RU50794U1 - ABERROMETER WITH EYE GUIDING SYSTEM - Google Patents

Abstract

The utility model is an ophthalmic device - an aberrometer designed to automatically measure aberrations of the human eye and determine objective refraction in order to select spherical-cylindrical vision correction using glasses, individual contact lenses, intraocular lenses or laser ablation. The main technical result that can be obtained by implementing the utility model is to simplify the design of the device and improve its operating conditions, which is achieved due to the fact that in a device containing a point source of light that projects onto the retina of the eye and creates a virtual source on it, the radiation of which is scattered by the retina, passes through the optical systems of the eye, while acquiring phase modulation corresponding to the total optical aberrations of the eye, a measurement system for s of the wavefront of radiation emitted from the eye in the form of a wavefront sensor, the output signal from which enters the device control system, located between the human eye and the measurement system, a refraction compensator, consisting of two fixed lenses and a movable reflector, and a device setup device that includes a sensor image registering the frontal view of the eye, the refraction compensator further comprises a dichroic mirror located between its fixed lenses, which is simultaneously is a beam splitter for the device setup device.

Description

An ophthalmic device, an aberrometer, used in clinical practice, is used as a useful model. It is designed to automatically measure aberrations of the human eye and determine objective refraction in order to select spherical-cylindrical vision correction using glasses, individual contact lenses, intraocular lenses, or laser ablation.

To determine visual acuity in clinical practice, tables of symbols and paintings are used, the size of which (for a given distance, usually 5 m) corresponds to their different angular sizes on the retina. An angular size of “1 minute” corresponds to a vision unit (20/20 in English literature). By interviewing the subject, the smallest size of distinguishable characters is established, which determines visual acuity (for example, if the size of distinguishable characters is 5 minutes, then visual acuity is 0.5). The selection of the best spherical-cylindrical correction is carried out using test lenses or automated sets of such lenses (phoropters, refractors), while the correction results are controlled by the symbol tables. This process is rather laborious and time-consuming, especially in the presence of complex astigmatism (E.I. Kovalevsky “Ophthalmology” M.Meditsina, 1995, p45-83).

To accelerate the selection of correction, various methods of measuring refraction are used, for example, skioscopy, or automated devices - refractometers. In this case, the initial parameters of corrective lenses are selected based on the readings of these devices. More advanced instruments for measuring the optical characteristics of the eye are aberrometers, which can measure not only refraction and astigmatism, but also aberrations of higher orders.

A device of the same purpose is known as the claimed utility model, an ophthalmic device described in "Objective measurement of wave aberrations of the human eye with use of a Hartmann-Shack wave-front sensor" Junzhong Liang, Bernhard Grimm, Stefan Goelz, Josef F. Bille (JOSA A, Volume 11, Issue 7, 1949-July, 1994), for measuring aberrations of the human eye, containing a point source of light to illuminate the eye, which is projected onto the retina of the eye and creates a virtual reference source on it, the radiation of which is scattered retina, passes through the optical systems of the eye, while acquiring phase modulation w corresponding to a total optical aberrations of the eye, the measurement system forms a wavefront emerging from the eye a radiation Shack-Hartmann sensor, the output of which enters the system

instrument control, consisting of a computer that provides data processing, restoring the aberration map, data storage and instrument control by operator’s commands, and a refraction compensator located between the human eye and the measurement system, designed to control the focus of the scattered radiation of the retina.

A disadvantage of the known device is the lack of a system for setting (guidance) the device, i.e. combining the entrance pupil of the device with the pupil of the eye, which leads to a decrease in measurement accuracy, the greater the higher the order of the measured aberrations and their value, and is the reason that impedes the achievement of a technical result, which consists in increasing the accuracy of measuring aberrations (deviation of the measured aberrations from the true ones).

In the known ophthalmological device for measuring and operating the eye (US patent No. 5,562,656), a device adjustment device is implemented that includes a projection image of the marks on the patient’s eye with its illumination sources, a visual observation system for the relative position of the images of these brands, a system for three-dimensional movement of the aforementioned device relative to the patient’s eye. The projection system includes two projectors located at an angle to the optical axis of the device, which create an image of one or more slits on the cornea of the eye, observing the relative position of which through a microscope, judge the distance from the device to the eye.

The disadvantages of this device and its tuning method are the low accuracy of measurements, which is caused by the formation of a picture of the image of the marks on the cornea of the eye, the limitation of the scope of the device when using light sources of low power only to the visible region of the spectrum, which is uncomfortable for the patient, since the picture of the slits is formed on the cornea medium and observation is possible only due to its scattering: the scattered image of the slits will not be visible on the cornea in infrared areas of the spectrum due to low contrast. In addition, the design of the brands used in the prototype does not allow the operator to unambiguously determine the direction of misregistration.

