RU2502212C2 - Method of forming image on display of digital device - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: two signals are transmitted to an image blurring device of a digital device with a display. A first signal is transmitted from a sensor for detecting stress in eye muscles which control accommodation of the eyes of the user, located near the eyes of the user in form of glasses or a headset. A second signal is generated by a program of the digital device with a display. The image blurring device generates an output signal which controls the degree of image blurriness on the display, which is proportional to the difference between two input signals. The greater the difference between the magnitude of input signals, the greater the image blurriness on the display, and the lesser the difference, the lesser the image blurriness on the display.

EFFECT: stimulating eye muscles to perform more eye accommodation work.

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Description

The invention relates to methods for forming images on displays of various digital devices, and can also be used in medicine in the prevention and treatment of eye diseases.

With the increasing use of various digital display devices, the eye strain is increasing. At the same time, vision deteriorates and myopia develops. This is due to the fact that under natural conditions, for the formation of a sharp image of the human eye, reflexively do the work of focusing the image all the time, that is, they carry out accommodation. The eyes respond to a fuzzy image on the retina and make the muscles work by deformation of the lens.

Unlike natural conditions, when users work with digital devices with a display, the image on the display of these devices is always formed sharp and clear. In this case, the eye muscles, once focusing the eyes on the plane of the screen, there is no need to continuously perform additional work on accommodation. The eye muscles responsible for accommodation are in the same voltage state during the entire time of working with the display. In this case, the user develops ossification and atrophy of the eye muscles, which leads to the development of myopia.

From the "prior art" is known a method of forming a stereoscopic image on the display screen, which includes displaying information on the display screen for the left and right eyes, and convert this information into a stereoscopic image. Moreover, the information for the left and right eyes of the observer is displayed on the display screen by converting the source information signals into two or more synchronous, sequential or alternating groups of encoded image signals for the left and right eyes of the observer, alternating image elements for the left and right are formed on the display screen eyes of the observer, and the conversion of image elements for the left eye and the right eye of the observer into a stereoscopic image is carried out by for selective transmission of images for the left and right eyes of the observer through an optical film dash screen (see RF patent No. 21114414, class H04N 13/04, publ. 08/10/1998).

The disadvantages of the known solution is the possibility of distortion of information obtained from the user's eyes, which can cause a negative effect by the display means on one eye or on both eyes at once.

In addition, there is a method for manipulating the image displayed on the display of an electronic device using the modality of touch-sensitive input (touch) input, which has the ability to perceive the location of the touch and touch pressure (see RF application No. 2010019740, class G06F 3/041, publ. September 27, 2011).

The known method generally does not provide the possibility of stimulation of the eye muscles in connection with the formation of the image on the display by tactile contact and does not exclude the negative impact of the display means on the user's eyes.

Also, from the “BACKGROUND OF THE INVENTION”, an interactive television method is known in which a video signal of the entire video image or video signals of video image portions having one or different quality levels are generated. In the means for generating video signals, at least one video signal is converted in at least one means for converting video signals into a series of video signals of video image sections and / or the quality level of video image sections is converted, and / or the boundaries of the video image sections are changed, all video signals are transmitted via information channels at least one means of converting video signals and at least one means of displaying information. On the screen of the information display means, a video image is formed, which is perceived by at least one user. At least one sensor determines the characteristics of at least one user’s eye relative to the video image generated by the information display means, and dynamically generates signals encoding the characteristics of at least one user’s eye, which transmit at least one computing a device in which according to the specified signals, taking into account the function of the resolution of the eyes. Request signals are generated that encode information about the boundaries of at least one portion of the video image and / or about the quality levels of the video image of at least one portion of the video image for at least one eye of at least one user and, at at least one user group. The request signals are transmitted to at least two of the indicated means of generating video signals, converting video signals and information display means, in which, taking into account the request signals, they respectively generate video signals, convert video signals, form a video image (see RF patent No. 2220514, class H04N 7/18, published July 27, 2003).

The disadvantages of the known invention are the lack of the possibility of forming an image that stimulates the eye muscles to perform work on accommodation of the eyes.

The objective of the present invention is to remedy the above disadvantages.

The technical result consists in stimulating the eye muscles to perform additional work on accommodation of the eyes.

The technical result is ensured by the fact that the method of image formation on the display of a digital device with a display comprises supplying two signals to the image blur forming device of a digital device with a display. In this case, the first signal is supplied from the eye muscle tension sensor, which controls the accommodation of the user's eyes located near the user's eyes in the form of glasses or a headset, and the second signal is generated by a digital device program with a display, the image blur forming device generates an output signal that controls the degree of image blur on the display proportional to the difference of the two input signals, the larger the difference between the absolute values of the input signals, the greater the blur The value displayed on the display, and the smaller the difference, the lower the blurriness of the image on the display, while the proportionality coefficient between the magnitude of the signal difference and the degree of blur is automatically adjusted or set manually.

