CN115886719A - Stereoscopic vision detection control system and detection device - Google Patents

Abstract

The application discloses stereoscopic vision detection control system and detection device relates to stereoscopic vision technical field. The stereoscopic vision detection control system includes: the stereoscopic electronic visual target retrieving module is used for presenting a stereoscopic electronic visual target selection interface and responding to the graphic representation of the stereoscopic electronic visual target selected by the user so that the lens cone of the video watching machine presents the stereoscopic electronic visual target selected by the user; the self-defining module is used for presenting a random point parameter setting interface, responding to the random point parameters set by a user, drawing a graphic representation of a corresponding self-defining quantitative random point stereoscopic vision electronic sighting mark, and enabling a lens cone of the synoptophore to present the drawn self-defining quantitative random point stereoscopic vision electronic sighting mark; and the stereoscopic electronic visual target parameter adjusting module is used for presenting a stereoscopic electronic visual target parameter adjusting interface. The application makes up the defects that the paper edition stereoscopic vision inspection picture album is easy to be dirty and damaged and cannot inspect medium and long distance stereoscopic vision; the problem that the stereoscopic picture carried in the traditional synoptophore product can not be quantitatively checked is solved.

Description

Stereoscopic vision detection control system and detection device

Technical Field

The application relates to the technical field of stereoscopic vision, in particular to a stereoscopic vision detection control system and a detection device.

Background

The stereoscopic vision is a special high-grade visual function of a human body, is an important component of the binocular visual function, has important significance for judging the binocular visual function and treating the oblique amblyopia patient, and is one of important examination items in ophthalmology clinic.

At present, the clinical examination of the stereopsis is mostly performed by short-distance stereopsis examination through printed paper edition stereopsis examination picture books.

However, this method cannot check the medium and long distance stereoscopic vision, and the paper version picture album is easy to be dirty and damaged; the paper printed random point stereoscopic inspection chart has the defects of single color, monotonous graph and the like in the aspects of brightness, color, shape and the like, and is not suitable for clinical inspection of low-vision patients with amblyopia and the like. And the stereoscopic picture carried in the traditional synoptophore product can only carry out stereoscopic qualitative inspection, and cannot carry out quantitative inspection.

Disclosure of Invention

Therefore, the application provides a stereoscopic vision detection control system and a detection device, which aim to solve the technical problems that a paper edition stereoscopic vision inspection picture album in the prior art is easy to be dirty and damaged, and a stereoscopic vision picture carried in a traditional synoptophore product can only carry out stereoscopic vision qualitative inspection and cannot realize quantitative inspection.

In order to achieve the above object, the present application provides the following technical solutions:

in a first aspect, a stereoscopic vision detection control system includes:

the stereoscopic electronic visual target retrieving module is used for responding to a starting command of a user and presenting a stereoscopic electronic visual target selection interface, the stereoscopic electronic visual target selection interface displays a plurality of groups of diagrams of stereoscopic electronic visual targets, and the plurality of groups of stereoscopic electronic visual targets comprise qualitative stereoscopic electronic visual targets and quantitative random point stereoscopic electronic visual targets; responding to the icon of the stereoscopic electronic sighting mark selected by the user in the electronic sighting mark selection interface, sending a control signal to the co-viewing machine, and enabling a lens barrel of the co-viewing machine to present the stereoscopic electronic sighting mark selected by the user;

the self-defining module is used for presenting a random point parameter setting interface when a user selects a group of diagrams of quantitative random point stereoscopic vision electronic sighting marks, drawing the diagrams of the corresponding self-defining quantitative random point stereoscopic vision electronic sighting marks in response to random point parameters set by the user on the random point parameter setting interface, and sending a control signal to the co-viewer to enable a lens cone of the co-viewer to present the drawn self-defining quantitative random point stereoscopic vision electronic sighting marks;

the stereoscopic electronic visual target parameter adjusting module is used for presenting a stereoscopic electronic visual target parameter adjusting interface, responding to the parameters set by the user on the stereoscopic electronic visual target parameter adjusting interface, and sending a control signal to the synoptophore to enable the synoptophore to adjust the parameters of the stereoscopic electronic visual target presented in the lens cone.

