CN116725473B - Dynamic stereoscopic vision detection device and method - Google Patents

Abstract

The invention relates to a dynamic stereoscopic vision detection device and a method, wherein the device comprises dynamic random point stereoscopic vision test equipment, a dynamic stereoscopic vision detection system with constant parallax and a dynamic stereoscopic vision detection system with variable parallax, and the dynamic random point stereoscopic vision test equipment comprises a computer for test, a screen, a determiner, a control panel and red-green glasses; the parallax-constant dynamic stereoscopic vision detection system is used for detecting a parallax-constant dynamic random point stereoscopic image; the parallax changing dynamic stereoscopic vision detection system is used for carrying out dynamic random point stereoscopic image detection of parallax size change.

Description

Dynamic stereoscopic vision detection device and method

Technical Field

The invention relates to the technical field of medical equipment, in particular to a dynamic stereoscopic vision detection device and a method.

Background

Stereoscopic vision is an advanced visual function of human binocular vision. The human body judges the distance between the object and the concave-convex shape of the object through stereoscopic vision. In life, 3D movies and virtual reality technologies all require users to have good stereoscopic vision. Stereovision is also a prerequisite for practitioners engaged in fine manipulation related professions, such as astronauts, pilots, microsurgical procedures. Disorders such as strabismus are often associated with stereovision abnormalities, which have been shown to occur in about 5% of the population. Since there is a distance of about 60-65mm between the eyes, the eyes view the same visual scene from different positions, respectively, and points at different distances from the observer generate images at different distances from the fovea of the eyes, thereby generating binocular parallax. When binocular parallax is within a certain range, a single image with depth, i.e., stereoscopic vision, can be formed through the visual cortex. The stereoscopic vision can accurately perform foreign object positioning and self positioning in the external environment. At present, slightly different images are usually displayed to eyes through different technologies such as polarization imaging, random dot patterns and the like, so that stereoscopic vision is formed in the brain. The currently common stereo vision detection methods in clinic comprise the modes of a Fribsy test, a Titmus test, a random point stereogram, a synoptic camera and the like. These examination methods are widely used in clinic due to their convenience. But still has the problems of monocular clues, fixed patterns, only qualitative screening of stereoscopic blindness, low repeatability and the like.

Studies have shown that patients who appear to be stereoblind in static stereo sharpness examinations can still recognize changes in target depth. At present, the clinical stereoscopic vision detection mode is limited to static stereoscopic vision sharpness detection, and a convenient dynamic stereoscopic vision sharpness detection tool is not available. But depth information of both eyes usually appears in dynamic form, both in real life and in 3D entertainment.

During the visual signal transduction process, signals are recognized by the retina and then transmitted to the brain to form an image. Retinal ganglion cells include M and P ganglion cells, wherein high-temporal frequency, low-spatial frequency signals are conducted primarily into the brain via M cell-related dorsal pathways that primarily process "where" information, including depth, motion, and location information. The damage to the passageway is associated with a reduced depth and motor vision recognition. Studies have shown that glaucoma patients may develop post-retinal intracranial neuropathy, particularly M cells in the lateral knee, due to the occurrence of cross-synaptic degeneration, with a greater susceptibility to damage in glaucoma. Therefore, detection of abnormalities in depth and motion signals related to the pathway is of great importance to screening and follow-up of glaucoma patients. The dynamic stereo vision detection contains depth and motion information, and the detection method may have important significance for screening and diagnosis of glaucoma patients.

The currently few available dynamic stereoscopic vision detection methods are only used for scientific research, cannot be applied to clinical patient assessment, lack of standard and convenient detection schemes at present, and have the problems of low repeatability, low sensitivity and specificity to target diseases and the like. Therefore, it is very necessary to design a detection means for dynamic stereoscopic vision, and provide a standard and repeatable high dynamic stereoscopic vision detection means for clinical application.

The current methods clinically applied to testing stereoscopic vision such as Titmus have monocular clues and have low repeatability. Different detection methods are often needed for short-distance and long-distance stereoscopic vision, different evaluation modes are needed between the two methods, and the comparability is poor.

In addition, the current dynamic stereoscopic vision detection mode is still in a scientific research stage, the movement mode of the sighting target is limited, and the sighting target is lack of more standard parameter settings, such as random point size, sighting target size and the like, so that the clinical application of the sighting target is limited.

Disclosure of Invention

In order to solve the above problems, the present invention aims to provide a dynamic stereoscopic vision detection device and method, and the technical problems to be solved at least include how to provide a standard, convenient and repeatable dynamic stereoscopic vision detection mode for clinical application.

In order to achieve the above purpose, the invention provides a dynamic stereoscopic vision detection device, which comprises a dynamic random point stereoscopic vision test device, a dynamic stereoscopic vision detection system with constant parallax and a dynamic stereoscopic vision detection system with variable parallax, wherein the dynamic random point stereoscopic vision test device comprises a computer for testing, a screen, a determiner, a control panel and red-green glasses; the screen is connected with the computer and used for displaying a dynamic random point stereogram; the judging device is connected with the computer and the screen, and the key information which is tested to be pressed on the judging device is transmitted to the computer, so that the computer can automatically judge whether the key information is correct or incorrect; the control panel is connected with the computer and is used for adjusting the parallax size of the sighting target or changing the parallax size, the movement speed or the parallax changing speed; the computer is used for running the detection program to display a dynamic random point stereogram, judging whether the selection of the visual target is correct or incorrect according to the direction pressed by the judging device, and receiving the control information of the control panel; the parallax-constant dynamic stereoscopic vision detection system is used for detecting a parallax-constant dynamic random point stereoscopic image; the parallax change dynamic stereoscopic vision detection system is used for detecting a parallax size change dynamic random point stereoscopic image.

Preferably, the dynamic stereoscopic vision detection device further comprises a random point stereoscopic image display unit, a random point stereoscopic image control unit, a data processing unit, a data storage unit and a data output unit; the random point stereogram display unit can display random point stereograms with different parallax sizes, different movement speeds, different graph shapes and different movement directions on a screen; the random point stereogram control unit is used for realizing parallax switching, optotype moving speed switching, optotype moving direction switching, optotype type direction switching and graphic shape switching; the data storage unit is used for realizing automatic storage of test results and automatically recording data in the whole test process; the data output unit is used for automatically outputting the result to the result interface according to the formats of the type of the sighting target, the movement speed, the movement direction and the parallax after one-time testing is completed.

Preferably, the data automatically recorded by the data storage unit includes the tested ID, the random dot size, the random dot density, the size of the optotype, the parallax of the background image, all parallaxes displayed in sequence under different optotypes, the movement speed and the movement direction, and the correct and incorrect judgment of the tested person.

