RU2825049C1 - Eye strain relief device - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: device for reducing visual strain, comprising at least one semiconductor radiation source in the wavelength range from 360 to 420 nm, which creates in the area of the user's eyes an energy illumination of 2 to 20% of the energy illumination of the user's eyes from the screen and at least one semiconductor radiation source in the wavelength range from 720 to 1700 nm, which creates in the area of the user's eyes an energy illumination of 2 to 80% of the energy illumination of the eyes of the user from the screen, wherein said semiconductor radiation sources are connected to an electronic control unit and are placed in one housing, which is configured to direct radiation of the semiconductor sources into the eyes of the user.

EFFECT: reduced visual strain, visual increase in perceived contrast and colour saturation.

2 cl, 4 dwg

Description

The invention relates to the field of visual hygiene, in particular to a device using combined infrared and ultraviolet-blue radiation and can be used when using screens for displaying digital information and data: computers, tablets, smartphones, televisions, virtual reality helmets and glasses, and instrument panel displays.

The advent of monitor screens and LED lighting has caused a large number of complaints about increased visual strain, eye pain, characteristic of the "dry eye" syndrome, and other ailments, which will be further united by the term "visual strain". The "dry eye" syndrome generalizes negative sensations in the organs of vision, usually associated with the impact of monitor screens and devices together with semiconductor lighting, having a radiation range in the visible region from 420 to 720 nm.

It is known that from the spectrum visible to humans, including from LED sources with the main emission band of the semiconductor crystal in the range from 420 to 460 nm, blue light is considered the most harmful to the retina, causing increased visual stress associated with biochemical processes in the retina. Manufacturers of monitors and other display devices with screens of this type offer to use a blue light reduction mode, adjusting the color temperature using a special "eye comfort" mode. The negative feature of this mode is an insufficient reduction of visual stress and a violation of the correct color rendering of the screen.

There are also a number of known means aimed at reducing visual strain and creating comfort when working with screen devices. Spheroprismatic glasses are known, the lenses of which are equipped with light filters that selectively cut off only the ultraviolet-blue part of the spectrum (patent RU 182007, published on July 31, 2018). This means implements a mode for reducing blue light from the monitor screen in a passive way - by blocking part of the spectrum and introducing distortions into the perceived image - and is practically an analogue of the user-controlled blue light reduction mode used in most modern screens.

A device is known for protecting a computer user's eyes from drying out, containing a frame located along the perimeter of the computer monitor, equipped with LEDs with the ability to change the parameters of the emitted light at a given frequency (patent RU 168044, published 17.01.2017). In this device, which stimulates blinking of the human eye, the visible part of the spectrum is used, which distracts the user from the information reproduced on the screen and interferes with concentrated work.

The Ambilight TV external lighting system from the manufacturer Koninkl Philips Electronics is known, used to improve viewing perception (patent RU 2443073, published 20.02.2012). The system contains one or two U-shaped light guides, the legs of which spatially correspond to three or four sides of the display screen. In one embodiment, the light sources illuminate the background surface behind the TV, such as a wall. In another embodiment, the light sources are located around the display screen (in one plane) and emit light forward. In yet another embodiment, the light sources directly or indirectly illuminate the dark area between the pixel area of the display screen and the front part of the lighting system. The known solution is used to achieve greater user engagement in viewing images using visible light to create visual effects and does not have a noticeable impact on eyestrain.

There are no known analogues of the proposed device from the current state of the art, however, some elements are used for therapeutic purposes. There are a number of therapeutic methods [5] using infrared (hereinafter referred to as IR) radiation sources for the purpose of recovery after surgeries and injuries of the visual organs, as well as for the purpose of reducing dry eye syndrome. However, their long-term use for hygienic irradiation of the eyes is impossible, since it will lead to injury to the visual organs due to photobiological hazard according to IEC 62471:2006 standards.

