RU2199938C2 - Method for testing stereoscopic vision analyzer - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves using synthesizing laser system composed of laser, screen, deflecting system and computer for producing spatial images as separated test images having reference points and movable markers. Patient head is fixed relative to unit for producing spatial images. Test images are shown to the patient. The patient controls movable marker displacement until its visual superposition with the reference point takes place. Marker and reference point coordinates are determined. Vision acuity and of stereoscopic vision analyzer is determined by interpreting the coordinate difference value and distance from patient eye to the reference point. EFFECT: enhanced accuracy of test results using known means. 3 dwg

Description

 The invention relates to medicine, namely to ophthalmology, and is intended for the study of binocular vision, diagnosis of disorders of stereoscopic vision and determination of the threshold of stereoscopic vision.

 The aim of the invention is to improve the accuracy of determining the threshold of stereoscopic vision.

 A known method for determining the threshold of stereoscopic vision [1], based on fixing the moment of appearance of the stereo effect in the process of observing stereo pairs in polarized light through polaroids.

 The method has an unresolved issue, namely the observation of stereo pairs, and not three-dimensional images. The separation of the visual fields is carried out due to the polaroids, which does not allow to observe the tests in an environment close to real, and leads to a decrease in accuracy.

 There is also known a method for training binocular vision [2], when the patient, focusing his eyes on the movable upper rod and at the same time choosing the position of the head so that the rods seem to be located in the same plane, tries to visually combine the movable rod with one of the fixed ones. The device for the method consists of a body with a three-dimensional stage and two openings for observation. Three rods are used as an object for observation, two of which are motionless and are mounted vertically on the lower table. The line connecting the ends of the rods is perpendicular to the wall of the housing with holes for observation. The third (movable) rod is mounted on the upper wall of the housing above the two lower ones. This method does not allow to determine the threshold of stereoscopic vision.

 A known method for testing stereoscopic vision [3], in which the subject can move the two extreme rods, observing their position through a horizontal window, and tries to combine them in range with a fixed rod. Testing results are recorded. The technical means for the method has a measuring and recording unit and a control panel. Three vertical rods are used as a test object, each of which can move along one of three parallel horizontal tracks. Tracks are located between the observation window and the rear wall.

 Unresolved issues of this method are: 1) low accuracy of determining the threshold of stereoscopic vision, due to the fact that the accuracy directly depends on the diameter of the rods on which there are no markers; 2) the inability to use other test objects.

 The closest in technical solution is the method presented in [3].

 In known methods for testing the binocular functions of the visual analyzer (as in the method taken as a prototype), the combination of a marker and a reference point has never been proposed, because click-and-stick devices do not allow such an operation in principle. Even if the marker was applied to the stick, the reference point could be located only in one plane with the marker, but not at one physical point. The fundamental impossibility of combining test figures in the x and y coordinates leads to an additional error in the patient determining the distance between the test figures in the z coordinate (in depth), which determines the threshold of stereoscopic vision. In the proposed method, this additional error is excluded. In the laser system used, three-dimensional images are generated (but do not really exist) under the control of a computer in three-dimensional space, therefore, these images of the marker and reference point can overlap each other and no tactile sensations arise in the patient. In the proposed method, using the device for forming three-dimensional images, the coordinates of the marker and the reference point are known with an accuracy that is at least 4 times higher than the accuracy of all known methods. Therefore, the error in determining the difference in the coordinates of the marker and the control point is eliminated.