Preferably, the parallax changing dynamic stereoscopic vision detection system has a dynamic random point stereoscopic image display function, a parallax rapid switching function, a movement speed rapid switching function, an automatic test function, a test data automatic storage function and a test result automatic output function.

Preferably, the control panel is configured to display a parameter setting interface, in which a random point size, a density, a sighting target size, a background map parallax, and an inspection distance can be set.

Preferably, the control panel is configured to display a parallax constant test mode parameter setting interface, in which a parallax size, a movement speed, a movement direction, a graphic, and a sighting target direction can be set.

Preferably, the control panel is configured to display a parallax change test mode parameter setting interface, in which a parallax size, a change parallax size, and a parallax change speed can be set.

Preferably, the parallax change dynamic stereoscopic vision detection system has a function of automatically storing a test result, and data in the whole test process can be automatically recorded, wherein the data comprise tested IDs, random point sizes, random point densities, sighting target sizes, background image parallaxes, all parallaxes displayed in sequence under different sighting target types, changing parallaxes and parallax change speeds, and the tested judgment errors.

Preferably, the parallax changing dynamic stereoscopic vision detection system automatically outputs the result to the result interface according to the format of the type of sighting target, the parallax, the changing parallax and the parallax changing speed after completing one test.

The invention also provides a dynamic stereoscopic vision detection method, which comprises the following steps:

s1, preparation before testing: opening and connecting a computer, a screen, a judging device and a control panel; running a dynamic random point stereogram detection program on a computer, jumping to a tested information input interface, and inputting a tested ID and age; adjusting the height of the tested seat or the screen height to enable the tested seat to head up the center of the screen; clicking the 'determining' to jump to a pre-training setting interface, wherein the setting content comprises whether pre-training is carried out or not, and the pre-training parallax is constant and the parallax is changed; after a parallax constant or parallax changing mode is selected, the color deepens, and a parameter setting interface is clicked to enter in 'determining'; if not, directly jumping to the parameter setting interface;

selecting a constant or variable mode at a parameter setting interface, and firstly setting an inspection distance, a random point size, a random point density, a background image parallax and a visual target size; entering a parallax constant test mode setting interface, and setting a graph type, an initial sighting target direction, initial parallax, initial movement speed, parallax switching intervals, speed switching intervals and sighting target movement directions;

Clicking 'determining' to enter a pre-training interface after setting is completed, and directly entering a testing interface if the setting is not pre-trained; according to the pre-training setting content, manually pressing a key of a control panel direction control module to display a random point stereogram, guiding the tested observation and fully knowing the mode of sighting mark movement and how to use a determiner, and clicking 'determining' to enter a test interface after the pre-training is finished;

s2, formal test:

starting a test according to a set value of an initial value setting interface, pressing a button for starting the test in the test interface to start a formal test, after a single or a plurality of random point stereograms displayed on a screen are examined, pressing a corresponding key judged by the button, and automatically judging the error of the tested identification by a computer; after the test terminal point is reached, automatically outputting the result to a result interface according to the type of the optotype, the movement speed, the movement direction, the parallax or the format of the type of the optotype, the parallax change speed, and after the result is successfully output, popping up a dialog window prompt of 'finished output' on the test interface; after the output is finished, adjusting the type of the sighting target, the movement direction of the sighting target, the movement speed of the sighting target or the type of the sighting target, the parallax change speed and the change parallax through keys on a control panel, so as to test the dynamic stereo vision sharpness under two test modes under different conditions;

S3, after the test is completed, the test interface is exited to enter a result interface, and all output results can be checked.

Advantageous effects

Compared with the prior art, the application has the beneficial effects that:

the dynamic stereoscopic vision detection device can combine dynamic vision with stereoscopic vision detection, so that dynamic random point stereoscopic diagram inspection is obtained, and various variable parameters are set to expand application scenes of the dynamic stereoscopic vision detection device. The application can detect the dynamic stereoscopic vision of the eyes at different distances, and meanwhile, the method only needs red and green glasses, does not need other special inspection equipment, is convenient to carry, is beneficial to reducing the cost and is convenient to be widely popularized in clinic.

Drawings

The accompanying drawings are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate and do not limit the application.

Fig. 1 is a schematic diagram of the structure of the arbiter according to the present application.

FIG. 2 is a schematic interface diagram of parameter settings in the present application.

FIG. 3 is a schematic interface diagram of a constant-range test mode parameter setting in accordance with the present application.

FIG. 4 is a schematic interface diagram of a range change test mode parameter set in accordance with the present application.

Fig. 5 is a schematic diagram showing a connection manner between different unit modules in the present invention.

Fig. 6 is a schematic diagram of a perspective view of a constant random point of parallax in the present invention.

FIG. 7 is a schematic diagram of an error constant mode result output interface in accordance with the present invention.

FIG. 8 is a schematic diagram of a completed output interface in accordance with the present invention.

Fig. 9 is a schematic diagram of a perspective view of a random point of variation in parallax in the present invention.

Fig. 10 is a schematic diagram of a parallax changing mode result output interface in the present invention.

FIG. 11 is a schematic diagram of an interface for the input of test information in the present invention.

FIG. 12 is a schematic diagram of a pre-training setup interface in accordance with the present invention.

Detailed Description

The present invention is described in more detail below to facilitate an understanding of the present invention.

Dynamic vision refers to the ability of an observer to discern details of a visual target in the presence of relative motion between the subject and the visual target. Currently, the clinical detection of visual functions (such as eyesight, stereoscopic vision and the like) mainly comprises the evaluation of static visual functions of a subject, and the evaluation of dynamic vision is relatively less. However, since visual targets in daily life are mainly sports, and with the increasing medical level, people are increasingly focusing on visual quality in real life. The current common visual function examination can not fully understand the actual visual state of a patient in daily life, the clinical needs can not be met far by the evaluation of simple static vision, and the influence of the visual function of a subject on the life ability can be understood by assisting with dynamic vision detection.

Furthermore, different types of neural cells in the visual pathway have a propensity to transmit different types of visual signals: the M channel is mainly used for conducting visual signals with low spatial frequency, low contrast and high time frequency, and the percentage of the transmitted signals of the M channel is gradually increased along with the increase of the time frequency of the visual signals, so that the M channel is mainly used for conducting motion visual information; in contrast, P-paths primarily conduct visual signals of high spatial frequency and low temporal frequency, primarily responsible for the identification of morphological details of the object. Studies have shown that the M-pathway of patients with early glaucoma is selectively impaired, so that abnormalities in dynamic vision may occur earlier than other abnormalities, and that assessing dynamic vision may be of early diagnostic value.

The evaluation means of dynamic vision are mainly divided into: dynamic vision testing of optotype rest and optotype movement.

