RU2208377C2 - Method and device for detection of eye pupil - Google Patents

Abstract

FIELD: ophthalmologic optics. SUBSTANCE: the method has additional operations consisting in creation of the plane or real image of the eye pupil and subsequent localization of this plane. The plane of the real image of the pupil is optically integrated with the detector, and the energy pattern in the plane of the rear image is detected using additionally two kinds or radiation: radiation scattered by the eye means and that mirror reflected from the cornea surface. Winking is detected and used. The pupil image is localized is space using the radiant flow mirror reflected by the front surface of the optical system producing the real image of the pupil. Localization of the plane of pupil image and detection of the energy pattern in this plane are not associated with the spectral band and time parameters. The device has an illuminating channel, radiation source in the form of a laser. The mirror is installed on the inner face of the prism-cube located in the optical axis of the illuminating and transmitting channels. An objective lens is provided in the transmitting channel. The detector is installed in the plane of image optically integrated with the plane of localization of the rear image of the pupil. In the illuminating of the rear image of the pupil. In the illuminating channel the laser may be installed for replacement by a laser with radiation with another spectral band. In the transmitting channel the objective lens has an internal focusing. EFFECT: expanded functional potentialities, simplified production of the final result, reduced power consumption and enhanced adaptability to manufacture. 5 cl, 4 dwg

Description

 The group of inventions relates to the field of ophthalmic optics and can be used for clinical examination of the eye or search for an observer.

A known method of registering a pupil, which is implemented in an infrared television fundus camera at the stage of mutual orientation of the device and the eye, is to perform the following sequence of operations [1, 2]:
1) seat the patient at the device;
2) irradiate the patient’s eye using the infrared radiation source built into the device;
3) set the plane of localization of the pupil using the installation;
4) register the picture on the receiver of an infrared television camera;
5) observe it on the monitor screen.

 The disadvantage of this method is that it is developed on the assumption that the patient understands the task of registering his pupil and the corresponding behavior in front of the fundus camera, and this, of course, reduces the functionality of the method.

 The closest technical solution to the proposed method for the intended purpose and a combination of essential features is a method for registering the pupil of the eye, including localizing the image plane of the pupil, energetic illumination of the eye through the pupil using a radiation source and recording the energy picture through an optical system installed in front of the eye in the pupil plane with using the fundus as a diffusely reflecting screen [3] (prototype).

Specifically, the known method of skioscopy is the following sequence of operations [2, 3]:
1) the operator and the patient are located opposite each other;
2) artificially illuminate the examined eye through its pupil;
3) the operator operator accommodates his eye on the plane of the studied pupil;
4) the operator operator observes a picture of the glow of the studied pupil in the light diffusely reflected from its illuminated fundus;
5) the observed picture is recorded on the retina of the operator.

 To create a standard energy picture, interchangeable lenses with a known optical power are installed in front of the examined eye. The plane of the studied pupil is observed through the central hole and the lens, performing the functions of the team.

 However, the known method has a significant drawback, which consists in the fact that the analysis of the pupil of the eye is performed visually and in the visible wavelength range, and the doctor-operator and the patient must be in relative position to each other in a strictly fixed position both in angular and linear coordinates. In this case, the distance between the operator operator and the patient is no more than 1 m, which is caused by the need to perform the accommodation operation of the visual analyzer of the operator operator on the plane of the studied pupil under conditions of limitation to 20% of the light flux diffusely reflected from the patient’s fundus. These disadvantages also reduce the functionality of the method. In order to neutralize the reaction of the pupil to light when implementing the method of skioscopy, it is necessary to use medications to expand the pupil of the patient’s eye, which also reduces the ergonomics of the method. It should be noted that the method is not high enough, because for its implementation the doctor has to hold a line of interchangeable lenses in his hands.

 The method described above is implemented using a known device (scioscope) containing a lighting channel with a radiation source and a mirror and a transmitting channel with an optical system installed in front of the eye and the recorder.

 The disadvantages of the prototype device are due to the above disadvantages of the prototype method, which reduce the functionality of the method and, accordingly, of the siascoscope.

 The task to which the proposed group of inventions is aimed is to eliminate the above-mentioned disadvantages, expand functionality and improve manufacturability, as well as ergonomics during registration of the studied pupil.

 The technical result in accordance with the task is achieved due to the fact that in the method of registering the pupil of the eye, including the localization of the image plane of the pupil, energetic illumination of the eye through the pupil using a radiation source and registration of the energy picture created in the plane of the pupil by the fundus as a source of secondary radiation through the optical system installed in front of the eye, an additional plane of the actual image of the pupil of the eye is additionally created, after which this plane is localized in this case, the plane of the actual image of the pupil is optically coupled to the recorder, and the energy picture is recorded in the plane of the actual image of the pupil, using two additional types of secondary radiation created by diffusely scattering ophthalmic media and specularly reflecting the front surface of the cornea, and blinking is also recorded.

