RU2669228C1 - Spheroperimeter - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: group of inventions relates to medicine, namely to ophthalmology. Spheromperimeter contains a screen with light test objects and a positive lens. Spheroperimeter is made in the form of spectacles in which one optical channel is used consisting of a positive aspherical Fresnel lens that is curved along a cylindrical surface and the screen is curved along a cylindrical surface. Radii of curvature of the cylindrical surfaces of the lens and shield are equal, and their symmetry axes are parallel and displaced to the focal length of the lens along the optical axis of the system. Angle of view of the eye is determined with the help of a control system for light test objects built into the spheroperimeter and an electrically connected electronic button. In another embodiment of the spheroperimeter, the control system of the light test objects is electrically connected to the eye oscillation sensor.EFFECT: application of this group of inventions will reduce the size of the device for use at home.6 cl, 1 dwg

Description

The invention relates to medicine, in particular to ophthalmology, and can be used for early diagnosis of primary glaucoma and other diseases that reduce the field of view of the human eye.

It is known that to detect the development of optical neuropathy, in particular with glaucoma, early detection of the initial changes in peripheral vision is of great importance. The initial signs of optical neuropathy are determined by lowering the threshold of sensitivity of the retina. Known devices for examining the field of view (copyright certificates No. 430841, 596219, 654245, 810209, 950305, 1205890 and SU patent No. 1489572), which have a common significant drawback due to the physiology of the face (the presence of the nose, eyebrow and zygomatic bone). These devices do not allow to study the full boundaries of the field of view of the eye, but only its certain narrowed areas. As a rule, these are: upward 55–60 °, downward 65–70 °, to the nose 55–60 °, to the zygomatic bone 90 °. Thus, without research, the lateral parts of the retina remain, the state of which is crucial in the early diagnosis of retinal diseases, which is recorded as a manifestation of the “nasal step”.

According to the international standard ISO 12866, light stimuli (light test objects) are used to determine the angle of peripheral vision, the sensitivity of the retina and the contrast of lateral vision (which should be clearly visible (be at a convenient observation distance of at least 250–300 mm), have a size of up to 0 , 75 mm (angular size up to 3 mrad), be able to change the brightness and on-time. The use of light emitting diodes as light test objects located on a spherical surface of small radius as close to the eye as possible (RF patent No. 2285440) is convenient, but does not allow fulfilling the main condition of the international standard ISO 12866 - a clear observation of the optical stimulus. As you know, it is impossible to clearly observe an object located at a distance of 50 ÷ 70 mm from the eye. In addition, the second requirement of the international standard ISO 12866 is violated - the size of the optical stimulus at the optimal observation distance should not exceed 0.75 mm. Since the LEDs are close to the eye and their standard sizes are usually not less than 1 mm, they have angular dimensions larger than necessary (according to calculations - more than 14 mrad).

In the invention, RF patent No. 2463947, presents an attempt to create a small sphere perimeter that complies with the requirements of the international standard ISO 12866. This invention uses a hemispherical screen with light test objects (stimuli) of a certain diameter installed, and a corrective lens is installed in front of the eye that builds an imaginary image of optical stimuli at an optimum distance for eye observation. The spherometer is paired with a personal computer. In addition, the overall dimensions of the presented sphere perimeter and the requirements for operation do not allow using it at home.

The technical result of the invention is aimed at creating a spheroperimeter of the minimum size - in the form of glasses, which will allow it to be used at home with maximum automation of the measurement process.

In the present invention, the technical result is achieved by using a sphere perimeter in the form of glasses, in which one optical channel is used, consisting of an aspherical positive Fresnel lens curved along the cylindrical surface, curved along the cylindrical surface of the screen, which forms light test objects, while the radii of curvature of the lens surfaces and of the screen are equal, and the centers of curvature are shifted by a distance equal to the focal length of the lens along the optical axis of the system.

The invention is illustrated by figure 1.

The figure 1 presents the optical scheme of the spherometer.