(1) Dynamic vision testing with stationary optotype: the method is mainly used for assessing the vestibular function, has relatively few application in clinical ophthalmology, and is only limited to be used for primarily identifying the asthenopia and dizziness caused by the vestibular function damage.

(2) The dynamic visual acuity test of the movement of the optotype is mainly used for evaluating the tested dynamic visual acuity of clinical ophthalmology, and a plurality of test systems of the type are developed at present and can be mainly divided into a mechanical optotype display method and a computer optotype display method.

(1) Mechanically displaying the optotype: the method has the advantages that the method is closer to reality and is not influenced by the refresh frequency and the corresponding speed in the computer display; but has the disadvantage of requiring specific equipment.

The driving device and the sighting target integrally move: according to the self-made optotype of the LogMAR visual acuity chart, a power model vehicle is used as a driving device, a plurality of optotypes which are different in size and are gradually arranged in a shrinking mode from left to right are carried on the loading vehicle each time, the loading vehicle moves from left to right in front of a tested person at a certain speed, and a subject is ordered to recognize the optotype moving on the loading vehicle from left to right under the condition that the head is kept still.

The driving device not only moves the sighting target: such as the KOWA HI-10 (Kowa company, ltd., japan) system. The system includes a mirror vertically fixed to a turntable, the rotational speed of which is controlled by a variable speed motor, and a projector which projects a Landolt-C optotype onto the mirror and which specularly reflects the optotype onto the screen. The mirror rotates at different speeds to realize horizontal movement of the optotype from left to right at different speeds, and the movement speed of the optotype is set to be gradually slowed down. The subject is instructed to recognize the optotype.

(2) The computer displays the optotype: the method comprises the steps of generating a dynamic visual target with adjustable size, movement speed and movement mode through computer software, directly displaying the visual target on a screen or utilizing a projector to show the visual target on a curtain, ordering a subject to distinguish the opening direction of the visual target, and recording a test result of the minimum visual target which can be distinguished at a certain speed. The method does not need specific examination equipment, and is convenient for wide clinical popularization. But has the disadvantage of being limited by the screen refresh frequency and response time.

Stereoscopic vision is the visual perception function of positioning a target object in a space depth coordinate by two eyes, and is also called depth vision, which is the highest form of binocular vision. Depth perception due to a small level difference on the retinal images of both eyes is the basis for the formation of stereoscopic vision. The stereoscopic information processing involves a plurality of central vision processing sites. Clinical stereoscopic detection includes near-distance stereoscopic vision and far-distance stereoscopic vision.

Common methods for short-range stereoscopic inspection include a Titmus inspection chart, a Frisby inspection chart, a random point inspection chart.

The Titmus inspection chart is formed by separating binocular images by applying a polarized light principle, and consists of a fly screening qualitative chart, an animal quantitative chart and a ring quantitative chart, wherein the parallax is divided into 9 stages from 800 to 40 and is used for detecting rough local stereoscopic vision. The three-dimensional vision detection device has the advantages of convenience in operation, easiness in understanding of a subject, and capability of being used for three-dimensional vision detection of low-age children. However, the Titmus examination chart has the artificial factors of monocular clues, implication signals and the like, is easy to memorize, and can be guessed, so that the false negative rate is higher, and the repeatability is poor.

The Frisby stereo test chart is the stereo test card with highest precision at present, does not need to wear red and green eyes or polarized light eyes, and is suitable for special patients such as low-age children, language disorder, intellectual disorder and the like. The Frisby stereo test chart consists of three stereo test plates with different thicknesses. Each three-dimensional detection plate is printed with four patterns, one of the patterns is a three-dimensional image, and a background image and a foreground image of the three-dimensional image are respectively printed on two sides of the detection plate, so that physical depth difference exists between the two patterns. By changing the thickness of the inspection board and adjusting the distance between the inspected person and the inspection board, the parallax of 20-600' can be detected.

The random point stereogram is composed of random points for detecting fine and advanced overall stereoscopic vision functions. A clinically common application is a red-green random dot stereogram, where a patient wears red-green glasses for separating binocular images. The random point stereogram is composed of points which are distributed randomly, binocular parallax is single, monocular clues are not generated, and the accuracy and the repeatability are high. In addition, the third generation of the pigment random point stereogram adopts an electronic grating carrier technology, stereoscopic vision detection can be carried out without wearing 3D carrier glasses, the method is high in repeatability, convenient to clinically apply without wearing glasses, and only short-distance stereoscopic vision detection can be carried out.

Remote stereoscopic vision detection is commonly used with a common-view machine drawing and a remote random point perspective view. When the stereoscopic vision is detected by the same-vision machine picture, the parallel light is emitted into the eye to be detected by the light source, and two pictures with micro displacement on the focal plane of the ocular lens are observed by two eyes to form micro horizontal parallax on retina, and the size of the horizontal displacement of the pictures is adjusted to detect the stereoscopic vision. The common vision machine is a multifunctional comprehensive diagnosis and treatment instrument which is not a special instrument for stereoscopic vision inspection, so the common vision machine has the problems of difficult carrying and high price. In addition, the stereoscopic vision detection process of the co-vision machine picture is complicated, needs understanding and cooperation of a patient, and has great limitation in application in low-age children. The remote random point stereogram is also composed of random points, no monocular clues exist, and clinical researches show that the remote random point stereogram has no obvious difference from the inspection result of the same-vision machine drawing. Due to the convenience of the use, the method has important significance in rapidly screening the stereoscopic blindness and monitoring the stereoscopic vision change in clinical work, and is particularly suitable for detecting the stereoscopic vision of low-age children.

Dynamic stereoscopic vision detection principle:

dynamic stereo vision includes both motion and stereo vision information. The detection process involves a visual target generation mode, a visual target display mode, a binocular parallax formation mode, a task of a tested person and the like.

1) Optotype generation mode: optotypes are typically composed of random points or generated by virtual reality techniques.

2) Visual target display mode: including two modes of displaying recorded video and computer generation. The recorded video generates a video containing dynamic stereoscopic vision through computer software, and a plurality of videos are manufactured according to different parallaxes, and the method has the defects that the variation of the sighting marks is constant, the method cannot be adjusted in the detection process, and the video can be only used under fixed detection conditions after the video is manufactured. The computer generation is to generate random point images by using computer software, and has the advantage that an inspector can adjust inspection parameters according to different testing conditions, so that the method is suitable for various detection conditions.

3) Binocular parallax formation mode: (1) generating random points through a computer to respectively form two images with micro parallax, wherein the two images can be positioned in the same image, a subject wears red-green glasses or polarized glasses, and a graph with horizontal parallax is formed on retina through binocular observation; (2) and generating a stereoscopic image through a virtual reality technology, and enabling a subject to wear polarized glasses to form binocular vision.

