RU2576798C2 - Method for determining sight characteristics and device therefor - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions relates to ophthalmology. Method for determining characteristics of sight, including examination. Examination is carried out by presenting a patient in a dark room at a distance of 1.0 m - 1.5 black screen on which there are three concentric circles A, B, C with diameter 15, 10 and 5 cm respectively, along outline of which are uniformly arranged dull, two-colour light-emitting diodes illuminating and in a single centre of which there are three bright light-emitting diode R, G, B; and fixation in diagnostic map patient caused visual sensation. To determine visual acuity, method comprises recording patient diverging waves thermal radiation, accompanying light radiation of R or G or B LEDs, and to determine light-perceptibility of photoreceptors of retina is described by patient degree of brightness of light emitting colour light-emitting diodes or combinations thereof. Device consists of a polymer square black screen on which there are three concentric circles of standard fields of view A, B and C for determining characteristics of vision, first of which is calibrated from 0° to 360°, with diameters 15, 10 and 5 cm along outline of which are uniformly arranged two-colour light-emitting diodes illuminating in amount of 12, 8 and 4 items, respectively, and in a single centre of which there are three bright R, G, light-emitting diode, and mains adapter with DC power supply voltage of +3 V to feed light-emitting diodes of screen with a set of micro switches, micro toggle switches and construction with micro switch buttons which provide light selected light-emitting diodes.

EFFECT: using present group of inventions enables higher accuracy of determining perimetry vision.

2 cl, 11 dwg

Description

The invention relates to the field of ophthalmology for determining the main characteristics of vision. The main characteristics of vision include perimetry of vision, visual acuity, color sensitivity, etc. The field of view of the eye is the amount of space that the human eye sees with a fixed gaze and a fixed position of the head. The visual field is a function of the peripheral parts of the retina, namely the rod apparatus; his condition is largely determined by the ability of a person to freely navigate in space.

Changes in the visual field are caused by organic or functional diseases of the visual analyzer: retina, optic nerve, optic pathway, central nervous system. Violations of the field of view are manifested either by a narrowing of its borders, or by the loss of its individual sections (hemianopsia), the appearance of scotoma - the area of loss of part of the field of vision. When assessing the field of view (in ophthalmology, this is called perimetry), a predisposition to ocular pathologies and diseases can be detected. So, if a person’s field of vision is narrowed or curved, then we can talk about the presence of such serious eye diseases as glaucoma or cataracts. The study is carried out using special instruments - perimeters, which are kinetic, having the form of an arc or hemisphere, and statistical, using a computer and its special programs. The kinetic and widespread perimeter of the Forster type is known from the prior art. This is an 180 ° arc, covered from the inside with black matte paint and having on the outer surface dividing into degrees - from 0 ° in the center to 90 ° on the periphery. The disc with divisions behind the arc allows you to put it in the position of any of the meridians of the field of view. During the diagnosis of vision, white test objects are used in the form of paper circles glued to the end of black matte sticks. White objects with a diameter of 3 mm are used to determine the external boundaries of the field of view, and with a diameter of 1 mm - to detect changes within these boundaries; for color perimetry, use colored (red, green and blue) objects with a diameter of 5 mm, mounted at the ends of the gray rods (reflection coefficient 0.2). Arc illumination of at least 160 lux. The examinee places his head on the chin and fixes with one eye (the other is covered with a cardboard shutter) a white dot in the center of the arc. The test object is conducted in an arc from the periphery to the center at a speed of about 2 cm / s. The patient reports the appearance of the test object, and the researcher notices which division of the arc corresponds at that time to the position of the test object. This will be the outer boundary of the field of view for this meridian. The definition of the boundaries of the field of view is usually carried out on 8 meridians every 45 °. Color perimetry is carried out in a similar manner. For detection by cattle, a test object with a diameter of 1 mm is used and it is slowly moved along an arc in various meridians, especially carefully in the central and paracentral parts of the field of view, where scotomas are most often observed. But with the advent of a method such as computer perimetry, diagnosing various diseases has become much easier and faster. When computer vision perimetry is performed, see FIG. 1, the patient sits down in front of a special spherical device and fixes his gaze on a specially created light mark. At the same time, light spots of various degrees of brightness appear randomly at various points on the spherical screen. As soon as the patient sees a white spot, he fixes it by pressing a button on the joystick. The speed of spots and the direction of their movement may vary. Based on the results of the diagnosis, the ophthalmologist sees a picture with the parameters of the patient’s field of view and, when compared with special maps of the field of view, can judge a narrowing of the field of view or other disorders. Such computer perimetry of the eye helps in the short term to conduct the necessary examination of a large number of people. Of course, not everything depends on the availability of complex and modern technology on which such diagnostic procedures are carried out. Of great importance is the experience of the doctor and his knowledge. Of the foreign computer perimeters, the most famous are the perimeters “Hutpnrey”, “Octopus”, “Peritest”, “Perimat”, the super-expensive “AR-3000”, the domestic computer static “Pericom” with the control module and printer, adopted for the prototype. A computer automatic spherometer is designed to detect pathologies of visual fields in glaucoma (including primary), diagnose retinal diseases (thrombosis, dystrophy in the initial phases, diabetic and hypertensive angioretinopathy), as well as pathologies of the optic nerve. The technical characteristics of the Perikom perigraph are as follows:

Hemisphere radius (standard) 300 mm Research field 180 ° Total number of objects (LEDs) 206 pcs. Study time from 2 to 10 min Research methodology suprathreshold The difference in brightness of the object (LED) 100,000 times Transport packaging dimensions 55 × 65 × 78 cm Functional block of the Perikom device System unit "Pentium 4" with installed software Licensed Windows XP Software 17 "LCD monitor (View Sonic or Asus) with integrated audio speakers Uninterrupted power supply unit Color Inkjet Printer (Epson or HP) Shipping Weight Not less than 23 kg

When conducting research, the perimetric results are displayed on a computer monitor screen, printed in the form of a standard research form in black and white or color. The computer database in electronic form stores the patient database with all the research results.

In recent years, to characterize changes in the field of view in the dynamics of the disease and statistical analysis, the total designation of the size of the field of view is used, which is formed from the sum of the visible sections of the field of view examined in eight meridians. Normally, the average boundaries for a white mark 5 mm in size and a perimeter with an arc or sphere radius of 33 cm (333 mm) along the eight meridians (through 45 °) are as follows: outward - 90 °, downward outward - 90 °, downward - 60 °, downward inward - 50 °, inward - 60 °, upward inward - 55 °, upward - 55 ° and upward outward - 70 °. Then it turns out 90 ° + 90 ° + 60 ° + 50 ° + 60 ° + 50 ° + 55 ° + 70 ° = 530 °. This value is taken as the norm. The average boundaries of the visual fields of color are as follows: outward - to blue 70 °, to red 50 °, to green 35 °; inward - 50 °, 40 ° and 30 °; up - 50 °, 40 ° and 30 °; down - 50 °, 40 ° and 30 ° respectively.

These techniques have disadvantages. Everyone who has gone through just such a perimeter of vision remembers that during this procedure, he lost more than one white point. The computer program “pulls” the assessment of the perimetry of the patient, according to available points, reducing the reliability of the result depending on the age of the patient by 15-25%, which is already an approximate result. The boundaries of the normal field of view (hereinafter referred to as the perimeter of vision) to a certain extent depend not only on the research methodology. They are influenced by the magnitude, brightness and distance of the object from the eye, the brightness of the background, as well as the contrast between the object and the background, the speed of the object and its color. In addition, the modern method for determining the perimetry of vision does not take into account the individual structural features of the patient's face (the size of the nose, the depth of the eye, the shape of the eyebrows, the presence of heavy eyelids, the shape of the lower part of the face, etc.), which limit the light effect on the retina. Therefore, the perimetry of the eye loses about 30%, which means that a considerable part of the retina is not diagnosed. It is for this reason that the perimetry of the eyes of patients on modern devices is elongated and offset from the center of the curve diagrams, see Fig. 2. Based on the optical structure of the eye, its perimeter of vision should be close to the circle. Modern perimeters conduct perimeter vision, usually with a radius of an arc or sphere of 33 cm, i.e. are a desktop option. All of the above-mentioned computer perimeters are large and heavy in composition, and “blind” in functional terms, because both the subject and the tester act blindly, at random. All visual characteristics are recorded according to the principle, like a guessing game, saw - did not see. Therefore, it is necessary to speak very carefully about the accuracy of measuring the characteristics of vision. The cost of such perimeters is rather big, and increases even more when additional application software is installed.

Color vision anomalies are usually referred to as those or other violations of color sensitivity. They are inherited as a recessive trait linked to the X chromosome. Color blindness is a disease in which a person has a violation in the recognition of one of three colors (R - red, G - green or B - blue). To identify color blindness (color blindness) and its manifestations in modern ophthalmology, Rabkin polychromatic tables are used, containing 27 color images in which monochrome figures or geometric figures are disguised as colorful mosaics. Ophthalmologists distinguish according to the degree of color sensitivity: trichromancers (norm), protoanopes (people with color perception disorders in the red spectrum) and deuteranops (people with color perception disorders in green). As you know, two types of photoreceptors are found in the retina of the human eye. These are cones and sticks. The sticks are responsible for the perception of gray shades and determine the tempo vision. Cones allow us to distinguish colors and shades and come in three types. Each of the three types of cones is responsible for the perception of the corresponding wavelength. If our eyes perceive green, then irritation of the "green" cones occurs. The corresponding signal enters the brain, is analyzed, and we feel that we are seeing something green. In the case of simultaneous irritation of green and red cones, a yellow sensation arises.

Testing on a well-known anomaloscope (Nagel, Rabkin, Rautian system, etc.) - a device for testing color vision and identifying its anomalies and their nature, shows that with protanomaly, the color mixture has more red color than normal, and with deuteranomaly the mixture has more than necessary green. In rare cases, the yellow-blue channel is disrupted. But the proposed test does not provide a quantitative assessment of the perception of various colors by the human optical visual apparatus.