The energy ranges used in IR therapeutic methods lie in the region from 0.001 to 0.1 J/ ^cm2 ([5], p. 4), which is ¹⁰⁴ times greater than the energy ranges from IR emitters in the proposed invention.

The objective of the present invention is to create a hygienic solution for reducing the visual strain of users when working with screens displaying digital information without disrupting correct color rendering using visually poorly distinguishable radiation sources that do not distract the user with bright visible light.

The technical result achieved by the claimed invention consists in reducing visual strain when using screen devices, as well as in visually increasing the perceived contrast and color saturation.

In order to solve the stated problem, a device for reducing eyestrain is claimed, comprising at least one semiconductor radiation source with a wavelength range from 360 to 420 nm, creating in the area of the user's eyes an irradiance of 2 to 20% of the irradiance of the user's eyes from the screen, and at least one semiconductor radiation source with a wavelength range from 720 to 1700 nm, creating in the area of the user's eyes an irradiance of 2 to 80% of the irradiance of the user's eyes from the screen, wherein said semiconductor radiation sources are placed in one housing and connected to an electronic control unit that regulates the power of the radiation sources, the housing of the device is located with the possibility of directing the radiation of the semiconductor radiation sources of both said ranges into the user's eyes.

The device may contain filters placed on semiconductor sources emitting a wavelength range from 360 to 420 nm and a wavelength range from 720 to 1700 nm, transparent for the specified ranges and opaque for visible light in the wavelength range from 420 to 720 nm.

The claimed device allows to reduce the user's visual strain by supplementing the spectral composition of the screen's radiation to the level of the natural daytime radiation spectrum of the band from 360 to 1700 nm.

The light emitted by screens and semiconductor light sources differs from the spectrum of fluorescent, halogen, gas-discharge lamps and natural daylight by the complete absence of a spectral range from 360 to 420 nm. In turn, the LEDs used in screens emit at wavelengths greater than 420 nm.

It is known that the transition of human vision from day to night begins at illumination less than 100 lux and is characterized by pupil dilation, decreased depth of field, visual dulling of colors and decreased contrast. For this reason, the illumination of workplaces with permanent presence of personnel should be at least 200 lux. It is noted that illumination of 200 lux received from semiconductor light sources is not enough to maintain full daytime vision, as evidenced by the occurrence of the above-mentioned characteristics of the transition to night vision. Other light sources, including those emitting a range from 360 to 420 nm, do not have this feature, all other things being equal. Thus, when using semiconductor light sources and screens, rhodopsin of the rods of the retina, responsible for night vision, is involved in visual perception, which causes increased visual strain associated, in particular, with deterioration of visual perception.

In addition, to replenish the rhodopsin reserves of the retinal rods, in the absence of the spectral component from 360 to 420 nm, retinol (vitamin A) is actively consumed. It is known [1, 2] that after absorbing a photon in the wavelength range from 440 to 550 nm, rhodopsin passes into the Meta I form, which is in equilibrium with the Meta II form and gradually decomposes from it into retinal, which is toxic to the retina. Excess retinal leads to the death of the retinal rods and causes pain in the eyes, which is perceived as visual strain. It was found that irradiation with a radiation range in the region from 360 to 420 nm converts the used rhodopsin into the Meta III form, which is the storage form of rhodopsin. Irradiation with photons from 360 to 420 nm prevents the formation of toxic retinal from the Meta II form and eliminates the need to create rhodopsin from retinol. Thus, the boundaries of the radiation range from 360 to 420 nm are justified by the absorption region of the Meta II form of rhodopsin, under the influence of which the Meta III form is formed, which maintains the rhodopsin reserves in the retina of the eye.

Additional evidence of the positive effect of the specified radiation range is the identified reduction in the progression of myopia in patients wearing contact lenses and glasses with increased light transmission in the range of less than 400 nm compared to others [3], as well as a reduction in the progression of myopia due to being outdoors [4].

