KR20000039248A - Display system having tool for correcting aged eyes - Google Patents

Abstract

PURPOSE: A display system having a tool for correcting aged eyes is provided to detect state of the crystalline lens according to the degree of aged eyes and correct a color of an image displayed according to the detected data. CONSTITUTION: A display system having a tool for correcting aged eyes includes a display(30) forming an image, a camera(10) picking up the image of the crystalline lens and outputting an information for the picked up image, and a controller(20) which is inputted the information from the camera and calculates the coloration degree for the yellow color of the crystalline lens and controls so that the blue color emitting amount of the display is increased.

Description

Display system with presbyopia correction mechanism

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display system, and more particularly, to a display system capable of optimally controlling a displayed image by providing means for correcting presbyopia due to deterioration of vision.

Display systems such as televisions and computer monitors are provided with a function for adjusting their own image, but this is merely to adjust the color tone of the image or the range of the image. In particular, it is preferable that a means for displaying an optimal image is provided in accordance with the visual characteristics of the individual using the display system as described above. For example, the visual acuity of older people is significantly reduced compared to that of normal people. In view of these characteristics, no means for precisely controlling the image has been provided.

Decreased vision, or presbyopia, a phenomenon seen in older people is caused by a slowing of the lens movement. Knowing these presbyopia mechanisms and phenomena is very important in providing a display system with presbyopia correction means.

Looking at this in detail, the lens, along with the cornea, is the main refractive organ of the eye and has elasticity. The refractive index of the lens is changed by the action of the Cilliary Muscle, so that the subject focuses precisely on the retina.

However, as they age, the lens gradually loses its elasticity, and thus the sufficient refractive index change cannot be achieved by contraction of the ciliary muscles. Thus, a so-called presbyopia phenomenon in which the subject's focus cannot be accurately formed on the retina occurs.

Another feature of presbyopia is that the lens gradually yellows as the lens ages. In other words, there are two types of chromophores in the lens, one of which is a tryptophan derivative, which absorbs light of 300-400 nm wavelength and the other absorbs light of about 500 nm wavelength. It is adsorbed by the lens protein, and its amount gradually increases with age. It is because of these pigments that the lens gradually becomes yellow with age, and when the lens is yellow, the amount of blue light reaching the retina from the outside is relatively reduced. Thus, as the lens ages, the yellowing tendency becomes more pronounced.

If the color image displayed in the presbyopia state is viewed, it is highly likely that the image corresponding to blue does not reach the retina or change to another color due to the yellow coloration of the lens. Therefore, the color image cannot be properly viewed.

The present invention was devised to compensate for the change of color image according to the presbyopia, and the presbyopia correction which can detect the state of the lens according to the degree of presbyopia and correct the color of the displayed image according to the detected data. It is an object of the present invention to provide a display system with a means.

Therefore, since the light emission intensity of the blue image can be adjusted according to the degree of individual presbyopia, even a presbyopia can correct a color image of a normal color.

1 is a block diagram schematically showing the configuration of a display system according to the present invention;

2 is a block diagram showing the configuration of the controller shown in FIG.

<Description of Main Parts of Drawing>

10 ... Camera 20 ... Controller

30.Display

A display system according to the present invention for achieving the above object, a display for forming an image; A camera for capturing the lens and outputting the captured image information; And a controller configured to receive the imaging information from the camera, calculate a degree of yellow coloration of the lens, and to increase the amount of blue light emitted from the display.

Here, the controller, the lens color concentration meter for measuring the yellow density of the lens in response to receiving the imaging information of the camera; A correction value calculator for calculating a correction value according to the measurement value of the lens color concentration meter; And a display signal controller for outputting a correction signal for controlling the image signal of the display according to the correction value of the correction value calculator.

In particular, the display comprises an electron gun; And a panel coated with blue, green, and red phosphors that emit light by colliding with an electron beam emitted from the electron gun, wherein the display signal controller increases the number of electron beams emitted from the electron gun to emit the blue phosphor. It is desirable to control so as to.

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

A configuration of a display system according to an embodiment of the present invention is shown in FIG. The present invention consists of means for photographing the eyes of a viewer to measure the degree of presbyopia and means for controlling a display such as a monitor to correct such presbyopia.

That is, from the display 30 on which the image is displayed, the camera 10 for capturing the eyes of the viewer, and the degree of aging of the lens of the viewer from the imaging information of the camera 10, the correction value is calculated and corrected. It includes a controller 20 for applying a control signal according to the value to the display 30.

The camera 10 is preferably installed in the main body of the display 30 so that the viewer of the display 30 can be captured. The camera 10 captures the viewer's eyes, in particular the lens, and outputs the image information. Alternatively, the camera 10 may be a bidirectional video communication camera.

As shown in FIG. 2, the controller 20 is composed of a lens color concentration meter 21, a correction value calculator 22, and a display signal controller 23. The lens color concentration measuring unit 21 measures a yellow color concentration value from the image information of the lens captured by the camera 10.

Subsequently, the lens color concentration measuring unit 21 outputs information on the yellow color concentration value to the correction value calculator 22, which calculates the difference between the normal value and the measured value and displays the correction signal. Output to the signal controller (23).

The display signal controller 23 increases the blue luminance of the image displayed on the display 30 according to the correction signal. That is, as described above, when the degree of coloration of yellow in the lens due to presbyopia increases, the amount of blue light reaching the retina from the outside decreases, thereby increasing the amount of blue light emitted from the display.

For example, when the display is a cathode ray tube (not shown), an increase in the amount of blue light can be achieved by increasing the electron beam reaching the phosphor applied to the cathode ray tube panel. In other words, when the number of electrons emitted from the electron gun to emit the blue phosphor increases, the luminance of blue light is higher than that of red and green.

Thus, a greater than normal amount of blue light can pass through the lens due to presbyopia, so a normal amount of blue light can reach the retina.

The display system according to the present invention measures the degree of yellow coloration of the lens due to presbyopia prior to viewing and outputs a correction signal for the correction value to the display so that the amount of blue light is emitted more than normal so that a viewer with presbyopia Color image viewing is enabled.

Claims (3)

A display forming an image; A camera for capturing the lens and outputting the captured image information; And And a controller configured to receive the imaging information from the camera, calculate a degree of yellow coloration of the lens, and control to increase the amount of blue light emitted from the display. The method of claim 1, wherein the controller, A lens color concentration meter which receives the imaging information of the camera and measures the yellow density of the lens; A correction value calculator for calculating a correction value according to the measurement value of the lens color concentration meter; And And a display signal controller for outputting a correction signal for controlling the image signal of the display according to the correction value of the correction value calculator. The display of claim 2, wherein the display is Electron gun; And A cathode ray tube comprising a panel coated with blue, green, and red phosphors which emit an electron beam emitted from the electron gun by collision; And the display signal controller controls to increase the number of electron beams emitted from the electron gun to emit the blue phosphor.