The closest set of essential features is the well-known device selected as a prototype (WO 01/28408 A 2 “WAVEFRONT SENSOR HAVING MULTI-POWER BEAM MODES, INDEPENDENT ADJUSTMENT CAMERA, AND ACCOMMODATION RANGE MEASUREMENT”), containing a point source of light that is projected onto the grid eyes and creates a virtual source on it, the radiation of which is scattered by the retina, passes through the optical systems of the eye, acquiring phase modulation corresponding to the total optical aberrations of the eye,

a system for measuring the shape of the wavefront of radiation coming out of the eye in the form of a wavefront sensor, the output signal from which enters the device control system located between the human eye and the measurement system designed to control the focus of the radiation scattered by the retina, a refraction compensator consisting of two fixed lenses and a movable reflector and a device setting device that includes a video camera that registers the image of the pupil of the eye. For measurements and pointing the device at the patient’s eye, it is necessary to obtain an image of the pupil of the eye from a camera exposed along the optical axis of the device.

The reasons that impede the achievement of the main technical result indicated below are the presence of an additional beam splitter between the patient’s eye and the optical input of the device (the first lens of the refraction compensator), which diverts part of the radiation to the guidance video camera, but, as a result, reduces the front working segment of the device, which also creates uncomfortable conditions for the subject during measurements.

The disadvantages of the device and the prototype adjustment method are the low accuracy of setting the working distance due to the projections of spots (marks) on the cornea. Since, for accurate measurements, the entrance pupil of the device must be aligned with the pupil of the eye, and the cornea is removed from the pupil of the eye by a certain distance (the size of the anterior chamber of the eye), which is subject to individual variations, the adjustment of the device relative to the top of the cornea introduces difficult-to-control errors.

In addition, the method of projecting laser spots does not allow us to determine the sign of the alignment of the pupils of the eye and the device (i.e. whether the device is closer to the eye). This complicates the guidance process.

The problem to which the claimed utility model is directed is to expand the range of accurate ophthalmic devices for automatically measuring aberrations of the human eye and determining objective refraction.

The main technical result that can be obtained by implementing the utility model is to simplify the design of the device and improve its operating conditions.

Additional technical results consist in increasing the accuracy and stability of measurements, as well as creating more comfortable conditions for the patient and more convenient conditions for the operator when using the device.

The specified main technical result in the implementation of the utility model is achieved due to the fact that in the known device containing a point source of light, which is projected onto the retina of the eye and creates a virtual source on it, radiation

which is scattered by the retina, passes through the optical systems of the eye, acquiring phase modulation corresponding to the total optical aberrations of the eye, a system for measuring the shape of the wavefront of radiation emitted from the eye in the form of a wavefront sensor, the output signal from which enters the control system of the device located between the human with an eye and a measurement system, a refraction compensator, consisting of two fixed lenses and a movable reflector, and a device tuning device that includes a sensor Images for registering a front view of eye refraction compensator further comprises located between its fixed lens dichroic mirror which simultaneously a beamsplitter for the instrument setting device

Changing the design of the compensator reduces the total number of optical elements due to the combination of functions in one element (there is no need for a separate dividing plate). The installation of a beam splitter between the fixed lenses of the compensator leads to an increase in the front working segment, which in turn leads to weakening the requirements for aberration correction for the first lens of the compensator and, therefore, to simplify its design (in reality, this is usually not a separate lens, but a group lenses - the lens). In addition, the installation of a beam splitter between the fixed lenses of the compensator leads to an increase in the front working segment, which facilitates the adjustment of the device (since the anatomical features of the structure of the patient's face, such as the size of the nose, do not prevent the device from pointing)

Increasing the accuracy of measurements and simplifying the process of setting up the device is achieved due to the fact that the device setting device contains a projection system for the image of marks on the iris, and the projection system is two projectors or a projector of marks with two identical channels, which are located symmetrically relative to the optical axis of the device at an angle to it and at a distance from it in such a way that in the plane of the entrance pupil of the device, with its required adjustment, the images are identical and symmetrical GOVERNMENTAL respect to the vertical axis of the device marks converge, forming a circle with a cross. With this design of marks, it is possible to determine the direction of longitudinal movement.

