input terminal 201 by one frame (frame 525H) and outputs the video signal 3111 delayed by one frame to the subtractor 312. The subtractor 312 subtracts the video signal inputted through the input terminal 201 from the video signal 3111 delayed by one frame inputted from the first 525H delay 311 and outputs the subtracted value 3101 To the absolute value circuit unit 320.

The absolute value circuit unit 320 may output the absolute value of the subtraction value 3101 from the subtracter 312 to the magnitude conversion unit 330. In response to the magnitude of the absolute value from the absolute value circuit unit 320, the magnitude conversion unit 330 converts the level of the motion detection signal 331 to zero, for example, as a motion detection signal 331 when the screen is a still image, The comparator 340 provides a maximum level value of 1 to the second comparator 340. Then, the second comparator 340 compares the motion detection signal 331 from the magnitude converter 330 with the level of the reference signal input from the outside, and outputs a predetermined control signal according to the comparison result to the first To the switch unit 700 to control the switch operation of the first switch unit 700.

Referring to FIG. 2 again, the horizontal low-pass filter 400 low-pass filters the image signal input through the input terminal 201 in the horizontal direction to remove the pulse noise included in the image signal. When a video signal including pulse noise passes through the horizontal low-pass filter 230, the pulse noise of the video signal is removed, and the pixels of the video signal lost by the pulse noise are interpolated And is output to the first switch input terminal S1 of the first switch unit 260. [

5 is a circuit diagram showing an example of the horizontal direction low-pass filter 400. In FIG. 5, the horizontal low-pass filter 400 includes a first 1-pixel delay 410, a second 1-pixel delay 420, a third summer 430, A fourth summing unit 440, and a fourth summing unit 450.

The first 1-pixel delay unit 410 delays the video signal 2010 input through the input terminal 201 for a time of one pixel and then outputs a 1-pixel delay video signal 411 corresponding to a 1-pixel delay Pixel delay 420 and the fourth summer 450, respectively. The second one-pixel delay unit 420 delays the one-pixel delayed video signal 411 generated by the first one-pixel delay unit 410 one pixel at a time to generate a two-pixel delayed video signal 421 And provides it to the third summer 430. The third summer 430 sums the video signal 421 delayed by two pixels input from the second one-pixel delay unit 420 and the video signal 2010 input through the input terminal 201, And provides the detected pulse noise component to the second half amplifier 440. The second half amplifier 440 detects the pulse noise component of the signal. The second 1/2 amplifier 440 half-amplifies the pulse noise component input from the third summer 430 and outputs it to the fourth summer 450. The fourth summer 450 sums the 1 pixel delay video signal from the first 1 pixel delay unit 410 and the pulse noise component signal from the second 1/2 amplifier 440, Pixel delayed video signal 411 from the 1-pixel delay 410 and outputs the video signal 4501 from which the pulse noise component has been removed to the first switch 700 of the first switch unit 700, And outputs it to the input terminal S1.

2, the temporal low-pass filter 500 low-pass-filters the video signal 2010 input through the input terminal 201 to remove pulse noise from the video signal and performs low-pass filtering And interpolates the lost pixels due to the pulse noise.

6 is a circuit diagram showing an example of the temporal low-pass filter 500. The temporal low-pass filter 500 includes a second 525H delay unit 510, a fifth summer 520, And a 3 1/2 amplifier 530. The second 525H delayer 510 delays the video signal 2010 inputted through the input terminal 201 by one frame and provides the video signal 5101 delayed by one frame to the fifth summer 520 do. The fifth summer 520 adds the video signal 5101 currently inputted through the input terminal 201 and the composite video signal 5201 delayed by one frame from the second 525H delay unit 520, And outputs the video signal 5201 from which the pulse noise has been removed to the third 1/2 amplifier 530. The third 1/2 amplifier 530 outputs the video signal 5201 having the pulse noise removed. The third 1/2 amplifier 530 amplifies the video signal from which the pulse noise is removed from the fifth summing unit 520 by 1/2 and outputs the amplified video signal to the second switch input terminal S2.

2, the delay unit 600 delays the video signal 2010 input from the input terminal 201 by a predetermined time, and then outputs the delayed video signal 601 to the second switch unit 800 And outputs it to the second switch input terminal S4. The first input terminal S1 and the second input terminal S2 of the first switch unit 700 are connected to the output terminal of the horizontal direction low pass filter 400 and the output terminal of the time direction low pass filter 500, And an output terminal thereof is connected to the first input terminal S3 of the second switch unit 800 and connected to the horizontal direction low pass filter 400 according to the switching control signal 341 of the movement sensing unit 300. [ Pass filter 500 and the output signal 4001 of the time-direction low-pass filter 500 to the first input terminal S2 of the second switch unit 800. [ The second switch unit 800 receives the image signal 701 input to the first input terminal S3 through the first switch unit 700 according to the pulse noise of the pulse noise sensing unit 200, And selectively outputs the delayed video signal 601 input from the delay unit 600 to the second input terminal S4.

