CN208876483U - Fundus camera optical system is imaged in Portable stereoscopic - Google Patents

Fundus camera optical system is imaged in Portable stereoscopic Download PDF

Info

Publication number
CN208876483U
CN208876483U CN201820068369.XU CN201820068369U CN208876483U CN 208876483 U CN208876483 U CN 208876483U CN 201820068369 U CN201820068369 U CN 201820068369U CN 208876483 U CN208876483 U CN 208876483U
Authority
CN
China
Prior art keywords
lens
image
sub
optical system
fundus camera
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn - After Issue
Application number
CN201820068369.XU
Other languages
Chinese (zh)
Inventor
肖志涛
吴骏
娄世良
耿磊
张芳
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Tianjin Polytechnic University
Original Assignee
Tianjin Polytechnic University
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Tianjin Polytechnic University filed Critical Tianjin Polytechnic University
Priority to CN201820068369.XU priority Critical patent/CN208876483U/en
Application granted granted Critical
Publication of CN208876483U publication Critical patent/CN208876483U/en
Withdrawn - After Issue legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Landscapes

  • Eye Examination Apparatus (AREA)

Abstract

A kind of Portable stereoscopic imaging fundus camera optical system, including nethike embrane object lens, field lens, half-reflecting half mirror, pre-objective, image-forming objective lens, imager chip and lighting device;Nethike embrane object lens, field lens, pre-objective are vertical with primary optical axis, and the angle between half-reflecting half mirror and primary optical axis is 30-60 °, and chief ray is divided into two symmetrical inclination sub-light road A in field lens rear surface1And A2, two inclination sub-light road A1And A2Between angle a be 11 °, an image-forming objective lens and imager chip constitute an imaging group, and the image-forming objective lens, imager chip in the imaging group of the top are successively set on the first sub-light axis A1On, image-forming objective lens, imager chip in the imaging group of bottom are successively set on the second sub-light axis A2On, the angle between the output light path and half-reflecting half mirror of lighting device is 45 °.The utility model solves the problems, such as that existing monocular fundus camera can not obtain one group of image in synchronization, and realize the miniaturization of fundus camera with it is portable.