Optionally, the qualitative stereoscopic electronic sighting mark comprises a digital perception stereoscopic electronic sighting mark, an object perception stereoscopic electronic sighting mark and a letter perception stereoscopic electronic sighting mark.

Optionally, the random point parameters include the number of points, size, shape and color of the random point.

Optionally, the customization module is further configured to:

displaying the drawn graphic representation of the customized quantitative random point stereoscopic electronic sighting target, wherein the user can dynamically adjust the graphic representation of the customized quantitative random point stereoscopic electronic sighting target in a display picture; and after dynamically adjusting the graphic representation of the customized quantitative random point stereoscopic vision electronic sighting mark, a user sends a control signal to the synoptophore, so that the lens cone of the synoptophore presents the customized quantitative random point stereoscopic vision electronic sighting mark after dynamic adjustment.

Further optionally, the dynamic adjustment includes rotation, scaling and movement processing.

Optionally, the stereoscopic electronic sighting mark parameter adjusting module includes:

the brightness adjusting module is used for presenting a brightness adjusting interface, responding to the brightness set by a user on the brightness adjusting interface, and sending a control signal to the co-watching machine to enable the co-watching machine to adjust the brightness of the stereoscopic vision electronic sighting mark presented in the lens cone;

and the color adjusting module is used for presenting a color adjusting interface, responding to the color set by the user on the color adjusting interface, and sending a control signal to the co-watching machine to enable the co-watching machine to adjust the color of the stereoscopic electronic sighting target presented in the lens cone.

Optionally, the system further comprises a saving module, configured to save the graphical representation of the customized quantitative random point stereoscopic electronic sighting target.

In a second aspect, a stereoscopic vision detecting apparatus includes:

a synoptophore;

the integrated text PLC machine is electrically connected with the synoptophore, and comprises the stereoscopic vision detection control system in any one of the first aspect.

Optionally, the text PLC integrated machine is disposed in a lower box of the synoptophore.

Compared with the prior art, the method has the following beneficial effects that:

1. the stereoscopic vision detection control system provided by the embodiment of the application can enable the lens cone of the synoptophore to present the stereoscopic vision electronic sighting mark to carry out stereoscopic vision inspection by arranging the stereoscopic vision electronic sighting mark adjusting module, the self-defining module and the stereoscopic vision electronic sighting mark parameter adjusting module, abandons the traditional paper-version stereoscopic vision inspection picture album, and overcomes the defects that the paper-version stereoscopic vision inspection picture album is easy to be dirty and damaged, cannot inspect medium-distance stereoscopic vision and cannot accurately inspect; because the selectable stereoscopic electronic visual targets comprise the qualitative stereoscopic electronic visual targets and the quantitative random point stereoscopic electronic visual targets divided by the visual acuity, the qualitative and quantitative inspection of visual functions can be completed, and the problem that the stereoscopic picture carried in the traditional synoptophore product can only carry out the qualitative inspection of stereoscopic vision and cannot carry out the quantitative inspection is solved; the stereoscopic electronic sighting mark avoids the interference of monocular clues and cued signals in design, eliminates the influence of artificial subjective psychological factors, and has more objective and reliable inspection results.

2. Through the stereoscopic electronic sighting mark parameter adjusting module, the color and the brightness of the stereoscopic electronic sighting mark can be adjusted, the defects of single color and monotonous graph of a printing plate stereoscopic picture album are overcome, and the stereoscopic electronic sighting mark parameter adjusting module is more suitable for clinical examination of low-vision patients with amblyopia and the like.

Drawings

To more intuitively illustrate the prior art and the present application, several exemplary drawings are given below. It should be understood that the specific shapes, configurations and illustrations in the drawings are not to be construed as limiting, in general, the practice of the present application; for example, it is within the ability of those skilled in the art to make routine adjustments or further optimization of the add/drop/attribute division, specific shapes, positional relationships, connection manners, size ratios, etc. of certain elements (components) based on the technical concepts disclosed in the present application and the exemplary drawings.