Visual acuity - the ability of the eye to perceive separately two points located at a certain distance from each other (detail, fine-grained, resolution). The measure of visual acuity is the angle of view, that is, the angle formed by the rays emanating from the edges of the subject in question (or from two points A and B) to the nodal point (K) of the eye. In this case, the visual acuity of a person is inversely proportional to the angle of view, that is, the smaller the angle of view, the higher the visual acuity. Normally, the human eye is capable of separately perceiving objects whose angular distance between them is at least 1 minute (1 ′). Visual acuity is also one of the most important functions of vision. The visual acuity of the patient is checked according to the well-known Golovin-Sivtsev tables, in which there are 12 rows of signs (letters and optotypes of Landolt rings with a gap) of various sizes. The tables allow you to determine visual acuity from a distance of 5 m from 0.1 (upper row) to 2.0 (lower row). The tables are placed in a lighting apparatus with an incandescent lamp or two fluorescent lamps. Illumination tables 700 lux. The illuminator is mounted on the wall so that its lower edge is 120 cm from the floor. During the study, the patient should keep his head straight, the eyelids of both eyes are open. An eye that is not subject to investigation is covered with an opaque white visor. Within 2-3 seconds, they show a sign on the table and ask the patient to name it. The definition is best to start with small characters, and then move on to larger characters. When evaluating the results of the study, they use the concepts of complete and incomplete visual acuity. Full visual acuity is one in which all the signs in the corresponding row are correctly named. If in the rows of the table corresponding to visual acuity 0.3: 0.4; 0.5; 0.6, one character is not recognized, but in the rows of 0.7; 0.8; 0.9; 1,0 - two signs, then such visual acuity is estimated in the corresponding row as incomplete. A visual acuity of 1.0 is considered normal.

The above diagnostic methods, determining the characteristics of vision, can be implemented in a different and less costly manner.

The proposed inventions solve the problem that allows for perimetric vision, to determine visual acuity, to quantify color sensitivity, to identify the initial shape and presence of cataracts, retinal anomalies, etc.

To obtain such a technical result in the proposed method, vision diagnostics is carried out by alternately registering with the patient’s eye, the luminous corona of radiation of one of the R - red, G - green and B - blue LEDs, against a black screen in a dark room. The ability of human vision to adapt to different lighting conditions and different spectral components of visible background light allows us to classify colors and perceive colors identically under different lighting conditions when perceiving the color of an object. By the corona of radiation or the radiation of the corona it is necessary to understand a certain “figurative” form of the external contour of light radiation recorded by the human eye. It is known that in the dark, the photosensitivity of the photoreceptors (rods) of the retina is as sensitive as possible, about a hundred times higher than with daytime vision, and they fix color radiation well. Moreover, most importantly, against a dark background, the degree of registration of the primary colors of R, G or B radiation does not differ significantly from each other. This is a distinctive property in our invention and is used to determine the characteristics of vision.

The generally recognized three-component model of vision, which assumes the presence of three types of visual photoreceptors in the retina of the eye, sensitive to different wavelengths of light. In accordance with this model, in the present invention, the red (R - long-wave), green (G - medium-wave) and blue (B - short-wavelength) LEDs are used as color radiation sensors for determining the characteristics of vision. Long-term practice of mixing (mixing) of such colors has confirmed their defining importance. Therefore, it is precisely this feature of LEDs for the color sensitivity of the human eye that underlies the method of diagnosing vision when determining the perimetry of vision, visual acuity, and identifying types of color blindness - deviations from the average human perception of color, cataracts, retinal anomalies, etc.

It was experimentally revealed that in the dark on a black screen, the visible radiation of the corona of a luminous object (LED), perceived by the patient’s eye, contains the characteristics of the optical apparatus of the eye. The combination of these characteristics allows us to evaluate the quality of the optical apparatus of the patient’s eye. So, for example, the parameters of the LED radiation corona visible to the patient’s eye against the background of the device’s dark screen, like the shape and size of the corona, are responsible for the perimeter of vision, the distribution of the density (brightness) of the radiation of each of the R, G and B LEDs is responsible for light sensitivity, the degree of registration of thermal propagation waves accompanying light emission, is responsible for visual acuity. The patient retells the seen picture of the LED radiation to the nurse, who transfers this picture to the perimeter diagrams of the eyes in the patient’s individual diagnostic card. From the radiation density distribution diagram, the ophthalmologist determines the quality of the photoreceptors of the central and peripheral zones of the retina. The perimetry of the vision from the R, G or B LEDs, color sensitivity and its brightness, as well as where in the diagram of the distribution of the radiation density there are anomalies (narrowing, dark spots, etc.) are determined. In addition, it was revealed and experimentally confirmed many times that the size of the corona and the degree of its brightness from R, G, B LEDs on a dark background do not differ significantly, and the light emission of the LEDs in the central region of the screen is accompanied by thermal wave radiation, which resembles diverging circles on water from an abandoned object. In reality, when observed, these thermal waves are thin circles that diverge from the emitter. When moving from the center of light emission to the periphery, these waves gradually increase in diameter and dissolve in the corona.

