KR20030094772A - Apparatus for processing of image signal having noise reduction and sharpness enhancement function and method thereof - Google Patents

Abstract

PURPOSE: A video signal processing apparatus capable of definition improvement and noise processing, and the method for the same are provided to improve clearness of a realized signal while removing noise signals of a high frequency signals. CONSTITUTION: A signal division unit(310) divides an inputted video signal into a high frequency signal and a low frequency signal. A first coring unit(322) removes a high frequency component signal of noise signals existing in a first threshold range area related to the high frequency signal, and extracts a signal which is out of the first threshold range area to be output as a first high frequency signal. A first signal amplifying unit(324) amplifies the first high frequency signal at a predetermined rate to output a second high frequency signal. A second coring unit(334) removes a high frequency component signal of noise signals existing in a second threshold range area related to the signal output from the intermediate frequency extracting unit, and extracts a signal which is out of the second threshold range area to be output as a first intermediate frequency signal. A second signal amplifying unit(336) amplifies the first intermediate frequency signal at a predetermined rate to output a second intermediate frequency signal. A signal adder(340) adds the first and second high frequency signals, the low frequency signals and the second intermediate signal for generating a compensated video signal.

Description

Apparatus for processing of image signal having noise reduction and sharpness enhancement function and method

The present invention relates to an image signal processing apparatus and a method capable of processing noise while increasing sharpness, and more particularly, to improve the resolution of an image by removing a noise signal included in an input image signal and improving edge sharpness. The present invention relates to an image signal processing apparatus and an method for an edge enhancement capable of processing noise 8.

Cathode ray tubes (CRTs), which have been the mainstay of display devices, must have a certain distance between the electron gun and the fluorescent surface in order to deflect the electron beam with respect to the display area. Due to these characteristics, the CRT is relatively bulky and occupies a lot of weight compared to the screen size, and there is a limit to the planarization and enlargement of the screen.

In addition, due to the rapid development of science and the abundance of life, modern people are inclined to pursue high-quality, high-quality and large-scale display devices.

In order to overcome the demands of the modern man and the problems of the CRT, the newly emerged is a liquid crystal display (LCD), a plasma display panel (PDP), and a projection TV. Such display devices are thin, light, and have a large screen.

However, display devices such as PDPs and projection TVs frequently reproduce output video signals with reduced resolution due to noise, blurring, and signal bandwidth limitation of input video signals as the screen size increases. do. In particular, the noise signal included in the input video signal has become a major factor in reducing the overall sharpness, sharpness of outlines, etc. of the output video signal to be reproduced.

1 is a block diagram illustrating a conventional image signal processing apparatus for noise processing.

Referring to the drawings, the conventional video signal processing apparatus 100 includes a high pass filter (HPF) 110, a coring unit 120, a multiplication unit 130, and a signal delay unit 140. , An adder 150, and a clipping 160.

Signal processing of the image signal processing apparatus will be described with reference to FIGS. 2A through 2E.

2A shows a waveform of a signal input to the HPF 110. N1 and n2 in FIG. 2A are first and second noise signals having small amplitudes, and s denotes a normal signal. The HPF 110 filters the input signal and outputs a high frequency signal (HF) as shown in FIG. 2B.

The coring unit 120 prevents boost-up of the noise signals n1 and n2 included in the high frequency signal. The coring unit 120 outputs a high frequency signal having a component outside the preset threshold range (-T) to (+ T) with respect to the input signal, that is, the signal HF 'as shown in FIG. 2C. Referring to FIG. 2C, the high frequency components of the first and second noise signals n1 and n2 passing through the HPF 110 existing between the preset thresholds -T to + T are removed through the coring unit 120. .

The signal amplifier 130 multiplies the gain HF ′ output from the coring unit 120 by a gain having a positive value or a negative value and amplifies the signal HF as illustrated in FIG. 2D. The signal delay unit 140 outputs the input signal after a predetermined time delay. That is, the signal delay unit 140 simultaneously outputs the signal HF " The delayed input signal input_d is output. Here, the predetermined time delayed signal input_d is the same as the signal input to the HPF 110.

The adder 150 adds the signal HF "output from the multiplier 130 and the signal input_d output from the signal delay unit 140. The signal output from the adder 150 is illustrated in FIGS. Likewise, it has a waveform obtained by adding Figures 2A and 2D, and the clipping unit 160 adjusts the dynamic range of the signal output from the adder 150.

2A and 2E, the first and second noise signals n1 ′ and n2 ′ of FIG. 2E are the same as the first and second noise signals n1 and n2 of the input signal input of FIG. 2A. On the other hand, while the amplitude is normal, the normal signal is changed from s to s', thereby improving the sharpness.

