CN115956876A - Fundus camera optical system with diaphragm and fundus camera - Google Patents

Abstract

The present disclosure relates to a fundus camera optical system having a diaphragm, including an illumination device, a first optical assembly, a second optical assembly, an imaging device, and a positioning device; the lighting device comprises a lighting source; the first optical assembly comprises a first half mirror, a first polaroid, a second half mirror and a retina objective lens, the first optical assembly directs the light beam from the illumination light source to the fundus of the eye to be detected and directs the reflected light of the fundus to the second optical assembly; the second optical assembly includes a second polarizer and a focusing module that directs the reflected light to the imaging device; the imaging device receives the light from the second optical assembly to form a fundus image; the positioning device comprises a guide light source and a diaphragm, a light beam of the guide light source has a preset shape after passing through the diaphragm, the imaging device acquires fundus images of different areas of the eye to be inspected based on the guide light source, and the first optical assembly guides the light beam of the guide light source to the fundus of the eye to be inspected for imaging.

Description

Fundus camera optical system with diaphragm and fundus camera

The application is a divisional application of patent applications with the application date of 2019, 12 and 01, and the application number of 201911209363.5, namely an optical system of a fundus camera and the fundus camera.

Technical Field

The disclosure relates to the technical field of medical equipment, in particular to an eye fundus camera optical system with a diaphragm and an eye fundus camera.

Background

The retina of the fundus of the human eye is distributed with a large number of capillaries, which can cause the pathological changes of the capillaries on the retina of a patient when the patient suffers from diseases such as diabetes, glaucoma, maculopathy, hypertension and the like. The medical staff can judge whether the patient has the disease or not by observing the microvascular network on the retina.

Currently, in actual clinical diagnosis, medical staff often acquires fundus images of a patient using a fundus camera to obtain a diagnosis result of the patient.

Most of the existing fundus cameras include an illumination system and an imaging system. The illumination system provides illumination light, fundus reflection light is generated after the illumination light reaches the fundus of the human eyes, and the fundus reflection light forms a fundus image after passing through the imaging system.

For example, patent document 1 (patent application publication No. CN 105581771A) discloses a fundus camera including a fixation light source. In the fundus camera of patent document 1, the image sensor and the fixation lamp element are positioned at the equivalent focal plane of the imaging lens group by the optical element, and the fixation lamp element and the image sensor element share the imaging system, and the fixation light source is incident on the eye fundus.

However, in the above-mentioned patent document 1, the fixation light source of the fundus camera and the image sensing element use the same optical path, so that the fundus reflection light of the human eye is weak compared with the reflection light of the cornea, and a large amount of stray light is generated at the time of photographing by the fundus camera.

Disclosure of Invention

The present disclosure has been made in view of the above circumstances, and an object thereof is to provide an optical system of a fundus camera and a fundus camera capable of reducing stray light generated when the fundus of an eye to be examined is imaged.

To this end, the present invention discloses an optical system of an eye fundus camera, characterized in that: the method comprises the following steps: an illumination device having an illumination light source; a first optical assembly having a first half mirror, a first polarizer for converting a light beam from the illumination light source received by the first half mirror into first polarized light having a first polarization state, a second half mirror for reflecting the first polarized light to the retinal objective lens, the retinal objective lens for directing the received first polarized light to a fundus of the eye and receiving reflected light of the fundus, and a retinal objective lens for receiving the reflected light passing through the retinal objective lens and directing the reflected light to a second optical assembly; the second optical assembly is provided with a second polaroid and a focusing module, the second polaroid is used for obtaining second polarized light with a second polarization state by using the reflected light, and the focusing module guides the second polarized light to an imaging device; the imaging device receives the second polarized light to form a fundus image; and a positioning device having a plurality of guiding light sources, the guiding light sources are used for guiding the visual direction of the eye to be inspected, the imaging device is based on the guiding light sources acquire fundus images of different regions of the eye to be inspected, wherein, the first optical assembly can receive the light beams received by the first half mirror to be guided to the fundus of the eye to be inspected for imaging, the polarization direction of the first polarization state is orthogonal to the polarization direction of the second polarization state, the omentum objective lens is coaxial with the focusing module, and the second half mirror is placed in a mode that the optical axis is 45 degrees.

In the present disclosure, a light beam provided by an illumination light source in an illumination device passes through a first polarizing plate, and forms first polarized light having a first polarization state, which is incident to an eye to be examined and reflected at a fundus to generate reflected light. The reflected light forms second polarized light with a second polarization state through a second polarizing plate, and the second polarized light reaches the imaging device to form a fundus image. In this case, the first polarized light is reflected at the retinal objective lens and the cornea of the eye to be inspected to generate stray light having the first polarization state, and the stray light having the first polarization state can be filtered by the second polarizer. Therefore, stray light doped in reflected light of the fundus can be filtered through the second polaroid, and a clear fundus image is obtained.

In the optical system of the fundus camera of the present disclosure, optionally, the positioning device includes a lens, the plurality of directing light sources are located at and near a focal point of the lens, and light beams of the directing light sources pass through the lens to reach the first half mirror. In this case, the light beam passing through the lens can be made parallel.