Distinctive features of the proposed method are that for the first time in the practice of determining the characteristics of vision, the patient uses his own vision of the light emitting from a color LED. During the perimetry of vision, the subject, seen with his own eye the picture of the light emitting corona of the central LED on the black screen of the diagnostic device, which forms the maximum number of retina photoreceptors, retells the nurse for recording in a special individual diagnostic card. Therefore, to determine the perimetry of vision, a test object is not required, and the characteristics of vision are determined at a distance of 1.0 m - 1.5 m in a dark room.

The proposed method, according to the image of corona light emission recorded by the eye, allows to determine the perimetry of vision in the correct form (in the form of a circle) because the control object is located at a distance farther than usual, which is not distorted by the structural features of the patient's face. Visual acuity is determined not according to the Golovin-Sivtsev tables, as is often the case, but by recording the movement of thermal waves of one of the R, G and B of the LEDs that are illuminated, and the degree of color sensitivity is determined by the light distribution density of various colors. This is especially important for patients suffering from weakened color sensitivity (color blind), as well as to predict and detect cataracts and glaucoma at an early stage. The procedure for diagnosing the patient’s vision occurs in a dark room, and R, G, B LEDs are used as a light source, located in the center of the dark screen, at a distance of 1.0 m - 1.5 m from the patient in a dark room.

In a broader sense, the proposed method allows to assess the state of the patient’s retina due to feedback, in which the light emits photoreceptors of the retina of the eye, as a result of such irritation, a signal appears in which everything that the eye sees is encoded. The brain simultaneously perceives this combined information from different receptors on the optic nerve and decodes it into visual sensations (perceptions), i.e. the feeling of seeing the shape of the object and its color. In the proposed method for determining the characteristics of vision, the patient plays an active role, like a “photographer observer”, who sees the light emitting crown, notes its size and shape, radiation density (brightness distribution from the center to the periphery), but really cannot photograph (fix) . Therefore, he retells with words the picture he saw to the nurse for recording in an individual diagnostic card. Moreover, if the patient does not have vision problems, then he sees the corona of light emission in the form of a luminous circle, the brightness of light emission of which decreases to the periphery of the corona. If the patient has vision problems, then this is primarily found in the presence of violations of the boundaries of the perimetry of the vision, which are manifested in narrowing of the borders, or in the loss of certain areas (hemianopsia) - the appearance of scotomas with a certain localization and a decrease in the brightness of the corona. A decrease in brightness in color sensitivity is an essential sign of visual impairment. The distinctive features for determining visual acuity in the proposed method include the registration of the accompanying light radiation of the waves of the thermal radiation of the LED. This interesting phenomenon is used to determine visual acuity, since this process is very poorly noticeable (very subtle) and is well suited for determining visual acuity and for testing color blind people. Visual acuity of the eyes of at least 1.0 allows a person to see the movement of such heat waves. So, everything that the patient’s diagnosed eye sees is carefully retold to the nurse, who enters in the individual form all the visible sensations of the patient.

As a result of the practical application of the proposed method, the accuracy of determining the perimetry of the patient’s vision, visual acuity appears, and the spectral sensitivity of the retina to the color distinguishability of the eyes of people with color blindness is estimated, for which the glow of colored LEDs is used.

To obtain the named technical result, the problem is solved in the creation of a device for determining the characteristics of vision (diagnostics) with wide functionality, which allows perimetric vision, determine visual acuity, quantify color sensitivity, identify the initial shape and presence of cataracts, eye retinal anomalies, etc. . The vision diagnostic device consists of an LED screen and an adapter. The LED screen is made of black polymeric material with a thickness of 4 mm square in the center of which there are three concentric circles of the conditional fields of view A, B and C (with 12 meridians), the first of which is graduated from 0 ° to 360 °, in a single center which mounted lenses of three bright R, G, B LEDs. The adapter connects to a 220 V AC network, has a + 3B DC voltage source for powering the LEDs and a set of microtum switches, micro switches and micro buttons. Such a set of technical means provides a device operating mode for correctly determining the perimetry of vision, color sensitivity, brightness and visual acuity of the patient.

Distinctive features of the proposed device for the diagnosis of vision are its multifunctionality. The technical means of the device make it possible to determine the perimetry of vision without involving additional devices, to provide a large combination of colors for detecting color retention anomalies in the retina photoreceptors, and to determine visual acuity. The type-setting field of the micro-buttons of the backlight LEDs allows you to turn on any of the 24 LEDs in any sequence, or as a whole along the circumferences of the conditional fields of view A, B or C in any sequence.

As a result of the practical application of the proposed device, the efficiency and accuracy of determining the characteristics of vision are increased and, based on the diagnostic results, a more accurate diagnosis is made for prophylaxis or the need for certain treatment.