The implementation in this device of a method of projecting marks directly onto the iris of the eye, allows you to more accurately combine the entrance pupil of the device and the pupil of the eye. This fact is due to the fact that the iris practically coincides with the optical pupil of the eye, while the distance from the top of the cornea to the pupil of the eye (in the prototype of the invention) is subject to significant individual variations. The image contrast is much higher even when using infrared

lighting, because the iris is opaque in the infrared and scatters this radiation well.

When implementing this method in the device, a difficulty arises caused by the blurring of one of the image boundaries, associated with the projection onto the inclined (relative to the projector) iris plane. To eliminate this difficulty, you can use a telecentric projection system with a large depth of field and an inclined position of the mark in the projector in accordance with the Sheimplefug principle (Theodor Scheimpflug's British Patent "Improved Method and Apparatus for the Systematic Alteration or Distortion of Plane Pictures and Images by Means of Lenses and Mirrors for Photography and for other purposes "(GB 1196/1904)).

Additional technical results, which include expanding the operational capabilities of an ophthalmic device and creating conditions more comfortable for the patient, are achieved by using infrared radiation sources in the device for adjusting the patient’s eyes and, as a result, using an infrared sensitive video camera in the visual observation system spectral region. Improving comfort is associated with the ability to configure the device in the absence of visible illumination of the eye.

Improving the convenience of servicing this device by the operator is achieved due to the fact that the claimed device for setting the ophthalmic device uses special marks of the "sector in a circle" type, the design of which is such that when their images converge in the plane of the entrance pupil of the device, a circle with a crosshair is formed. At distances shorter or greater than required, this picture is disturbed. From the view of the picture, it is easy to determine the direction of displacement of the device to accurately set the required distance to the eye being examined.

The claimed utility model implements a method for measuring the center-to-center and vertex distances using the instrument’s adjustment (guidance) system present in the aberrometer by sequentially pointing it at the center of one eye, then at the bridge of the nose and at the center of the second eye. The position of the device during these operations is fixed by a position sensor mounted on the movable table of the device. Using the device with this purpose expands its functionality.

An additional increase in the accuracy and stability of measurements is possible if there is a three-dimensional movement of the device in the device relative to the eye, which allows the device to be guided and fix its position.

The list of figures of the attached graphic materials:

FIG. 1- structural diagram of the claimed device

FIG. 2 - schematic optical diagram of the device

FIG. 3 is a diagram of the orientation of images of projected brands when setting up an ophthalmic device:

a) a view of the eye mounted at a working distance with a picture of the marks projected onto the iris

b) type and orientation of marks for two channels

c) pattern of misregistration of stamps at a distance less than the working

d) pattern of misregistration of stamps at working distance

e) picture of misregistration of stamps at a distance greater than the working

Figure 4 - optical diagram of the projector brands with a telecentric projection system

The following is information confirming the feasibility of implementing a utility model with the implementation of this purpose.

"Aberrometer with guidance system on the eye" has the following structural blocks (figure 1):

1) point source of light

2) a measurement system in the form of a wavefront sensor (for example, Shack-Hartmann type)

3) refraction compensator

4) tuning device (guidance camera)

5) projector of test pictures

6) control system (computer and microprocessor controller).

The design and principle of operation of the device is as follows (see figure 2).

The radiation from a point light source 1 (a semiconductor laser, a superluminescent diode or a light emitting diode with a small radiation area with a wavelength of 780 nm-850 nm) is incident on a polarization dividing cube 2, The laser radiation is polarized so that it passes almost completely through the dividing face of the cube (on figure 2 towards the left). The radiation passes through a rotating wedge 3, which scans the beam around the circumference. This is necessary to reduce the power density of laser radiation on the retina and suppress speckle modulation. The scan angle is approximately 0.5 °. Next, the radiation enters the telescopic system 4 with the necessary increase. After reflection from the dichroic mirror 5 (rotary mirror), radiation passes through a refraction compensator 6 (a telescope consisting of lenses 6a, 6d, with a movable reflector (prism) 6 b and a dichroic mirror (spectral beam splitter) 6 c), which allows you to control the focus of the laser beam . Leaving the device, the laser radiation enters the patient’s examined eye, focuses on the retina with optical

elements of the eye and creates on it a virtual reference source, the radiation of which is partially scattered on the retina and passes through the optical media of the eye in the opposite direction, acquiring phase modulation. The phase modulation of the beam emerging from the eye carries information about the total aberrations that characterize the optical system of the eye. This radiation passes through the already mentioned optical elements of the aberrometer in the opposite direction. However, since the radiation scattered by the retina is practically non-polarized, when passing through the polarizing beam splitter 2, one of the polarizing components is reflected from the dividing face and enters the telescope 7, which is necessary for pairing the entrance pupil with the plane of the lens raster 8 of the wavefront sensor 9.