In the optical system of the fundus camera of the present disclosure, optionally, the illumination device has a light uniformizing sheet that uniformizes the light beam from the illumination light source. In this case, the light beam after passing through the light uniformizing sheet can be made uniform.

In the optical system of the fundus camera of the present disclosure, optionally, the light uniformizing sheet has a conjugate relationship with the pupil of the eye to be examined. In this case, a uniform spot can be formed at the pupil of the eye to be examined.

In the optical system of the fundus camera of the present disclosure, optionally, the illumination device includes a field stop for adjusting the size of the light spot on the pupil. In this case, the size of the light beam emitted from the illumination device can be controlled.

In the optical system of the fundus camera of the present disclosure, optionally, the retinal objective lens assembly includes at least a cemented lens. In this case, partial color difference can be eliminated.

In the optical system of a fundus camera of the present disclosure, optionally, the focusing module includes a focusing group and a first aperture stop, the focusing group being close to the second polarizing plate. In this case, it is possible to perform clear imaging in the following by adjusting the focusing group and the first aperture stop.

In the optical system of the fundus camera of the present disclosure, optionally, a distance of the focusing group from the second polarizing plate is adjustable. In this case, the purpose of focusing on the eyes to be inspected having different degrees of visibility can be achieved.

In the optical system of a fundus camera of the present disclosure, optionally, a pupil of the eye to be examined has a conjugate relationship with the first aperture stop. In this case, the influence of the pupil of the eye to be examined on the fundus image acquired by the imaging device 14 can be avoided.

The present disclosure relates to an eye fundus camera, characterized in that: the method comprises the following steps: the optical system of the fundus camera of any of the above; and a peripheral device connected to the image forming apparatus, wherein the peripheral device further includes: a control module for controlling movement of optical elements within the first and second optical assemblies; and an information processing module for processing imaging information captured by the imaging device.

In the present disclosure, a light beam provided by an illumination light source in an illumination device passes through a first polarizing plate, and forms first polarized light having a first polarization state, which is incident to an eye to be examined and reflected at a fundus to generate reflected light. The reflected light forms second polarized light with a second polarization state through a second polarizing plate, and the second polarized light reaches the imaging device to form a fundus image. The imaging device is connected with the peripheral device, and in the peripheral device, the control module can control the distance between the focusing group in the focusing module and the second polaroid so as to achieve the purpose of focusing. In this case, the imaging apparatus can obtain a clearer fundus image. Meanwhile, the information processing module can store, deform, transmit and display imaging information captured by imaging.

Compared with the prior art, the method and the device can reduce stray light generated by the cornea during shooting, obtain clearer fundus images and simplify the structures of the fundus camera and the optical system thereof.

Drawings

Embodiments of the present disclosure will now be explained in further detail, by way of example only, with reference to the accompanying drawings, in which:

fig. 1 is a schematic diagram showing an application scenario of a fundus camera according to the present disclosure.

Fig. 2 is a schematic diagram showing a module frame of a fundus camera according to the present disclosure.

Fig. 3 is a schematic diagram showing a module frame of an optical system of a fundus camera according to the present disclosure.

Fig. 4 is a schematic diagram showing an illumination device of the fundus camera according to the present disclosure.

Fig. 5 is a schematic diagram showing a modification of the illumination device of the fundus camera according to the present disclosure.

Fig. 6 is a schematic diagram showing an illumination light source of an illumination device of a fundus camera according to the present disclosure.

Fig. 7 is a schematic diagram showing a first optical component of an optical system of a fundus camera according to the present disclosure.

Fig. 8 is a schematic diagram illustrating a second optical component in the optical system according to the present disclosure.

Fig. 9 is a schematic diagram showing a positioning device of a fundus camera according to the present disclosure.

Fig. 10 is a schematic view showing a guidance light source of the positioning device according to the present disclosure.

Fig. 11 is a schematic diagram showing a module frame of a peripheral device of a fundus camera according to the present disclosure.

The main reference numbers illustrate:

1 \8230, fundus camera 10 \8230, optical system 11 \8230, lighting device 12 \8230, first optical assembly 13 \8230, second optical assembly 14 \8230, imaging device 15 \8230, positioning device 16 \8230, optical axis 17 \8230peripheraldevice 2 \8230, examined eye 21 \8230, fundus 22 \8230andcornea.

Detailed Description

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, the same components are denoted by the same reference numerals, and redundant description thereof is omitted. The drawings are schematic and the ratio of the dimensions of the components and the shapes of the components may be different from the actual ones.

It should be noted that the terms "first", "second", and the like in the description and claims of the present disclosure and in the above-described drawings are used for distinguishing between different objects and not for describing a particular order. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements but may alternatively include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

In addition, the subtitles and the like referred to in the following description of the present disclosure are not intended to limit the content or the scope of the present disclosure, and serve only as a hint in reading. Such a subtitle should neither be understood as a content for segmenting an article, nor should the content under the subtitle be limited to only the scope of the subtitle.