When talking about the effect of infrared radiation (including the wavelength range from 720 to 1700 nm) on reducing eyestrain, it should be noted that under the influence of IR radiation, tissue regeneration is activated and biochemical reactions are accelerated, as evidenced by data on IR radiation eye therapy. Near IR radiation can penetrate eye tissue and promote the restoration of neurons in methanol intoxication, optic nerve injury and neuropathy, retinal damage and pigmentation, and macular degeneration. IR radiation can also help the brain recover from stroke, traumatic brain injury, and neurodegeneration [5]. Taking this into account, as well as the fact that about half of the solar energy is distributed in the infrared rays with a wavelength of more than 720 nm, a conclusion was made about the need for the presence of a spectrum of the IR component with a wavelength of 720 to 1700 nm, which is perceived by the human eye, for normal vision, including for reducing eye strain, which was confirmed by a physiological experiment. The boundary of the selected IR range is due to the fact that about 80% of the energy of the IR spectrum of natural daylight is concentrated in this range.

The declared ranges of energy illumination of radiation sources with wavelengths from 360 to 420 nm and from 720 to 1700 nm are justified by the following.

Based on data on the natural ratio of irradiance in the range from 360 to 420 nm and from 720 to 1700 nm to irradiance in the visible part of the solar spectrum [6], it was found that the ratio of irradiance from sources in the range from 360 to 420 nm and IR sources (incandescent lamps or semiconductor sources) from 720 to 1700 nm to irradiance from the monitor screen should be from 2 to 20% and from 2 to 80%, respectively. Taking into account that the monitor screen copies the radiation reflected from objects, the specified ratio of the irradiance from radiation sources in the wavelength range from 360 to 420 nm and radiation sources in the wavelength range from 720 to 1700 nm to the irradiance from the screen allows to repeat the spectral characteristic and energy indicators of reflected natural daylight, as well as to adjust the energy indicators of the sources in accordance with the color temperature of the image and the color balance on the screen in the range of irradiance natural for humans. The large difference between the minimum and maximum irradiance from radiation sources in the wavelength range from 360 to 420 nm and radiation sources in the wavelength range from 720 to 1700 nm is due to the fact that the eyes are better adapted to the perception of reflected light, the indicators of which significantly depend on the color and reflectivity of the surface at the corresponding wavelength.

Based on the data on the brightness of the monitor screens, the photobiological safety of the proposed method was calculated using the methods of IEC 62471:2006. The calculation shows that with continuous 8-hour use of the device, the user's eyes will receive a photobiological impact several tens of times less than the maximum permissible safe level.

The above-mentioned ratio of the irradiances from radiation sources with wavelengths from 360 to 420 nm and from 720 to 1700 nm to the irradiance from the screen is based on the natural spectral composition of daylight and its relative energy indices, taking into account possible fluctuations in screen radiation that depend on the colors being reproduced. Thus, with a low relative intensity of the red part of the spectrum, the intensity of the infrared part should also be reduced. The intensity of radiation in the wavelength range from 360 to 420 nm corresponds to the intensity of the blue part of the spectrum. At the same time, during the physiological experiment it was noted that violation of the limits of the above-mentioned ratios of irradiances leads to an increase in visual strain.

The device for reducing visual strain is illustrated in Fig. 1, which shows the spectral characteristic of the screen, supplemented by the radiation in Example 1, where 1 is the radiation spectrum of the monitor screen; 2 is the radiation spectrum of the source in the range from 360 to 420 nm, filtered through Wood's glass; 3 is the radiation spectrum of the incandescent lamp from 720 to 1700 nm, filtered through an IR filter;

Fig. 2 - which shows the spectral characteristic of the screen, supplemented by the radiation in example 2, wherein 4 is the radiation spectrum of the monitor screen; 5 is the radiation spectrum of the source in the range from 360 to 420 nm, filtered through Wood's glass, 6 is the radiation spectrum of the semiconductor source from 720 to 1700 nm;

Fig. 3 - which shows the external appearance of the device implementing example 1;

Fig. 4 - which shows a front view, a general view in 3/4 angle, and also A - a local view of the device in example 2, wherein: 7 - the device body; 8 - a source of ultraviolet-blue radiation in the wavelength range from 360 to 420 nm; 9 - a source of infrared radiation in the wavelength range from 720 to 1700 nm.