The conventional video signal processing apparatus 100 prevents amplification of a noise signal having a small amplitude included in an input video signal and improves the sharpness of the video signal by increasing the amplitude of the normal signal.

However, the conventional video signal processing apparatus 100 is suitable for noise processing of an image signal containing less noise signal, and amplifies the noise signal in the case of a high frequency signal including a lot of noise signal or a lot of contour components, such as an RF image signal. If the signal is added to the original input signal, the signal is amplified and the noise signal is amplified. That is, there is a limit to improving the sharpness and resolution of the image implemented on the screen by only amplifying the noise signal.

An object of the present invention is to provide a video signal processing apparatus capable of noise processing that can improve the resolution of a video signal by increasing the sharpness of an edge while removing a noise signal included in an input video signal.

1 is a block diagram showing a conventional video signal processing apparatus;

2A to 2E are waveform diagrams of output signals of respective units for explaining a signal processing procedure of the image signal processing apparatus of FIG. 1;

3 is a block diagram showing an image signal processing apparatus according to an embodiment of the present invention;

4 is a block diagram illustrating a signal divider of an image signal processing apparatus according to another embodiment of the present invention;

FIG. 5 is a graph for describing a signal processing process of the coring unit of FIG. 3;

6A and 6B are block diagrams illustrating embodiments of the intermediate frequency extractor of FIG. 3, and

7A to 7G are waveform diagrams of output signals of respective units for explaining a signal processing procedure of the image signal processing apparatus of FIG. 3.

Description of the main parts of the drawing

300: image signal processing apparatus 310: signal splitter

320: high frequency processing unit 330: low frequency processing unit

340: signal adding unit 350: clipping unit

According to an aspect of the present invention, there is provided a video signal processing apparatus capable of processing noise, including: a signal splitter configured to divide an input video signal into a high frequency signal and a low frequency signal to output the divided signal; Removing a high frequency component signal of a noise signal existing in a first threshold range region set for the high frequency signal output from the signal splitter, extracting a signal outside the first threshold range region, and outputting the signal as a first high frequency signal A first coring portion; A first signal amplifier for amplifying the first high frequency signal at a predetermined rate and outputting a second high frequency signal; An intermediate frequency extracting unit extracting a signal corresponding to a predetermined reference frequency or more among the low frequency signals output from the signal dividing unit; Removing a high frequency component signal of a noise signal existing in a second threshold range region set for the signal output from the intermediate frequency extracting unit, extracting a signal outside the second threshold range region, and outputting the signal as a first intermediate frequency signal A second coring portion; A second signal amplifier configured to amplify the first intermediate frequency signal output from the second coring unit at a predetermined ratio and output a second intermediate frequency signal; And a signal adder configured to add the first high frequency signal, the second high frequency signal, the low frequency signal output from the signal divider, and the second intermediate frequency signal to generate a corrected image signal.

In more detail, the signal dividing unit may include: a first high pass filter configured to extract and output a signal having a frequency or higher set for the input signal; And a low pass filter for extracting and outputting a signal below a frequency set for the input signal.

And a first signal delay unit configured to delay the first high frequency signal output from the first coring unit by a predetermined time and output the delayed signal to the adder. The apparatus may further include a second signal delay unit configured to delay the low frequency signal output from the signal splitter for a predetermined time and output the delayed signal to the adder.

Preferably, the signal adding unit is configured to add the second high frequency signal output from the first signal amplifier and the second intermediate frequency signal output from the second signal amplifier to output a first compensation signal. 1 signal adder; And generating the corrected video signal by adding the first high frequency signal output from the first coring unit, the low frequency signal output from the signal splitting unit, and the first compensation signal output from the first signal adding unit. And a second signal adder.

And a clipping unit for adjusting a dynamic range of the corrected image signal output from the adder.

On the other hand, to solve the above technical problem, a video signal processing method capable of noise processing according to the present invention, the step of outputting the input video signal divided into a high frequency signal and a low frequency signal; Removing the high frequency component signal of the noise signal existing in the first threshold range region set for the high frequency signal output through the signal dividing step, extracting a signal outside the first threshold range region, and outputting a first high frequency signal step; Amplifying the output first high frequency signal at a predetermined rate and outputting a second high frequency signal; Extracting a signal corresponding to a predetermined reference frequency or more from the low frequency signals output from the signal splitter; The first intermediate frequency signal is removed by removing a high frequency component signal of a noise signal existing in a second threshold range region set for the signal corresponding to the extracted reference frequency or more, and extracting a signal outside the predetermined second threshold range region. Outputting to; Amplifying the output first intermediate frequency signal at a predetermined ratio and outputting a second intermediate frequency signal; And generating a corrected image signal by adding the first high frequency signal, the second high frequency signal, the low frequency signal output from the signal dividing step, and the second intermediate frequency signal.

