RU76558U1 - VISUAL EASY CONTROL DEVICE - Google Patents

Abstract

The utility model relates to ophthalmology and is intended to determine visual acuity.

The objective of the proposed device is to create the possibility of electrical control of the process of changing the optotype, changing over a wide range, determined by the tasks of controlling visual acuity, the size of the optotype, its shape and orientation with the optotype remaining in the field of view of the device. The task solved by this utility model also includes the possibility of determining retinal visual acuity in the practical absence of the influence of refraction of transparent media of the eye and cataract of the lens of the patient’s eye.

The problem is solved in that in the device for controlling visual acuity including the light source located along the light rays, the first optical system forming the illuminating light beam, the plate forming the signs of optotypes, the second optical system serving to form the image of optotypes on the retina of the eye, according to the proposed solution, the plate is made in the form of a banner display with the possibility of external electrical control of its light transmission in predetermined areas of the plate corresponding to the shape and size of the signs of optotypes, and the second optical system is configured to form an image of the light source in the pupil of the patient’s eye. The transparency display is made of liquid crystal with electrodes, the shapes and sizes of which correspond to the shape and size of the optotypes. The banner display electrodes have a matrix structure. In the direction of the rays of light, a translucent plate is installed in front of the banner display, and a mirror is installed behind the banner.

Description

The utility model relates to medicine, and more specifically to ophthalmology, and can be used to control visual acuity in ophthalmic diseases and in healthy patients.

Known devices for determining visual acuity, with the help of which images of optotypes are formed on the retina of the eye - special signs or periodic gratings having one or another angular size of the elements of these signs or the angular period of the gratings. In particular, a device for determining visual acuity is known, including a light source that collects a (condenser) optical system, a plate with a set of gratings as optotypes, a special rotary prism, and an optical system that is designed to work together with the eye to form an optotype on the retina . This device uses a plate with gratings deposited on it with a different period of strokes. The image of one of the gratings is projected using the imaging optical system onto the retina. Visual acuity is assessed by the ability of the eye to distinguish strokes of the lattice with the shortest period (see US patent No. 5479221, IPC АВВ 3/10).

The main disadvantage of this device lies in the mechanical method of changing the lattice with one period of strokes on the lattice with another period of strokes and the mechanical method of changing the orientation of the strokes of the lattice using a special rotary prism. If necessary, changes in the shape and types of optotypes when measuring visual acuity also require the mechanical replacement of a plate with gratings, for example, a plate with other optotypes, which leads to inconvenience in operation.

Closest to the proposed is a device that overcomes the disadvantage of the above device. The device includes a matrix light source, consisting of individual elements that independently emit light, a unit for generating commands and controlling the operation of the matrix light source, a plate with optotypes optically coupled to individual elements of the matrix source, and depicting an optical system for forming optotypes on the retina of the eye. In this device, it is possible to individually highlight a single optotype or group of optotypes using a matrix source and a command and control unit, and, accordingly, it is possible to form images of an individual optotype or group of optotypes of a certain size and type on the retina. The change of the image of one optotype to the image of an optotype with a different angular size is realized and controlled by an electric

way by switching the highlight of the optotype by switching the elements of the matrix source. For this, a unit for generating commands and controlling the operating mode of the elements of the matrix light source is introduced into the device (see RF patent No. 21644074, IPC АВВ 3/02).

The main disadvantage of this device is that to determine the visual acuity over a fairly wide range, a plate with a sufficiently large number of optotypes of various sizes with an appropriate number of elements of a matrix light source is needed. This imposes restrictions on the size of the plate and, accordingly, on the dimensions of the optical system and the entire device as a whole. In addition to this disadvantage, the device has a disadvantage in that optotypes of various sizes are located on the plate in different parts of the field of view and therefore their images are formed under different conditions that differ from the conditions for the formation of images of the optotype located on the optical axis of the system. The disadvantages of the device include the different luminous intensities of individual elements of the matrix source, which also affects the conditions for the formation of images of optotypes located in different places of the plate. The disadvantages of the device include the lack of the envisaged ability to control retinal visual acuity in the practical absence of the influence of refraction of transparent media of the eye, as well as cataracts of the lens.

The objective of the proposed device is to create the possibility of electrical control of the process of changing the optotype, changing over a wide range, determined by the tasks of controlling visual acuity, the size of the optotype, its shape and orientation with the optotype remaining in the field of view of the device. The task solved by this utility model also includes the possibility of determining retinal visual acuity in the practical absence of the influence of refraction of transparent media of the eye and cataract of the lens of the patient’s eye.

The problem is solved in that in the device for controlling visual acuity including the light source located along the light rays, the first optical system forming the illuminating light beam, the plate forming the signs of optotypes, the second optical system serving to form the image of optotypes on the retina of the eye, according to the proposed solution, the plate is made in the form of a banner display with the possibility of external electrical control of its light transmission in predetermined areas of the plate corresponding to the shape and size of the signs of optotypes, and the second optical system is configured to form an image of the light source in the pupil of the patient’s eye.