Fig. 1 is a schematic diagram showing an application scene of a fundus camera according to the present disclosure. In the present embodiment, as shown in fig. 1, the fundus camera 1 is a hand-held fundus camera. The medical staff can obtain the fundus image of the eye 2 of the patient by operating the fundus camera 1 with one hand or both hands.

Fig. 2 is a schematic diagram showing a module frame of a fundus camera according to the present disclosure. In the present embodiment, as shown in fig. 2, the fundus camera 1 may include an optical system 10 and an external device 17. The optical system 10 of the fundus camera 1 can obtain a clear fundus image of the eye 2 to be examined. The peripheral device 17 is capable of controlling part of the optical components in the optical system 10 of the fundus camera 1 and processing a fundus image obtained by the optical system 10 of the fundus camera 1. The optical system 10 of the fundus camera 1 according to the present embodiment may be simply referred to as the optical system 10.

Fig. 3 is a schematic diagram disclosing a module frame of the optical system 10 of the fundus camera 1 according to the present disclosure. In the present embodiment, as shown in fig. 3, the optical system 10 of the fundus camera 1 may include an illumination device 11, a first optical component 12, a second optical component 13, and an imaging device 14. The light beam generated by the illumination light source of the illumination device 11 may be incident on the eye 2 through the first optical assembly 12, and reflected at the fundus of the eye 2 to generate reflected light, which reaches the imaging device 14 through the first optical assembly 12 and through the second optical assembly 13 in sequence.

Fig. 4 is a schematic diagram showing the illumination device 11 of the fundus camera 1 according to the present disclosure. In the present embodiment, as shown in fig. 4, the illumination device 11 may include an illumination light source 111. The illumination source 111 may be a single spectrum light source. In some examples, the illumination light source 111 may be a multi-spectral light source.

In some examples, as shown in fig. 4, the illumination device 11 may include a light uniformizer 112 (also referred to as a light uniformizer). The light uniformizer 112 may receive the light beam emitted from the illumination light source and uniformize the light beam from the illumination light source. In this case, the light beam after passing through the light uniformizing sheet can be made uniform.

In some examples, the light equalizing sheet 112 has a conjugate relationship with the pupil of the subject eye 2. That is, the image plane of the light beam emitted from the light equalizing sheet 112 has a conjugate relationship with the pupil image formed in the eye 2. In this case, a uniform spot can be formed at the pupil of the eye 2 to be examined. That is, the light spot emitted from the light-equalizing sheet 112 can be imaged on the pupil of the eye 2.

In some examples, the light equalizing sheet 112 may be thin and light. For example, the thickness of the light-equalizing sheet 112 may range from 0.05mm to 60mm. The light of the light beam emitted by the light-thin light-equalizing sheet 112 can be uniformly distributed, and the light energy utilization rate is improved. Examples of the present disclosure are not limited thereto, and for example, the thickness of the light uniformizing sheet 112 may be greater than 60mm.

In some examples, the illumination device 11 may include a first lens 113. The first lens 113 may be positioned between the illumination light source 111 and the light equalizing sheet 112. The light beam emitted from the illumination light source 111 may be formed into a parallel light beam by the first lens 113.

In the present embodiment, the first lens 113 of the lighting device 11 may be a convex lens. The illumination source 111 may be placed at the focus of the convex lens. However, the present embodiment is not limited thereto, and the first lens 113 may be an optical instrument composed of a plurality of lenses, for example. The optical instrument may direct the light beam emitted by the illumination source 111 as a parallel light beam.

Fig. 5 is a schematic diagram showing a modification of the illumination device 11 of the fundus camera 1 according to the present disclosure. In some examples, the number of illumination light sources 111 may be plural. As shown in fig. 5, the illumination device 11 may include two illumination light sources and a third half mirror 114, for example, a first illumination light source 111a and a second illumination light source 111b. The light beams respectively emitted from the plurality of illumination light sources may be combined into one light beam by the third half mirror 114. The third half mirror 114 may be a beam splitter or a beam splitter prism for splitting the first illumination light source 111a and the second illumination light source 111b. In some examples, the third half mirror 114 may combine half of the light beams of each illumination source. In other examples, the light beam combined by the third half mirror 114 may be mainly transmitted light in the spectrum of one of the first illumination light source 111a or the second illumination light source 111b.

In some examples, as shown in fig. 5, the light beams emitted by the first illumination light source 111a and the second illumination light source 111b may form two parallel light beams through the first lens 113a and the first lens 113b, respectively. The parallel light beams emitted from the first lens 113a or the first lens 113b may respectively pass through the first light equalizing sheet 112a and the second light equalizing sheet 112b to reach the third half mirror 114.

In some examples, the light beams emitted by the first and second illumination light sources 111a and 111b may directly pass through the first and second light-equalizing sheets 112a and 112b to the third half mirror 114 without the first and second lenses 113a and 113b, respectively.

In some examples, the first and second light-equalizing sheets 112a and 112b may be symmetrically positioned about the third half mirror 114.