Description

Fundus camera optical system is imaged in Portable stereoscopic
Technical field
The utility model belongs to the micro- imaging in eyeground and eyeground three-dimensional reconstruction field, and in particular to Portable stereoscopic imaging Fundus camera optical system.
Background technique
People, which have 80% from the extraneous process for obtaining information by sense organ, to be completed by eyes.Human eyes structure essence Thin and complicated, eyeground is important component therein.In clinical examination, for eye part disease, eyeground is first checked for, observation has Without lesion, correctly to judge the cause of disease.The lesion on eyeground is maintained close ties with and is influenced each other with whole body other systems disease.Many diseases It is all showed on eyeground.According to some features on eyeground, other clinical specialities can be assisted to make correct diagnosis.Other The early symptom of disease appears in eye, and funduscopy can make these diseases obtain in due course treatment.Human eye is rich in many micro- Thin blood vessel is the fine vascular position that human body can most observe directly, therefore is also the significant points of microcirculation in human body research.
Human eye retina, also known as eyeground are the films of one layer of high level of architectural complexity, are the important components of human eye.Depending on Status of the nethike embrane in eyes is equivalent to the receiver of imaging system.Eyeground is this sensory important group of eyes At part, most of lesion of eyes comes from eyeground.Eyeground is dispersed with a large amount of various artery and vein vasculars simultaneously, these blood vessels can To reflect the state of system vascular disease.Such as hypertension, arteriovenous thrombus, arteriosclerosis fracture, ephritis and tumour disease Disease can make these diseases according to the variation symptom on eyeground by the observation analysis to eyeground choroid and retina Early diagnosis and prevention.And retinal vessel is also cerebrovascular branch, can speculate cerebrovascular situation from it.Eyeground phase Machine is the Ophthalmologic apparatus for being checked eyeground pathological changes, is a kind of important means that doctor carries out dynamic retinoscopy, Clinically have important application.
Since the two dimensional image that fundus camera generates can not show the sky of three-dimensional eye ground image realisticly Between relationship, thus bring some inconvenience to diagnosis.The three-dimensional reconstruction of eye fundus image can be by two-dimensional medical imaging data True sensory effects show diagnostic personnel, compensate for existing medical imaging equipment imaging when be lost third dimension information The shortcomings that, allow size, spatial position, the geometry of the observing eye bottom lesion that medical worker is more accurate, is more clear And its relationship with surrounding other institutional frameworks, multi-angle, multi-level observation can be carried out to the institutional framework at patient's eyes bottom, To greatly reduce subjective judgement and the clinical experience deficiency because of medical worker and the adverse effect caused by diagnostic result. Doctor can also be assisted to carry out qualitative and quantitative analysis to patient's eyeground pathological changes by eye fundus image three-dimensional reconstruction, to make medical treatment The utility value of image documentation equipment output 2-D data is played to the greatest extent, the accuracy of diagnosis is improved, to improve doctor Treat diagnostic level.
More for the method type of eye fundus image three-dimensional reconstruction at present, research discovery by contrast uses binocular stereo vision Method carry out that eye fundus image reconstruction accuracy is relatively high, be the method for most advantage at present.Utilize the side of machine vision The three-dimensional reconstruction matter of utmost importance that method carries out eye fundus image is the eye fundus image for obtaining the condition that meets, and how to obtain human eye in same a period of time Inscribing one group of eye fundus image with overlapping region is to need key problems-solving.Fundus camera is monocular system at present, Although monocular fundus camera technology mature, one group of image, three-dimensional imaging fundus camera skill can not be obtained in synchronization Art is in space state, therefore it is very necessary to design a kind of fundus camera optical system that can be realized three-dimensional imaging, to clinic Medicine and scientific research are all of great significance.
Utility model content
The utility model aim is: it is intended to provide Portable stereoscopic imaging fundus camera optical system, it is existing to solve Monocular fundus camera can not the problem of synchronization obtains one group of image, and realize the miniaturization of fundus camera with it is portable. To realize the above-mentioned technical purpose, the technical solution adopted in the utility model is as follows:
Fundus camera optical system, including nethike embrane object lens, field lens, half-reflection and half-transmission is imaged in the Portable stereoscopic of the utility model Mirror, pre-objective, image-forming objective lens, imager chip and lighting device;The nethike embrane object lens, field lens, half-reflecting half mirror and preposition Object lens are successively set on primary optical axis, and nethike embrane object lens, field lens, pre-objective are vertical with primary optical axis, half-reflecting half mirror and key light Angle between axis is 30-60 °;The rear end of pre-objective forms inclination sub-light road A1With inclination sub-light road A2, tilt sub-light road A1 With inclination sub-light road A2About key light axial symmetry, and tilt sub-light road A1、A2Between angle a be 10-12 °, it is described two inclination son Optical path A1And A2Inclination vertex in field lens rear surface;Tilt sub-light road A1With inclination sub-light road A2On be respectively set by one at As the imaging group that object lens and an imager chip are constituted, two imaging groups are about key light axial symmetry, in an imaging group of top Image-forming objective lens, imager chip be successively set on inclination sub-light road A1On, image-forming objective lens in another imaging group of lower section, at As chip is successively set on inclination sub-light road A2On, the angle between the output light path and half-reflecting half mirror of the lighting device is 30-60°。
Utility model by adopting the above technical scheme, the first Cheng Yici on the field lens after nethike embrane object lens of the picture of human eye retina Real image, the real image on field lens are irradiated on pre-objective through half-reflecting half mirror, become collimated light beam through pre-objective and project Two symmetrical inclination sub-light road A1And A2On, be arranged in image-forming objective lens on two symmetrical inclination sub-light roads by the picture of retina respectively at On picture to respective imager chip, two symmetrical inclination sub-lights roads are placed with identical image-forming objective lens respectively and core are imaged Piece, and tilt sub-light road A1With inclination sub-light road A2Between angle a it is adjustable between 10 °~12 °, two symmetrical inclination sub-light roads Image quality it is identical and formed two images have subtense angle on two imager chips, to realize simultaneously from two Different angle shoots the purpose of same eye ground image, can be realized binocular stereo imaging, grinds to clinical medicine and science Study carefully and is all of great significance.
Further, the rear focus of the nethike embrane object lens is located at field lens, i.e. real image face and field lens formed by nethike embrane object lens It is overlapped.Such design, image quality are preferable.
Further, the field lens is located at the intermediate region of nethike embrane object lens and half-reflecting half mirror.Such design, imaging effect It is more satisfactory.
Further, imaging beam can be become collimated light beam by the pre-objective.Such design is conducive to mentioning for image quality It is high.
Further, the two inclinations sub-light road A1And A2About key light axial symmetry.Such design is ensuring image quality On the basis of, simplied system structure can reduce production cost to a certain extent.
Further, the two inclinations sub-light road A1And A2Between angle a it is adjustable between 10 °~12 °.Such design, The angle between two inclination sub-light roads can arbitrarily changed in ideal range, adjusted between two inclination sub-light roads on demand Distance, the scope of application is wider, design it is relatively reasonable.
Further, the nethike embrane object lens, field lens, half-reflecting half mirror, pre-objective, image-forming objective lens are spheric glass.This The design of sample, nethike embrane object lens, field lens, half-reflecting half mirror, pre-objective, image-forming objective lens do not have paraboloid and irregular mirror surface, Manufacture easy to produce, production cost is low, and precision is higher.
Further, the image-forming objective lens are intense light irradiation camera object lens or Zoom camera object lens, the imager chip For CCD or CMOS.Such design, not only imaging effect is preferable, but also processing speed is very fast, shortens to a certain extent double The time of mesh three-dimensional imaging.
Further, Portable stereoscopic imaging fundus camera optical system is to exempt from mydriasis fundus camera optical system, The Portable stereoscopic imaging fundus camera optical system overall length is less than 250mm, and the lighting device is using coaxial Lighting method.Such design, applicable pupil range is wider, so as to for the binocular solid on many people eyeground at Picture;And optical system size is smaller, can be convenient the carrying of instrument and equipment, and medical staff is facilitated to use;And lighting device uses Coaxial illumination mode may further ensure that the uniformity of illumination, improve the quality of imaging.
Detailed description of the invention
The utility model can be further illustrated by the nonlimiting examples that attached drawing provides;
Fig. 1 is the structural schematic diagram that fundus camera optical system embodiment is imaged in the utility model Portable stereoscopic;
Fig. 2 is that light beam seperated schematic diagram in fundus camera optical system embodiment is imaged in the utility model Portable stereoscopic;