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

3 is a block diagram illustrating an image signal processing apparatus according to an embodiment of the present invention.

Referring to the drawings, the image signal processing apparatus 300 includes a signal divider 310, a high frequency processor 320, a low frequency processor 330, a signal adder 340, and a clipping unit 350.

The signal dividing unit 310 divides and outputs an input video signal into a high frequency signal HF and a low frequency signal LF. The high frequency signal HF includes more noise signals and contour components of the image than the low frequency signal LF. Therefore, by dividing the input image signal (input) into a high frequency signal (HF) and a low frequency signal (LF) to perform a noise removing process suitable for the characteristics of each frequency it is possible to remove the noise signal more effectively.

The signal splitter 310 has a first high pass filter and a low pass filter. The first high pass filter extracts a signal above a frequency set for the input image signal and outputs only a high frequency signal HF. It is preferable to use a first 2D-HPF (High Pass Filter) 312 as the first high pass filter. The first 2D-HPF 312 extracts a high frequency component in the vertical direction and a high frequency component in the horizontal direction among the input image signals, and outputs the high frequency signal HF.

The first low pass filter extracts a signal less than a frequency set for the input image signal and outputs only the low frequency signal LF. It is preferable to use a first 2D-LPF (Low Pass Filter) 314 as the first low pass filter. The first 2D-LPF 314 extracts the low frequency component in the vertical direction and the low frequency component in the horizontal direction from the input image signal input, and outputs the low frequency signal LF.

In addition, the signal dividing unit 310 may include a second 2D-LPF 310a and a subtracting unit 310b as shown in FIG. 4. In FIG. 4, the second 2D-LPF 310a extracts a signal less than the frequency set for the input image signal input and outputs only the low frequency signal LF. The subtraction unit 310b subtracts the low frequency signal LF from the input signal input to output the high frequency signal HF.

The high frequency processor 320 processes a high frequency signal including many contour components and noise signals. The high frequency processor 320 includes a first coring unit 322, a first signal amplifier 324, and a first signal delay unit 326.

The first coring unit 322 removes the high frequency component signal of the noise signal existing in the threshold range region set for the high frequency signal HF output from the first 2D-HPF 312 and moves out of the first threshold range region. The signal is extracted and the first high frequency signal 1_HF is output.

A coring processing method performed by the first coring unit 322 to remove the noise signal will be described with reference to FIG. 5.

Referring to FIG. 5, the dashed-dotted line indicates the signal HF before the coring process, the thick solid line indicates the signal 1_HF after the coring process, and ± T indicates the threshold value of the coring. Among the signals after the coring process, the signal existing within the threshold has a value of '0'. That is, if the input signal is within the threshold value, the output signal corresponding to the input signal has a value of '0'. This coring treatment method is also applied to the second coring unit 334 described later.

The first high frequency signal 1_HF generated by the first coring unit 322 is provided to the first signal amplifier 324 and the first signal delay unit 326.

The first signal amplifier 324 amplifies the first high frequency signal 1_HF at a predetermined ratio and outputs the second high frequency signal 2_HF. That is, the amplified second high frequency signal 2_HF is output by multiplying a gain having a positive or negative value by the first high frequency signal 1_HF. The first signal delay unit 326 delays the first high frequency signal 1_HF output from the first coring unit 322 by a predetermined time and then outputs the signal to the signal adding unit 340. This is to match the input timing of various signals input to the signal adding unit 340.

The low frequency processor 330 processes the low frequency signal LF output from the signal divider 310. The low frequency processor 330 includes an intermediate frequency extractor 332, a second coring unit 334, a second signal amplifier 336, and a second signal delay unit 338.

The intermediate frequency extractor 332 extracts a signal corresponding to a predetermined reference frequency or more among the low frequency signals LF. This is to extract the intermediate frequency signal MF and / or the third high frequency signal 3_HF of the input image signal input partially included in the low frequency signal LF output from the signal dividing unit 310.

An embodiment of the intermediate frequency extractor 332 is shown in FIG. 6A or 6B.

Referring to FIG. 6A, the intermediate frequency extractor 332 is implemented by the second 2D-HPF 332_1. The second 2D-HPF 332_1 extracts a signal higher than or equal to a frequency set for the low frequency signal LF and outputs an intermediate frequency signal MF. In other words, the second 2D-HPF 332_1 extracts the midrange component in the vertical direction and the midrange component in the horizontal direction among the input signals included in the low frequency signal LF and outputs the intermediate frequency component MF. .