4) Subject task: in one task, the graphics on the screen may be presented as single or multiple optotypes. When a single optotype is displayed, the subject is required to recognize the characteristics of the optotype, such as the shape of the optotype, the direction of the E-optotype, the direction of the missing portion of the circle, whether the pattern is prominent or depressed. When a plurality of targets are displayed, the subject is required to recognize targets different from other targets, such as targets with different directions of protrusions, different shapes and different parallaxes.

At present, dynamic stereoscopic vision detection modes are divided into two types: dynamic stereoscopic detection with constant parallax and dynamic stereoscopic detection with variable parallax.

1) Parallax-constant dynamic stereoscopic detection: the method uses computer software to generate a red-green random point stereogram with adjustable image size, parallax and movement speed, and generates regular figures of circles, squares and triangles on a screen. When in detection, a tested person wears red-green glasses, the shape of a sighting target on a screen is distinguished, and the minimum parallax which can be distinguished at a certain speed is recorded as a test result. The method generates the graph by utilizing the random point stereogram, has no monocular clues, does not need specific examination equipment, and is convenient for clinical popularization. The method has the defects that the method is limited by the screen refresh rate and the response time, the movement direction of the optotype is limited in the existing designs, and the random point parameters and the optotype size are not standard. The parallax changes are mostly of fixed parallax size, the span is larger, and the detection precision is lower.

2) Dynamic stereoscopic detection of parallax changes: the random point stereogram is generated by computer software or the image is generated by virtual reality technology, the sizes and the shapes of the targets are the same, the parallax of each target is increased from an initial state along with time, and the parallax is reduced at a constant speed after the parallax is increased to a maximum value. One of the optotypes has a disparity magnitude difference from the other optotypes. The detection result is the difference of parallax of the two types of optotypes.

In view of the problems existing in the prior art, the invention provides a detection system capable of conveniently testing dynamic stereoscopic vision in the ophthalmic clinical diagnosis and treatment process. The system comprises two test modes of a dynamic stereoscopic vision detection system with constant parallax and variable parallax.

Dynamic random point stereogram test equipment and test environment:

the test equipment comprises a test computer, a screen, a judging device, a control panel and red-green glasses. The screen is connected with the computer and used for displaying the dynamic random point stereogram. The judging device is connected with the computer and the screen, the information of the key to be pressed is transmitted to the computer, and the program can automatically judge whether the key is correct or incorrect. The control panel is connected with the computer and used for adjusting the parallax size of the sighting target or the testing parameters such as the parallax size, the movement speed or the parallax changing speed and the like. The computer is connected with other components and used for running the detection program to display a dynamic random point stereogram, judging whether the direction pressed by the judging device or the optotype selection is correct or incorrect, and receiving the control information of the control panel. The red-green glasses are also called red-green filters, the color of the red-green glasses is consistent with the red-green random points displayed on a screen, one eye is a red lens, the other eye is a green lens, and the same-color patterns cannot be observed through the lenses. As the screen is viewed through the red lens, the red random dots coincide with the lens colors, only the green random dots can be observed, and the other eye wearing the green lens can only observe the red random dots. The same figure with a certain parallax is observed by both eyes, thereby forming stereoscopic vision.

The requirement of the test screen is selected according to the movement speed or parallax change speed of the optotype: if the movement speed or parallax change speed of the optotype is smaller than 50 degrees/second (low-speed test), a screen with refresh frequency of 60Hz can be selected, and most of screens on the market can meet the test requirement; if higher speed testing is required, a higher refresh rate screen support, such as 144Hz or 200Hz, is required. The response time of the test screen should be less than 4ms, and for a optotype that is tested for high speed movement, it is recommended that the test screen response time be less than 1ms.

Four keys are respectively drawn on the determiner (see figure 1), and the arrows of up, down, left and right are respectively corresponding to the opening directions of four E optotypes of vertical upward, vertical downward, horizontal leftward and horizontal rightward, the directions of four circular notches of vertical upward, vertical downward, horizontal leftward and horizontal rightward, or the graph corresponding to the circle, the square and the triangle (the right arrow is not used), the judging device is held in the hand by a tested person, after the optotype displayed on the screen is observed by the tested person, the corresponding key is pressed down, and then the error of the tested person is judged automatically by the computer program.

In the parameter setting interface shown in fig. 2, a random dot size, density, optotype size, background map parallax, inspection distance may be set.

In the parallax constant test mode parameter setting interface shown in fig. 3, a parallax size, a movement speed, a movement direction, a pattern (E/circle), a pattern direction (optotype direction) may be set.

In the parallax change test mode parameter setting interface shown in fig. 4, the parallax size, the change parallax size, the parallax change speed may be set.

Clicking the setting in the test interface, and switching to the parameter setting interface, the parallax constant test mode parameter setting interface and the parallax change test mode parameter setting interface respectively. The size adjustment in the parameter setting interface requires manual input.

In the parallax constant test mode, after the upper and lower keys in the parallax setting module are clicked, corresponding parallaxes are respectively increased/decreased according to preset parameters. After the upper button and the lower button in the speed setting module are clicked, the corresponding cursor moving speed is respectively increased/decreased according to preset parameters. After clicking on the horizontal (left/right), vertical (up/down), left (up/down) and right (up/down) directions in the movement direction setting module, the horizontal movement, the vertical movement and the diagonal movement of the optotype are respectively set, and the contents in brackets are starting points of the movement of the optotype, such as the left (up) directions, and the optotype moves along the diagonal from the left up to the right down directions. Clicking the graphic type button switches the optotype to an "E" optotype, a circle lacking 60 deg. or a regular graphic. After the up, down, left and right keys in the sighting target direction are clicked, four E sighting target opening directions of vertical upward, vertical downward, horizontal leftward and horizontal rightward are respectively arranged, and four circular notch directions of vertical upward, vertical downward, horizontal leftward and horizontal rightward are respectively arranged, or the figures corresponding to the circular, square and triangle are respectively arranged (right arrow is not used).

In the parallax change test mode, after the upper and lower keys in the parallax setting module are clicked, corresponding parallaxes are respectively increased/decreased according to preset parameters. After the upper key and the lower key in the parallax setting module are clicked, the corresponding parallax is increased/decreased according to preset parameters. After clicking the up and down keys in the parallax changing speed setting module, the corresponding parallax changing speed is respectively increased/decreased according to preset parameters. Clicking the graphic type button switches the optotype to an "E" optotype, a circle lacking 60 deg. or a regular graphic. After the up, down, left and right keys in the sighting target direction are clicked, four E sighting target opening directions of vertical upward, vertical downward, horizontal leftward and horizontal rightward are respectively arranged, and four circular notch directions of vertical upward, vertical downward, horizontal leftward and horizontal rightward are respectively arranged, or the figures corresponding to the circular, square and triangle are respectively arranged (right arrow is not used).