The claimed device may contain an electronic control unit (ECU) regulating the power of sources of both radiation ranges. The ECU takes into account the indicators of energy illumination in the corresponding parts of the visible spectrum and dynamically adjusts the power of the source of each range separately, receiving a signal either from its own sensors or directly from the visualization device by means of standard hardware. In the case of using several radiation sources for each range, an ECU with a separate output for each source is used. The ECU is placed in the same housing with the radiation sources, including in the case where the radiation sources are combined with a device containing a screen.

In order to prevent radiation from sources from interfering with or distracting the user, the device may contain light filters that block the visible part of the radiation spectrum of the radiation sources: a filter placed on the ultraviolet-blue radiation source that is transparent for ultraviolet-blue but not transparent for visible light in the wavelength range from 420 to 720 nm (for example, Wood's glass ZWB1), as well as a filter placed on the infrared radiation source that is not transparent for the region less than 720 nm and transparent for the band from 720 to 1700 nm, for example, the Hoya Infrared R72 IR photography filter.

A semiconductor radiation source or a group of them can be used as a source of ultraviolet-blue radiation in the wavelength range from 420 to 720 nm. A semiconductor radiation source or a group of them, or an incandescent lamp (or a group of such lamps) can be used as a source of infrared radiation in the wavelength range from 720 to 1700 nm.

Example 1.

The device for reducing eyestrain contains radiation sources, which are two light-emitting diodes with radiation in the range of 360-420 nm 8 and two incandescent lamps 9, which are separately connected to an electronic control unit (ECU) that regulates their power (not shown in Fig. 3). The ECU consists of a PWM controller controlled by a microcontroller, connected by a data bus to a personal computer that transmits an image to the screen. Radiation sources 8 and 9, as well as the ECU, are placed in a single housing 7 with direction adjustment so that the radiation from them is directed to the area of the user's eyes on the screen. To reduce the visual perception of radiation sources 8 and 9, light filters are installed on them, blocking the visible part of the spectrum in the range from 420 to 720 nm. The algorithm for controlling the power of sources of both ranges is given in Example 2.

Example 2.

The device for reducing visual strain contains radiation sources, which are a group of twelve light-emitting diodes with a wavelength range from 360 to 420 nm - 8 and a group of forty-two light-emitting diodes with a wavelength range from 720 to 1700 - 9. Groups of light-emitting diodes 8 and 9 are controlled separately using an ECU consisting of a PWM controller controlled by a microcontroller connected by a data bus to the monitor controller. The ECU together with groups of light-emitting diodes 8 and 9 are integrated into the body of the monitor 7 measuring 27 inches with an aspect ratio of 16:9.

LEDs 8 and 9 are placed in one line evenly along the perimeter of the screen on the lower, upper and side sides of the front part with an inclination relative to the plane of the screen, so that the axes of the light fluxes of all the LEDs converge at one point in front of the screen at a distance of 60 cm from its center, which corresponds to the approximate location of the user's eyes. Neighboring LEDs have different emission bands. UVA-LEDs with maxima at 385 and 405 nm and emission bands in the areas of 360-405 and 380-420 nm, respectively, are used as an ultraviolet-blue source of the 360-420 nm band. The infrared source of the 720-1700 nm band is IR-LEDs with maxima at 750, 870, 950, 1050, 1200, 1450 and 1550 nm and emission bands in the regions of 700-800, 800-900, 900-1000, 950-1150, 1100-1300, 1200-1600 and 1300-1700 nm, respectively. The LED powers within the ranges are matched to each other in accordance with the natural irradiance curve. The device does not have the ability to adjust the direction relative to the screen. The UVA-LEDs are equipped with light filters (Wood's glass) that block the visible region of emission longer than 420 nm. IR-LEDs with a maximum of 750 nm are equipped with IR filters that are not transparent for the radiation band shorter than 720 nm.