In addition, referring to FIG. 6B, the intermediate frequency extractor 332 includes a first differentiator 332a, a second order differentiator 332b, and a multiplier 332c. The first differential 332a first differentiates the low frequency signal LF, and the second differential 332b second differentiates the low frequency signal LF. The multiplier 332c multiplies the first-differentiated low frequency signal LF 'and the second-differentiated low frequency signal LF ". As a result, an intermediate portion of an input signal partially included in the low frequency signal LF The frequency signal MF can be obtained.

Hereinafter, only the intermediate frequency signal MF will be described. The intermediate frequency signal MF extracted by the intermediate frequency extractor 332 is input to the second coring unit 334.

The second coring unit 334 removes a small amount of the noise signal included in the intermediate frequency signal MF by coring, and then outputs the first intermediate frequency signal 1_MF from which the noise signal is removed. That is, the second coring unit 334 removes the noise signal existing in the second threshold range region set for the intermediate frequency signal MF output from the intermediate frequency extracting unit 332, and moves out of the second threshold range region. The signal is extracted and the first intermediate frequency signal 1_MF is output.

The structures of the first and second coring units 322 and 334 are the same and perform noise processing according to the set first and second threshold range regions, respectively. That is, each of the first and second threshold range regions may be appropriately set to remove noise of the input image signal according to characteristics of the display device to which the first and second threshold range regions are applied.

The second signal amplifier 336 amplifies the output first intermediate frequency signal 1_MF at a predetermined ratio and outputs the second intermediate frequency signal 2_MF. That is, the amplified second high frequency signal 2_MF is output by multiplying a gain having a positive or negative value by the second intermediate frequency signal 2_MF.

The second signal delay unit 338 delays the low frequency signal LF output from the first 2D-LPF 314 of the signal division unit 310 for a predetermined time and outputs the signal to the signal adding unit 340. This is to match the input timing of various signals input to the signal adding unit 340.

The signal adder 340 includes a first signal adder 342 and a second signal adder 344. The first signal adder 342 adds the second high frequency signal 2_HF output from the first signal amplifier 324 and the second intermediate frequency signal 2_MF output from the second signal amplifier 336. A first compensation signal is generated.

The second signal adder 344 is a first high frequency signal 1_HF_d delayed output from the first signal delay unit 326, a low frequency signal LF_d and a first signal delayed output from the second signal delay unit 338. The first compensation signal compen generated by the adder 342 is added to generate a corrected image signal last_compen.

In addition, the signal adding unit 340 may include only one adding device (not shown). That is, the included one adder adds a delayed first high frequency signal 1_HF_d, a second high frequency signal 2_HF, a second intermediate frequency signal 2_MF, and a delayed low frequency signal LF_d to correct the image signal last_compen. Can be generated. In this case, the internal structure of the image signal processing apparatus 300 can be simplified and the unit cost of the product can be reduced by providing one adding device.

The clipping unit 350 adjusts a dynamic range of the compensated image signal last_compen output from the second signal adder 344. That is, the size of the corrected image signal last_compen is adjusted to suit the output level of the display.

7A to 7G are waveform diagrams for describing an image signal processing process performed by each unit of the image signal processing apparatus of FIG. 3.

FIG. 7A illustrates an example of an image signal input to the first 2D-HPF 312 and the first 2D-LPF 314 of the signal divider 310.

The high frequency signal HF output from the first 2D-HPF 312 has a waveform as shown in FIG. 7B. The noise signal existing in the first threshold range areas (T) to (-T) set for the high frequency signal HF is removed by the first coring unit 322 and the first threshold range area (T) to The signal out of (-T)) is output as the first high frequency signal 1_HF as shown in FIG. 7C.

When the ratio of amplifying the first high frequency signal 1_HF is 1 (gain = 1), the second high frequency signal 2_HF output from the first signal amplifier 324 has the same waveform as the first high frequency signal 1_HF. Has In addition, the signal output after the predetermined time delay from the first signal delay unit 326 is the same as in FIG. 7C.

Meanwhile, the low frequency signal LF output from the first 2D-LPF 314 has a waveform as shown in FIG. 7D. The intermediate frequency signal MF shown in FIG. 7E output from the intermediate frequency extractor 332 is input to the second coring unit 334. The noise signal existing in the second threshold range regions (T ') to (-T') set for the intermediate frequency signal MF is removed by the second coring unit 334, and the second threshold range region (( Signals outside T ') to (-T') are output as the first intermediate frequency signal 1_MF as shown in FIG. 7F.

