KR102169674B1 - Mixed reality fundus camera - Google Patents

Abstract

The present invention is a frame in which an inner space is formed, and an alternative hole is formed on one side so as to contact both eyes of the inspector; A pair of camera units provided on the other side of the frame and spaced apart from each other; A display unit provided between the alternative hole and the pair of camera units, and connected to the pair of camera units to output an image captured by the pair of camera units; An additional information unit connected to the display unit and transmitting additional information to the display unit; And a control unit that is electrically connected to the additional information unit and controls the additional information transmitted from the additional information unit, wherein the control unit includes a past data storage member that stores a past test screen of the subject, and treatment is performed on the past test screen. And a treatment site display screen storage member for storing a treatment site display screen displaying a necessary site, and the control unit includes a past inspection screen stored in the past data storage member and a treatment site generated by the treatment site display screen storage member It provides a mixed reality fundus camera that controls a display screen to be output to the display unit.
The mixed reality fundus camera according to the present invention can be used as a portable, and by using a pair of camera units, the fundus can be checked three-dimensionally, and the fundus is observed by tilting to the axis of the pupil, or by applying indentation technology to the peripheral fundus. The examination is possible, and the fundus image can be stored through the examination image storage unit, so that the fundus image of the subject can be checked later or the course of the disease can be checked. In addition, by outputting additional information to the display unit through the additional information unit, it is possible to perform an examination while viewing the previously saved data screen, the past examination screen, or the treatment site display screen showing the treatment site at the same time as the fundus observation, reducing the time of the fundus examination. And, because the accuracy of the inspection can be improved, inspection efficiency can be improved.

Description

Mixed reality fundus camera

The present invention relates to a mixed reality fundus camera, and more particularly, to a mixed reality fundus camera for examining the vitreous body, retina, choroid, optic nerve papilla, etc. inside the eyeball.

In general, the fundus test is a test method in which the vitreous body, retina, choroid, optic nerve papilla, etc. are checked through the pupil using an ophthalmoscope or slit. As a method for fundus examination, direct ophthalmoscope examination, which is an examination method that can be used by doctors of various majors because it is easy to carry and can be performed relatively easily, is worn by a doctor on the head and a lens is held in the hand to examine the fundus. There are slit lamp fundus examination, which is suitable for precise fundus examination due to its excellent resolution, and it examines the fundus using a planoscopic ophthalmoscope and various auxiliary lenses and slit lamps.

Among the fundus examination methods, the portable indirect drawing ophthalmoscope used in the planoscopic examination is a method in which an ophthalmologist directly looks into the fundus using a fundus lens.After the examiner wears the indirect drawing ophthalmoscope on the head, the fundus lens is in one hand. Holds and observes the fundus, and quickly moves the position of the fundus lens to focus and observe the fundus. Compared to the direct ophthalmoscope, the above-described indirect ophthalmoscope is easier to observe a wide range of the fundus, and is therefore used in most ophthalmologists.

During the fundus examination as described above, a method of photographing the fundus is required to continuously check the fundus. As a conventional method of photographing the fundus, there is a method of photographing the fundus while the patient sits on a fundus imager, but children who cannot cooperate with the photographing or patients with disabilities may move to a place equipped with a fundus imager or when the photographing is finished. It is difficult to sit up to, causing restrictions on shooting. Therefore, in order to secure the above restrictions, a portable fundus imaging device has been developed.

Meanwhile, in order to observe the periphery of the fundus in order to examine diseases such as retinopathy and retinal detachment, it is required to apply an indentation technique that presses the periphery of the retina. Because the stage of prematurity retinopathy, which is the cause of blindness in premature infants, can be divided into 1-3 stages depending on the protrusion shape and extent of the boundary area between the retina with blood vessels and the retina without blood vessels, depending on the extent of retinal detachment. It is divided into 4-5 steps. Accordingly, the examiner must see the shape in three dimensions and make a judgment in order to accurately diagnose steps 1-5.

However, the conventional portable fundus photographing apparatus cannot obtain a three-dimensional image of the fundus because only one camera is used. In addition, since the optical device capable of wide viewing angle cannot be used for portability, the range of the fundus is narrow, so there is a limitation in that it is not possible to photograph the peripheral fundus. Therefore, for children who cannot cooperate or patients with discomfort in movement, it takes a lot of time to take a fundus, and it is difficult to check the periphery of the fundus, which may reduce the accuracy of the examination.

As a technology related to a conventional portable fundus imager, Korean Patent Publication No. 10-2017-0043714 is disclosed.