The claimed group of inventions meets the requirement of unity of invention, since it forms a single inventive concept, moreover, one of the claimed objects of the group - the device "Device for the diagnosis of vision" is intended to implement another claimed object of the group - the method of "Method for determining the characteristics of vision." In this case, both objects of the group of inventions are aimed at solving the same problem with obtaining a single technical result.

The present invention is represented by 9 figures. In FIG. Figure 3 shows the screen of a square-vision diagnostic device of black polymer material (1) with a thickness of 4 mm and a side length of at least 20 cm, in the central part of which there are three concentric circles of the conditional fields of view A, B and C, the first of which is calibrated from 0 ° to 360 ° and is divided into 12 segments around the circle, like a clock dial, with diameters of 15, 10 and 5 cm, along the contour of which holes for two-color backlight LEDs (3) are evenly placed in the amount of 12, 8 and 4 pcs. respectively, and in the single center of which a hole is made for installing the lenses of three bright R, G, B LEDs. The backlight LEDs (3) denote the value (border) of the conventional fields of view A, B or C. The diameter of the conventional field of view A, on which 12 backlight LEDs (3) are located, is 15 cm, taken as the normal field of view. The diameter of the conventional field of view B, on which 8 backlight LEDs (3) are located, is 10 cm, taken as the average field of view. And the diameter of the conventional field of view of the circle C is 5 cm with 4 backlight LEDs (3) taken as the field of view of visually impaired people. The total number of illuminated LEDs (3) is 24 pcs. The maximum diameter of the circumference of the conditional field of view A, which characterizes good vision, was selected according to the results of testing the vision of young people who are not color blind by the age of 30 years, having a perimeter of vision of no worse than 530 ° and visual acuity of at least 1.0.

Figure 4 shows the assembly of the screen (1) and the mounting panel (4), which has the same geometric dimensions as the screen (1). The mounting panel (4) is made of foil-coated fiberglass with a thickness of not more than 1.5 mm, on which a protective coating with nitro-varnish is applied through a photolithographic template of the connecting conductors for subsequent etching in ferric chloride (Fe ₂ Cl ₃ ). The connecting conductors connecting the terminals of the LEDs to the supply DC voltage are performed with a width of not more than 1 mm. All LEDs (2 and 3) are installed and soldered on the mounting panel (4) according to the holes of the screen stencil (1). The black screen (1) is superimposed on the mounting plate (4), with the LEDs (2 and 3) installed and soldered, through dielectric bushings (5) about 7 mm high, mounted at the corners of the screen (1). The shield (1) and the mounting plate (4) are interconnected by short screws and nuts M4. For the convenience of combining the optical axis of patients with different heights with the optical axis of the central LED, the screen of the device (1) assembled with the mounting panel (4) has a stand (7) that allows the assembled screen (1) to be tilted in both directions relative to the vertical position angle α to 20 °. To supply a constant voltage for powering the LEDs, the 37th pin connector (6) 5501 of the D-SUB series of the standard type for soldering 5501-37RA02 (plug) is provided on the mounting panel (4). Strictly speaking, the screen (1) and the mounting panel (4) connected together represent one functionally complete product, which in the further description of the invention can be seen as the screen (1) of the diagnostic device.

In FIG. 5 shows an example of an electrical circuit for powering the central R, G, B LEDs (2). The central (2) LEDs R, G, V are fed from a direct current source with a voltage of +3.0 V, which is assembled on a transformer of type TPG-1 for printed wiring with an output alternating voltage of 4.2 V and a load current of 0.5 A rectifying KC407 type bridge with filtering capacitors C3 = 2000 μF at 16 V, C4 = 0.1 μF at 60 V, controlled LM317T stabilizer with smoothing capacitors C1 = 0.1 μF at 60 V, C2 = 470 μF at 16 V, R6 = 240 Ohms, trimmer resistance R5 = 5.0 kOhm. For equal light emission of the central R, G, B LEDs (2), the power supply current of the R LED is set to I = 2 mA, for B and G LEDs the power supply current is set to I = 1 mA. The values of the damping resistances of the electrical circuit are selected from conditions that ensure the optimal operation of the LEDs: R1 = 2 kOhm, R2, R3, R4 = 200 Ohm. The electrical circuit has a 3-position microswitch P1, which selects one of the R, G, B LEDs and microtummer S for operation, which sets two modes of illumination of one selected from the central (2) LEDs - normal (with a limiting resistor R4 in the electric circuit ), when the microtumber switch S is in position 1, or bright for visually impaired patients, when the microtumber switch S switches to position 2. The electrical circuit has a micro button Kn. 25, which blocks the quenching resistance R7. The inclusion of this button reduces the brightness of the main LEDs (2) to detect color sensitivity when working with color blind. Figure 6 presents a structural diagram of a device for diagnosing vision without a stand (7). A device for diagnosing vision includes a screen (1) and an adapter (9). The adapter (9) of the diagnostic device has a network cable (12) for connecting to a 220 V AC network through a microtumber switch (11) on the on / off adapter body, a connecting cable (8) with a connector (10) 5501 of the D-SUB series of a standard type for soldering 5501-37SA02 (socket), for connection to the mounting panel (4) of the screen (1) through the connector (6). On the front panel of the adapter (9), there are 2 microswitches P1, P2, 5 microswitches R, G, B, S, N and 24 microswitches (Кн1 - Кн25). As the three main central (2) LEDs R, G, B, which provide the main color emission, LEDs with a transparent lens and strong glow are used. For the R glow, you can use the WU-8-53SEC T005849 transparent LED, with a lens diameter of 5 mm and a lens length of 9 mm. The LED can be SML-Z14 models transparent with a lens of 5 mm · 9 mm, and the G LED can be models NSPG500DS, also with a transparent lens 5 mm · 9 mm. As the illumination LEDs of the conditional fields of view A, B and C, matte two-color LEDs of the L115VEGW RED / GREEN model (red / green) with a lens diameter of 3 mm and a lens length of 5 mm can be used.