Fig. 3 is the modulation transfer function that fundus camera optical system embodiment is imaged in the utility model Portable stereoscopic (MTF) curve graph;
Fig. 4 is the curvature of field and distortion curve that fundus camera optical system embodiment is imaged in the utility model Portable stereoscopic Figure;
Symbol description in diagram is as follows:
1. nethike embrane object lens, 2. field lenses, 3. half-reflecting half mirrors, 4. pre-objectives, 5. image-forming objective lens, 6. imager chips, 7. are shone Bright device.
Specific embodiment
It is right with reference to the accompanying drawings and examples in order to make those skilled in the art that the utility model may be better understood Technical solutions of the utility model further illustrate.
As depicted in figs. 1 and 2, fundus camera optical system, including nethike embrane object is imaged in the Portable stereoscopic of the utility model Mirror 1, field lens 2, half-reflecting half mirror 3, pre-objective 4, image-forming objective lens 5, imager chip 6 and lighting device 7;The nethike embrane object lens 1, field lens 2, half-reflecting half mirror 3 and pre-objective 4 are successively set on primary optical axis, and nethike embrane object lens 1, field lens 2, pre-objective 4 are equal Vertical with primary optical axis, the angle between half-reflecting half mirror 3 and primary optical axis is 45 °;The rear end of pre-objective forms inclination sub-light road A1With inclination sub-light road A2, tilt sub-light road A1With inclination sub-light road A2About key light axial symmetry, and tilt sub-light road A1、A2Between Angle a be 11 °, it is described two inclination sub-light road A1And A2Inclination vertex field lens 2 rear surface;Tilt sub-light road A1With incline Oblique sub-light road A2On be respectively set the imaging group being made of an image-forming objective lens 5 and an imager chip 6, two imaging groups about Key light axial symmetry, image-forming objective lens 5, imager chip 6 in an imaging group of top are successively set on inclination sub-light road A1On, under Image-forming objective lens 5, imager chip 6 in another imaging group of side are successively set on inclination sub-light road A2On, the lighting device 7 Output light path and half-reflecting half mirror 3 between angle be 45 °.
When angle between half-reflecting half mirror 3 and primary optical axis is 30 °, the output light path and half-reflecting half mirror 3 of lighting device 7 Between angle be 60 °;If the angle between half-reflecting half mirror 3 and primary optical axis is 60 °, the output light path of lighting device 7 Angle between half-reflecting half mirror 3 is 30 °, and above-mentioned angle is mutually remaining two-by-two.
In the present embodiment, the distance between human eye retina e and nethike embrane object lens 1 are at least 10mm, the picture of human eye retina The first Cheng Yici real image at the field lens 2 of nethike embrane object lens 1, the diameter of real image is between 10-20mm, and the real image on field lens 2 is through half Anti- pellicle mirror 3 is irradiated on pre-objective 4, becomes collimated light beam through pre-objective 4 and project symmetrically arranged two-way respectively inclining Oblique sub-light road A1And A2On, the image-forming objective lens 5 being arranged on oblique sub-light road are by the picture of retina and are imaged onto respective imaging respectively On chip 6, sub-light road A is tilted1With inclination sub-light road A2It is upper to be placed with identical image-forming objective lens 5 and imager chip 6 respectively, And inclination sub-light road A1With inclination sub-light road A2Between angle a it is adjustable between 10 °~12 °, two symmetrical inclination sub-light roads at Image quality amount is identical and formed two images have subtense angle on two imager chips 6, thus realize simultaneously from two not With the purpose of the same eye ground image of angle shot, binocular stereo imaging can be realized, to clinical medicine and scientific research All it is of great significance.
The rear focus and field lens 2 of nethike embrane object lens 1 coincide with real image face, and image quality is preferable at this time.That is the position of field lens 2 At the rear focus of nethike embrane object lens 1, i.e., real image face formed by nethike embrane object lens 1 is overlapped with field lens 2, can also be according to the actual situation The specific relationship considered between field lens 2 and the rear focus of nethike embrane object lens 1.
Likewise, the position of field lens 2 is the object focus of pre-objective 4 simultaneously, at this time light by pre-objective at As effect is best;The relationship between field lens 2 and the object focus of pre-objective 4 can also be specifically considered according to the actual situation.
Imager chip (6) be arranged at the rear focus of image-forming objective lens (5), thus on imager chip at clearly as, Position between two imager chips and corresponding image-forming objective lens can also be adjusted according to the actual situation.
Field lens 2 is located at the intermediate region of nethike embrane object lens 1 and half-reflecting half mirror 3, and such imaging effect is more satisfactory.It can also root According to the specific specific location for considering field lens 2 between nethike embrane object lens 1 and half-reflecting half mirror 3 of actual needs.