In other examples, the illumination device 11 may provide three or more illumination sources 111.

In some examples, where the illumination device 11 has multiple illumination sources, each illumination source may operate simultaneously or individually.

In some examples, the illumination source 111 may be a ring light source. In this case, it is possible to cause stray light generated at the cornea of the eye to be reflected outside the imaging optical path (i.e., the transmission optical path of reflected light from the fundus), thereby reducing stray light doped in the reflected light from the fundus.

Fig. 6 is a schematic diagram showing an illumination light source 111 of the illumination device 11 of the fundus camera 1 according to the present disclosure. In some examples, as shown in fig. 6, the illumination light source 111 may be composed of a plurality of illumination sub-light sources 1111. The illumination source 111 may be composed of a single color illumination sub-source 1111. For example, the illumination light source 111 is composed of visible yellow light as the illumination sub-light source 1111.

However, the present embodiment is not limited thereto, and the illumination light source 111 may be composed of illumination sub-light sources 1111 of two or more single color LEDs. For example, the illumination light source 111 may be a white light source formed by mixing two wavelengths of blue light and yellow light. The illumination light source 111 may be a white light source formed by mixing three wavelengths of blue light, green light, and red light.

Additionally, in some examples, illumination source 111 may be an LED luminescence. Thus, using the LED luminescence as the illumination light source 111 can reduce the operation power of the illumination device 11, reduce the amount of heat generation, reduce the volume of the illumination device 11, and increase the service life of the illumination device 11. In the present embodiment, as shown in fig. 6, the plurality of illumination sub-light sources 1111 may be ring-shaped. However, the present embodiment is not limited to this, and the plurality of illumination sub-light sources 1111 of the illumination light source 111 may be, for example, a tiled type or a rectangular type.

In some examples, the illumination device 11 may include a field stop (not shown). The field stop has a conjugate relationship (i.e., an object-image relationship) with the pupil of the eye 2. The field stop may be used to adjust the size of the spot on the pupil of the eye 2 to be examined. That is, the size of the light beam from the illumination light source 111 can be adjusted by the field stop.

In some examples, the illumination device 11 may include a second lens (not shown). When the illumination device 11 has only one illumination light source (for example, the illumination light source 111), the light equalizing sheet 112 and the field stop are in an object-imaging relationship with respect to the second lens. When the illumination device 11 has a plurality of illumination light sources (e.g., the first illumination light source 111a and the second illumination light source 111 b), each light equalizing sheet (e.g., the first light equalizing sheet 112a and the second light equalizing sheet 112 b) is in an object imaging relationship with the field stop with respect to the second lens.

In some examples, when the illumination device 11 has only one illumination light source (e.g., the illumination light source 111), the light beam emitted from the light equalizing sheet 112 passes through the second lens to reach the field stop. When the illumination device 11 has a plurality of illumination light sources, for example, the first illumination light source 111a and the second illumination light source 111b, the light beam combined by the third half mirror 114 reaches the field stop through the second lens.

In some examples, the illumination device 11 may include a lens group and a second aperture stop. The light beam passing through the field stop reaches the first optical assembly 12 through the lens group and the second aperture stop in sequence (described later in detail).

Fig. 7 is a schematic diagram showing the first optical component 12 of the optical system 10 of the fundus camera 1 according to the present disclosure. As shown in fig. 7, the first optical assembly 12 may project a light beam from the illumination light source of the illumination device 11 to the fundus 21 of the eye 2. In some examples, the first optical assembly 12 may direct a light beam of a directing light source 151 of a positioning device 15 (described in detail later) to the eye 2.

In the present embodiment, as shown in fig. 7, the first optical assembly 12 may include a first polarizing plate 121. The first polarizer 121 may transmit a light beam having a first polarization state. In particular, the first polarizer 121 may be used to convert a light beam from an illumination source of the illumination device 11 into first polarized light having a first polarization state. The present embodiment is not limited to this, and for example, the first polarizing plate 121 may be replaced with an optical element including a polarizing plate capable of forming a light beam having the first polarization state, or may be replaced with an optical device having the same or similar polarizing function.

In some examples, as shown in fig. 7, the first optical assembly 12 may include a first half mirror 122. The first half mirror 122 may receive a light beam from an illumination source of the illumination device 11 and direct the light beam to the first polarizer 121. I.e. the light beams from the illumination sources of the illumination device 11 may pass through the first half mirror 122 to reach the first polarizer 121.

In some examples, the first half mirror 122 can be a beam splitting plate or a beam splitting prism.

In some examples, as shown in fig. 7, the first half mirror 122 may couple a light beam from the illumination source of the illumination device 11 and a light beam from the positioning device 15 and direct the coupled light beam to the first polarizer 121. The first half mirror 122 is disposed between the illumination device 11 and the first polarizer 121.