In FIG. Figure 7 shows, as an example, the perimetric diagram of the normal optical apparatus of a person who has undergone diagnostics of vision on R, G and LEDs (2), showing a field of view of 80 ° × 8 = 640 °, good color sensitivity and visual acuity no worse than 1.0 . The perimeter of vision on the visibility chart of the corona is determined by the 8 meridians (through 45 °) at the edges of the corona at the points indicated by crosses, where 80 ° is the value of the circumference of the corona on a horizontal scale. As an example, the diagram shows diverging waves from the center of radiation to the periphery in the form of circles, which are the thermal radiation that accompanies the light emission of the LED (2). Only with good vision can one see this thermal movement in the light emission of the corona. In FIG. 8 is a color-sensitivity diagram of the light emission of the central R LED (2) of the patient’s left eye. The diagram of the left eye shows a narrowing of the perimetry of vision and a decrease in the brightness of color sensitivity, which does not have a pronounced contour of the density of the perceived glow, which characterizes the field of view of the patient's eye below normal. The perimetry of the left eye along the 8 meridians through 45 ° is: 58 ° + 56 ° + 57 ° + 51 ° + 50 ° + 52 ° + 51 ° + 53 ° = 428 °. In addition, due to poor color sensitivity, the patient does not see the diverging waves of the thermal radiation of the LED with his left eye, which reveals the incomplete visual acuity of the patient's eye. The reason for this quality of vision is the low sensitivity of the photoreceptors (rods) of the retina due to the revealed degradation of the lens of the eye (the presence of an initial form of cataract). The patient sees into the distance, but for reading and work he was prescribed a lens for glasses of the left eye +3.0. In FIG. Figure 9 shows a diagram of the right eye for red light from the same patient whose lens of the right eye was replaced by an intraocular lens (IOL) in April 2012. The diagram shows good perimetry of vision, which occupies most of the conditional field of view (A) on the screen of the diagnostic device, and the color sensitivity density, which occupies the full conventional visual field (B) and overshadows its backlight LEDs (3), confirms the good sensitivity of the retina photoreceptors of the right eye. The perimeter of vision of the right eye with IOL is 83 ° × 8 = 664 ° and does not have anomalies in the area of the corona, which is a good result. The patient confidently sees radiation of diverging heat waves from the central red LED (2) and propagating to the border of the conventional field of view C, which confirms visual acuity of at least 1.0. It also follows from the description of the vision diagram that the retina of the right eye and the optic nerve are working normally, i.e. cope with light and color loads. In FIG. 10 and FIG. Fig. 11 shows vision diagrams in which the sensitivity maxima of both eyes of the patient fall on the blue part of the spectrum (glow of LED B (2)). The perimetry of the patient’s left eye on the blue glow of FIG. 10 has grown a little, becoming 61 ° + 67 ° + 63 ° + 57 ° + 56 ° + 60 ° + 60 ° + 50 ° = 484 ° against 428 ° of the perimeter of FIG. 7, but remained low. The perimetry of the right eye of FIG. 11 grew up and reached a high level of 87 ° × 8 = 696 °, which confirms the good color sensitivity of the retina, visual acuity and good work of the optic nerve.