Imaging beam can be become collimated light beam by pre-objective 4, be conducive to the raising of image quality.In fact, can also basis Actual needs is specific to consider whether pre-objective 4 needs imaging beam becoming collimated light beam.
Two inclination sub-light road A1And A2About key light axial symmetry, two symmetrical inclination sub-light road A1And A2It can be with about primary optical axis Bilateral symmetry can also be symmetrical above and below, can be on the basis of ensuring image quality, and simplied system structure can be to a certain degree Upper reduction production cost can also specifically consider two inclination sub-light road A according to actual needs1And A2Whether about key light axial symmetry.
Two inclination sub-light road A1And A2Between angle a it is adjustable between 10 °~12 °.Such design, can be more Arbitrarily change the angle between two inclination sub-light roads in ideal range, to adjust the distance between two inclination sub-light roads on demand, fits It is wider with range, it designs relatively reasonable.Optimal is selected as 11 °, can also specifically consider the model of angle a according to the actual situation It encloses.
Nethike embrane object lens 1, field lens 2, half-reflecting half mirror 3, pre-objective 4, image-forming objective lens 5 are spheric glass, nethike embrane object lens 1, field lens 2, half-reflecting half mirror 3, pre-objective 4, image-forming objective lens 5 are without paraboloid and irregular mirror surface, manufacture easy to produce, Production cost is low, and precision is higher.In fact, can also specifically consider nethike embrane object lens 1, field lens 2, half-reflection and half-transmission according to the actual situation The type of mirror 3, pre-objective 4, image-forming objective lens 5.
Image-forming objective lens 5 are intense light irradiation camera object lens or Zoom camera object lens, and imager chip 6 is CCD or CMOS.It is such Design, not only imaging effect is preferable, but also processing speed is very fast, shortens the time of binocular stereo imaging to a certain extent. In fact, can also specifically consider the type of image-forming objective lens 5 and imager chip 6 according to the actual situation.
Portable stereoscopic imaging fundus camera optical system is to exempt from mydriasis fundus camera optical system, the Portable standing Body is imaged fundus camera optical system overall length and is less than 250mm, and the lighting device 7 uses coaxial illumination mode.In this way Design, applicable pupil range is wider, so as to the binocular stereo imaging for many people eyeground;And optical system ruler It is very little smaller, it can be convenient the carrying of instrument and equipment, medical staff facilitated to use;And lighting device 7 uses coaxial illumination mode, it can To further ensure that the uniformity of illumination, improve the quality of imaging.In fact, can also specifically consider according to the actual situation portable Whether formula three-dimensional imaging fundus camera exempts from the lighting method of mydriasis and lighting device 7.
As shown in figure 3, in the MTF curve of the utility model Portable stereoscopic imaging fundus camera optical system, it is each to regard The mtf value of field is all larger than 0.2 at 150lp/mm, meets China " ophthalmological instrument eyeground pharmaceuticals industry standard YY0634-2008 Camera " as defined in image resolution ratio be greater than the technical requirements of 80lp/mm, and the transfer curve trend of each visual field is flat Sliding, image quality is preferable.
Optical system there are each point that when curvature of field, cannot make on a biggish planar object simultaneously in same image planes at Sharply defined image, since imager chip 6 requires image planes must in the same plane, therefore the curvature of field needs very little.Field curve as shown in Figure 4 It can be seen that curvature of field value is up to 0.012mm, planar imaging requirement is complied fully with.The presence of distortion makes chief ray pass through optical system It is not equal to ideal image height after system with the intersection height of Gauss image planes, makes to cause image distortion as losing similitude relative to object.By Distortion curve shown in Fig. 4 can be seen that distortion value maximum is only -2.5%, therefore image is without obvious distortion phenomenon.
In summary, the Portable stereoscopic imaging fundus camera optical system of the utility model design can be from two differences Angle shoots same eye ground photo simultaneously, and image quality has reached the pharmaceuticals industry standard YY0634- of China's formulation The standard of 2008 " ophthalmological instrument fundus camera " defineds, and it is better than this standard.
Above-described embodiment is merely exemplary to illustrate the principle and effect of the utility model, and not for limitation, this is practical new Type.Any person skilled in the art can all carry out above-described embodiment under the spirit and scope without prejudice to the utility model Modifications and changes.Therefore, all those of ordinary skill in the art are without departing from the revealed spirit of the utility model With all equivalent modifications completed under technical idea or change, should be covered by the claim of the utility model.

