KR20050074726A - Method and apparatus of adjusting brightness according to adjustment of keystone - Google Patents

Abstract

The method of correcting the change in brightness according to the keystone correction of the projector of the present invention includes determining whether the brightness of the input video signal is changed according to the keystone correction when the keystone correction of the projector is requested, and the video signal. If the brightness is changed according to the keystone correction, characterized in that it comprises the step of performing the keystone correction and correcting the brightness change according to the keystone correction.

The apparatus for correcting the change in brightness according to the keystone correction of the projector includes a video signal converter which receives a video signal and changes the brightness, a scaler IC which scales and outputs the converted video signal, and the scaled video. When a keystone correction command is made through the display panel unit for displaying a signal on a screen, a user interface providing an interface with a user, a memory storing various data, and the user interface, the input video signal is subject to keystone correction. The controller may determine whether the brightness is changed, and if the brightness of the video signal is changed according to keystone correction, the controller performs the keystone correction and corrects the brightness change according to the keystone correction.

Description

Brightness correction method and device according to keystone correction {METHOD AND APPARATUS OF ADJUSTING BRIGHTNESS ACCORDING TO ADJUSTMENT OF KEYSTONE}

The present invention relates to a projector, and more particularly, to an apparatus and a method for correcting a change in brightness during keystone correction of a projector.

In general, a projector is a device for displaying an image of a small screen on a large screen, and with the development of technology, display of a high-definition large screen image is also desired for the projector.

Since the image of the projector is distorted and displayed according to the position and angle between the screen and the projector, the projector is provided with a keystone correction function.

The projector equipped with such a keystone correction function is disclosed in Korean Patent Application No. 10-2002-0003335 filed with the name "Keystone Correction Device and Method of an LCD Projector".

According to the patent application, the user can set the correction area as much as the user wants with the remote control, and perform the linear interpolation of horizontal lines automatically from the microcomputer receiving the set area information. The keystone of the LCD projector equipped with the mouse remote control In the correction method, if the user sets the keystone correction mode, the user can correct the area by using the mouse remote control to set the area to be corrected and the keystone area to be corrected using the mouse remote control. In addition, more accurate keystone correction is possible even for an asymmetric screen, which enables more accurate image projection.

As described above, since the keystone correction is performed by the linear interpolation method between the horizontal lines, partial brightness decreases according to the type of display image.

This will be described in more detail with reference to FIG. 1 showing a screen composed of text and FIG. 2 showing a screen composed of geometric patterns.

1 and 2, the screen composed of the text or the geometric pattern is composed of only black and white, and the screen is trapezoidally distorted.

This distorted screen is corrected to a rectangular screen through keystone correction.

When the keystone correction is performed, the screen is corrected to a rectangle by extending only the lower portion while maintaining the upper portion of the screen as it is, and linear interpolation between horizontal lines is performed to increase the lower portion.

When linear interpolation is performed like this, the median value for two pixels is taken as the interpolated value. As a result, when the difference between the two pixels is obvious, as shown in the right screen of FIGS. 1 and 2, the brightness and the sharpness of the screen are also lowered.

That is, the brightness of the area b where linear interpolation is not maintained remains the same, but the brightness of the area b where linear interpolation is reduced is reduced.

Such a partial change in the brightness of the screen has a problem of degrading the quality of the image.

In addition, as the brightness of the screen is partially reduced as described above, there is a problem in that an unidentifiable portion of the screen composed of text or graphics is generated.

Accordingly, an object of the present invention is to provide a brightness correction method and apparatus according to keystone correction, which can solve the problem that the brightness is partially changed during the keystone correction of the projection.

In addition, an object of the present invention, when the keystone correction for a particular screen is made, by performing the brightness correction for the keystone corrected screen, the brightness correction method according to the keystone correction that can prevent the partial brightness degradation in advance according to the keystone correction And providing an apparatus.

The method for correcting the change in brightness according to the keystone correction of the projector of the present invention for achieving the above object, if the keystone correction of the projector is requested, determines whether the brightness of the input video signal is changed according to the keystone correction And if the brightness of the video signal changes according to the keystone correction, performing the keystone correction and correcting the brightness change according to the keystone correction.