The proposed method for the diagnosis of vision is carried out in the following sequence: the power cable (12) of the adapter (9) is inserted into an AC outlet of 220 V. The power switch (11) is set to On. The operation mode switches of the adapter (9) of the diagnostic device are set to the following positions: microswitch P1 of the color of the main (2) LEDs in position (1) - R (red), light output switch S to position (1) - normal, light backlight microswitch P2 to position (2) - G (green). When diagnosing the main characteristics of vision: the patient sits on a chair at a distance of 1.0 m - 1.5 m from the on screen of the diagnostic device, puts his head on the chin mounted on the treatment table. The nurse explains to the patient the test procedure, in which he must combine the optical axis of his open eye (with a cardboard overlay, for example, the right eye), with the optical axis of the light-emitting red LED in the center of the screen (1) of the included diagnostic device, which is mounted on a table located opposite. In this case, the patient will see the work of the retina of the open eye, like a photograph, which will be reflected in the round and bright form of the radiation of the corona. Then the patient must tell the nurse the shape, size and color sensitivity of the corona radiation relative to the coordinates of the conditional fields of view of the screen (1) A, B or C, limited by the backlight LEDs (3). The light in the room turns off. The patient closes the right eye with a cardboard overlay and aligns the optical axis of the open left eye with the horizontal axis R of the light emitting LED (2) of the screen (1) of the diagnostic device. Looking at the center of light emission, the patient sees a luminous crown above a red emitter against a black screen and talks about this to his sister. If the patient has no vision problems, then the crown of the luminous emitter will be a luminous circle of bright red glow. The patient with his left eye sees the size, shape and density of this radiation on the dark screen (1) of the device. In this case, the brightness of color sensitivity of the patient confirms the high sensitivity of the retinal photoreceptors of his eye. If the patient has vision problems, the patient tells the nurse where the boundaries of the conditional fields of vision A, B or C are where there are differences from the circular image of the corona radiation on the screen of the device and the underestimation of color sensitivity. The patient evaluates and passes on to the nurse in words the size (by eclipsing the backlight LEDs (3)) and the shape of the perceived glow crown, which the nurse notes on the diagram for the left eye in the patient’s diagnostic chart. If the patient sees a bright corona reaching the backlight LEDs (3) of the visual field of vision (A), and the luminescence of the crown overshadows the weak glow of the backlight LEDs (3) of the visual fields (C and B), and the patient does not see blackout radiation or of dark spots, then the perimetry of vision on the red light of the patient is normal. If the patient sees blackouts or dark spots in the crown, he will notify the nurse. The locations of these dimming are indicated by the hour or degree marks of the backlight LEDs (3) of the circles of the field of view of the screen A, B or C, as well as their feelings of color sensitivity. On the diagram for the left eye of an individual diagnostic card, the nurse notes the size and shape of the visible image of the central red light emitter (2). Then, to determine visual acuity, the nurse invites the patient to pay attention to the central R glowing LED (2), the light emission from which is accompanied by wave thermal radiation. This radiation has the form of thin diverging circles moving from the center, which, when moving to the periphery, gradually increase in size and, when cooled, dissolve in the corona of light emission. The patient says to what extent the conditional field of view of C or B can be observed by this unusual phenomenon. The fixation of the displacement of diverging heat waves R of the light emission to the boundary of the conventional field of view (C) indicates the visual acuity of the eye of at least 1.0. This completes the diagnosis of the left eye vision on the R LED (2) and the diagnostic procedure is switched to the G light emitter (2) by switch P1, switching it to position 2 of the adapter (9). The patient, as in the first examination, combines the optical axis of his open left eye with the optical axis G of the light emitter (2) located in the center of the screen (1), and the same program is used to diagnose vision perimetry, color sensitivity, brightness and visual acuity of the eye. The nurse enters the same diagram into the individual diagnostic card diagnostic parameters - the reaction of the eye to green light. Then, the nurse switches the vision diagnostic device to the blue light emitter (2) using the P1 microswitch, turning the P1 microswitch to position 3, in which the patient repeats the previous sequence of recording the corona radiation characteristics in the diagnostic card. When determining visual acuity at one of the central LEDs (2), when the patient weakly sees or does not see diverging thermal waves of light emission, he is selected with a spectacle lens to a visual acuity of 1.0 or, to improve vision, a laser recommendation is written in an individual diagnostic card correction. Thus, the diagnostic diagrams of the left eye contain three individual characteristics of the patient’s left eye when defined in R, G and In color: the perimetry of vision, the brightness of color sensitivity of these colors, as well as the characteristic of visual acuity. The patient’s right eye is subjected to the same procedure with careful recording of all characteristics in the diagnostic map of the right eye.

To diagnose anomalies in color perception in people suffering from a reduced ability to perceive any color, the present invention provides an ophthalmologist with the opportunity to diagnose vision both in individual colors and in combination of colors. For this, the adapter (9) of the diagnostic device has a microswitch (P1), which allows you to turn on any of the central LEDs (2) R, G, B for diagnosing the patient’s vision, you can additionally add colors by turning on any of the microtum switches R, G, B of the adapter ( 9). For example, you can turn on red using the microswitch P1, and use microtumber B or G to turn on additionally blue or green, or both at the same time, creating a mixture of colors. Or turn on the green LED with the P1 microswitch and add a blue color, etc. The simultaneous illumination of color LEDs allows one to evaluate the possibilities of color sensitivity of the photoreceptors of the retina of the patient’s eye in a wide color range. In the process of diagnosing vision for color sensitivity, the nurse can change the illumination of the backlight LEDs (3) from green to red, or by combining red with green using the P2 microswitch, get a yellow color for the backlight, moving it to position 3. Diagnostic results of the patient’s eye vision for light sensitivity also are entered in the individual patient card. After such a thorough diagnosis of the left eye, they switch to the diagnosis of vision of the right eye, for which the patient is given several minutes of rest with the lights on in the room. This short rest time helps the patient to understand the importance of having an eye examination on time, because during this procedure the patient directly not only sees, but also feels the state of his own eye. After a short rest, the ophthalmologist turns off the light in the room, the patient closes the left eye with a cardboard lining. Diagnosis of the right eye for the detection of anomalies in color light perception repeats the procedure for diagnosing the left eye. Diagnostic results for the right eye are also recorded on the patient’s diagnostic card. For a patient who weakly perceives color changes, one or another form of color blindness is revealed in the diagrams, with the prescription of an additional examination and treatment. For example, the correction of color sensitivity is carried out using special lenses, and diseases and anomalies of the retina are treated using laser technology.