Claims (9)

1. fundus camera optical system is imaged in a kind of Portable stereoscopic, it is characterised in that: including nethike embrane object lens (1), field lens (2), Half-reflecting half mirror (3), pre-objective (4), image-forming objective lens (5), imager chip (6) and lighting device (7);The nethike embrane object Mirror (1), field lens (2), half-reflecting half mirror (3) and pre-objective (4) are successively set on primary optical axis, nethike embrane object lens (1), field lens (2), pre-objective (4) is vertical with primary optical axis, and the angle between half-reflecting half mirror (3) and primary optical axis is 30-60 °;Preceding glove The rear end of mirror forms inclination sub-light road A1With inclination sub-light road A2, tilt sub-light road A1With inclination sub-light road A2About primary optical axis pair Claim, and tilts sub-light road A1、A2Between angle a be 10-12 °, it is described two inclination sub-light road A1And A2Inclination vertex in field lens (2) rear surface;Tilt sub-light road A1With inclination sub-light road A2On be respectively set by an image-forming objective lens (5) and an imager chip (6) the imaging group constituted, image-forming objective lens (5), imaging of two imaging groups about key light axial symmetry, in an imaging group of top Chip (6) is successively set on inclination sub-light road A1On, image-forming objective lens (5), imager chip (6) in another imaging group of lower section It is successively set on inclination sub-light road A2On, the angle between the output light path and half-reflecting half mirror (3) of the lighting device (7) is 30-60°。
2. fundus camera optical system is imaged in Portable stereoscopic according to claim 1, it is characterised in that: the field lens (2) position is at the rear focus of nethike embrane object lens (1), i.e., real image face formed by nethike embrane object lens (1) is overlapped with field lens (2);And The position of field lens (2) is the object focus of pre-objective (4) simultaneously;The image space coke in image-forming objective lens (5) is arranged in imager chip (6) At point.
3. fundus camera optical system is imaged in Portable stereoscopic according to claim 1, it is characterised in that: described half anti-half Lens (3) are located at region between field lens (2) and pre-objective (4).
4. fundus camera optical system is imaged in Portable stereoscopic according to claim 1, it is characterised in that: the preceding glove Mirror (4) is located between half-reflecting half mirror (3) and image-forming objective lens (5), and imaging beam becomes collimated light beam after pre-objective (4) It projects at image-forming objective lens (5).
5. fundus camera optical system is imaged in Portable stereoscopic according to claim 1, it is characterised in that: described two is symmetrical Tilt sub-light road A1And A2Inclination vertex in field lens (2) rear surface, and two symmetrical inclination sub-light road A1And A2It can about primary optical axis With symmetrically can also be symmetrical above and below.
6. fundus camera optical system is imaged in Portable stereoscopic according to claim 5, it is characterised in that: inclination Optical path A1With inclination sub-light road A2Between included angle a be 11 °.
7. fundus camera optical system is imaged in Portable stereoscopic according to claim 1, it is characterised in that: the imaging Object lens (5) are strong light image-forming objective lens or varifocal imaging object lens, and the imager chip (6) is CCD or CMOS.
8. fundus camera optical system is imaged in Portable stereoscopic according to claim 1, it is characterised in that: described is portable Formula three-dimensional imaging fundus camera optical system is to exempt from mydriasis fundus camera optical system, and eyeground phase is imaged in the Portable stereoscopic Machine optical system overall length is less than 250mm.
9. fundus camera optical system is imaged in Portable stereoscopic according to claim 1, it is characterised in that: half-reflecting half mirror (3) angle between primary optical axis is 45 °, and the angle between the output light path and half-reflecting half mirror (3) of lighting device (7) is 45°。
CN201820068369.XU 2018-01-16 2018-01-16 Fundus camera optical system is imaged in Portable stereoscopic Withdrawn - After Issue CN208876483U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201820068369.XU CN208876483U (en) 2018-01-16 2018-01-16 Fundus camera optical system is imaged in Portable stereoscopic