The transparency display is made of liquid crystal with electrodes, the shapes and sizes of which correspond to the shape and size of the optotypes. As an example, such a banner can be a liquid crystal banner (Vasiliev A.A., Keysesent D., Kompanets I.N., Parfenov A.V. Spatial light modulators. - M .: Radio and communications, 1987. 320 s; Groshev A.A., Sergeev V.B. Information display device based on liquid crystals.- L. Energia, 1977, 68 s; Sukharier A.S. Liquid Crystal Indicators.M: Radio and Communication, 1991. 256 p.).

The banner display electrodes have a matrix structure.

In the direction of the rays of light, a translucent plate is installed in front of the banner display, and a mirror is installed behind the banner.

A special shape of the banner display electrodes or a matrix set of banner display electrodes allow you to change its transmission in areas corresponding in shape and size to the shape and size of a particular optotype, which serves to determine the visual acuity of the patient. Electrical control of the local light transmission of the banner-display is carried out using a special electronic control unit - a command and control unit, which generates an electric signal supplied to the corresponding electrodes of the banner. The shape and dimensions of the electrodes determine, respectively, the shape and dimensions of the optotypes. The electrodes can have a matrix structure and consist of many elements - pixels, with the help of which it is possible to form a given transmission area of the banner display, corresponding to the shape and size of a given optotype.

The utility model is illustrated by drawings, where Fig. 1 is an optical diagram of a visual acuity control device; figure 2 - as an example presents the image of the plate with different light transmission in areas corresponding to different optotypes; figure 3 presents a variant of the optical system of the device for controlling visual acuity.

The device contains (see Fig. 1) a light source (for example, a white light-emitting diode LED, or a quasi-monochromatic light emitting diode of one color or another; an incandescent lamp can be used) 1, the first optical system 2 (collecting (condenser) optical system), a plate forming optotypes 3, the command and control unit 4, the second optical system 5 (depicting the optical system), designed to form the optotype on the retina of the patient's eye 6. At the same time, the light source 1 collecting optical system 2, plates 3

forming optotypes depicting the optical system 5 and the eye 6 of the patient are arranged sequentially along the rays of light.

The optical system of the device for controlling visual acuity may additionally contain a translucent plate 10 (Fig.3) and a mirror with a high reflection coefficient 11 mounted along the rays of light from the source.

The device operates as follows. Using a light source 1 and a collecting optical system 2, an optical beam is formed, which is sent to a plate 3, forming optotypes. As this plate, this device uses a controlled transparency display, the light transmission of which can be changed with the help of electrical signals generated by the command and control unit 4, in predetermined areas corresponding in shape and size to a particular optotype. Figure 2 shows as an example images of a plate 3 with different light transmission in the regions corresponding to the following three optotypes: 7 - Landolt ring, 8 - letter of the Russian alphabet (Cyrillic), 9 - lattice. The rays of light passing through the banner display experience different absorption in different areas of the plate. Thus, spatial modulation of the light beam is carried out and the optotype of a given size and type is reproduced. A light beam spatially modulated in intensity using an imaging optical system 5 at a certain distance, such that the image of the source 1 formed by the system 5 is located in the pupil of the patient’s eye. This arrangement of the eye provides the formation of a practically projection image of optotite on the retina, since in this case, with a sufficiently small source size and, accordingly, a small image size, light penetrates the eye only through a small area of the cornea and lens of the eye. Therefore, the refractive properties of these eye media have a negligible effect on the image formation process. In addition, the formation of a small image of the light source in the region of the pupil of the eye allows us to solve another important problem associated with the determination of visual acuity with cataract of the lens. In this case, clouding is formed in the lens, which prevents the formation of a clear image on the retina. However, in these opacities, as a rule, there are areas of transparency. By directing a focused beam of light into these areas of transparency (forming an image of the light source in them), using this device you can get a clear image of the optotype on the retina of the patient’s cataract eye.

The device, the circuit of which is presented in figure 3, works similarly to the device according to the scheme in figure 1. In the diagram of figure 3 introduced additional elements -

a translucent plate 10 and a mirror with a high reflection coefficient 11. The introduction of these elements allows the use of a controlled transparency display in the mode of double passage of light through it. The light from the source and lens 2 is partially reflected from the plate 10, passes through the banner display 3, is reflected from the mirror 11, again passes through the same sections of the banner display, then through the plate 10 and is sent to the patient’s eye using the optical system 5. Using this device, as well as using the device in figure 1, receive the image of the optotypes formed by the banner display 3, while focusing the image of the light source 1 in the pupil of the patient’s eye.

Claims (4)

1. A device for controlling visual acuity, including a light source located along the light rays, a first optical system forming an illuminating light beam, a plate forming signs of optotypes, a second optical system serving to form an image of optotypes on the retina of the eye, characterized in that the plate made in the form of a banner display with the possibility of external electrical control of its light transmission in predetermined areas of the plate, corresponding in shape and size to signs of optotypes, and the second optical The sky system is configured to form an image of a light source in the pupil of the patient’s eye. 2. The device according to claim 1, characterized in that the transparency display is made of liquid crystal with electrodes, the shapes and sizes of which correspond to the shape and size of the optotypes. 3. The device according to claim 2, characterized in that the banner display electrodes have a matrix structure. 4. The device according to claim 1, characterized in that a translucent plate is installed in front of the banner display along the rays of light, and a mirror is installed behind the banner.