It is known that a point object located in the focal plane of an ideal (aspherical) lens is observed by the eye at infinity (without tension), and a point image of the object is built on the retina of the eye. To reduce the size of a spherical perimeter and reduce spherical aberrations, you can use a screen in the form of an indicator created using the LCD or OLED technology used in phones, smartphones, projectors and flat TVs, and place its pixels in the focus of the aspherical Fresnel lens. This method of constructing images at infinity is used in most modern virtual helmets (glasses). Unlike virtual glasses (helmets), where two identical optical channels are used (for each eye), for a sphere perimeter it is enough to use one channel of vision. The maximum angles of formation of light test objects in this way ± 45 ° from the axis of symmetry of the circuit, which is not enough to diagnose diseases of the retina when it is necessary to form the maximum angles of observation of light test objects up to ± 90 ° from the axis of symmetry of the circuit.

To increase the viewing angle of light test objects, you can bring the Fresnel lens to the eye as close as possible, but then spherical aberrations (such as distortion) will grow, while the maximum angle of formation of light test objects will increase by only ± 10 °, which is not enough.

Some manufacturers of virtual helmets (glasses) use an additional lens and an additional screen mounted at the focal length of the lens and parallel to each other to increase the angle of view of virtual space in each channel. This construction allows you to create virtual helmets with viewing angles of virtual space (the angle of formation of light test objects) to the zygomatic bone more than 90 ° from the optical axis, so the method can be used in a sphere perimeter. Significant disadvantages of a sphere perimeter with such an optical design are the increase in price (several times), the complexity of the software (stitching images for multiple screens), and the presence of junction points for tilted lenses where useful information is missing.

The authors propose to use the following spheroperimeter device to increase the angle of formation of light test objects: a spherical perimeter in the form of glasses, in which one optical channel is used, which consists of a positive Fresnel aspherical lens bent along a cylindrical surface, and a screen containing a light test bent along a cylindrical surface objects, while the radii of curvature of the cylindrical surfaces of the lens and the screen are equal, and their axis of symmetry is parallel and offset by the focal length of the lens along the optical axis of the system, while the angle of view is determined using the control system of light test objects of the spherometer and an electronically connected electronic button.

The operation of the spheroperimeter is illustrated using FIG. 1. A sphere-perimeter in the form of glasses is put on the patient’s face, while for the studied eye 1, one optical channel is used, and the second eye is darkened. Further, in the optical channel, the light test object control system is turned on according to a specific program for the light test object 4. The light flux from the test object (pixel) 4 of the screen 3, curved along the cylindrical surface, passes through the positive Fresnel lens 2, also curved along the cylindrical surface . The calculations showed that if the radii of curvature of the cylindrical surfaces of the lens and the screen are equal, and their axis of symmetry is parallel and offset along the optical axis by the focal length of the lens, then the image of any test object 4 will be observed by the eye at infinity (without voltage). In this case, spherical aberration is manifested - distortion, which can be compensated electronically by shifting the pixels of the screen. With this construction of the optical scheme, the viewing angles of light test objects reach ± 90 ° from the central axis of the system. In the process of determining the field of view of the eye, the central light test object is constantly illuminated on the screen, and the peripheral light test object is moved to the side and periodically briefly turned on. In this case, the patient should focus on the central, constantly glowing test object, and when the peripheral light test object is turned on for a short time, confirm with the electronic button that the peripheral test object is observed. If the peripheral light test object is not observed, then the button is not pressed. According to the international standard ISO 12866, to diagnose the sensitivity of the retina, it is necessary to control the brightness of the light test objects, and to measure the light contrast it is necessary to change the overall light background against which the light test objects are observed. To do this, you can use standard LCD, OLED, AMOLED screens, the pixel size (minimum diameter of the light test object) which reaches 63 microns. In addition, there are already screens made using LCD and flexible AMOLED technology (www: oled-info.com) that can be bent (bending radius up to 10 mm). Information on the results of measuring the field of view of the eye can be displayed on the information screen, which is used to form light test objects, or on an external device (smartphone, personal computer, etc.). As a control system for light test objects of a sphere perimeter, you can use the microcontroller built into the sphere perimeter or an external device (smartphone, netbook, tablet or personal computer).

To carry out the procedure for diagnosing the state of the retina of the second eye, it is advisable to provide for the construction of a spherometer with the possibility of flipping the glasses of the spherometer and performing the procedure on the second eye.

Using a button connected by wires to the glasses of a spherical perimeter can cause some inconvenience when using a spherical perimeter; therefore, it is proposed to use a button associated with the control system of light test objects of a spherical perimeter via a radio channel (for example, via a blue-tooth channel).