The calculation of the power of the radiation ranges complementing the image is performed by the ECU by analyzing the image displayed on the monitor screen. The image is analyzed by comparing the main 7 colors displayed on the screen with the library of reference reflected radiation of samples painted in these colors. For each color, the power factors K _UV and K _IR are preset, corresponding to the reflection factors in the ultraviolet-blue and infrared regions. The required energy illuminance of the ultraviolet-blue range is recalculated using the formula E _UV = K _UV × E _UVS × E _VGA / E _S , where E _UVS is the energy illuminance of the 360-420 nm range from direct sunlight, E _VGA is the energy illuminance from the main color on the monitor screen, E _S is the energy illuminance from the color sample illuminated by sunlight. The required irradiance of the infrared range is recalculated using the formula E _IR = K _IR × E _IRS × E _VGA / E _S , where E _IRS is the irradiance of the 720-1700 nm range from direct sunlight, E _VGA is the irradiance of the primary color on the monitor screen, E _S is the irradiance of the color sample illuminated by sunlight. For the blue color sample, it is assumed that the power factors K _UV and K _IR are equal to 1 for both complementary ranges. The required irradiance for the ultraviolet-blue (from 360 to 420 nm) and IR ranges (from 720 to 1700 nm) is recalculated for each color separately, and the power of sources of radiation ranges 8 and 9 is calculated based on the sum of the required irradiances of all colors.

Example 3.

The device contains radiation sources, which are a group of ultraviolet-blue light-emitting diodes with wavelengths from 360 to 420 nm and a group of IR light-emitting diodes with wavelengths from 720 to 1700 nm in a ratio of 1/4. The light-emitting diodes are placed on a transparent substrate together with a control layer and are controlled separately by means of TFT address control technology. The size of the light-emitting diodes is 200 μm, and the placement step is 1/100. The control layer with light-emitting diodes occupies the central area of the transparent substrate in the form of a circle with an area of 200 mm ² . The transparent substrate is mounted in place of the glasses in the frame for glasses in such a way that the emitting side of the light-emitting diodes is directed towards the user's eyes. The frame is combined with the device body. The body also contains a power battery and an ECU with a microcontroller of the energy illumination sensors. On the outer side of the frame there are sensors for the visible 420-720 nm, ultraviolet-blue 360-420 nm and IR 720-1700 nm irradiance. The signals from the sensors are used to recalculate the required radiation power of both radiation ranges of the device. If the required irradiance from an external source is present, the LEDs are off. If the required irradiance is insufficient, the device supplements the missing part using the algorithm described in example 3, taking into account the correction for the ultraviolet-blue and IR components present in the spectrum.

The claimed device operates as follows.

While viewing information from the screen, the user's eyes are irradiated with semiconductor sources of ultraviolet-blue (from 420 to 720 nm) and infrared (from 720 to 1700 nm) radiation.

A physiological experiment was conducted showing the dependence of visual strain on the presence of radiation in the range from 360 to 420 nm and in the range with a wavelength from 720 to 1700 nm when working at a monitor screen with a semiconductor backlight.

For this purpose, the subject is placed in front of the monitor screen of a working computer, and during the time of its operation - eight hours with breaks (one break per hour for five minutes and one break after four hours of operation for one hour) the subject's eyes are irradiated with a semiconductor source emitting through a Wood's filter (ZWB1), with a range of 360 to 420 nm with a fixed irradiance of 8% (0.008 W/ ^m2 ) and a source of infrared radiation, namely an incandescent lamp emitting through a Hoya Infrared R72 filter, with a range of 720 to 1700 nm with a fixed irradiance of 40% (0.05 W/ ^m2 ) of the irradiance of the subject's eyes from the screen. For all subjects, the standard screen operation mode was set, namely: the illumination from the screen was about 80 lux, the color temperature setting was 6500 K, the main images were text documents and tables, black text on a white background, and the design theme was standard for MS Windows 10 software.