The illuminance of the test environment is controlled between 170 and 180lux, strong light is prevented from being directly irradiated on the screen, and the ambient temperature is suitable for the comfort of patients.

The shape of the visual target E shown is drawn according to the international standard visual chart, i.e. each stroke of the visual target and the interval between each stroke have the same thickness.

The circles containing the up, down, left and right direction information are shown as a circle lacking 60 °, and the lacking portions thereof are centered at 0 °, 90 °, 180 ° and 270 °, and lack 30 ° up and down, respectively.

The size of the optotype is determined by the set viewing angle and the test distance. The circular diameter is equal to the square side length and the triangular side length. Circle diameter = 2 x inspection distance arctan (view angle/2/60), inspection distance in mm and view angle in arcinute.

Parallax-constant dynamic random point stereogram detection:

the parallax constant dynamic stereoscopic vision detection system has a dynamic random point stereoscopic image display function, a parallax rapid switching function, a movement speed rapid switching function, a movement direction rapid switching function, an automatic test function, a test data automatic storage function and a test result automatic output function. Correspondingly, the parallax-constant dynamic stereoscopic vision detection system comprises a random point stereoscopic image display unit, a random point stereoscopic image control unit, a data processing unit, a data storage unit and a data output unit, wherein the connection mode of different unit modules is shown in fig. 3.

Dynamic random point stereogram display function:

the random point stereogram display unit can display random point stereograms with different parallax sizes, different movement speeds, different graphic shapes and different movement directions on a screen, and fig. 6 is a static schematic diagram with four different directions, and arrows represent the movement directions of optotype. The optotype is in the shape of an E in different directions, lacking a 60-degree circle or regular pattern (circular, square, triangle). The optotype size is set according to different test distances and visual angle sizes. The system can automatically and randomly display, and can manually control and display four different opening directions or pattern shapes by clicking a key in pattern switching (sighting target direction) control on a control panel. The up, down, left and right directions of the sighting target respectively correspond to the E sighting target in the directions of four openings of vertical upward, vertical downward, horizontal leftward and horizontal rightward, and the directions of four circular notches of vertical upward, vertical downward, horizontal leftward and horizontal rightward, or correspond to the figures of circles, squares and triangles (right arrow is not used). And the movement direction of the switching sighting target can be controlled by the direction on the control panel. The parallax varies in magnitude between 10-1500'. The speed of movement varies between 10 and 100 dps.

Parallax fast switching function:

the parallax quick switching function can quickly switch the parallax of the visual target, and the switching strategy is to quickly switch between adjacent parallaxes, and the implementation mode is realized by clicking an up button and a down button in a parallax control module on the control panel. The system sets a series of parallaxes in the program in advance, and the range is 10-1500'. Before the test starts, setting the parallax value of each key increase and decrease in the setting interface in advance, for example, setting the parallax of each key increase and decrease to be 30 ", setting the switching interval to be 30", pressing the up direction key can increase 30 ", and pressing the direction key can decrease 30", so as to realize rapid switching between adjacent parallaxes. The current parallax may be presented in a status bar of the test interface (see fig. 6).

And (3) a quick switching function of the movement speed of the optotype:

the quick switching function of the movement speed of the sighting target can quickly switch the movement speed of the sighting target, and the switching strategy is to quickly switch between adjacent movement speeds, and the implementation mode is realized by clicking an up button and a down button in a speed control module on a control panel. The speed of increasing and decreasing each time of keys is preset in the setting interface before the test starts, for example, the movement speed value of increasing and decreasing each time of keys is set to be 5 degrees/second, the switching interval is 5 degrees/second, the upward direction key can be pressed to be increased by 5 degrees/second, and the downward direction key can be pressed to be reduced by 5 degrees/second, so that the rapid switching between adjacent movement speeds is realized. The current speed of movement may be presented in a status bar of the test interface.

Fast switching function of motion direction:

the rapid movement direction switching function can rapidly switch the movement direction of the optotype, and the switching strategy is to rapidly switch between horizontal, vertical and diagonal directions, wherein after clicking horizontal (left/right), vertical (up/down), left (up/down) and right (up/down) on the control panel, the horizontal movement, the vertical movement and the diagonal movement of the optotype are respectively set, and the contents in brackets are the starting points of the movement of the optotype, such as the left (up), and the optotype moves along the diagonal from the left upper part to the right lower part.

Optotype type fast switching function:

the quick switching function of the visual target type can quickly switch the visual target type, the switching strategy is to quickly switch between the 'E' visual target and the circle or the regular graph which is lack of 60 degrees, and the implementation mode is to click a graph type button on the control panel, and the switching visual target is the 'E' visual target and the circle or the regular graph which is lack of 60 degrees.

Graphics switching (optotype direction) fast switching function:

the quick visual target direction switching function can quickly switch visual target directions or graph shapes, the switching strategy is that four E visual target opening directions are vertically upwards, vertically downwards, horizontally leftwards and horizontally rightwards, and four circular notch directions are vertically upwards, vertically downwards, horizontally leftwards and horizontally rightwards, or quick switching is carried out among circular, square and triangular graphs, the implementation mode is that up-down, left-right keys on a control panel are clicked, and the E visual targets are respectively arranged in circular, square and triangular graphs (right arrows are not used) or the opening directions are respectively vertically upwards, vertically downwards, horizontally leftwards and horizontally rightwards, or 60-degree-lacking circles.

Test data automatic storage function:

the dynamic random point stereogram test system has the function of automatically storing test results, and the data in the whole test process can be automatically recorded, including the tested ID, the random point size, the random point density, the visual target size, the background image parallax, all parallaxes displayed in sequence under different visual target types, movement speeds and movement directions, and the correct and incorrect judgment of the tested. The original data in the test process is automatically stored in a local folder, and a file named testID (N) is automatically named (N is the tested ID input before the test).

Test result automatic output function:

the output function is that after one test is completed (i.e. the parallax under a certain sighting target type, a certain movement speed and a certain movement direction is tested), the system can automatically output the result to the result interface according to the format of the sighting target type, the movement speed, the movement direction and the parallax (see fig. 7), after the result is successfully output, a dialog window for indicating that the output is completed is popped up on the test interface (see fig. 8), and after the completion, the test of different sighting target types, different movement speeds and different movement directions can be performed. After all the tests are completed, the ESC button is pressed to exit the test interface and automatically enter the result interface, and all the output results are displayed on the result interface.

Detecting a dynamic random point stereogram with variable parallax size:

the parallax change dynamic stereoscopic vision detection system has a dynamic random point stereoscopic image display function, a parallax rapid switching function, a movement speed rapid switching function, an automatic test data storage function and an automatic test result output function.