To further automate the process of diagnosing the retina, the authors propose to use the vibrational reflex of the eye in the event of a short-term light signal on the periphery of the eye. This reflex is due to the fact that if a person observes an object in front of him and at this time the light impulse is registered with the side vision, then the eye will involuntarily twist towards the light impulse. This property of the eye can also be used to diagnose the retina with a spherometer, and there may be no electronic button, and eye vibrations can be detected using an eye vibration sensor, which can be used as a short-focus video camera, a probe mounted on the eyelid, or an optical triangulation sensor etc.

Based on the foregoing, the authors propose the following device for a sphere perimeter: a sphere perimeter in the form of glasses, which use one optical channel, which consists of a positive Fresnel aspherical lens curved along the cylindrical surface and a screen curved along the cylindrical surface containing light test objects, while the radii of curvature the cylindrical surfaces of the lens and the screen are equal, and their axis of symmetry is parallel and offset by the focal length of the lens along the optical axis of the system, with the angle Rhenium is determined using light test objects sferoperimetra control system which is electrically connected to the eye sensor oscillations as can be used which short-camcorder probe, an optical triangulation sensor, etc.

The operation of the spheroperimeter is illustrated using FIG. 1. A sphere-perimeter in the form of glasses is put on the patient’s face, while for the studied eye 1, one optical channel is used, and the second eye is darkened. Further, in the optical channel, the light test object control system is turned on according to a specific program for the light test object 4. The light flux from the test object (pixel) 4 of the screen 3, curved along the cylindrical surface, passes through the positive Fresnel lens 2, also curved along the cylindrical surface . The calculations showed that if the radii of curvature of the cylindrical surfaces of the lens and the screen are equal, and their axis of symmetry is parallel and offset along the optical axis by the focal length of the lens, then the image of any test object 4 will be observed by the eye at infinity (without voltage). In this case, spherical aberration is manifested - distortion, which can be compensated electronically by shifting the pixels of the screen. With this construction of the optical scheme, the viewing angles of light test objects reach ± 90 ° from the central axis of the system. In the process of determining the fields of vision of the eye, the central light test object is constantly illuminated on the screen, and the peripheral light test object is moved to the side and periodically briefly turned on. In this case, the patient should focus his eyes on the central, constantly glowing test object, and if an eye vibration sensor is triggered when the peripheral light test object is turned on for a short time, this confirms that the peripheral light test object is observed. If the eye vibration sensor does not work, then it is concluded that the peripheral light test object is not observed.

Since in an ordinary person the reflex of moving the eye towards the light signal acts on both eyes simultaneously, structurally, the eye vibration sensor can be connected with the second eye, which is darkened during the procedure of measuring vision angles.

Claims (6)

1. A spherometer containing a screen with light test objects and a positive lens, characterized in that the spherometer is made in the form of glasses, in which one optical channel is used, consisting of a positive aspherical Fresnel lens that is curved along a cylindrical surface and the screen is curved along a cylindrical surfaces, while the radii of curvature of the cylindrical surfaces of the lens and the screen are equal, and their axis of symmetry is parallel and offset by the focal length of the lens along the optical axis of the system, while the angle of view of the eye is it is distributed using the control system of light test objects built into the sphere perimeter and the electronic button electrically connected to it. 2. The spherometer according to claim 1, characterized in that the electronic button is connected to the control system of light test objects of the spherometer perimeter over the air. 3. A spherometer containing a screen with light test objects and a positive lens, characterized in that the spherometer is made in the form of glasses, in which one optical channel is used, consisting of a positive aspherical Fresnel lens that is curved along a cylindrical surface and the screen is curved along a cylindrical surfaces, while the radii of curvature of the cylindrical surfaces of the lens and the screen are equal, and their axis of symmetry is parallel and offset by the focal length of the lens along the optical axis of the system, while the angle of view of the eye is It is distributed using a light test object control system built into the spherometer, which is electrically connected to the eye vibration sensor. 4. The spherometer according to claim 3, characterized in that a short-focus video camera is used as an eye vibration sensor. 5. The spherometer according to claim 3, characterized in that a probe mounted on the eyelid of the eye is used as a sensor for oscillating the eye. 6. The spherometer according to claim 3, characterized in that an optical triangulation sensor is used as an eye vibration sensor.

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