The subjects were a test group of professional computer screen users aged 30 to 57 years, who spent at least 5 hours each working day working. 100% of the subjects had increased visual strain, which manifested itself mainly as variations of dry eye syndrome symptoms.

During the experiment, the following eye symptoms were monitored on a 4-point scale: burning; foreign body sensation; pain; blurred vision; increased sensitivity to light; lacrimation; redness of the whites of the eyes. The indicators of the occurrence of eye fatigue, blinking frequency, and the desire to rub the eyes were also quantitatively measured and compared. In addition, tests for subjective color perception and perception of image contrast were conducted on a 2-point scale using blind testing with and without eye irradiation.

The following results were obtained in terms of symptom reduction: burning by 85%; foreign body sensation by 87%; pain by 68%; blurred vision by 84%; increased sensitivity to light by 60%; redness of the whites of the eyes by 54%. At the same time, for each subject individually, the overall summary reduction of these symptoms ranged from 50 to 86%. Quantitative indicators of blinking frequency decreased by 26% and the desire to rub eyes by 73%. The occurrence of eye fatigue from work began to occur more than twice as late. Improvement in subjective color perception was noted by 36% of subjects, and subjective improvement in the contrast of image perception - by 72%.

Thus, the claimed invention allows to reduce visual strain when using screen devices, as well as to increase the perceived contrast and color saturation.

List of non-patent literature:

[1] Eglof Ritter, Kerstin Zimmermann, Martin Heck, Klaus Peter Hofmann and Franz J. Bartl. Germany

Transition of Rhodopsin into the Active Metarhodopsin II State Opens a New Light-induced Pathway Linked to Schiff Base Isomerization.

THE JOURNAL OF BIOLOGICAL CHEMISTRY 04/2004 Vol. 279, No. 46, Issue of November 12, pp. 48102–48111, 2004, © 2004 by The American Society for Biochemistry and Molecular Biology, Inc. (p. 48104 - Fig. 1; p. 48111). https://cloud.mail.ru/public/wnad/Qst3rhJxJ

[2] Mohana Mahalingama, Karina Martínez-Mayorgab, Michael F. Brownc,1, and Reiner Vogela.

Two protonation switches control rhodopsin activation in membranes.

PNAS, November 18, 2008 vol. 105 no. 46, 17797 (p.17797, Fig. 2). https://cloud.mail.ru/public/vjDJ/vTXAA1FfR

[3] Hidemasa Torii, Toshihide Kurihara, Yuko Seko, Kazuno Negishi, Kazuhiko Ohnuma, Takaaki Inaba, Motoko Kawashima, Xiaoyan Jiang, Shinichiro Kondo, Maki Miyauchi, Yukihiro Miwa, Yusaku Katada, Kiwako Mori, Keiichi Kato, Kinya Tsubota, Hiroshi Goto , Mayumi Oda, Megumi Hatori, Kazuo Tsubota. Japan.

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Claims (2)

1. A device for reducing eyestrain, comprising at least one semiconductor radiation source with a wavelength range from 360 to 420 nm, creating in the area of the user's eyes an irradiance of 2 to 20% of the irradiance of the user's eyes from the screen, and at least one semiconductor radiation source with a wavelength range from 720 to 1700 nm, creating in the area of the user's eyes an irradiance of 2 to 80% of the irradiance of the user's eyes from the screen, wherein said semiconductor radiation sources are located in a single housing and connected to an electronic control unit that regulates the power of the radiation sources, the housing of the device being arranged with the possibility of directing the radiation of the semiconductor radiation sources of both said ranges into the user's eyes. 2. The device according to paragraph 1, characterized in that it contains filters placed on semiconductor sources emitting a range of wavelengths from 360 to 420 nm and a range of wavelengths from 720 to 1700 nm, transparent for the said ranges and opaque for visible light in the range of wavelengths from 420 to 720 nm.