 The solution to the problem is also achieved due to additional features of the method, namely, that, firstly, the image of the pupil can be localized in space using a radiant flux mirrored by the front surface of the optical system that creates the actual image of the pupil, and, secondly, by that the localization of the image plane of the pupil and the registration of the energy picture in the plane of the pupil may not be related by the spectral range and time parameters.

 The implementation of the proposed method is achieved by using the proposed device for recording the pupil of the eye, which includes a lighting channel with a radiation source and a mirror and a transmitting channel with an optical system installed in front of the eye and the recorder, and which differs from the prototype device in that the lighting channel is provided as a laser radiation source, the mirror is mounted on the inner face of the prism-cube, located on the optical axis of the lighting and transmitting channels, in front of yuschem channel provided lens and recorder installed in the lens image plane optically conjugate to the localization plane a real image of the pupil.

 In this case, the laser can be installed with the possibility of replacement by a laser with radiation in a different spectral range, and the lens must have internal focusing.

 In the present invention, the functionality of the method for registering the pupil of the eye and the device for implementing the method are significantly expanded, since the restriction is removed from the distance to this pupil. Due to the introduction of an additional operation of optical pairing of the plane of its actual image with the recorder and the use of a lens with internal focusing in the transmitting channel of the device, the reliability and ergonomics of the proposed method have increased.

 Figure 1 shows an optical diagram of the proposed device for implementing the method of registering a pupil; figure 2 - the operation of localization of the image plane of the pupil in space; figure 3 is an optical diagram that implements the proposed method for registering a pupil; figure 4 is a picture in the plane of the image of the lens: a - without an observer; b - with an observer in the periods between blinking; c - with the observer, at the moment of blinking.

The proposed device (Fig. 1) contains interchangeable lasers 1, 2, an inclined mirror 3 mounted in a prism-cube 4 on the optical axis of a mirror lens 5 mounted with the possibility of displacement along the optical axis, and a recorder 6 located in the rear focal plane of the mirror lens 5 passing through the back focus point F _{5 of} this lens.

 Here, for example, a well-known optoelectronic recorder can be used, including a receiver, amplifier and information board.

 To implement the method, the mirror lens 5 is displaced along the optical axis, as shown by arrows (see Figs. 1, 2), thereby setting the distance to the established plane of localization of the pupil image, and laser 1 (2) is installed on the optical axis with the selected operating spectral interval .

The implementation of the method begins with the installation at a known distance of the second optical system, as shown in figure 2. For example, consisting of a lens 7 with the main planes H ₇ , H ' ₇ , which are respectively the front and rear main planes of this lens, an eyepiece 8 with an ametropia compensation system, an entrance pupil 9, a frontal surface 10 and an exit pupil 11. Moreover, the optical system 7 -11 coaxially with the mirror lens 5 of the proposed device so that the entrance pupil 9 is paired with the plane of the receiving device with the recorder 6. After that, the laser 1 is turned on.

The laser radiation is deflected by the mirror 3 and becomes coaxial to the optical axis of the mirror lens 5 and the optical system 7-11, heading towards the plane 9 of the localization of the image of the pupil (see figure 2). Having reached the optical system 7-11, the energy flux of the radiation of the laser 1 falls on its frontal surface 10 with a peak P ₉ located on the optical axis near the plane 9 of the localization of the image of the pupil (see figure 2). Part of the energy flux of the radiation from the laser 1 is reflected by the frontal surface 10 as a mirror and directed towards the sides of the mirror lens 5, which focuses it as a luminous area centered at the axial point P ' ₉ . Moving the mirror lens 5 along the optical axis, as shown by arrows, the luminous area centered at the axial point P ' _{9 is} combined with the plane of the recorder 6, which generates a signal with a maximum intensity I ₁ (see Fig. 2, a).

Then, instead of laser 1, laser 2 is installed with radiation in a different spectral range. Then the system shown in FIG. 2 generates a signal with intensity I ₂ in the plane of the recorder 6 on the optical axis of the mirror lens 5 (FIG. 4, a).