Fig. 1 is a block diagram of a module architecture of a stereoscopic inspection control system according to an embodiment of the present disclosure;

fig. 2 is a block diagram of a module architecture of a stereoscopic detection apparatus according to a second embodiment of the present disclosure;

fig. 3 is a front view of a stereoscopic inspection apparatus according to a second embodiment of the present application;

fig. 4 is a rear view of a stereoscopic detecting device according to a second embodiment of the present application;

fig. 5 is a side view of a stereoscopic inspection apparatus according to a second embodiment of the present application.

Description of reference numerals:

1. a stereoscopic vision detection control system; 101. a stereoscopic electronic sighting mark calling module; 102. a self-defining module; 103. a stereoscopic electronic sighting mark parameter adjusting module; 104. a storage module;

2. a synoptophore; 21. a left barrel; 22. a right barrel; 23. a chin support; 24. a forehead support; 25. a lower box body;

3. a text PLC all-in-one machine; 301. a display screen is touched.

Detailed Description

The present application will be described in further detail below with reference to specific embodiments in conjunction with the accompanying drawings.

In the description of the present application: "plurality" means two or more unless otherwise specified. The terms "first", "second", "third", and the like in this application are intended to distinguish one referenced item from another without having a special meaning in technical connotation (e.g., should not be construed as emphasizing a degree or order of importance, etc.). The terms "comprising," "including," "having," and the like, are intended to be inclusive and mean "not limited to" (some elements, components, materials, steps, etc.).

In the present application, terms such as "upper", "lower", "left", "right", "middle", and the like are generally used for easy visual understanding with reference to the drawings, and are not intended to absolutely limit the positional relationship in an actual product. Changes in these relative positional relationships without departing from the technical concepts disclosed in the present application should also be considered as the scope of the present application.

Example one

In this embodiment, a stereoscopic vision detection control system 1 is provided, which is applied to a synoptophore 2, wherein two eyes are separated by the synoptophore 2, a left eye sees a left optotype, and a right eye sees a right optotype, and then the synoptophore 2 is used to simulate an infinite optical path characteristic, and a stereoscopic vision electronic optotype in the stereoscopic vision detection control system 1 is used for performing a visual inspection; referring to fig. 1 and 3, the stereoscopic vision inspection control system 1 includes the following program modules:

the stereoscopic electronic visual target retrieving module 101 is configured to respond to a start command of a user and present a stereoscopic electronic visual target selection interface, where the stereoscopic electronic visual target selection interface displays multiple groups of icons of stereoscopic electronic visual targets, and the multiple groups of stereoscopic electronic visual targets include qualitative stereoscopic electronic visual targets and quantitative random-point stereoscopic electronic visual targets; in response to the icon of the stereoscopic electronic visual target selected by the user in the electronic visual target selection interface, a control signal is sent to the peer machine 2 after the confirmation of the user, so that the stereoscopic electronic visual target selected by the user is respectively presented in the left lens barrel 21 and the right lens barrel 22 of the peer machine 2.

The qualitative stereoscopic electronic sighting mark can comprise a digital perception stereoscopic electronic sighting mark, an object perception stereoscopic electronic sighting mark and an alphabet perception stereoscopic electronic sighting mark. That is, the stereoscopic electronic sighting marks displayed on the stereoscopic electronic sighting mark selection interface are divided into qualitative stereoscopic electronic sighting marks consisting of digital perception, object perception and letter perception, and quantitative random point stereoscopic electronic sighting marks divided by visual acuity. The qualitative and quantitative inspection of the visual function can be completed by setting two kinds of qualitative and quantitative stereoscopic vision electronic sighting marks. During examination, the corresponding stereoscopic electronic sighting mark is selected according to the examination requirement to carry out examination.

For example, a quantitative random point stereoscopic electronic visual target may comprise a random point stereoscopic electronic visual target of 800 "-60" visual acuity.

The user-defined module 102 is configured to present a random point parameter setting interface when a user selects a group of diagrams of quantitative random point stereoscopic electronic sighting marks, draw the diagrams of corresponding user-defined quantitative random point stereoscopic electronic sighting marks after the user confirms the random point parameter setting interface, and send a control signal to the peer 2, so that lens barrels (the left lens barrel 21 and the right lens barrel 22) of the peer 2 present the drawn user-defined quantitative random point stereoscopic electronic sighting marks.