When the ratio of amplifying the first intermediate frequency signal 1_MF is 1 (gain = 1), the second intermediate frequency signal 2_MF output from the second signal amplifier 336 is the first intermediate frequency signal 1_MF. Has the same waveform as In addition, the signal output after the predetermined time delay from the second signal delay unit 338 is the same as that of FIG. 7D.

The delayed first high frequency signal 1_HF_d of FIG. 7B, the second high frequency signal 2_HF of FIG. 7B amplified by ratio 1, the delayed low frequency signal LF of FIG. 7D, and the second of FIG. 7F amplified by ratio 1 The intermediate frequency signal 2_MF is added by the signal adder 340 and output as a compensated image signal last_compen as shown in FIG. 7G. According to FIG. 7G, it can be seen that the compensated image signal last_compen removes the noise signal and increases the image sharpness (in particular, the sharpness of the outline) compared to the input signal input.

According to an image signal processing apparatus and a processing method thereof capable of processing noise according to the present invention, after splitting an input image signal into a high frequency signal and a low frequency signal, and performing a noise signal processing suitable for each frequency characteristic, Sharpness can be improved. In particular, in the case of a high frequency signal including a large amount of noise signal or a large number of contour components, such as an RF image signal, when the noise signal is removed and added to the input signal, the contour component is emphasized and the overall image clarity and resolution are improved.

Although the present invention has been described in detail through the representative embodiments, those skilled in the art to which the present invention pertains can make various modifications without departing from the scope of the present invention with respect to the embodiments described above. Will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

Claims (7)

A signal divider for dividing an input video signal into a high frequency signal and a low frequency signal and outputting the divided signal; Removing a high frequency component signal of a noise signal existing in a first threshold range region set for the high frequency signal output from the signal splitter, extracting a signal outside the first threshold range region, and outputting the signal as a first high frequency signal A first coring portion; A first signal amplifier for amplifying the first high frequency signal at a predetermined ratio and outputting a second high frequency signal; An intermediate frequency extracting unit extracting a signal corresponding to a predetermined reference frequency or more among the low frequency signals output from the signal dividing unit; Removing a high frequency component signal of a noise signal existing in a second threshold range region set for the signal output from the intermediate frequency extracting unit, extracting a signal outside the second threshold range region, and outputting the signal as a first intermediate frequency signal A second coring portion; A second signal amplifier configured to amplify the first intermediate frequency signal output from the second coring unit at a predetermined ratio and output a second intermediate frequency signal; And And a signal adder configured to generate the corrected image signal by adding the first high frequency signal, the second high frequency signal, the low frequency signal output from the signal divider, and the second intermediate frequency signal. Image signal processing device capable of noise processing. The method of claim 1, The signal splitter, A first high pass filter for extracting and outputting a signal having a frequency set above the input signal; And And a low pass filter for extracting and outputting a signal having a frequency lower than a predetermined frequency with respect to the input signal. The method of claim 1, And a first signal delay unit for delaying the first high frequency signal output from the first coring unit by a predetermined time and outputting the delayed signal to the adder. The method of claim 1, And a second signal delay unit configured to delay the low frequency signal output from the signal splitter for a predetermined time and output the delayed signal to the adder. The method of claim 1, The signal adding unit, A first signal adder configured to add the second high frequency signal output from the first signal amplifier and the second intermediate frequency signal output from the second signal amplifier to output a first compensation signal; And Generating the corrected video signal by adding the first high frequency signal output from the first coring unit, the low frequency signal output from the signal splitting unit, and the first compensation signal output from the first signal adding unit; And a two-signal adder. The method of claim 1, And a clipping unit for adjusting a dynamic range of the corrected image signal output from the adder. Dividing and outputting an input video signal into a high frequency signal and a low frequency signal; Removing a high frequency component signal of a noise signal existing in a first threshold range region set for the high frequency signal output through the signal dividing step, extracting a signal outside the first threshold range region, and outputting a first high frequency signal step; Amplifying the output first high frequency signal at a predetermined rate and outputting a second high frequency signal; Extracting a signal corresponding to a predetermined reference frequency or more from the low frequency signals output from the signal splitter; The first intermediate frequency signal is removed by removing a high frequency component signal of a noise signal existing in a second threshold range region set for the signal corresponding to the extracted reference frequency or more, and extracting a signal outside the predetermined second threshold range region. Outputting to; Amplifying the output first intermediate frequency signal at a predetermined ratio and outputting a second intermediate frequency signal; And And generating a corrected image signal by adding the first high frequency signal, the second high frequency signal, the low frequency signal output from the signal dividing step, and the second intermediate frequency signal. Possible video signal processing method.