The present invention was created in order to solve the above-described problems, and can be used as a portable, and it is possible to photograph a fundus periphery, and to display a region requiring treatment while storing the photographed fundus image, and then a treatment area display screen storage member And the control unit outputs the treatment site display screen stored in the treatment site display screen and the fundus image captured by the camera unit together to monitor the progress of the disease and perform procedures such as laser treatment by referring to the area marked with the treatment site. An object of the present invention is to provide a mixed reality fundus camera that can be easily performed.

In order to achieve the above object, the present invention is a frame in which an inner space is formed, and an alternative hole is formed on one side so as to contact both eyes of the inspector; A pair of camera units provided on the other side of the frame and spaced apart from each other; A display unit provided between the alternative hole and the pair of camera units, and connected to the pair of camera units to output an image captured by the pair of camera units; An additional information unit connected to the display unit and transmitting additional information to the display unit; And a control unit that is electrically connected to the additional information unit and controls the additional information transmitted from the additional information unit, wherein the control unit includes a past data storage member that stores a past test screen of the subject, and treatment is performed on the past test screen. And a treatment site display screen storage member for storing a treatment site display screen displaying a necessary site, and the control unit includes a past inspection screen stored in the past data storage member and a treatment site generated by the treatment site display screen storage member It provides a mixed reality fundus camera that controls a display screen to be output to the display unit.

Here, the mixed reality fundus camera includes an objective lens disposed at a distance from the frame and disposed in front of the eyeball of the subject by being gripped by the examiner, and a light source unit provided on the other side of the frame to irradiate light to the eyeball of the subject And a test image storage unit electrically connected to the pair of camera units to receive and store a fundus image photographed through the pair of camera units.

In addition, the control unit may further include a data storage unit for storing a pre-stored data screen, and the inspector may select a data screen stored in the data storage unit and control it to be output to the display unit.

In addition, the control unit is connected to the camera unit, compared with the fundus image of the subject photographed from the camera unit and the data screens stored in the data storage unit, the similarity to the fundus image of the subject photographed among the stored data screens. It may further include an image determination unit for controlling the highest data screen to be output to the display unit.

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In addition, a screen transmission unit for transmitting the image displayed on the display unit to an external display through a wireless or wired network network may be further included.

In addition, the control unit includes a control frame provided on the floor and disposed close to the examiner's feet, a control ball provided to be rotatable in the control frame, and a control signal is generated according to the rotation of the control ball, and the display unit It may include a control signal unit for transmitting the control signal to.

In addition, it is preferable that the pair of camera units are spaced apart so as to face each other based on the central axis of the pupil of the subject, and each outer periphery is disposed at a position corresponding to the inner periphery of the pupil.

In addition, it is preferable that the distance between the central axis of one camera unit and the central axis of the other camera unit is 0.5 to 5 (cm).

Meanwhile, the pair of camera units according to another embodiment of the mixed reality fundus camera includes a first camera provided in front of the examiner's left eye, and a center of the first camera disposed to be inclined in front of the first camera. A pair of first reflectors for moving the axis, a second camera provided in front of the examiner's right eye, and a pair of second cameras disposed to be inclined in front of the second camera to move the central axis of the second camera Including a reflector, a central axis of the first camera moved from the first reflector and a central axis of the second camera moved from the second reflector may be disposed at a position within the pupil of the subject.

Here, it is preferable that the distance between the central axis of the first camera and the central axis of the second camera is 0.5 to 5 (cm).

The mixed reality fundus camera according to the present invention can be used as a portable, and by using a pair of camera units, the fundus can be checked three-dimensionally, and the fundus is observed by tilting to the axis of the pupil, or by applying indentation technology to the peripheral fundus. The examination is possible, and the fundus image can be stored through the examination image storage unit, so that the fundus image of the subject can be checked later or the course of the disease can be checked.

In addition, by outputting additional information to the display unit through the additional information unit, it is possible to perform an examination while viewing the previously saved data screen, the past examination screen, or the treatment site display screen showing the treatment site at the same time as the fundus observation, reducing the time of the fundus examination. And, because the accuracy of the inspection can be improved, inspection efficiency can be improved.

In addition, since it is configured to control the control unit with the examiner's feet through the control ball, it is possible to easily control the output of additional information to the display unit, thereby increasing use efficiency.