The operation of the device for the diagnosis of vision is to provide conditions for determining the characteristics of: perimetric vision, visual acuity and color sensitivity. So, for example, for perimetric vision, the microswitch P1 of the adapter (9) sets one light emitter - from R, G or B of the central LEDs (2). And the microtumber switch N is set to position (1) for selectively turning on the backlight LEDs (3) using the control buttons Кн1-Кн24, or to position 2 for simultaneously turning on the backlight LEDs (3) to highlight conditional fields of view A, B and C. To identify anomalies in color sensitivity of color blind people, R, G and B microtum switches, together with the P1 microswitch, it is possible to create a variety of colors (multicolor) on the central LEDs (2) of the screen (1). In addition to this mode, by activating the KN25 micro button, an additional limiting resistor R7 is turned on, which reduces the power supply current of the central LEDs (2) in order to detect color sensitivity for color blinds by lowering the brightness of the LEDs (2). In addition, the adapter (9) has a microswitch (P2), which allows you to change the color of the backlight from red (position 1) to green (position 2) and vice versa, and also allows you to combine the glow of red and green light emitting from the backlight LED to obtain yellow light emission ( position 3). In addition, for the visually impaired, the microtumber switch S of the device allows you to switch the operation of the central R, G or B of the LED (2) from the “normal” mode in position 1 to the “bright” mode - position 2.

The presented invention makes it possible to evaluate the slightest deviations from the norm, the depth of visual field defects at different color combinations of emitters, color sensitivity disorders at the very early stage of the development of color blindness disease, as well as to evaluate the degree of color sensitivity and the magnitude of visual acuity of the eyes. The procedure for the proposed diagnosis of vision is indispensable in identifying early cataracts, pathologies of the retina and optic nerve. If two LEDs of different colors are added to the main LEDs (2), then the proposed diagnostic device may well replace the ophthalmoscope. The proposed device for the diagnosis of vision allows you to examine patients with any visual impairment in the conditions of ophthalmic regional offices, at home and even bedridden patients. It is distinguished by low weight and size (for a screen, the weight is not more than 1.0 kg, 25 cm · 25 cm, thickness is not more than 1.5 cm, for the adapter weight is not more than 1.5 kg), reliability and ease of operation. In functional terms and in terms of price - quality, the proposed invention is many times superior to modern complex vision diagnostic devices and can be used in any clinics in the country (especially in subsidized regions) and at home.

Literature

1. S.N. Basinsky, E.A. Egorov: "Clinical Lectures in Ophthalmology", 2007, ed. GEOTAR-Media INSBN.

2. Rabkin EB Polychromatic tables for the study of color perception. - Minsk, 1998.

3. Izmailov Ch.A., Sokolov E.N. Metric characteristics of a spherical color discrimination model // Tomsk State University Journal. Moscow State University. Ser. 14. Psychology. 1978. No. 2. S. 47-61.

Claims (2)

1. A method for determining the characteristics of vision, including conducting a study, characterized in that the study is carried out by: presenting to the patient in a dark room from a distance of 1.0-1.5 m a black screen on which there are three concentric circles A, B, C with a diameter 15, 10 and 5 cm, respectively, along the contour of which are matte two-color backlight LEDs evenly placed and in the single center of which are three bright LEDs R, G, B; and fixing in the patient’s diagnostic card the visual sensations that arise, in order to determine visual acuity, the patient uses the fact of registration of diverging waves of thermal radiation accompanying the light emission of the R or G or B LEDs, and to determine the color sensitivity of the retina photoreceptors, the degree of light emission of the color LEDs described by the patient or their combinations. 2. A device for determining the characteristics of vision, characterized in that it consists of a polymer square black screen on which there are three concentric circles of the conditional fields of view A, B and C for determining the characteristics of vision, the first of which is calibrated from 0 ° to 360 °, with diameters of 15, 10 and 5 cm, along the contour of which two-color backlight LEDs are evenly placed in the amount of 12, 8 and 4 pcs. respectively, and in a single center of which there are three bright R, G, V LEDs, and a network adapter with a DC voltage source of + 3V for powering the LEDs on the screen with a set of microswitches, micro tumblers and micro buttons that ensure the selected LEDs glow.

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