The random point parameters include the number, size, shape (circle, square, random) and color of the random point. In other words, the user can readjust and draw the size, color, shape, etc. of the random points in the stereoscopic electronic sighting mark according to the specific situation of the examinee in the examination.

In addition, the custom module 102 is further configured to:

displaying the drawn graphic representation of the customized quantitative random point stereoscopic electronic sighting target, wherein the user can dynamically adjust the graphic representation of the customized quantitative random point stereoscopic electronic sighting target in a display picture, including but not limited to operations of rotating, zooming and moving; when the user dynamically adjusts and confirms the graphic representation of the customized quantitative random point stereoscopic vision electronic sighting mark, a control signal is sent to the synoptophore 2, so that the lens cones (the left lens cone 21 and the right lens cone 22) of the synoptophore 2 present the customized quantitative random point stereoscopic vision electronic sighting mark after dynamic adjustment.

The user-defined module 102 can adjust the scaling of the size and the shape of the random point in the random point stereoscopic electronic sighting mark. When the examinee is in special condition, the random point stereoscopic vision electronic sighting mark can be adjusted or redrawn.

In other words, the random dot stereoscopic electronic sighting mark has an adjusting function, so that a user can adjust corresponding parameters (the number of dots, the size of the dots, the shape of the dots and the color of the dots) before checking, and can also dynamically adjust after generating a stereoscopic graph, and further generate a new random dot stereoscopic electronic sighting mark through rotation, zooming and moving processing.

The stereoscopic electronic visual target parameter adjusting module 103 is configured to present a stereoscopic electronic visual target parameter adjusting interface, respond to a parameter set on the stereoscopic electronic visual target parameter adjusting interface by a user, and send a control signal to the peer viewer 2 after the user confirms the parameter, so that the peer viewer 2 adjusts the parameter of the stereoscopic electronic visual target presented in the lens barrel.

Specifically, the stereoscopic electronic sighting mark parameter adjusting module 103 includes:

the brightness adjusting module is used for presenting a brightness adjusting interface, responding to the brightness set by the user on the brightness adjusting interface, and sending a control signal to the video watching unit 2 after the user confirms so that the video watching unit 2 can adjust the brightness of the stereoscopic vision electronic sighting marks presented in the lens barrels (the left lens barrel 21 and the right lens barrel 22);

and the color adjusting module is used for presenting a color adjusting interface, responding to the color set by the user on the color adjusting interface, and sending a control signal to the video watching machine 2 after the user confirms so that the video watching machine 2 adjusts the color of the stereoscopic electronic sighting mark presented in the lens cone.

The brightness and color of the stereoscopic electronic sighting mark can be adjusted in the brightness adjusting module and the color adjusting module according to the reaction of the examinee through the stereoscopic electronic sighting mark parameter adjusting module 103.

Further, the stereoscopic vision detecting and controlling system 1 further includes a saving module 104, configured to save the graphical representation of the customized quantitative random point stereoscopic vision electronic optotype.

The user generates a new customized random point stereoscopic vision electronic sighting mark through the customization module 102, and after determining that the corresponding parameter setting is correct, the user can save the corresponding parameter setting through the saving module 104 if necessary so as to be directly called for use at a later period.

An overall work flow of the stereoscopic vision detection control system 1 may be as follows:

the user adjusts the chin rest 23, the forehead rest 24 and the interpupillary distance of the synoptophore 2 to the position suitable for the examinee, the two eyes of the examinee are separated through the synoptophore 2, and the left eye of the user sees the left sighting target in the left lens barrel 21 and the right eye of the user sees the right sighting target in the right lens barrel 22; after clicking a button entering the stereoscopic vision detection system on the operation interface of the synoptophore 2, a user can enter a stereoscopic vision electronic sighting mark selection interface; the user selects a group of qualitative stereoscopic electronic sighting marks or quantitative random point stereoscopic electronic sighting mark icons on the stereoscopic electronic sighting mark selection interface according to the examination requirement, for example, a group of quantitative random point stereoscopic electronic sighting marks with 700' visual acuity can be selected, after the icon of a certain group of stereoscopic electronic sighting marks is selected and confirmed, the lens barrels (the left lens barrel 21 and the right lens barrel 22) of the video watching machine 2 can present the pattern of the selected stereoscopic electronic sighting marks, and the examinee can see the pattern of the selected stereoscopic electronic sighting marks through the lens barrels, so that the stereoscopic detection can be carried out.