Therefore, according to the above configuration, the pixel data of the pulse noise portion included in the video signal is detected without using a horizontal low-pass filter, and a horizontal low-pass filter or a temporal low-pass filter The pixel data lost by the pulse noise can be more faithfully interpolated.

As described above, the present invention can provide a pulse noise canceling circuit that can detect a motion of a video signal and interpolate a video signal according to the degree of motion of the detected video signal when removing pulse noise from the video signal .

Although the present invention has been described in detail by way of the above embodiments, the present invention is not limited thereto, but can be modified or improved within the ordinary knowledge of those skilled in the art.

Claims (10)

A pulse noise sensing means (200) for sensing a pulse noise from a video signal inputted through an input terminal, motion sensing means (200) for sensing a motion degree of the screen in accordance with a variation of video information of a video signal input through the input terminal 300) horizontal direction low-pass filtering means (400) for horizontally low-pass-filtering the video signal inputted through the input terminal, time direction low-pass filtering means for low-pass-filtering the video signal input through the input terminal The filtering means 500 includes a delay means 600 for outputting a delayed video signal by delaying a video signal inputted from the input terminal 201 by a predetermined time and a delay means 600 for detecting the motion of the motion sensing means 300 and the pulse noise sensing means Based on the pulse noise detection of the horizontal direction low pass filtering means 400 (700, 800) for selectively outputting a video signal from the temporal low-pass filtering means (500) and a video signal from the delay means (600) Pulse noise canceling circuit. The apparatus according to claim 1, wherein the pulse noise sensing means (200) comprises: a signal generating means (210) for processing a video signal to generate a reference signal and a comparison signal; And comparison means (220) for comparing the comparison signals with each other. [3] The apparatus of claim 2, wherein the signal generating means comprises: a first delay means for delaying an input video signal by a predetermined time; a second delay means for delaying a video signal delayed by the first delay means by a predetermined time; Means (212) for summing a current input video signal and a video signal delayed by said second delay means (212) to generate a reference signal; a first summing means (213) (214) for amplifying the amplified signal and outputting the amplified sum signal, and second summing means (215) for summing the amplified signal amplified by the amplifying means with a predetermined constant level signal The pulse noise canceling circuit comprising: 2. The apparatus of claim 1, wherein the motion sensing means (300) comprises dynamic correlation adaptation means (310) for dynamic correlation adaptation of the video signal, The absolute value circuit unit 320 includes a magnitude conversion unit 330 for generating a motion detection signal in response to a magnitude of an absolute value from the absolute value circuit unit 320 and a magnitude conversion unit 330 for receiving a motion detection signal from the magnitude conversion unit 330, And a second comparison means (340) for comparing the level of the reference signal with the level of the reference signal and outputting a predetermined control signal in accordance with the comparison result. The apparatus as claimed in claim 4, wherein the dynamic correlation adaptation means (310) comprises a first 525H delayer (401) for delaying an input video signal by one frame and a second 525H delayer And a subtracter (312) for subtracting the video signal inputted through the input terminal (201) from the subtracter (312). The horizontal low-pass filter (400) according to claim 1, wherein the horizontal low-pass filter (400) comprises a first 1-pixel retarder (410) for delaying a video signal inputted through the input terminal (201) A second one-pixel delay unit 420 for delaying the one-pixel delayed video signal by the delay unit 410 one pixel at a time, and a second one-pixel delay unit 420 for delaying the video signal delayed by two pixels by the second one- A second amplifier 440 for amplifying the sum signal generated by the summing of the third summer 430 and a second 1-pixel delay 440 for amplifying the sum signal generated by the summing of the third summer 430, And a fourth summer 450 for summing the 1 pixel delay video signal from the first amplifier 410 and the amplified signal from the second amplifier 440. The apparatus of claim 1, wherein the temporal low-pass filter (500) comprises: a second 525H delayer (510) for delaying a video signal input through the input terminal (201) by one frame; And a fifth adder 520 for adding a composite video signal delayed by one frame from the second 525H delay unit 520 and a third amplifier 520 for amplifying a video signal from the fifth adder 520. [ (530). ≪ / RTI > The apparatus as claimed in claim 1, wherein the selecting means (700, 800) comprises means for selecting a video signal from the horizontal low-pass filtering means (400) and a video signal from the temporal low- (700) for selectively outputting a video signal from the first selection means (500) and a video signal output from the first selection means (700) based on pulse noise sensing of the pulse noise sensing means And a second selection means (800) for selectively outputting a video signal output from the delay means (600). The apparatus as claimed in claim 8, wherein the first selecting means (700) selectively outputs a video signal output from the horizontal direction low pass filtering means (400) and a video signal outputted from the temporal low pass filtering means (500) And a first switch unit (700) for applying a pulse signal to the pulse signal. The display device according to claim 8, characterized in that the second selection means (800) comprises a second switch portion for selectively outputting the video signal output from the first selection means (700) and the video signal output from the delay means (600) 800). ≪ / RTI >