In some examples, the first half mirror 122 may change the direction of propagation of the pointing light source of the positioning device 15. Specifically, the first half mirror 122 may receive the light beam from the guidance light source 151 (see fig. 7) of the positioning device 15 and reflect the light beam of the guidance light source so that the light beam from the illumination light source and the light beam of the guidance light source share one optical path. That is, the light beam from the illumination source and the light beam from the directing source share the first optical assembly 12. In this case, coaxial illumination and positioning can be formed, and the use of optical elements can be reduced, and the structure of the fundus camera 1 can be simplified.

In other examples, the first half mirror 122 may be replaced by an optical element having a similar function as the first half mirror 122, such as a beam splitter, or an optical element group such as a beam expanding mirror, a lens, or a lens group, which can change the propagation direction of the light beam from the guiding light source of the positioning device 15.

In some examples, the angle of the first half mirror 122 is adjustable. In this case, the optical path structure in the optical system 10 can be simplified.

In some examples, when the fundus camera 1 does not include the positioning device 15, the first optical assembly 12 may not include the first half mirror 122, in which case the light beam from the illumination light source of the illumination device 11 is directly received by the first polarizing plate 121. The example of the present disclosure is not limited thereto, and when the fundus camera 1 does not include the positioning device 15, the first optical assembly 12 may include the first half mirror 122.

In the present embodiment, as shown in fig. 7, the first optical element 12 may include a second half mirror 123. The second half mirror may be used to receive the first polarized light and reflect the first polarized light to the web objective 124 (described in detail later). In some examples, the second half mirror 123 can be substantially parallel to the first half mirror 122.

In some examples, the second half mirror 123 may be disposed between the first polarizer 121 and the second polarizer 131 (see fig. 7 and 8). As shown in fig. 7, the second half mirror 123 may be disposed at an angle to the optical axis 16 (described later) of the retinal objective lens 124. The degree of the included angle may be, but is not limited to, 40 °, 45 °, or 50 °.

In some examples, the second half mirror 123 may be replaced with a beam splitter. The beam splitter may be an optical element having the same or similar function as the second half mirror 123. Examples of the present disclosure are not limited thereto, and the second half mirror 123 may be replaced with an optical element group such as a beam expander, a lens group, a polarization splitting prism, a depolarization splitting prism, and the like. The polarization beam splitter prism and the depolarization beam splitter prism can be provided with antireflection films.

In some examples, as shown in fig. 7, the second half mirror 123 may change the propagation direction of the first polarized light having the first polarization state so that the light beam having the first polarization state shares part of the optical element (for example) with the reflected light of the fundus 21. This can reduce the use of optical elements, and can simplify the structure of the fundus camera 1.

In this embodiment, as shown in fig. 7, the first optical assembly 12 may comprise a retinal objective 124 positioned between the second half mirror 123 and the eye 2. The retinal objective lens 124 may be used to guide the received first polarized light to the fundus 21 of the eye 2 to be examined and receive reflected light of the fundus 21.

In some examples, the retinal objective 124 may be, for example, a three-piece retinal objective, thereby enabling a reduction in the use of optical elements and a reduction in chromatic aberration generated by the light beam reflected by the fundus 21.

In this embodiment, one or more lenses 124a may be provided in the mesh objective lens 124. Therefore, the definition of the light beam can be improved, and the light beam is more uniform.

In this embodiment, the web objective 124 may include a cemented lens 124b. The cemented mirror may be formed by a lens of two different materials cemented together. This makes it possible to eliminate partial chromatic aberration, specifically, to correct chromatic aberration of light of three wavelengths, i.e., blue light, green light, and red light.

In the present embodiment, the retinal objective lens 124 may guide the first polarized light reflected by the second half mirror 123 to the fundus 21 of the eye 2 and receive the reflected light from the fundus 21. The reflected light from the eye 2 passes through the retina objective lens 124 and reaches the second optical element 13 through the second half mirror 123. That is, the second half mirror 123 may be used to receive the reflected light passing through the retinal objective lens 124 and directed to the second optical assembly 14.

In some examples, the first optical assembly 12 can direct the light beam received by the first half mirror 122 from the directing light source 151 to the fundus 21 of the eye 2 to be imaged (described in detail later).

Fig. 8 is a schematic diagram illustrating the second optical component 13 in the optical system 10 according to the present disclosure. In the present embodiment, the second optical assembly 13 may guide the reflected light that has passed through the second half mirror 123 to the imaging device 14 (described later).

In the present embodiment, as shown in fig. 8, the second optical assembly 13 may include a second polarizer 131. The second polarizer 131 may be used to obtain second polarized light having a second polarization state using the reflected light. That is, the reflected light passing through the second half mirror 123 forms a light beam having the second polarization state through the second polarizer 131. Wherein the second polarization state is orthogonal to the polarization direction of the first polarization state. The polarization direction of the first polarization state may be S-polarized and the polarization direction of the second polarization state may be P-polarized. Examples of the present disclosure are not limited thereto, and the polarization direction of the first polarization state may be P-polarization and the polarization direction of the second polarization state may be S-polarization.