When the user selects a group of quantitative random point stereoscopic vision electronic sighting marks, the system can present a random point parameter setting interface; if the user feels that the random point stereoscopic vision electronic sighting mark needs to be deformed to a certain extent, the random point parameter can be set or adjusted in the random point parameter setting interface, for example, the point number, the size, the shape and the color of the random point in the selected quantitative random point stereoscopic vision electronic sighting mark are adjusted; after the user finishes setting the random point parameter setting interface, the system draws a graphic representation of the customized quantitative random point stereoscopic vision electronic sighting mark, and the user confirms that the drawtubes (the left drawtube 21 and the right drawtube 22) of the synoptophore 2 can present the drawn customized quantitative random point stereoscopic vision electronic sighting mark.

After the drawing of the user-defined quantitative random point stereoscopic electronic sighting mark is finished, the system can also display the drawn user-defined quantitative random point stereoscopic electronic sighting mark, and in a display picture, a user can directly rotate, zoom, move and the like the drawn user-defined quantitative random point stereoscopic electronic sighting mark; when the user performs a series of dynamic adjustments and confirms on the drawn graphic representation of the customized quantitative random point stereoscopic electronic sighting mark, the lens cone of the synoptophore 2 presents the customized quantitative random point stereoscopic electronic sighting mark after dynamic adjustment. Meanwhile, the system provides a storage button, and if a user needs to store the graphic representation of the customized quantitative random point stereoscopic vision electronic sighting mark, the user can click the storage button so as to directly call and use the graphic representation next time.

In the detection process of the examinee, if a user needs to adjust parameters of the stereoscopic electronic sighting mark, such as brightness and color, a stereoscopic electronic sighting mark parameter adjusting button provided by the detection system can be clicked; after a user clicks the stereoscopic electronic sighting target parameter adjusting button, the system can present a stereoscopic electronic sighting target parameter adjusting interface, in the stereoscopic electronic sighting target parameter adjusting interface, the system can provide brightness adjusting and color adjusting functions, the user can set required brightness and color according to the brightness adjusting and color adjusting functions, and therefore the co-viewing machine 2 can adjust the brightness and color of the stereoscopic electronic sighting target presented in the whole lens barrel to be consistent with the set brightness and color.

According to the stereoscopic vision detection control system 1 provided by the embodiment of the application, by arranging the stereoscopic vision electronic visual target calling module 101, the self-defining module 102 and the stereoscopic vision electronic visual target parameter adjusting module 103, lens cones (the left lens cone 21 and the right lens cone 22) of the synoptophore 2 can present stereoscopic vision electronic visual targets to carry out stereoscopic vision detection, a traditional paper-version stereoscopic vision detection album is abandoned, and the defects that the paper-version stereoscopic vision detection album is easy to dirty and damaged, long-distance stereoscopic vision cannot be detected, and precise detection cannot be carried out in the detection process are overcome; moreover, because the selectable stereoscopic electronic sighting marks comprise qualitative stereoscopic electronic sighting marks and quantitative random point stereoscopic electronic sighting marks divided by visual acuity, the qualitative and quantitative inspection of visual functions can be completed, and the problems that the stereoscopic picture carried in the traditional video watching machine product can only carry out stereoscopic qualitative inspection and cannot carry out quantitative inspection are solved; the stereoscopic electronic sighting mark avoids the interference of monocular clues and cued signals in design, eliminates the influence of artificial subjective psychological factors, and has more objective and reliable inspection results; in addition, the parameters (color and brightness) of the stereoscopic electronic sighting mark can be adjusted through the stereoscopic electronic sighting mark parameter adjusting module 103, the defects of single color and monotonous graph of the printing plate stereoscopic picture album are overcome, and the device is more suitable for clinical examination of low-vision patients such as amblyopia patients.