1 is a block diagram schematically showing a mixed reality fundus camera according to an embodiment of the present invention;
FIG. 2 is a configuration diagram specifically showing the positions of central axes of a pair of cameras of the mixed reality fundus camera shown in FIG. 1;
3 is a block diagram showing a partial configuration of a control unit of the mixed reality fundus camera shown in FIG. 1;
4 is a block diagram showing a partial configuration of a control unit of the mixed reality fundus camera shown in FIG. 1;
5 is a block diagram schematically showing a mixed reality fundus camera according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors appropriately explain the concept of terms in order to explain their own invention in the best way. Based on the principle that it can be defined, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, so at the time of application, they are equivalent to It should be understood that there may be variations.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4, the mixed reality fundus camera 10 according to an embodiment of the present invention is for the examiner (D) to perform a fundus examination on the subject's eye (E), and to take a fundus image. , The mixed reality fundus camera 10 includes an objective lens 100, a frame 200, a pair of camera units 300, a display unit 400, an additional information unit 500, a control unit 600, and a light source unit 700 ), and a test image storage unit 800.

The objective lens 100 may be configured to be grasped by the inspector D, and may be grasped by the inspector D and disposed in front of the eyeball E of the subject. That is, the objective lens 100 is spaced apart from the frame 200 to be described later.

The frame 200 has an internal space, and an alternative hole 201 in contact with both eyes of the inspector D is formed on one side. In other words, the frame 200 is preferably formed of a head mounted, which can be worn on the head so that the alternative hole 201 is in close contact with both eyes of the inspector D. Accordingly, the examiner D may look at the fundus E of the subject through the alternative hole 201.

The pair of camera units 300 are for photographing a fundus image of the subject, and are provided on the other side of the frame 200 and are spaced apart from each other. In addition, the pair of camera units 300 are spaced apart so as to face each other based on the central axis of the pupil E of the subject, and each outer periphery is disposed at a position corresponding to the inner periphery of the pupil E. It is desirable. That is, it is preferable that the pair of camera units 300 are disposed in a straight line, and the central axes C1 and C2 of the pair of camera units 300 are disposed within the pupil E of the subject. More specifically, in the pair of camera units 300, the distance d between the central axis C1 of one camera unit 300a and the central axis C2 of the other camera unit 300b is 0.5 It is preferably ~5 (cm). In other words, when the distance between the pair of camera units 300 becomes too narrow, stereoscopic vision is reduced, and the distance between the central axes C1 and C2 of the pair of camera units 300 is 0.5 to 5 (cm). By being spaced apart, it is possible to observe a clear stereoscopic vision of the fundus. Therefore, by having the pair of camera units 300, it is possible to photograph a fundus image in three dimensions, so that the accuracy of the examination can be improved, and the central axes C1 and C2 of the pair of camera units 300 are 0.5~ By being spaced apart by a distance of 5 (cm), the best 3D image can be received.

The display unit 400 is provided between the alternative hole 201 and the pair of camera units 300. The display unit 400 is electrically connected to the pair of camera units 300 and outputs an image captured by the pair of camera units 300. That is, the display unit 400 receives and outputs the fundus image captured by the pair of camera units 300, so that the examiner D can check the fundus image of the subject. In other words, it is preferable that the display unit 400 outputs a fundus image in three dimensions using a VR (Virtual Reality) program or a 3D Stereo program. The display unit 400 is preferably provided in both eyes of the subject, but is not limited thereto, and may be applied as one display unit 400.

The additional information unit 500 is connected to the display unit 400 and transmits additional information to the display unit 400. That is, the additional information unit 500 transmits additional information to the display unit 400, so that the examiner D overlays the additional information together with the fundus image captured by the pair of camera units 300. can see.

The control unit 600 is electrically connected to the additional information unit 500 and controls additional information transmitted from the additional information unit 500. The control unit 600 may include a data storage unit 610, an image determination unit 620, a past data storage unit 630, and a treatment area display screen storage unit 640.

The data storage unit 610 is for storing a previously stored data screen, and stores a data screen required for the fundus examination. Accordingly, the control unit 600 may output the data screen stored in the data storage unit 610 as additional information. In other words, the controller 600 may control the display unit 400 to output the data screen by selecting a data screen desired by the inspector D from among the data screens stored in the data storage unit 610.

The image determining unit 620 is connected to the camera unit 300 and compared with the eye image of the subject photographed from the camera unit 300 and data stored in the data storage unit 610, and stored data Among the screens, the data screen with the highest similarity to the photographed fundus image of the subject is extracted. That is, the image determination unit 620 may control the display unit 400 to output a data screen having a high similarity to an eye image of the subject among the data screens stored in the data storage unit 610. Therefore, the examiner D can perform the examination while checking the data screen having the highest similarity to the eye image of the subject, thereby improving examination efficiency.