In some examples, if the second half mirror 123 in the first optical assembly 12 is a polarization splitting prism, the second optical assembly 13 may not include the second polarizer 131. In this case, the reflected light passing through the second half mirror 123 may directly reach the focusing module. Specifically, when the second half mirror 123 is a polarization splitting prism, the second half mirror 123 can convert the reflected light into second polarized light having a second polarization state, and in this case, the purpose of eliminating stray light can be achieved by the polarization splitting prism. At this time, the first polarizing plate may be attached to the surface of the polarization splitting prism through a connector. The distance between the first polarizer and the surface of the polarization splitting prism ranges from 0mm to 100mm.

In this embodiment, the second optical assembly 13 may include a focusing module. The focusing module may direct the second polarized light to the imaging device 14. The second polarizer 131 and the second half mirror 123 are located on the same side of the focusing module. The focusing module is located between the second polarizer 131 and the imaging device 14. In this case, the light beam having the second polarization state passes through the focusing module to the imaging device 14.

In this embodiment, the web objective lens 124 may be coaxial with the focusing module 16.

In the present embodiment, as shown in fig. 8, the focusing module may include a focusing group 132 and a first aperture stop 134 which are sequentially disposed. The focusing group 132 is close to the second polarizer 131. In this case, it is possible to perform sharp imaging later by adjusting the focus group and the first aperture stop.

In some examples, the focus group 132 may move independently of the optical axis 16. The focusing group 132 may be composed of one or more lenses. The distance between the focusing group 132 and the second polarizer 131 is adjustable. In this case, the focusing group 132 is adjusted for the purpose of focusing (i.e., focusing) the eye 2 to be inspected having a different degree of visibility.

In life, the vision conditions of the examined eyes 2 are different, and the refraction conditions of the lens to the light rays are also different, so that the object image conditions of the light beams reaching the focusing group 132 are different. In this embodiment, the lens base of the focus group 132 is bound to a motor (not shown), and the focus group 132 can be adjusted by controlling the sliding of the motor. Thereby, it is possible to achieve control of the focus of the light beam passing through the second polarizing plate 131 and improve the sharpness of the image formation.

In some examples, the pupil of the subject eye 2 has a conjugate relationship with the first aperture stop 134. In this case, the pupil of the eye 2 can be clearly imaged inside the second optical assembly 13, and the first aperture stop 134 is disposed at the image plane of the pupil. Thereby, it is possible to avoid the influence of the pupil of the eye to be examined 2 on the fundus image acquired by the imaging device 14 (described later), and to improve the reliability of the analysis result.

In some examples, the aperture size of the first aperture stop 134 is adjustable. Thus, by controlling the aperture size of the first aperture stop 134, it is possible to reduce the unevenness of the light beam passing through the focusing group 132 and to weaken stray light in the light beam passing through the focusing group 132, so that the imaging device 14 obtains a clearer fundus image.

In the present embodiment, as shown in fig. 8, the focusing module may further include a field lens 133 disposed between the focusing group 132 and the first aperture stop 134. The field lens 133 may be composed of one or more lenses, whereby the quality of imaging can be improved.

In the present embodiment, as shown in fig. 8, the focus adjustment module may further include a lens group 135 disposed between the first aperture stop 134 and the imaging device 14. Lens group 135 may be comprised of one or more lenses. Thereby, with the lens group 135, the exit light of the first aperture stop 134 is guided to the imaging device 14 better to obtain a clear fundus image.

In the present embodiment, the focusing module is located in the second optical assembly 13, and when the detected eye 2 has different degrees of vision, the focusing module can be focused so that the imaging device 14 obtains a clear fundus image without affecting the optical path in the first optical assembly 12. In this case, the distance of the eye 2 to be examined from the imaging device 14 remains constant.

In the present embodiment, the imaging device 14 may receive the second polarized light to form a fundus image. Specifically, reflected light from the fundus 21 of the eye 2 passes through the retina objective lens 124 and reaches the second optical unit 13 through the second half mirror 123, and the reflected light forms a fundus image at the imaging device 14 through the second optical unit 13. In addition, the imaging device 14 may acquire fundus images of different regions of the eye 2 based on the guidance light sources, that is, when the eye 2 is gazing at different guidance light sources, the imaging device 14 may capture fundus images of different regions of the fundus 21 of the eye 2.

In some examples, the imaging device 14 may be selected from one of a CMOS image sensor or a CCD image sensor or the like. The photosensor can convert image information (light signal) into an electrical signal.

In the present disclosure, the light beam provided by the illumination light source in the illumination device 11 passes through the first polarizing plate 121, and forms first polarized light having a first polarization state, which is incident on the eye to be inspected 2 and reflected at the fundus 21 to generate reflected light. The polarization of the reflected light changes (e.g., the reflected light has no polarization). The reflected light passes through the second polarizing plate 131 to form second polarized light having a second polarization state, and the second polarized light reaches the imaging device 14 to form a fundus image. In this case, the reflection of the first polarized light at the retinal objective 124 and the cornea 22 of the eye 2 generates stray light having the first polarization state, which can be filtered by the second polarizer 131. Accordingly, stray light doped in reflected light of the fundus can be filtered out by the second polarizer 131, and a relatively clear fundus image can be obtained.