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201820068369.XU CN208876483U (en) 2018-01-16 2018-01-16 Fundus camera optical system is imaged in Portable stereoscopic

Publications (1)

Publication Number Publication Date
CN208876483U true CN208876483U (en) 2019-05-21

Family

ID=66491843

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201820068369.XU Withdrawn - After Issue CN208876483U (en) 2018-01-16 2018-01-16 Fundus camera optical system is imaged in Portable stereoscopic

Country Status (1)

Country Link
CN (1) CN208876483U (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN108577801A (en) * 2018-01-16 2018-09-28 天津工业大学 Portable stereoscopic is imaged fundus camera optical system

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN108577801A (en) * 2018-01-16 2018-09-28 天津工业大学 Portable stereoscopic is imaged fundus camera optical system
CN108577801B (en) * 2018-01-16 2023-12-01 天津工业大学 Portable three-dimensional imaging fundus camera optical system

Similar Documents

Publication Publication Date Title
CN110934563B (en) Ophthalmologic information processing apparatus, ophthalmologic apparatus, and ophthalmologic information processing method
US20080198330A1 (en) Pupillometers
JP2006341094A (en) Method for operating ophthalmological analysis system
US20150313462A1 (en) Method and System of using Photorefractive effects to examine eyes using a portable device
CN103142210B (en) Peripheral refraction measuring method based on OCT technology
CN110441901A (en) It is a kind of can real-time tracing watch the optical microscope system and method for position attentively
JP2022526867A (en) Eye examination
CN106343950A (en) Fundus camera binocular stereo-imaging system based on eye model
CN108294726A (en) Binocular fundus camera imaging optical system
CN207168484U (en) Binocular fundus camera imaging optical system
CN101474061B (en) Contact type eyeground imaging system
CN208876483U (en) Fundus camera optical system is imaged in Portable stereoscopic
CN108577801A (en) Portable stereoscopic is imaged fundus camera optical system
CA3086400C (en) Multiple off-axis channel optical imaging device with rotational montage
CN207081931U (en) A kind of fundus imaging apparatus based on mobile device
Konstantinou et al. Retinal imaging using a confocal scanning laser ophthalmoscope-based high-magnification module
Gellrich et al. History of the slit lamp
Wu et al. Design of optical system for binocular fundus camera
US11614623B2 (en) Holographic real space refractive system
CN206443683U (en) Ultra-wide angle eyeground imaging system
Garcia CWhatUC: Software Tools for Predicting, Visualizing and Simulating Corneal Visual Acuity
Coppin Mathematical modeling of a light field fundus camera and its applications to retinal imaging
WO2024004455A1 (en) Opthalmic information processing device, opthalmic device, opthalmic information processing method, and program
Zhao et al. Optical Design of a Snapshot Nonmydriatic Fundus-imaging Spectrometer Based on the Eye Model
WO2021256132A1 (en) Ophthalmic device, method for controlling ophthalmic device, and program

Legal Events

Date Code Title Description
GR01 Patent grant
GR01 Patent grant
AV01 Patent right actively abandoned
AV01 Patent right actively abandoned
AV01 Patent right actively abandoned

Granted publication date: 20190521

Effective date of abandoning: 20231201

AV01 Patent right actively abandoned

Granted publication date: 20190521

Effective date of abandoning: 20231201