The apparatus for correcting the change in brightness according to the keystone correction of the projector includes a video signal converter which receives a video signal and changes the brightness, a scaler IC which scales and outputs the converted video signal, and the scaled video. When a keystone correction command is made through the display panel unit for displaying a signal on a screen, a user interface providing an interface with a user, a memory storing various data, and the user interface, the input video signal is subject to keystone correction. The controller may determine whether the brightness is changed, and if the brightness of the video signal is changed according to keystone correction, the controller performs the keystone correction and corrects the brightness change according to the keystone correction.

In the present invention, the brightness is corrected according to the type of screen during keystone correction to prevent partial brightness degradation due to the keystone correction.

A configuration of an image signal processing apparatus according to a preferred embodiment of the present invention will be described with reference to FIG.

The image signal processing apparatus includes a microprocessor 100, a memory unit 102, a user interface 104, an AD converter 106, a scaler IC 108, and a display panel 110.

The microprocessor 100 not only controls the image signal processing device as a whole, but also corrects the brightness according to the type of screen during keystone correction according to the preferred embodiment of the present invention. The memory unit 102 stores a processing program and various information of the microprocessor 100. The user interface 104 is responsible for the interface between the microprocessor 100 and the user. In particular, the user interface 104 provides a keystone adjustment command by the user to the microprocessor 100.

The AD converter 106 receives a video signal input from the outside, for example, a PC signal, converts the digital signal into digital video data, and provides the same to the scaler IC 108. The scaler IC 108 provides the display panel 110 after scaling the digital video data. The display panel 110 forms an image according to the digital video data, and projects the image on a large screen, not shown, so that the image is displayed.

A video signal processing method according to a preferred embodiment of the present invention applicable to the above-described video signal processing apparatus will now be described with reference to the flowchart of FIG.

The user may command keystone correction through the user interface 104 if the image displayed on the screen is distorted. When keystone correction is commanded from the user interface 104 (step 200), the microprocessor 100 checks whether the video signal input to the AD converter 106 is a graphic signal (step 204). Here, text or geometric patterns are generally provided as graphic signals.

If the video signal is not a graphic signal, the microprocessor 100 determines that there is no change in brightness according to keystone correction, performs keystone correction, and outputs a keystone corrected screen (step 226).

That is, as shown in FIG. 5, the video signal in which the value of the pixel is gradually changed is not changed in brightness due to the keystone correction. Therefore, the video signal is output as it is after the keystone correction is performed.

On the contrary, as shown in FIG. 6, the text or geometry pattern in which the value between each pixel changes abruptly causes the brightness change according to the keystone correction, and thus the brightness after the keystone correction according to the preferred embodiment of the present invention. Calibration should also be performed.

If the video signal is a graphic signal that is likely to be a text or geometric pattern, the microprocessor 100 stores the pixel data of the keystone correction area in the memory unit 102 (step 206).

When the pixel data for the keystone correction region is stored, the microprocessor 100 detects the maximum and minimum brightness of the pixel data in the keystone correction region and calculates a first brightness difference that is a difference between the brightnesses (step 208). ).

When the first brightness difference is calculated, the microprocessor 100 checks whether the calculated first brightness difference exceeds a predetermined value (step 210).

Here, when the first brightness difference exceeds the predetermined value, the microprocessor 100 determines that the keystone correction area is a graphic in which pixels rapidly change, such as text, and the first brightness difference determines the predetermined value. If not exceeded, the microprocessor 100 determines that the keystone correction region is a graphic in which pixels do not change abruptly.

If the first brightness difference does not exceed the predetermined value, the microprocessor 100 determines that there is no change in brightness according to keystone correction, performs keystone correction and outputs a keystone corrected screen (step 226).

If the first brightness difference exceeds the predetermined value, the microprocessor 100 extracts the brightness value before correction for the keystone correction area (step 212).

When the brightness value before the correction is extracted, the microprocessor 100 performs keystone correction according to the user's request (step 214). When the keystone correction is completed, the microprocessor 100 extracts the brightness value after correction for the keystone correction region (step 216).

When the brightness value after the keystone correction is extracted, the microprocessor 100 calculates a second brightness difference that is a difference between the brightness value before the keystone correction and the brightness value after the keystone correction (step 218).

When the second brightness difference is calculated, the microprocessor 100 increases the gain of the AD converter 106 by the second brightness difference (step 220).