In this embodiment, as shown in fig. 3, the optical system 10 may further include a positioning device 15. The positioning device 15 may provide a plurality of directing light sources for directing the rotation of the eye 2. In other words, the positioning device 15 may have a plurality of directing light sources. The directing light source may be used to direct the line of sight of the eye 2.

Fig. 9 is a schematic diagram showing the positioning device 15 of the fundus camera 1 according to the present disclosure. In the present embodiment, as shown in fig. 9, the positioning device 15 may include a directing light source 151 and a lens 152. The light beam of the directed light source 151 may pass through a lens 152 to the first half mirror 122. The light beam of the directed light source reflected by the first half mirror 122 may be transmitted through the first polarizer 121 to generate a light beam having a first polarization state.

In some examples, the directing light source 151 may be a single light source. The directing light source 151 may be placed at the focal point of the lens 152. Thus, the light beam passing through the lens 152 may be parallel light. The light beam passing through the lens 152 passes through the diaphragm 153 to form a directed light source. The directing light source may direct the rotation of the eye 2. In some examples, the shape of the directing light source may be a number, letter, or other pattern.

In some examples, the number of directing light sources 151 may be multiple. A plurality of directing light sources may be at and near the focal point of the lens 152. This makes it possible to make the light flux passing through the lens 152 parallel, that is, to make the angle of view of the light flux emitted from the stop 153 small, thereby avoiding the need to provide a focusing mechanism in the positioning device 15.

Fig. 10 is a schematic view showing the guiding light source of the positioning device 15 according to the present disclosure. The number of the guidance light sources 151 may be represented by a natural number n. In some examples, as shown in fig. 10, the number of directing light sources 151 may be 9.

In this embodiment, the guiding light sources 151 may be distributed at different positions. As shown in fig. 10, one of the plurality of guiding light sources 151 _n As a center of circle, other guiding light sources 151 _n Forming a circle. In other examples, the distribution of the plurality of directing light sources 151 may also be in the shape of a cross, a rectangle, or the like.

In some examples, the number of lenses 152 may be one or more. The image plane of the light source emitted through the diaphragm 153 is a real image. The light beam of the guidance light source can be kept in a nearly parallel state in the optical path to make the light beam image clearly on the fundus 21 (see fig. 9) of the eye 2 to be examined.

In some examples, the positioning device 15 may include a diaphragm 153. The diaphragm 153 is located between the lens 152 and the first half mirror 122. Directing the light source 151 through the lens 152 and the aperture 153 may create uniform illumination.

In some examples, the number of diaphragms 153 may be multiple. The diaphragms 153 may be distributed in a desired shape, whereby the guidance light source formed by the plurality of diaphragms 153 can have a desired shape.

In other examples, the number of diaphragms 153 may be 1. The diaphragm 153 may have n apertures. Each aperture may be of a desired shape. The n pores may be distributed in a desired shape. Thereby, the light source can have a desired shape by the guide of the diaphragm 153.

In some examples, the color of the directing light source 151 may be a different light source than the color of the illumination light source 111 of the illumination device 11. The illumination light source 111 provided by the illumination device 11 is a white LED for cooling light, and the guiding light source 151 may be a red LED, but the example of the present disclosure is not limited thereto, and for example, the illumination light source 111 provided by the illumination device 11 is a white LED for cooling light, and the guiding light source 151 may be a blue LED for cooling light.

In some examples, a lens or lens group (not shown) may be disposed between the stop 153 and the first half mirror 122. Wherein a lens or a group of lenses may be used to direct the light beam passing through the diaphragm 153 to the first half mirror 122.

In some examples, the fundus 21 (i.e., retina) of the eye 2 to be examined is in a conjugate relationship (i.e., object-image relationship) with the diaphragm 153. That is, the eye 2 can observe the diaphragm 153 and the image on the diaphragm 153.

Fig. 11 is a schematic diagram showing a module frame of the peripheral device 17 of the fundus camera 1 according to the present disclosure. In the present embodiment, the fundus camera 1 may include the peripheral device 17 connected to the imaging device 14. As shown in fig. 11, the peripheral device 17 may include an information processing module 171 and a control module 172.

In some examples, the information processing module 171 may be used to process imaging information (e.g., fundus images) captured by the imaging device 14. For example, the information processing module 171 may store, transform, transmit, analyze, and display imaging information (e.g., fundus image).

In some examples, the signal processing module 171 may receive the electrical signals converted by the imaging device 14, apply an artificial intelligence algorithm to compensate the image, and process the data. In some examples, the signal processing module 171 may apply artificial neural network techniques for deep learning, self-screening fundus images for lesion determination.

In other examples, the information processing module 171 may screen out a fundus image that is difficult to distinguish by the artificial intelligence algorithm and extract the fundus image so that the medical staff can review the fundus image to improve the accuracy of the diagnosis result.

In some examples, the information processing portion 171 may also include a display. The display may be used to display fundus images. In addition, the pair of fundus images may be correlated by the display (e.g., magnifying the fundus image).