Example two

In the present embodiment, as shown in fig. 2 and 3, there is provided a stereoscopic vision detecting apparatus including:

a synoptophore 2;

the text PLC all-in-one machine 3 is electrically connected with the synoptophore 2 through a data transmission signal line, and the text PLC all-in-one machine 3 comprises the stereoscopic vision detection control system 1 provided in the first embodiment. The text PLC all-in-one machine 3 is provided with a touch display screen 301, and a series of operations can be realized through the touch display screen 301.

Wherein, the text PLC all-in-one machine 3 can be placed in the lower box body 25 of the synoptophore 2.

That is, the stereoscopic vision detection control system 1 provided in the first embodiment is loaded in the text PLC integrated machine 3, and has functions of displaying, storing, visual target drawing, customizing, and the like.

An exemplary simple introduction of the operation method of the stereoscopic vision detecting apparatus is as follows:

the two eyes of the examinee are separated through the synoptophore 2, the left eye sees a left visual target in the left lens cone 21, the right eye sees a right visual target in the right lens cone 22, a light source is turned on, and a button of a 'stereoscopic vision detection system' is selected on a touch display screen 301 of the text PLC all-in-one machine 3 to enter an operation page; one group of the stereoscopic vision electronic sighting marks can be selected from the stereoscopic vision electronic sighting mark selection interface presented by the touch display screen 301 of the text PLC all-in-one machine 3 according to the specific condition of the examinee and the quantitative random point stereoscopic vision electronic sighting marks with the visual acuity of 800 '-60' can be selected, and the brightness and the color of the sighting marks can be adjusted in the brightness adjusting interface and the color adjusting interface according to the reaction of the examinee. The scaling adjustment of the size and the shape of the random points in the quantitative random point stereoscopic vision electronic sighting mark can be carried out through the touch display screen 301 of the text PLC all-in-one machine 3, so that the quantitative random point stereoscopic vision electronic sighting mark can be adjusted or redrawn when a person to be examined meets special conditions; the new stereoscopic random point icon can be saved by a saving function if necessary so as to be called for use later.

To better illustrate the stereoscopic inspection device and make it easier to understand, a rear view of the inspection device can be seen in fig. 4, and a side view of the inspection device can be seen in fig. 5.

For specific definition of the stereoscopic vision detecting device, reference may be made to the above definition of the stereoscopic vision detecting control system 1, and details thereof are not repeated here.

The stereoscopic vision detection device provided by the embodiment combines the traditional synoptophore 2 and the automatic text PLC all-in-one machine 3, and performs stereoscopic vision inspection on the positions of the subjective and objective squint angles of the examinees, so that the inspection result is more objective and accurate. The defects that the paper edition random point stereoscopic vision inspection picture album can not inspect medium and long distance stereoscopic vision and can not accurately inspect are overcome.

The text PLC all-in-one machine 3 has the characteristics of constant screen brightness and color saturation, simplicity and convenience in operation, easiness in use and the like, and can meet the requirements and requirements of stereoscopic vision clinical examination and the standardized and personalized research work of stereoscopic vision.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above may be implemented by hardware instructions of a computer program, which may be stored in a non-volatile computer-readable storage medium, and when executed, may include the processes of the embodiments of the methods described above. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include at least one of non-volatile and volatile memory. Non-volatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical Memory, or the like. Volatile Memory can include Random Access Memory (RAM) or external cache Memory. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), for example.

All the technical features of the above embodiments can be arbitrarily combined (as long as there is no contradiction between the combinations of the technical features), and for the sake of brevity, all the possible combinations of the technical features in the above embodiments are not described; these examples, which are not explicitly described, should be considered to be within the scope of the present description.

The present application has been described in considerable detail with reference to certain embodiments and examples thereof. It should be understood that several conventional adaptations or further innovations of these specific embodiments may also be made based on the technical idea of the present application; however, such conventional modifications and further innovations can also fall into the scope of the claims of the present application as long as they do not depart from the technical idea of the present application.