After increasing the gain of the AD converter 106 by the second brightness difference in this manner, the microprocessor 100 subtracts the second brightness difference from the pixel data for the region that is not keystone corrected. This completes the brightness adjustment for the entire screen.

When the brightness adjustment is completed, the microprocessor 100 outputs the keystone correction and brightness correction screen (step 224).

According to the present invention, the screen change when the brightness correction is performed after the keystone correction will be described with reference to FIG.

First, (a) of FIG. 7 illustrates a screen distorted in a rhombus shape. The distorted screen is keystone corrected according to a user's command. 7B shows the keystone corrected screen.

7B illustrates a screen in which a rhombic distorted screen is corrected to a rectangle. Since text is displayed on the screen, brightness of both edges is deteriorated.

As described above, the brightness of the screens of which both edges are reduced is corrected according to the present invention. As a result, a screen having constant brightness may be displayed for the entire screen as shown in FIG.

As described above, the present invention has the advantage of solving the problem that the brightness is partially changed during the keystone correction of the projection.

In addition, according to the present invention, when the keystone correction is performed on a specific screen, the brightness correction is performed on the keystone corrected screen, and thus there is an advantage in that partial brightness degradation can be prevented in advance according to the keystone correction.

1 and 2 are views showing a state of brightness change according to a conventional keystone correction.

3 is a block diagram of a brightness correction device according to keystone correction according to a preferred embodiment of the present invention.

4 is a flowchart of a brightness correction method according to keystone correction according to a preferred embodiment of the present invention.

5 is a diagram illustrating a screen in which a value of a pixel is gradually changed.

6 is a diagram illustrating a screen in which a value of a pixel changes abruptly.

7 is a diagram illustrating a process of calibrating a screen according to a preferred embodiment of the present invention.

Explanation of symbols on main parts of drawing

100 microprocessor

102: memory

104: user interface

106: AD converter

108: Scaler IC

110: display panel

Claims (8)

In the method of correcting the change in brightness according to the keystone correction of the projector, Determining whether the brightness of the input video signal changes according to the keystone correction when the keystone correction of the projector is requested; And adjusting the brightness of the video signal according to the keystone correction, and correcting the change in brightness according to the keystone correction. The method of claim 1, The determination of the video signal, A brightness correction method according to keystone correction, characterized in that it is made only for graphic signals. The method of claim 1, The determination of the video signal, Obtaining a brightness difference between the maximum brightness value and the minimum brightness value in the keystone correction area; And determining the video signal whose brightness varies according to the keystone correction if the brightness difference is greater than or equal to a predetermined value. The method of claim 1, Brightness change correction according to the keystone correction, Obtaining an average brightness value for the keystone correction area before keystone correction; Obtaining an average brightness value for the keystone correction region after the keystone correction; Adjusting an amplification factor of a video signal by a brightness difference between average brightness values before and after the keystone correction; And reducing the pixel value of an area other than the keystone correction area by the brightness difference by the brightness difference. In the device for correcting the change in brightness according to the keystone correction of the projector, A video signal converter which receives a video signal and outputs the converted video signal; A scaler IC for scaling and outputting the converted video signal; A display panel unit which displays the scaled video signal on a screen; A user interface that provides an interface with the user, Memory for storing various data, When the keystone correction commanded through the user interface, it is determined whether the brightness of the input video signal is changed according to the keystone correction. If the brightness of the video signal is changed according to the keystone correction, the keystone correction is performed. And a controller for correcting a change in brightness according to the keystone correction. The method of claim 5, The determination of the video signal, Brightness correction device according to the keystone correction, characterized in that only for graphics signals. The method of claim 5, The determination of the video signal, Find the difference in brightness between the maximum and minimum brightness values in the keystone correction area. And the brightness difference is greater than or equal to a predetermined value, determining that the video signal changes brightness according to the keystone correction. The method of claim 5, Brightness change correction according to the keystone correction, Obtain the average brightness value for the keystone correction area before keystone correction, Obtain the average brightness value for the keystone correction area after keystone correction, Adjust the amplification factor of the converter by the brightness difference between the average brightness values before and after the keystone correction, And adjusting the scaler to reduce the pixel value of an area other than the keystone correction area by the brightness difference by the brightness difference.