где n выражен в угловых секундах в данной формуле или может быть переведен в радианы, а - межзрачковое расстояние, Δz - измеренная разница глубинных координат, d - расстояние, с которого производилось исследование.The task is to increase the accuracy of determining the threshold of stereoscopic vision - is achieved in the proposed method due to the formation of volumetric test images in the form of spaced test images with reference points and moving markers. Images of control points and markers are formed with a depth of space less than the threshold of stereoscopic vision. These images are obtained using a synthesizing laser system consisting of a laser, a three-dimensional screen, a deflecting system, a positioning tool, and a computer. When using the method, the patient’s head is fixed in relation to the screen, test images are presented to him. Then the patient, using the positioning means, controls the movement of the moving marker until it is visually aligned with the reference point, after which the coordinates of the marker and the reference point are determined. The acuity of the stereoscopic vision of the visual analyzer is determined by the difference in the depth coordinates of the marker and the reference point and the distance from the patient’s eyes to the reference point. If we place the x, y coordinate axes parallel to the plane of the moving frosted glass, then the z coordinate of the Cartesian coordinate system will be the deep coordinate. By the acuity of stereoscopic (deep) vision, we mean the smallest distance in depth, expressed, for example, in millimeters, between two objects, at which the patient still receives the correct answers regarding the relative position of the two objects (for example, the rods in Best's click wand). Most often, the acuity of stereoscopic (deep) vision is expressed by the disparity angle (binocular parallax) n = β ₁ -β. The notation used is illustrated in FIG. With a very large disparity, this angle is easily determined by the formula:

where n is expressed in angular seconds in this formula or can be converted to radians, a is the interpupillary distance, Δz is the measured difference in depth coordinates, d is the distance from which the study was performed.

 In addition, it is envisaged that the processes of testing the visual analyzer, setting test images, determining the magnitude of the mismatch of coordinates and the acuity of stereoscopic vision, as well as data for correction, are determined manually by a software task using a hybrid integrated circuit or computer. The accuracy of determining the threshold of stereoscopic vision increases due to the small extent of the depth of the image space of the marker and reference point.

 In the proposed solution, the new features in relation to the known methods for a similar purpose are all the distinguishing features in accordance with the claims, except for one feature in general - the analysis of the patient according to the test image.

 The proposed solution allows testing a binocular visual analyzer with increased accuracy in conditions closer to natural.

 The proposed method is illustrated by the following graphic materials.

 FIG. 1 - illustrates the determination of the angle of dispersion and the directions of the coordinate axes.

 FIG. 2 - shows a functional diagram for determining the threshold of stereoscopic vision and training of the visual analyzer.

 Figure 3 - shows a structural diagram of a device that implements the method.

 The essence of the proposed method is as follows (figure 2).

 Using a synthesizing laser information display system with a three-dimensional screen 1 and positioning means 2, three-dimensional test images are formed in the form of spaced graphic figures 3, 4 with reference points 5. A movable controllable marker 6 is also formed. Reference points are clearly indicated in the figures and are known to the patient. The patient’s head 7 is fixed in relation to the screen using the latch 8. Test images 3, 4 are presented to the patient, and he uses the positioning means to control the movement of the marker 6 until it is visually aligned with one of the reference points. The coordinates of the marker are determined, for example, by a computer, while the difference in the coordinates (in depth relative to the visual analyzer) of the marker and the corresponding reference point and the distance from the visual analyzer to the reference point determine the acuity of stereoscopic vision.

 As a laser device for displaying information according to the method, it is proposed to use the known means [4] for forming three-dimensional images (Fig. 3).

 This synthesizing laser system consists of a laser 9, a deflecting system 10, a matte electromechanical screen 11 and a control computer 12. The point 13 of the screen onto which the laser beam falls becomes visible as a result of the beam scattering on the surface of the screen. The deflecting system 10 is capable of deflecting the laser beam in two coordinates (vertically and horizontally), and the electromechanical screen 11 makes a reciprocating movement in the third coordinate. Figure 3 shows the two extreme positions of the screen 14, 15, between which the reciprocating movement. The spatial position of the point 13 on which the laser beam fell is determined by the current beam deflection angles of the system 10 and the current position of the screen 11. The movement of the screen 11, the beam deflection and the beam on / off are synchronized with each other. With a sufficiently rapid deflection of the beam and rapid movement of the screen, visible points on the surface of the screen are not perceived separately by the observer, but rather, due to the visual memory, the observer creates a single spatial image of a three-dimensional object, which can be located in the space between the planes 14, 15. This area we call a three-dimensional screen.

