SU1680058A1 - Keratometer - Google Patents

Abstract

The invention relates to medical technology, in particular, to devices for determining the relief of the outer surface of the cornea of the eye. The purpose of the invention is to improve the accuracy and efficiency of measurements. The device contains a point source 1 of light, a convex three-element mirror 2 with a generatrix of three segments of straight lines, a concave three-element mesoptical mirror 3 with a generator of three parts parabolic, a point photodetector 4, a system 5 of transverse linear displacement and position control of the device, block 6 data recording . The device works as follows. The patient's head must be positioned in a position where the beam of light passes along the line on which it is required to find the profile of the cornea. With the help of system 5, the device is moved and produced data on the profile of the cornea using the block 6 of data recording. 1 il. with s

Description

The invention relates to medical equipment, in particular to devices for determining the relief of the outer surface of the cornea of the eye (keratometers).

The aim of the invention is to improve the accuracy and efficiency of measurements.

The drawing shows a schematic diagram of a keratometer.

The device contains a point source of light 1, a convex three-element conical mirror 2 with a three-element straight line, a concave three-element meso-optical mirror 3 with a three-piece parabola and a cutout in the center, a point photodetector 4, a system of lateral linear movement and control of the device relative to cornea of the patient’s eye, data recording unit 6. Mirrors 2 and 3 are made as a single unit.

The outer and inner segments of the generatrix of the conical mirror 2 are a continuation of each other, and the middle segment of the generatrix is located at an angle φ to adjacent segments of the generatrix, while the value of the angle φ is selected from the condition φ-arcsln

ΠΖ __________

Li + L2 + r2cos y - arcsln

G2

Li + r2cos γ where Г2 is the distance from the center of the middle segment of the generatrix of mirror 2 to the optical axis of the keratometer; 2 y - the angle at the apex of the cone of the mirror 2; Li is the distance from the top of the cone of the mirror 2 to the light source 1; L ₂ is the distance from the light source 1 to the photodetector 4.

The outer part of the generatrix of the meso-optical mirror 3 has the form of an arc of the first parabola, the focus of which is at the point where the imaginary image of the light source formed by the mirror 2 is located, and the axis of the first parabola is parallel to the central ray of light coming from the outer part of the generatrix of the mirror 3 to the cornea of the eye. The inner part of the generatrix of the mirror 3 has the form of an arc of the second parabola, the focus of which is at the point where the imaginary image of the light source 1, formed by the mirror 2, is located, and the axis of the second parabola is parallel to the central ray of light coming from the inner part of the generatrix of the mirror 3 to the cornea of the eye. The middle part of the generatrix of the mirror 3 has the form of an arc of the third parabola, the focus of which is at the point where the imaginary image of the photodetector 4 is formed by the mirror 2, and the axis of the third parabola is parallel to the central ray of light coming from the illuminated part of the cornea of the eye to the middle part of the generatrix of the mirror 3. _

The function of the optical lighting system is performed by the external elements of both mirrors, and the function of the lens is performed by the internal elements of the mirrors.

The device operates as follows.

Turn on the light source 1 and the photodetector 4, prepare the system 5 transverse linear displacement and 10 control the position of the device. Include block 6 data recording. The patient’s head is set in a position in which a ray of light goes along the line on which you want to find the profile of the cornea of the eye. Then, using the system 5, the device is moved and the corneal profile data is acquired using the data recording unit 6. In this case, the light rays coming out of the light source 1 illuminate the conical mirror 20 2, the light rays that are reflected from the two outer parts of the conical mirror 2 fall on the two outer bands of the meso-optical mirror 3 and, reflected from the latter, intersect each other on the optical axis devices at the location of the cornea of the eye. If the portion of the cornea of the eye on the optical axis of the keratometer falls into the region where the light intensity is maximum, then the reflected rays of light, which 30 are captured by the middle belt of the meso-optical mirror 3, are sent to the middle zone of the conical mirror 2 and then fall into the point photodetector 4 located below the point source 1 35 light. The signal of the photocurrent from the photodetector 4 enters the block 6 data recording. There is also data on the position of the keratomet-. RA, formed in the system 5. If the portion of the cornea of the eye fell into the region where 40 the light intensity is zero, then there will be no reflected light rays and there will be no photocurrent signal.

Claims (1)

Claim A keratometer containing a point source of light, an optical system for illuminating the surface of the cornea of the eye, a lens, a point photodetector, a data recording unit, as well as a system of transverse linear displacement and position control, which are characterized in that in order to increase the accuracy and efficiency of measurements, the optical system for lighting the surface of the cornea of the eye and the lens are made in the form of a block consisting of a convex three-element conical mirror with a generatrix of three segments of straight lines and a concave three-element ezoopticheskogo mirror with the generatrix of the three parts of parabolas, wherein the inner and outer segments of the generatrix of the conical mirror are a continuation of each other, and the average length of the generatrix is at an angle φ to the adjacent segments of the generatrix, while the angle φ is selected from uelo ^Via g η 1 r - ί * P ^arcsln | ^jLi -4- L2 H- g2soz yj ^{arcs, n} γ, where G2 is the distance from the center of the middle segment of the generatrix of the conical mirror to 1 optical axis of the keratometer; 2 y is the angle at the apex of the cone of the conical mirror; Li is the distance from the top of the cone of the conical mirror to the light source; 1_2 is the distance from the light source to the photodetector, 1 the outer part of the generatrix of the meso-optical mirror has the form of an arc of the first parabola, the focus of which is at the point where the imaginary image of the light source formed by the conical 2 mirror is located, and the axis of the first parabola is parallel to the central ray of light going from the outer part of the generatrix of the mesoptic mirror, the inner part of the generatrix of the mesoptic mirror has the form of an arc of the second parabola, whose focus is at the point where the imaginary image is located regular enrollment light formed conical mirror, and the axis of the parabola is parallel to the second central ray of ^light; coming from the inner part of the generatrix of the mesoptic mirror, the middle part of the generatrix of the mesoptic mirror has the form of an arc of the third parabola, the focus of which is at the point where the imaginary image of the photodetector formed by the conical mirror is located, and the axis of the third parabola is parallel to the central ray of light going to the middle part of the generatrix of the mesoptic mirrors.