Dynamic random point stereogram display function:

the dynamic random point stereogram display function refers to a random point stereogram with different parallax sizes and different parallax changing speeds, which can be displayed on a screen by a dynamic stereovision detection system with parallax changing, fig. 9 is a schematic diagram of the random point stereogram with parallax changing, and the diagram comprises 4 targets with the same size and shape, wherein the parallax of a target 1 (position random) is different from the parallaxes of other targets, and the parallax is the difference value of the parallaxes between the target 1 and the other targets. The parallax of each parallax starts from "0" (parallax starts from "parallax" for parallax 1), increases by "changing parallax" (parallax+changing parallax for parallax 1), gradually decreases to "0" (parallax for parallax 1), and loops until the next parallax is switched. The optotype is in the shape of an E in different directions, lacking a 60-degree circle or regular pattern (circular, square, triangle). The different graphic shapes or four different opening directions can be manually controlled and displayed by clicking a key in the graphic switching control on the control panel. The up, down, left and right directions of the sighting target respectively correspond to the E sighting target in the directions of four openings of vertical upward, vertical downward, horizontal leftward and horizontal rightward, and the directions of four circular notches of vertical upward, vertical downward, horizontal leftward and horizontal rightward, or correspond to the figures of circles, squares and triangles (right arrow is not used). The optotype size is set according to different test distances and visual angle sizes. The parallax can be regulated and controlled by clicking a parallax module on the control panel. The parallax change can be regulated and controlled by clicking a parallax change module on the control panel.

Parallax fast switching function:

the parallax rapid switching function refers to that the dynamic stereoscopic vision detection system with parallax change can rapidly switch the parallax of a sighting target, and the switching strategy is to rapidly switch between adjacent parallaxes, and the implementation mode is realized by clicking an up button and a down button in a parallax control module on a control panel. The system sets a series of parallaxes in the program in advance, and the range is-3000 to 3000'. Before the test starts, setting the parallax value of each key increase and decrease in the setting interface in advance, for example, setting the parallax of each key increase and decrease to be 30 ", setting the switching interval to be 30", pressing the up direction key can increase 30 ", and pressing the direction key can decrease 30", so as to realize rapid switching between adjacent parallaxes. The current parallax may be presented in a status bar of the test interface (see fig. 9).

And (3) a parallax-changing rapid switching function:

the quick change function of the parallax is that the dynamic stereoscopic vision detection system with parallax change can quickly change the parallax of the visual target, and the switching strategy is to quickly switch between adjacent parallaxes, and the implementation mode is realized by clicking an up button and a down button in a parallax change control module on a control panel. The system sets a series of parallaxes in the program in advance, and the range is-3000 to 3000'. The parallax degree value of each time of key increase and decrease is preset in the setting interface before the test starts, for example, the parallax of each time of key increase and decrease is set to be 30 ", the switching interval is set to be 30", 30 "parallax can be increased by pressing the up direction key, 30" parallax can be reduced by pressing the down direction key, and therefore rapid switching between adjacent parallaxes is achieved. The current changing disparity may be presented in the status bar of the test interface (see fig. 9).

Parallax change speed fast switching function:

the parallax change speed rapid switching function refers to that the parallax change speed of the parallax change dynamic stereoscopic vision detection system can be rapidly switched, and the switching strategy is to rapidly switch between adjacent parallax change speeds, and the implementation mode is realized by clicking an up button and a down button in a parallax change speed control module on a control panel. The speed of increasing and decreasing each time of keys is preset in the setting interface before the test starts, for example, the movement speed value of increasing and decreasing each time of keys is set to be 5 degrees/second, the switching interval is 5 degrees/second, the upward direction key can be pressed to be increased by 5 degrees/second, and the downward direction key can be pressed to be reduced by 5 degrees/second, so that the rapid switching between adjacent parallax changing speeds is realized. The current speed of movement may be presented in a status bar of the test interface. The speed of movement varies between 5 and 100 dps.

Optotype type fast switching function:

the visual target type rapid switching function refers to that a dynamic stereoscopic vision detection system with parallax change can rapidly switch visual target types, the switching strategy is to rapidly switch between an 'E' visual target and a circle or regular graph lacking 60 degrees, the implementation mode is to click a graph button, and the switching visual target is an 'E' visual target and a circle or regular graph lacking 60 degrees.

Graphics switching (optotype direction) fast switching function:

the graphic switching (sighting target direction) quick switching function refers to that a dynamic stereoscopic vision detection system with parallax change can quickly switch the graphic shape (sighting target direction), the switching strategy is that four E sighting target opening directions are vertically upwards, vertically downwards, horizontally leftwards and horizontally rightwards, and four circular notch directions are vertically upwards, vertically downwards, horizontally leftwards and horizontally rightwards or quick switching is carried out among circular, square and triangular graphics, the implementation mode is that upper, lower, left and right keys are clicked, the graphics (right arrow is not used) which are respectively arranged into a circle, a square and a triangle, or the opening directions are respectively vertically upwards, vertically downwards, horizontally leftwards and horizontally rightwards E sighting targets or circles which lack 60 degrees.

Test data automatic storage function:

the dynamic stereoscopic vision detection system with parallax change has an automatic test result storage function, and data in the whole test process can be automatically recorded, wherein the data comprise tested IDs, random point sizes, random point densities, sighting target sizes, background image parallaxes, all parallaxes displayed in sequence under different sighting target types, changing parallaxes and parallax changing speeds, and the errors and errors of tested judgment. The original data is automatically stored in a local folder, and a file automatically named testID (N) (N is the tested ID input before testing) is automatically stored in the folder.

Test result automatic output function:

after one test (namely, testing a certain optotype type, a certain parallax changing speed and a parallax under a certain changing parallax) is completed, the program can automatically output the result to a result interface (see fig. 10) according to the format of the optotype, the parallax, the changing parallax and the parallax changing speed, and after the result is successfully output, a dialog window prompt of 'completed output' is popped up on the test interface to prompt that the result is successfully output (see fig. 8), and after the completion, the test of different optotypes, different parallax changing speeds and different changing parallaxes can be performed. After all the tests are completed, the ESC button is pressed to exit the test interface and automatically enter the result interface, and all the output results are displayed on the result interface.

The detection process of the dynamic random point stereogram comprises the following steps:

(1) Preparation before testing: and opening and connecting the computer, the screen, the determiner and the control panel. The dynamic random point stereogram detection program is run on the computer, the computer jumps to the tested information input interface (see fig. 11) and inputs the tested ID and age. Adjusting the height of the tested seat or the screen height enables the tested to look up the center of the screen. Clicking "determine" jumps to the pre-training settings interface (see fig. 12), the settings including whether pre-training is performed, pre-training parallax constant and parallax changing modes. In the pre-training project, if clicking yes, the text boxes of the rest set contents are changed from gray to light blue, the rest set contents are prompted, the colors are deepened after the parallax constant or parallax change mode is selected, and clicking yes is performed to enter a parameter setting interface; if not, directly jumping to the parameter setting interface.