The past data storage unit 630 stores the subject's past inspection screen. Accordingly, the controller 600 may control the past inspection screen stored in the past data storage unit 630 to be output as additional information from the display unit 400. By outputting the past examination screen as additional information through the past data storage unit 630, the examiner (D) can view the subject's past examination screen and the current fundus image together, confirming the progress of the fundus disease and performing the examination. Can proceed, and inspection efficiency can be improved.

The treatment site display screen storage unit 640 stores a treatment site display screen in which the examinee displays a region requiring treatment on the subject's past test screen stored in the past data storage unit 630. The controller 600 may control the treatment area display screen to be output to the display unit 400. Therefore, the treatment area display screen is output together with the fundus image captured by the camera unit 300, so that the user can easily perform procedures such as laser treatment by referring to the treatment area displayed on the treatment area during treatment. have.

Meanwhile, the control unit 600 is preferably configured to be controlled using the feet (F) of the examiner (D). To this end, the control unit 600 may include a control frame 601, a control ball 602, and a control signal unit 603.

The control frame 601 is provided on the floor G and is disposed close to the foot F of the inspector D.

The control ball 602 is provided to be rotatable in the control frame 601. Therefore, the inspector (D) can rotate the control ball 602 using the foot (F).

The control signal unit 603 generates a control signal according to the rotation of the control ball 602 and transmits the control signal to the display unit 400. In other words, the control ball 602 is configured to transmit a control signal corresponding to a preset rotation angle, and may transmit a control signal to the display unit 400 according to a rotation section. Therefore, when the inspector (D) rotates the control ball 602 using the foot (F), a control signal may be transmitted to the display unit 400 in response to the rotation section, and the display unit 400 You can control the type of additional information displayed on the screen or the size of the screen. Since the control unit 600 is controlled using the examiner D's foot, an indentation technique can be applied using the examiner's hand. Through this, the retinal examination of the periphery can also be performed, so that the use efficiency is improved. Can be augmented.

Meanwhile, a screen transmission unit for transmitting an image displayed on the display to the outside is installed in the frame 200. The screen transmission unit provides an image to an external display through a wireless or wired network so that other examiners can simultaneously view the examination screen as well as receive remote medical treatment from a medical person in a remote location.

The light source unit 700 is provided on the other side of the frame 200 and irradiates a light source to the eyeball E of the subject. That is, the light source unit 700 may receive images such as the vitreous body, retina, choroid, and optic nerve papilla in the eyeball by irradiating a light source to the eyeball E of the subject for fundus examination.

The examination image storage unit 800 is for storing a fundus image of a subject photographed through the pair of camera units 300 and is electrically connected to the pair of camera units 300. That is, the examination image storage unit 800 receives and stores the fundus image photographed through the pair of camera units 300, and checks the fundus image of the subject later through the examination image storage unit 800, or You can check the course of the disease.

Hereinafter, a mixed reality fundus camera 20 according to a second embodiment of the present invention will be described with reference to FIG. 5. Here, the same reference numerals in the other drawings are the same members having the same configuration and function, so a repetitive description will be omitted.

5, a pair of camera units 300 of a mixed reality fundus camera 20 according to a second embodiment of the present invention include a first camera 310, a pair of first reflectors 320, and It includes two cameras 330 and a pair of second reflectors 340.

The first camera 310 is provided in front of the left eyeball of the examiner D.

The pair of first reflectors 320 are disposed to be inclined in front of the first camera 310 to move the central axis C1 of the first camera 310. That is, the pair of first reflectors 320 may move the central axis C1 of the first camera 310 to move the viewing axis photographed by the first camera 310.

The second camera 330 is provided in front of the right eyeball of the examiner D.

The pair of second reflectors 340 are disposed to be inclined in front of the second camera 330 to move the central axis C2 of the second camera 330. That is, the pair of second reflectors 320 may move the central axis C2 of the second camera 310 to move the viewing axis photographed by the second camera 330.

Meanwhile, the central axis C1 of the first camera 310 moved from the first reflector 320 and the central axis C2 of the second camera 320 moved from the second reflector 340 are It is preferable to be placed in a position within the pupil (E). More specifically, the central axis C1 of the first camera 310 moved from the first reflector 320 and the central axis C2 of the second camera 320 moved from the second reflector 340 The distance between them is preferably 0.5 to 5 (cm). That is, the distance between the central axis C1 of the first camera 310 moved from the first reflector 320 and the central axis C2 of the second camera 320 moved from the second reflector 340 By being spaced apart from 0.5 to 5 (cm), it is possible to observe a clear stereoscopic vision of the fundus. That is, the distance between the central axes (C1, C2) of the first camera 310 and the second camera 320 through the first reflector 320 and the second reflector 340 can be moved and adjusted. Installation of the first camera 310 and the second camera 320 is easy, and the central axes C1 and C2 of the first camera 310 and the second camera 320 are 0.5 to 5 (cm) By being spaced apart from each other, you can receive the best 3D image.