 The proposed method is implemented on this device as follows (Fig. 2). In the three-dimensional screen 1 of the synthesizing laser system, three-dimensional images of several spaced test graphic figures are formed. Patient 7 observes these images and controls the movement of the marker using positioning means 2, for example, a keyboard or mouse. At the moment of visual alignment of the moving marker 6 with the reference point 5, the patient presses a certain button on the positioning device 2. The distance from the visual analyzer to the reference point and the difference in the coordinates of the marker 6 and the reference point 5 in depth relative to the visual analyzer determine the acuity of stereoscopic vision.

 The acuity of stereoscopic vision is automatically calculated by the computer from the known value of the difference in the coordinates of the marker and the reference point (in depth), the distance from the visual analyzer to the reference point. Then, the calculation result is transmitted to the information output device (display or printer). Due to the high speed of formation of images of the marker and the reference point, their length, determined by the shift of the screen in the depth of space, can be quite small. In the proposed method using a synthesizing laser system, the coordinates of the marker and the reference point are determined with an accuracy that is at least 4 times higher than the accuracy of all known methods. Therefore, the error in determining the difference in the coordinates of the marker and the control point is eliminated.

 As a result, the accuracy of determining the threshold of stereoscopic vision is increased.

An example implementation of the method
The patient's head with full monocular vision of each eye and binocular vision is fixed in relation to the screen and is located at a distance of 1 m from the three-dimensional screen. Interpupillary distance is measured and is 60 mm. Three-dimensional contour figures with fixed anchor points are spaced in depth on the screen. There may be several figures. Using the keyboard, the patient controls the movement of a moving marker (for example, a cross). Moving the marker using a positioning device, the patient achieves visual alignment of the marker with the reference point indicated in the figure. At this point, he presses the "Enter" button on the keyboard. The difference in depth relative to the visual analyzer of the coordinates of the marker and the reference point in millimeters is automatically entered by the computer program into a special file. The process is repeated. The patient moves the marker to the next anchor point and presses the Enter button on the keyboard again, the difference between the depth coordinates of the marker and the anchor point becomes the next entry in the file. The number of repetitions should be at least 10 times. At the doctor’s command, the program performs statistical processing of the file, calculates the average value of the difference in depth coordinates in millimeters, and then binocular parallax in angular seconds is calculated according to (1). Statistical averaging of results improves the accuracy of testing. The patient turned out to have a visual acuity of 4.9 mm, which amounted to 60 arc seconds. The method provides a smooth, accurate and continuous study of the acuity of stereoscopic vision with a resolution of 0.25 arc seconds.

Literature
1. A.S. SU 1637759, MKI A 61 V 3/08.

 2. US patent 4506963, MKI A 61 B 3/08.

 3. US patent 4035066, MKI A 61 B 3/08.

 4. V.V. Saveliev, P.E. Tverdokhleb, A.V. Trubetskoy, Yu.A. Shchepetkin, The formation of three-dimensional images using a cascading high-speed acousto-optical deflector. Autometry, 2, 1997, p. 11-14.

Claims (1)

 A method for testing a stereoscopic visual analyzer by presenting test images, characterized in that using a synthesizing laser system consisting of a laser, a screen, a deflecting system and a computer, three-dimensional images are formed in the form of spaced test images with reference points and movable markers, the patient's head is fixed by in relation to the screen, test images are presented to him, then the patient, using the positioning tool, controls the movement of the moving marker to his visa ceiling elements align with the set point, then determining the coordinates of the marker and the reference point, and the stereoscopic visual acuity analyzer is determined by the magnitude difference between these coordinates and distance from the patient's eye to the reference point.

Images