The parameter setting interface selects a parallax constant or variable mode, and firstly, the checking distance, the random point density, the random point size, the sighting mark size and the background image parallax are set. And entering a parallax constant test mode setting interface, and setting a graph type, an initial optotype direction, an initial parallax, an initial movement speed, a speed switching interval, a parallax switching interval and an optotype movement direction. The random dot size is typically set to 1.1 arcmin, the random dot density is set to 60%, the background map disparity is set to 2.2 arcmin, the optotype size is set to 171.6 arcmin, the initial disparity is set to 15 arcmin, the initial speed is set to 10dps, the disparity switching intervals are set to 0.5 and 2.5 arcmin, and the speed switching interval is set to 10dps. The setting interface setting content of the initial value setting interface for the dynamic stereoscopic vision detection of the parallax change comprises a setting graphic type, a sighting target direction, initial parallax, initial change parallax, initial parallax change speed, parallax switching interval, speed switching interval and change parallax interval. The optotype size was set to 85.8 arcmin, the initial parallax was set to 15 arcmin, the initial varying parallax was set to 18 arcmin, the initial speed was set to 1dps, the parallax switching intervals were set to 0.5 and 2.5 arcmin, the speed switching interval was set to 1dps, and the varying parallax interval was set to 1 arcmin.

Clicking "ok" to enter the pre-training interface after the setup is completed (directly entering the test interface if setup is not pre-trained). According to the pre-training setting content, a button of the control panel direction control module is manually pressed to display a random point stereogram, the tested observation is guided, the mode of sighting mark movement is fully known, a determiner is used, and after the pre-training is finished, a 'determining' entering test interface is clicked.

(2) Formally testing:

(1) the program starts testing according to the set value of the initial value setting interface, presses the 'start test' button in the testing interface to start formal testing, orders that after the single or multiple random point stereograms displayed on the screen are watched, presses the corresponding key judged by the random point stereograms, the computer will automaticallyThe error of the tested identification is dynamically judged (if the tested person does not press the judging device after the optotype moves for 5 seconds or directly enters the next test value, the computer automatically judges that the tested person is judged to be wrong). The logic of the program automatic test is as follows: starting from the initial parallax, the testee successfully judges 2, reduces the parallax to be 1/2 of the current parallax, makes 1 error, increases the parallax to be 2 times of the current parallax, and changes the parallax after the first inversionAnd (5) converting the test times to 76 times or 9 times, reaching a test end point, and calculating a threshold according to a maximum likelihood method. After the test end point is reached, the program automatically outputs the result to the result interface according to the format of (optotype, movement speed, movement direction, parallax) or (optotype, parallax, changing parallax, parallax changing speed), and after the result is successfully output, a dialogue window prompt of 'finished output' is popped up on the test interface. After the output is finished, the type of the optotype, the movement direction of the optotype, the movement speed of the optotype or the type of the optotype, the parallax change speed and the change parallax are adjusted through keys on the control panel, so that the dynamic stereoscopic vision sharpness under two test modes under different conditions is tested.

(3) After the test is finished, the ESC is pressed down to exit the test interface and enter the result interface, and all output results can be checked.

(4) Pressing Q exits the program.

On the basis of the embodiment, the invention provides a dynamic stereoscopic vision detection device, which comprises dynamic random point stereoscopic vision test equipment, a dynamic stereoscopic vision detection system with constant parallax and a dynamic stereoscopic vision detection system with variable parallax, wherein the dynamic random point stereoscopic vision test equipment comprises a computer for testing, a screen, a determiner, a control panel and red-green glasses; the screen is connected with the computer and used for displaying a dynamic random point stereogram; the judging device is connected with the computer and the screen, and the key information which is tested to be pressed on the judging device is transmitted to the computer, so that the computer can automatically judge whether the key information is correct or incorrect; the control panel is connected with the computer and is used for adjusting the parallax size of the sighting target or changing the parallax size, the movement speed or the parallax changing speed; the computer is used for running the detection program to display a dynamic random point stereogram, judging whether the selection of the visual target is correct or incorrect according to the direction pressed by the judging device, and receiving the control information of the control panel; the parallax-constant dynamic stereoscopic vision detection system is used for detecting a parallax-constant dynamic random point stereoscopic image; the parallax change dynamic stereoscopic vision detection system is used for detecting a parallax size change dynamic random point stereoscopic image.

Preferably, the dynamic stereoscopic vision detection device further comprises a random point stereoscopic image display unit, a random point stereoscopic image control unit, a data processing unit, a data storage unit and a data output unit; the random point stereogram display unit can display random point stereograms with different parallax sizes, different movement speeds, different graph shapes and different movement directions on a screen; the random point stereogram control unit is used for realizing parallax switching, optotype moving speed switching, optotype moving direction switching, optotype type direction switching and graphic shape switching; the data storage unit is used for realizing automatic storage of test results and automatically recording data in the whole test process; the data output unit is used for automatically outputting the result to the result interface according to the formats of the type of the sighting target, the movement speed, the movement direction and the parallax after one-time testing is completed.

Preferably, the data automatically recorded by the data storage unit includes the tested ID, the random dot size, the random dot density, the size of the optotype, the parallax of the background image, all parallaxes displayed in sequence under different optotypes, the movement speed and the movement direction, and the correct and incorrect judgment of the tested person.

Preferably, the parallax changing dynamic stereoscopic vision detection system has a dynamic random point stereoscopic image display function, a parallax rapid switching function, a movement speed rapid switching function, an automatic test function, a test data automatic storage function and a test result automatic output function.

Preferably, the control panel is configured to display a parameter setting interface, in which a random point size, a density, a sighting target size, a background map parallax, and an inspection distance can be set.

Preferably, the control panel is configured to display a parallax constant test mode parameter setting interface, in which a parallax size, a movement speed, a movement direction, a graphic, and a sighting target direction can be set.

Preferably, the control panel is configured to display a parallax change test mode parameter setting interface, in which a parallax size, a change parallax size, and a parallax change speed can be set.

Preferably, the parallax change dynamic stereoscopic vision detection system has a function of automatically storing a test result, and data in the whole test process can be automatically recorded, wherein the data comprise tested IDs, random point sizes, random point densities, sighting target sizes, background image parallaxes, all parallaxes displayed in sequence under different sighting target types, changing parallaxes and parallax change speeds, and the tested judgment errors.

Preferably, the parallax changing dynamic stereoscopic vision detection system automatically outputs the result to the result interface according to the format of the type of sighting target, the parallax, the changing parallax and the parallax changing speed after completing one test.