The lens raster forms a picture in the form of a system of focal spots on a matrix of a standard CCD (charge-coupled device) or CMOS (complementary metal-oxide semiconductor) sensor camera (creates a set of images of a virtual source). The output signal from the matrix is transmitted to a computer, which restores the aberration map and generates control signals for the refraction compensator. Moreover, the measurement speed is determined by the speed of reading data from the camera to the computer and can reach 100 frames per second. The shift of the spots in the picture is proportional to the local slopes of the wavefront within the corresponding subaperture of the lens raster. By measuring these displacements, one can reconstruct the wavefront shape using the least squares method. Spot coordinates can be determined using the center of mass algorithm: [J. Lang, B. Grimm, S. Goels, J. Bill, "Objective measurements of the wave aberrations of the human eye using a Hartman-Shack wavefront sensor", J.OptSoc . Am. A, 11 1949-1957 (1994)]. The parameters of the lens raster are selected in such a way that when processing the picture of the Shack-Hartmann sensor, it is possible to restore the wavefront with an accuracy of 1/8 of the wavelength of the probe radiation. In this case, the wavefront shape can be represented by 36 Zernike polynomials.

The refraction compensator is necessary for correcting the defocusing of the wavefront of optical radiation with a given amplitude.

The refraction compensator 6 (6 a-6 d), located directly at the input of the device, operates as follows. After passing through the first lens 6 d of the refraction compensator, the radiation of the virtual reference source coming out of the eye enters the dichroic beam splitter 6c, made in the form of a cube or plate. The beam splitter selectively reflects the radiation of the visible spectrum and the infrared radiation of the reference point source 1, but transmits infrared radiation from the backlight of the tuning device. The reflected radiation falls on a movable reflector 6b, made in the form of a prism or a system of mirrors and, then, on the second lens

6 a compensator. This lens is located so that does not overlap the beam of rays that build the image of the eye. The prism drive 6 b is equipped with an optical or induction displacement sensor and an initial position sensor 10.

When conducting measurements, the subject must fix his gaze on the circle formed from the laser radiation of source 1 by a rotating wedge. This is not always convenient, since the radiation from laser 1 is infrared and its visual brightness is low. To improve the convenience of working with the device, a picture projector can be provided in it for fixing the gaze, working in the visible range. The projector consists of a lens system (lens) 11, which, together with the refraction compensator and the elements of the eye, provides the projection of the image of the picture 12 on the retina. The exit pupil of the projector is aligned with the image plane of the pupil (for example, with the exit pupil of the refraction compensator), and therefore with the entrance pupil of the eye. The test picture can be either passive (slide, transparency, liquid crystal panel), or self-luminous, for example, LED display. In the case of a passive picture, it is necessary to use a light source 13, which can be any radiation source (incandescent lamp, light emitting diode, etc.), with a corresponding capacitor 14, which projects the image of the light source into the plane of the exit pupil of the refraction compensator. Various paintings, compositions that attract the eye to the highlighted detail (for example, the image of a balloon against a desert highway) can be used as paintings.

The tuning device (guidance camera) of an aberrometer as an example includes (see Fig. 2): a projection system, which is a projector of marks with two identical channels 15 and 16, installed at an angle to the optical axis of the device, with sources for illuminating the eyes 17 a and 17 b, which can be used as LEDs, the image sensor is a video camera 18, the optical axis of which is combined with the optical axis of the device, with a lens 19, which together with the lens 6 d forms a complex telecentric lens (if there is no 6 d lenses, the image can be built simply with a camcorder lens). Since infrared radiation is used to illuminate the eye, a sensitive video camera in the infrared is used. A beam splitter of 6 s is used to combine the axes of the tuning and measurement channels.

In the projection system of the device settings device, instead of a brand projector with two identical channels, two Identical projectors can be used, which can be any lens, mirror-lens and mirror optical systems that create a brand image at some predetermined distance from the output aperture a projector. Usually each projector contains a source

light, condenser, brand and imaging lens. Preferably, the optical circuit of the projector should operate in the telecentric path of the rays. Projectors must project the image of the brand onto the iris at a certain angle to the optical axis of the device. Preferably, if the projection axis is located symmetrically with respect to the optical axis of the device.

In FIG. 4 shows the preferred type of projector brands: the lenses 20 a, b and 21 a, b form a telecentric projection system in which the brands 22 a and 22 b are inclined at an angle different from the perpendicular to the optical axis to compensate for distortions arising from oblique projection on the iris of the eye.