Claims (9)

1. A stereoscopic vision inspection control system, comprising:

the stereoscopic electronic visual target retrieving module (101) is used for responding to a starting command of a user and presenting a stereoscopic electronic visual target selection interface, wherein the stereoscopic electronic visual target selection interface displays a plurality of groups of graphical representations of stereoscopic electronic visual targets, and the plurality of groups of stereoscopic electronic visual targets comprise qualitative stereoscopic electronic visual targets and quantitative random point stereoscopic electronic visual targets; responding to the icon of the stereoscopic electronic sighting mark selected by the user in the electronic sighting mark selection interface, sending a control signal to the synoptophore (2) to enable a lens barrel of the synoptophore (2) to present the stereoscopic electronic sighting mark selected by the user;

the self-defining module (102) is used for presenting a random point parameter setting interface when a user selects a group of diagrams of quantitative random point stereoscopic vision electronic sighting marks, drawing the diagrams of the corresponding self-defining quantitative random point stereoscopic vision electronic sighting marks in response to random point parameters set by the user on the random point parameter setting interface, and sending a control signal to the synoptophore (2) to enable a lens cone of the synoptophore (2) to present the drawn self-defining quantitative random point stereoscopic vision electronic sighting marks;

the stereoscopic electronic sighting target parameter adjusting module (103) is used for presenting a stereoscopic electronic sighting target parameter adjusting interface, responding to the parameter set by the user on the stereoscopic electronic sighting target parameter adjusting interface, and sending a control signal to the synoptophore (2) to enable the synoptophore (2) to adjust the parameter of the stereoscopic electronic sighting target presented in the lens cone.

2. The stereoscopic vision detection control system according to claim 1, wherein the qualitative stereoscopic electronic optotype includes a digital perception type stereoscopic electronic optotype, an object perception type stereoscopic electronic optotype, and a letter perception type stereoscopic electronic optotype.

3. The stereoscopic detection control system according to claim 1, wherein the random point parameters include a number of points, a size, a shape, and a color of a random point.

4. The stereoscopic detection control system of claim 1, wherein the customization module (102) is further configured to:

displaying the drawn graphic representation of the customized quantitative random point stereoscopic electronic sighting target, wherein the user can dynamically adjust the graphic representation of the customized quantitative random point stereoscopic electronic sighting target in a display picture; and after dynamically adjusting the graphic representation of the customized quantitative random point stereoscopic electronic sighting mark, a user sends a control signal to the synoptophore (2) to enable a lens cone of the synoptophore (2) to present the customized quantitative random point stereoscopic electronic sighting mark after dynamic adjustment.

5. The stereoscopic viewing detection control system of claim 4, wherein the dynamic adjustment comprises rotation, scaling and movement processing.

6. The stereoscopic vision detection control system according to claim 1, wherein the stereoscopic electronic optotype parameter adjusting module (103) includes:

the brightness adjusting module is used for presenting a brightness adjusting interface, responding to the brightness set by a user on the brightness adjusting interface, and sending a control signal to the video watching machine (2) to enable the video watching machine (2) to adjust the brightness of the stereoscopic electronic sighting mark presented in the lens cone;

and the color adjusting module is used for presenting a color adjusting interface, responding to the color set by the user on the color adjusting interface, and sending a control signal to the synoptophore (2) to enable the synoptophore (2) to adjust the color of the stereoscopic electronic sighting target presented in the lens cone.

7. The stereoscopic inspection control system of claim 1 further comprising a save module (104) configured to save a graphical representation of the customized quantitative random point stereoscopic electronic optotype.

8. A stereoscopic vision detecting apparatus, comprising:

a synoptophore (2);

the text PLC all-in-one machine (3) is electrically connected with the synoptophore (2), and the text PLC all-in-one machine (3) comprises the stereoscopic vision detection control system of any one of claims 1 to 7.

9. The stereoscopic vision detecting apparatus according to claim 8, wherein the text PLC all-in-one machine (3) is provided in a lower case (25) of the synoptophore (2).

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