In some examples, the information processing module 171 may be in communication with an external system or cloud via a wireless connection or a wired connection.

In this embodiment, the control module 172 may be used to control the movement of optical elements within the first optical assembly 12 and the second optical assembly 13. For example, the control module 172 may control the distance between the focusing group 132 and the second polarizer 131 in the focusing module for focusing, in which case the imaging device 14 can clearly capture the fundus image.

In some examples, the control module 172 may control switches that control the illumination device 11, the first optical assembly 12, the second optical assembly 13, and the imaging device 14.

In some examples, the control module 172 may control the brightness level of the illumination sources 111 of the lighting device 11. In the case that there are a plurality of illumination light sources of the illumination device 11, the control module 172 may control on/off of each illumination light source respectively.

In some examples, the plurality of directing light sources 151 in the positioning device 15 may have independent on-off switches. The control module 172 can independently control the on/off switches so that the control module 172 can control the number of lights of the directing light sources 151 in the positioning device 15.

In some examples, the positioning device 15 may drive an adjustment motor of the imaging device 14 and may also drive a photosensor.

In the present disclosure, the light beam provided by the illumination light source in the illumination device 11 passes through the first polarizing plate 121, and forms first polarized light having a first polarization state, which is incident on the eye to be inspected 2 and reflected at the fundus 21 to generate reflected light. The polarization of the reflected light changes (e.g., the reflected light has no polarization). The reflected light passes through the second polarizing plate 131 to form second polarized light having a second polarization state, and the second polarized light reaches the imaging device 14 to form a fundus image. The imaging device 14 is connected to the peripheral device 17. In the peripheral device 17, the control module 172 may control a distance between the focusing group 132 and the second polarizer 131 in the focusing module, so as to achieve the purpose of focusing. In this case, the imaging device 14 can obtain a clearer fundus image. While the information processing module 171 is capable of storing, morphing, transmitting, and displaying imaging information captured by the imaging.

While the invention has been specifically described above in connection with the drawings and examples, it will be understood that the above description is not intended to limit the invention in any way. Those skilled in the art can make modifications and variations to the present invention as needed without departing from the true spirit and scope of the invention, and such modifications and variations are within the scope of the invention.

Claims (10)

1. An fundus camera optical system having a diaphragm, characterized in that:

the device comprises an illuminating device, a first optical assembly, a second optical assembly, an imaging device and a positioning device;

the illumination device comprises an illumination light source;

the first optical assembly comprises a first half mirror, a first polarizer, a second half mirror and a mesh objective lens, wherein the first polarizer is used for converting the light beam received by the first half mirror from the illumination light source into first polarized light with a first polarization state, the second half mirror is used for reflecting the first polarized light to the mesh objective lens, the mesh objective lens is used for guiding the received first polarized light to the fundus of the eye to be detected and receiving reflected light of the fundus, and the second half mirror is used for receiving the reflected light passing through the mesh objective lens and guiding the reflected light to the second optical assembly;

the second optical assembly includes a second polarizer through which the reflected light is converted into second polarized light having a second polarization state, and a focusing module that guides the second polarized light to the imaging device;

the imaging device is used for receiving the second polarized light to form a fundus image;

the positioning device comprises a guide light source and a diaphragm, wherein the diaphragm is used for enabling a light beam of the guide light source to have a preset shape, the guide light source is used for guiding the sight direction of the eye to be detected, the light beam of the guide light source passes through the diaphragm to reach the first half-transmission half-reflection mirror, the light beam of the guide light source is formed to have the preset shape after passing through the diaphragm, the imaging device acquires fundus images of different areas of the eye to be detected based on the guide light source, and the first optical assembly guides the light beam of the guide light source to the fundus of the eye to be detected for imaging.

2. The fundus camera optical system of claim 1,

the illumination light source is an annular light source.

3. The fundus camera optical system of claim 1,

the lighting device comprises a light homogenizing sheet for homogenizing the light beam from the lighting source.

4. The fundus camera optical system of claim 3,

the light homogenizing sheet and the pupil of the eye to be detected have a conjugate relation.

5. The fundus camera optical system according to claim 1,

the positioning device comprises a lens positioned between the guiding light source and the diaphragm, and the light beam of the guiding light source forms parallel light after passing through the lens.

6. The fundus camera optical system according to claim 5,

the directing light source is positioned at a focal point of the lens.

7. The fundus camera optical system of claim 1,

the polarization direction of the first polarization state is orthogonal to the polarization direction of the second polarization state.

8. The fundus camera optical system according to claim 1,

the diaphragm has an aperture in the predetermined shape.

9. The fundus camera optical system of claim 1,

the fundus of the eye to be examined and the diaphragm are in a conjugate relation.

10. An eye fundus camera, characterized in that:

the method comprises the following steps:

the fundus camera optical system of any one of claims 1 to 9; and

a peripheral device connected with the image forming device,

wherein the peripheral device further comprises:

a control module for controlling movement of optical elements within the first and second optical assemblies; and

an information processing module for processing imaging information captured by the imaging device.

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