The technical essence of the invention is illustrated by the illustration, which depicts a control system for image blur. The composition of the image blur control system includes the following structural elements: sensor 1 for measuring the tension of the eye muscles of the user, providing accommodation; hardware-software complex of image blur control system 2; blurr 3.

In this case, the sensor 1 for measuring the voltage of the user's eye muscles can be made in the form of glasses or a headset, worn by the user while working with a digital device with a display (computer).

Sensor 1 measuring the tension of the eye muscles generates a signal proportional to the degree of tension of the eye muscles of the user. Ocular muscles mean muscles that deform the lens and provide focusing of the image on the retina. This signal can be measured both from both eyes, and from one. In the case of measuring the signal from two eyes, the resulting signal is averaged.

The hardware-software complex 2 can be implemented autonomously from a digital device with a display or implemented inside the device with a display and performs the following functions.

When visual objects are displayed, the program of the hardware-software complex simultaneously generates signals that specify the “virtual” distance from these objects to the user's eyes, that is, the distance that the user's vision must be adjusted so that the image on the screen is sharp (not blurry) .

For example, when displaying an image of a landscape photograph, for a tree in the foreground, the virtual distance in the program can be formed equal to 3 meters, for a forest in the background - 50 meters. The formation of virtual distance signals using a software-hardware complex program can be performed not only for images of physical objects, but in general for any objects displayed on the screen. For example, when displaying text for one paragraph, a distance of 1.5 meters can be specified, for another - 0.5 meters.

Thus, for each object being visualized on the display, a virtual “mark” is formed, indicating the distance at which this object should look sharp.

The generated virtual distance values are sent to one of the inputs of the image blur forming device.

The image blur forming apparatus 3 controls the degree of blur of images of objects displayed on a display screen. The sharpness of the output image is formed depending on the magnitude of the difference between the two signals supplied to the two inputs of this module.

The first signal comes from the sensor 1 for measuring the voltage of the user's eye muscles and corresponds to the distance at which the user's eyes are actually "tuned" at the moment.

The second signal comes from the program of the hardware-software complex 2 and corresponds to the software setting of the virtual distance to the object displayed on the screen.

If both signals supplied to the input of the image blur forming device 3 (and reduced by scaling to comparable values) are equal in magnitude (with a given degree of accuracy), then the image of the object on the display screen is formed clear and not blurry.

If there is a non-zero difference between the input signals, then the image blur forming apparatus 3 forms an image of the object on the display screen blurred. The blurriness of the image is proportional to the magnitude of the difference between the input signals with some gain K, namely, the larger the difference, the greater the blurriness of the image.

The gain K between the difference signal and the degree of blur of the generated image can be made adjustable. Moreover, its adjustment can be performed automatically or manually by the user through the on-screen setup interface.

The method is as follows.

Initially, the sensor 1 is calibrated to measure the user's eye muscle tension for a specific user. Calibration consists in the fact that the user sequentially focuses his vision on objects located at predetermined fixed distances. Corresponding to these distances, the signal values from the sensor 1 for measuring the voltage of the user's eye muscles are stored in the hardware-software complex 2. Further, during the operation of the image blur control system, these calibrated values are used to determine the distance at which the user's eyes are currently tuned. This is achieved by interpolating and extrapolating the previously measured calibrated values. Calibration is carried out as the user's visual acuity changes.

When the user is working with a digital device with a display, which includes a control system for image blur, using the sensor 1 for measuring the voltage of the eye muscles of the user, a continuous measurement of the voltage of the eye muscles of the user is performed. At the same time, the program of the hardware-software complex 2 displays objects on the screen and forms a virtual distance for them. The image blur forming device 3 processes the signals from the sensor 1 for measuring the voltage of the user's eye muscles and from the program of the hardware-software complex 2. Based on their difference, it generates the corresponding image for the displayed objects.

If during the operation of the hardware-software complex 2 the “virtual” distances to the visualized objects are changed programmatically, this causes an increase in the difference in signals at the input of the image blur forming device 3 and, accordingly, blurring of the image on the screen. Blurring the image on the screen stimulates the adaptation of the user's eyes. If the user's eyes adjust to the new virtual distance, the image on the screen becomes sharp. Thus, when operating a digital device with a display with a blur control system, the mobility of the muscles that control the lens develops, which prevents the development of myopia.

Claims (1)

A method of forming an image on a display of a digital device with a display, comprising supplying two signals to a digital imaging device with a display device, the first signal being supplied from an eye muscle tension sensor controlling the accommodation of a user's eyes located near the user's eyes in the form of glasses or a headset, and the second signal is generated by a program of a digital device with a display, the image blur forming device generates an output signal controlling the degree of the blurriness of the image on the display, proportional to the difference between the two input signals, the larger the difference between the absolute values of the input signals, the greater the blurriness of the image displayed on the display, and the smaller the difference, the smaller the blurriness of the image on the display, in addition, the proportionality coefficient between the magnitude of the difference of the signals and the degree of blur is adjusted automatically or set manually.