The invention combines the stereoscopic vision and the dynamic vision to obtain the dynamic random point stereoscopic image for dynamic stereoscopic vision test. On the one hand, the invention can efficiently, standardized, conveniently and effectively detect the capacity of observing the dynamic random point stereogram to be tested, thereby better knowing the visual state of the patient in the actual life; on the other hand, the device does not need special examination equipment, thereby being beneficial to reducing the cost and being widely popularized in clinic.

The foregoing describes preferred embodiments of the present invention, but is not intended to limit the invention thereto. Modifications and variations to the embodiments disclosed herein may be made by those skilled in the art without departing from the scope and spirit of the invention.

Claims (8)

1. The dynamic stereoscopic vision detection device is characterized by comprising dynamic random point stereoscopic vision test equipment, a dynamic stereoscopic vision detection system with constant parallax and a dynamic stereoscopic vision detection system with variable parallax, wherein the dynamic random point stereoscopic vision test equipment comprises a computer, a screen, a determiner, a control panel and red-green glasses for testing; the screen is connected with the computer and used for displaying a dynamic random point stereogram; the judging device is connected with the computer and the screen, and the key information pressed by the tested person on the judging device is transmitted to the computer, so that the computer can automatically judge whether the key information is correct or incorrect; the control panel is connected with the computer and is used for adjusting the parallax size of the sighting target or changing the parallax size, the movement speed or the parallax changing speed; the computer is used for running the detection program to display a dynamic random point stereogram, judging whether the direction pressed by the judging device is correct or incorrect or the sighting target is selected, and receiving control information of the control panel; the parallax-constant dynamic stereoscopic vision detection system is used for detecting a parallax-constant dynamic random point stereoscopic image; the parallax change dynamic stereoscopic vision detection system is used for detecting a parallax size change dynamic random point stereoscopic image;

The dynamic stereoscopic vision detection system with parallax change has an automatic test result storage function, and data in the whole test process can be automatically recorded, wherein the data comprise the IDs of testees, the sizes of random points, the densities of random points, the sizes of visual targets and the parallax of a background image, all the parallaxes displayed in sequence under different visual target types, changing parallaxes and parallax changing speeds, and the judgment of the testees;

after the parallax change dynamic stereoscopic vision detection system completes one-time test, the result is automatically output to a result interface according to the optotype type, the parallax, the change parallax and the parallax change speed.

2. The dynamic stereoscopic vision detection device according to claim 1, further comprising a random point stereoscopic image display unit, a random point stereoscopic image control unit, a data processing unit, a data storage unit, and a data output unit; the random point stereogram display unit can display random point stereograms with different parallax sizes, different movement speeds, different graph shapes and different movement directions on a screen; the random point stereogram control unit is used for realizing parallax switching, optotype moving speed switching, optotype moving direction switching, optotype type direction switching and graphic shape switching; the data storage unit is used for realizing automatic storage of test results and automatically recording data in the whole test process; the data output unit is used for automatically outputting the result to the result interface according to the formats of the type of the sighting target, the movement speed, the movement direction and the parallax after one-time testing is completed.

3. The apparatus according to claim 2, wherein the data automatically recorded by the data storage unit includes a subject ID, a random dot size, a random dot density, a visual target size, a background image parallax, different visual target types, a movement speed, all parallaxes sequentially displayed in a movement direction, and a positive error judged by the subject.

4. The dynamic stereoscopic vision detecting device according to claim 1, wherein the dynamic stereoscopic vision detecting system for parallax change has a dynamic random point stereoscopic image display function, a parallax fast switching function, a movement speed fast switching function, an automatic test function, a test data automatic storage function, and a test result automatic output function.

5. The dynamic stereoscopic vision detection apparatus according to claim 1, wherein the control panel is configured to display a parameter setting interface in which a random dot size, a density, a optotype size, a background image parallax, and an inspection distance can be set.

6. The dynamic stereoscopic vision detection device according to claim 1, wherein the control panel is configured to display a parallax constant test mode parameter setting interface in which a parallax size, a movement speed, a movement direction, a graphic, and a optotype direction can be set.

7. The dynamic stereoscopic vision detection device according to claim 1, wherein the control panel is configured to display a parallax change test mode parameter setting interface in which a parallax size, a change parallax size, and a parallax change speed can be set.

8. The method of detecting a dynamic stereoscopic vision detecting device according to any one of claims 1 to 7, comprising the steps of:

s1, preparation before testing: opening and connecting a computer, a screen, a judging device and a control panel; running a dynamic random point stereogram detection program on a computer, jumping to a tested person information input interface, and inputting the ID and age of the tested person; adjusting the seat height or the screen height of the tested person to enable the tested person to head up the center of the screen; clicking the 'determining' to jump to a pre-training setting interface, wherein the setting content comprises whether pre-training is carried out or not, and the pre-training parallax is constant and the parallax is changed; after a parallax constant or parallax changing mode is selected, the color deepens, and a parameter setting interface is clicked to enter in 'determining'; if not, directly jumping to the parameter setting interface;

selecting a constant or variable mode at a parameter setting interface, and firstly setting an inspection distance, a random point size, a random point density, a background image parallax and a visual target size; entering a parallax constant test mode setting interface, and setting a graph type, an initial sighting target direction, initial parallax, initial movement speed, parallax switching intervals, speed switching intervals and sighting target movement directions;

Clicking 'determining' to enter a pre-training interface after setting is completed, and directly entering a testing interface if the setting is not pre-trained; according to the pre-training setting content, a key of the control panel direction control module is manually pressed to display a random point stereogram, so that a tested person is guided to observe and fully know the mode of sighting mark movement and how to use a determiner, and click 'confirm' to enter a test interface after the pre-training is finished;

s2, formal test:

starting testing according to the set value of the initial value setting interface, pressing a button for starting testing in the testing interface to start formal testing, ordering a tested person to see a single or a plurality of random point stereograms displayed on a screen, pressing a corresponding button judged by the tested person, and automatically judging the error recognized by the tested person by a computer; after the test terminal is reached, automatically outputting the result to a result interface according to the formats of the type of the sighting target, the movement speed, the movement direction and the parallax, or automatically outputting the result to the result interface according to the formats of the type of the sighting target, the parallax, the change parallax and the parallax change speed, and after the result is successfully output, the dialog window prompt of 'finished output' is popped up on the test interface to prompt that the result is successfully output; after the output is finished, the type, the moving direction and the moving speed of the optotype are adjusted through keys on the control panel, or the type, the parallax changing speed and the changing parallax are adjusted through keys on the control panel, so that the dynamic stereo vision sharpness under two testing modes under different conditions is tested;

S3, after the test is completed, the test interface is exited to enter a result interface, and all output results can be checked.