When the eye 12 is placed in front of the system 7-11 (see Fig. 3) so that its pupil is aligned with the exit pupil 11 of the optical system 7-11, and the ametropia is compensated by this system, the exit pupil of the system 7-11 is localized in the plane registration 9. The latter, therefore, becomes conjugated with the plane of the pupil 12. A part of the energy flux generated by the laser 2, passing through the optical system 7-11, penetrates through the exit pupil 11 into the eye 12, falls on the frontal surface of the cornea 13, passes the ocular media 14 and enters the fundus 15. Part of this radiant flux is mirrored by the frontal surface of the cornea 13 (up to 12%), part of the energy flux is scattered by the ophthalmic media 14 as cloudy media (up to 50%), and part is reflected by the fundus 15 according to Lambert’s law, those. like a diffuse reflective screen. The radiant flux reflected from the fundus returns to the exit pupil 11 of the optical system 7-11 and shows the pupil of the eye 12 combined with it in the plane of the entrance pupil 9 of the optical system 7-11, which is optically coupled to the recorder 6. Since the transmittance of the eye 12 as an optical system statistics is 50-80% [4], then the magnitude of the reflected flux is at least 20% of the incident radiant flux. This radiant flux forms an energy picture with an intensity of I _{3 of the} pupil of the eye 12 in the plane of the recorder 6, passing the prism-cube 4 as a plane-parallel plate or in addition to it (see Fig. 4, b). Since the optical system 7-11 and the proposed device 1-6 are aligned, the energy patterns from the optical system 7-11 together with the eye 12 and its front surface 10 are localized in the same zone of the recorder 6 with an intensity of (I ₂ + I ₃ ) (see Fig. 4, b, c). Then, in the presence of the observer's eye, the energy picture is recorded with a periodic intensity of I ₂ or (I ₂ + I ₃ ). Due to the blinking of the eye 12, when the signal intensity is I ₂ , the picture on the recorder corresponds to FIG. 4, c. In the absence of an eye 12 in the circuit, the recorder 6 transmits a signal constantly corresponding to the intensity I ₂ , i.e. the intensity of the flow reflected from the front surface 10 of the optical system 7-11.

 If the operation of localizing the plane (see Fig. 2) of the image of the pupil 9 and recording the energy picture in this plane is carried out in the working spectral range, then the replacement of laser 2 by laser 1 is not performed.

 The functionality of the proposed method significantly increases due to the input of the plane of the actual image of the pupil and the opportunity to vary both the distance to the plane of localization of the pupil image and the working spectral interval of the laser used as a radiation source.

 Ergonomics and manufacturability of the method increase due to the fact that the device for its implementation can be installed stationary and perform the operation of localizing the plane of the image of the pupil in the absence of the patient (observer).

Sources of information
1. Japan patent 62-1724, MKI A 61 B 3/14, 04/01/87.

 2. NON-MYDRIATIC RETINAL CAMERA TRG-NW: Prospectus from TOPCON, 1990.

 3. Rosenblum Yu.Z. Optometry. - St. Petersburg: Hippocrates, 1998 .-- 247 p. - S. 70 (prototype).

 4. Tamarova P. M. Optical instruments for eye research. - M.: Medicine, 1982. - 176 p.

Claims (5)

 1. The method of registering the pupil of the eye, including the localization of the image plane of the pupil, the energetic illumination of the eye through the pupil using a radiation source and the registration of the energy pattern created in the plane of the pupil by the fundus as a secondary radiation source through the optical system installed in front of the eye, characterized in that create a plane of the actual image of the pupil of the eye, and then localize this plane, while the plane of the actual image of the pupil is optically yazhena with the registrar, and the energy picture is recorded in a real image of the pupil plane using further two kinds of secondary radiation produced by the diffusely scattering media eye and specularly reflective front surface of the cornea, as well as recorded blinking.  2. The method according to claim 1, characterized in that the image of the pupil is localized in space using a radiant flux mirrored by the front surface of the optical system that creates a real image of the pupil.  3. The method according to p. 1 or 2, characterized in that the localization of the image plane of the pupil and the registration of the energy picture in the plane of the pupil are not connected by the spectral range and time parameters.  4. The device for implementing the method of registering the pupil of the eye according to claim 1, containing a lighting channel with a radiation source and a mirror and a transmitting channel with an optical system installed between the eye and the registrar, characterized in that a laser and a mirror are provided in the lighting channel as a radiation source mounted on the inner edge of the prism-cube, located on the optical axis of the lighting and transmitting channels, a lens is provided in the transmitting channel, and the recorder is installed in the image plane tive optically conjugated with the plane of localization of the actual image of the pupil.  5. The device according to claim 4, characterized in that the laser is mounted in the illumination channel with the possibility of replacing it with a laser with radiation in a different spectral range, and the lens has internal focusing in the transmitting channel.

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