The system of three-dimensional movement of the device during its adjustment can be implemented similarly to the coordinate table used in slit lamps SHL56 or SHL2B (see L. S. Urmacher, L. I. Aizenshtat “Ophthalmic devices”, 1988, pp. 111-123). It should be noted that the system of three-dimensional movement of the device can be completely replaced or supplemented by a system for moving the patient’s eye relative to the device.

The adjustment (guidance) of the aberrometer in the infrared region of the spectrum is as follows.

The projector of marks projects specially formed images of marks (see FIG. 3) of the “sector in a circle” type onto the iris of the eye at an angle to the optical axis of the device. The angle and the distance between the channels are selected so that in the plane of the entrance pupil of the device, the images converge and form a circle with a crosshair (Fig. 3 d). At distances greater and less than required, this picture is disturbed (Fig. 3 c, f). The choice of the angle between the projector channels in the range from 15 to 60 ° is due to the following considerations: with a decrease in the angle, the guidance sensitivity decreases, at large angles, the operating range decreases.

The lens 19 of the video camera 18 builds an image of the patient’s eye on the matrix of the video camera (Fig. 3 a). In this case, the spectral characteristics of the beam splitter 6 s are selected in such a way that the infrared radiation of the backlight LEDs of the device setup device passes through it without attenuation, while the radiation of the reference source 1 and the radiation of the visible spectrum from the projector of the fixation pattern are reflected almost completely from it. From the view of the picture, it is easy to determine the direction of displacement of the device to accurately set the required distance to the object under study (human eyes). The image from the camcorder is transmitted to a computer monitor (or a separate video monitor). When setting up the device, the operator achieves combining brand images from both channels of the projector, which ensures that the working distance from

instrument to the eye, and the combination of the center of the pupil with the center of the coordinate grid deposited on the monitor.

When the tuning device is operating in visible light, the beam splitter 6c should be translucent, i.e. partially transmit and reflect the radiation of the visible spectrum. The division coefficient is determined by the relative energy sensitivity of the guidance and measurement systems.

An example of the implementation of the method for setting up an aberrometer may be a description of the design of the tuning device.

The implementation of the method for measuring intercenter and vertex distances is as follows.

To set the exact parameters of the spectacle correction, it is necessary to know the intercenter (distance between the centers of the pupils of the eye) and vertex (the distance from the top of the cornea to the plane of the spectacle correction) distances. The last distance is actually determined by the distance (in depth) from the nose to the top of the cornea. The device may use a sensor (optical, induction or otherwise) to move the coordinate table of the device, which allows you to remember the trajectory of the coordinate table on which the device is installed. Then, pointing the device sequentially at the center of one eye, then at the bridge of the nose and at the center of the second eye, you can determine the intercenter and vertex distances.

The control system of the device consists of a computer that provides data processing, restoring the aberration map, data storage and device control on the instructions of the operator and microprocessor controller.

Thus, the above information shows that when using the utility model the following set of conditions is fulfilled:

- a tool embodying the claimed invention in its implementation, is intended for use in the medical industry, namely for the automatic measurement of aberrations of the human eye and the determination of objective refraction in order to select spherical cylindrical vision correction;

- for the utility model as described in the independent clause of the stated formula, the possibility of its implementation using the means and methods described above or known prior to the priority date is confirmed.

Therefore, the utility model meets the condition of “industrial applicability”.

Claims (6)

1. Aberrometer containing a point light source located with the possibility of projecting it onto the retina of the eye, a system for measuring the shape of the wavefront of scattered radiation in the form of a sensor, a control system located between the human eye and the measurement system, a refraction compensator consisting of two fixed lenses and a movable reflector and a setting device including an image sensor for the eye, characterized in that the refractive compensator further comprises a dichroi located between the stationary lenses ny beam splitter. 2. Aberrometer according to claim 1, characterized in that the tuning device comprises a system for projecting images of marks onto the iris of the eye and sources of illumination of the eye. 3. Aberrometer according to claim 2, characterized in that the projection system of the tuning device is two projectors or a projector of brands with two identical channels, which are located symmetrically relative to the optical axis of the aberrometer, at an angle to it and at a distance from it with the possibility of convergence in the plane the entrance pupil of the aberrometer when adjusting images that are identical and symmetrical with respect to its vertical axis marks with the formation of a circle with a crosshair. 4. Aberrometer according to claim 3, characterized in that each brand has the form of a sector in a circle. 5. Aberrometer according to claim 2, characterized in that infrared sources are used as sources of illumination of the eye. 6. Aberrometer according to claim 3, characterized in that it further comprises a three-dimensional movement system relative to the eye.