The mixed reality fundus camera according to the present invention can be used as a portable, and by using a pair of camera units, the fundus can be checked three-dimensionally, and the fundus is observed by tilting to the axis of the pupil, or by applying indentation technology to the peripheral fundus. The examination is possible, and the fundus image can be stored through the examination image storage unit, so that the fundus image of the subject can be checked later or the course of the disease can be checked.

In addition, by outputting additional information to the display unit through the additional information unit, it is possible to perform an examination while viewing the previously saved data screen, the past examination screen, or the treatment site display screen showing the treatment site at the same time as the fundus observation, reducing the time of the fundus examination. And, because the accuracy of the inspection can be improved, inspection efficiency can be improved.

In addition, since it is configured to control the control unit with the examiner's feet through the control ball, it is possible to easily control the output of additional information to the display unit, thereby increasing use efficiency.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10,20: mixed reality fundus camera 100: objective lens
200: frame 201: alternative hall
300: a pair of camera units 310: first camera
320: first reflector 330: second camera
340: second reflector 400: display unit
500: additional information unit 600: control unit
601: control frame 602: control ball
603: control signal unit 610: data storage unit
620: image judgment unit 630: past data storage unit
640: treatment area display screen storage unit 700: light source unit
800: inspection image storage unit D: inspector
E: Eye

Claims (14)

A frame having an internal space formed, and an alternative hole formed on one side thereof so as to contact both eyes of the inspector;
A pair of camera units provided on the other side of the frame and spaced apart from each other;
A display unit provided between the alternative hole and the pair of camera units, and connected to the pair of camera units to output an image captured by the pair of camera units;
An additional information unit connected to the display unit and transmitting additional information to the display unit; And
And a control unit that is electrically connected to the additional information unit and controls the additional information transmitted from the additional information unit,
The control unit,
Past data storage member for storing the subject's past test screen,
And a treatment site display screen storage member for storing a treatment site display screen displaying a site requiring treatment on the past test screen,
The control unit,
A mixed reality fundus camera that controls the past inspection screen stored in the past data storage member and the treatment area display screen generated by the treatment area display screen storage member to be output to the display unit. delete The method according to claim 1,
A mixed reality fundus camera provided on the other side of the frame and further comprising a light source unit for irradiating light to the eye of the subject. The method according to claim 1,
A mixed reality fundus camera further comprising a test image storage unit electrically connected to the pair of camera units to receive and store a fundus image photographed through the pair of camera units. The method according to claim 1,
The control unit,
Further comprising a data storage unit for storing the previously stored data screen,
A mixed reality fundus camera for controlling the data screen stored in the data storage unit to be selected by an inspector and output to the display unit. The method of claim 5,
The control unit,
The data screen having the highest similarity to the photographed fundus image among the data screens stored by being connected to the camera unit and comparing with the data screens stored in the data storage unit and the fundus image of the subject photographed from the camera unit is Mixed reality fundus camera further comprising an image determination unit for controlling to be output to the display unit. delete delete The method according to claim 1,
A mixed reality fundus camera further comprising a screen transmission unit for transmitting the image displayed on the display unit to an external display through a wireless or wired network network. The method according to claim 1,
The control unit,
A control frame provided on the floor and disposed close to the examiner's feet,
A control ball provided to be rotatable in the control frame,
A mixed reality fundus camera comprising a control signal unit for generating a control signal according to the rotation of the control ball and transmitting the control signal to the display unit. The method according to claim 1,
The pair of camera units,
Mixed reality fundus cameras that are spaced apart from each other based on the central axis of the subject's pupil, and each outer periphery is disposed at a position corresponding to the inner periphery of the pupil. The method of claim 11,
The pair of camera units,
A mixed reality fundus camera in which the distance between the central axis of one camera unit and the central axis of the other camera unit is 0.5-5 (cm). The method according to claim 1,
The pair of camera units,
A first camera provided in front of the examiner's left eye,
A pair of first reflectors arranged to be inclined in front of the first camera to move the central axis of the first camera,
A second camera provided in front of the examiner's right eye,
It includes a pair of second reflectors arranged to be inclined in front of the second camera to move the central axis of the second camera,
A mixed reality fundus camera in which a central axis of the first camera moved from the first reflector and a central axis of the second camera moved from the second reflector are disposed at a position within the pupil of the subject. The method of claim 13,
A mixed reality fundus camera in which a distance between the central axis of the first camera and the central axis of the second camera is 0.5-5 (cm).

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