JPH01284228A - Optical system for laser scan eye-ground camera - Google Patents

Abstract

PURPOSE:To lessen scatter in inspection due to age and conditions by providing an optical system with a luminous flux diameter adjusting means adjusting the luminous flux diameter of laser beams. CONSTITUTION:A light receiving optical system is equipped with an optical system ranging from a beam splitter 3 to an object lens 11, a beam expander 12 acting as a luminous flux diameter adjusting means, a light collecting lens 13, a pin hole plate 14 and with a photo diode 15 acting as a light receiving section. Luminous flux reflected by an eye-ground E1 comes into the beam splitter 3 from the object lens 11 while being guided by a polygon mirror 4 so as to be reflected to the beam expander 12 side. The reflected luminous flux is changed in diameter by the beam expander 12 while being adjusted so that the flux is collected into the pin hole 14a of the pin hole plate 14 by the light collecting lens 13 so as to let the flux come into the photo diode 15. The pupil diameter of the light receiving optical system is specified by the effective diameter of the beam expander 12. When there exists no eclipse therefore in the lens of a scanning device A, if only the expander 12 which is different in a variable power ratio is ready for use, the pupil diameter can thereby be changed by replacing the expander.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an optical system of a laser scanning fundus camera in which the fundus of an eye to be examined is scanned and illuminated with laser light.

(Prior Art) In general, when observing and photographing the fundus of an eye to be examined, a fundus camera is designed to evenly illuminate the entire fundus of the eye to be examined. In this case, the fundus of the subject's eye is illuminated with relatively strong light, which places a burden on the subject, which is not very desirable.

In recent years, fundus cameras that can reduce this burden have been developed by scanning and illuminating the fundus of the examinee's eye with a laser beam of a fixed spot diameter, and detecting the amount of light reflected from the fundus of the examinee's eye at each interval of the laser beam spot diameter. This detected spot light information is used to construct a fundus image of the subject's eye on a monitor television.

As such a fundus camera, for example, JP-A-60-1
32536 and Japanese Patent Laid-Open No. 62-117524 are known. In order to improve image contrast, this fundus camera uses an optical scanning device in both the illumination optical system for emitting laser light and the receiving optical system for guiding reflected light or fluorescence from the fundus to a receiver. I'm doing it like that.

In these fundus cameras, by placing a pinhole (diaphragm) in a position conjugate with the fundus in the light-receiving optical system, the diameter of this pinhole determines the size of the light flux projected onto the fundus, that is, each pixel of the image. The resolution is determined by specifying the size of the image.

In other words, in the light receiving optical system of these fundus cameras,
The structure is configured so that only the light reflected from the part of the projected image on the fundus passes through the pinhole, so even if the illumination light spot is larger than this projected image, for example, the reflected light from outside the projected image will not pass through the pinhole. does not pass through the pinhole. Therefore,
The resolution of the image is determined by the pinhole image projected onto the fundus. Therefore, in an apparatus having such a configuration, the resolution is determined by the optical system that projects the pinhole, that is, by the performance of the light receiving optical system.

(Problem to be Solved by the Invention) In such a fundus camera, the diameter of the laser beam of the illumination optical system is covered by a lens in order to have the light receiving section receive as much light reflected from the fundus as possible and improve resolution. It is preferable to make the pupil diameter of the light receiving optical system as large as possible while making it changeable according to the scanning magnification for the fundus.

However, when the diameter of the light-receiving optical system is large, the resolution improves, but the depth of field becomes shallow, making it difficult to focus on the entire fundus of the subject's eye, which has irregularities, and if the subject's eye moves even slightly, the focus will be lost. There was a problem that the parts would shift.

This point also applies to the illumination optical system.

Therefore, even if there are individual differences in conditions such as the age of the examinee, the examinee's familiarity with the examination, and the structure of the fundus,
In order to make it possible to adjust the depth of field so as to reduce the variations in examination due to age and conditions, a beam diameter adjustment means is provided that allows the pupil diameter of at least one of the illumination optical system and the light receiving optical system to be variable. The object of the present invention is to provide an optical system for a laser scanning fundus camera.

(Means for Solving the Problems) In order to achieve this object, the optical system of the laser scanning fundus camera of the present invention includes an illumination optical system that scans and irradiates the fundus with laser light from a light source using a light scanning device; In the optical system of a laser scanning fundus camera, the optical system includes a light-receiving optical system that guides reflected light from the fundus to a light-receiving section via a light scanning device, wherein the optical system is provided with a beam diameter adjusting means for adjusting the beam diameter of the laser beam. ing.

Further, in the optical system of the laser scanning fundus camera, at least the light receiving optical system is provided with a beam diameter adjusting means for adjusting the beam diameter of the laser beam reflected from the fundus.

(Example) Embodiments of the present invention will be described below based on the drawings.

1 to 3 show a first embodiment of the present invention.

The optical system of the fundus camera shown in FIGS. 1 and 2 uses a laser beam to be inspected [111! Fundus E of H, projected upwards.

It has an illumination optical system for scanning and illuminating the fundus E, and a light receiving optical system that guides reflected light from the fundus E to a light receiving section.

The illumination optical system includes a laser oscillator 1. Lens 2. Beam splitter 3, polygon mirror 4 as a horizontal scanning member
．． Variable magnification lens 5, 6. Galvano mirror 7 and relay lens 8 as vertical scanning members. Focus lens 9, reflection mirror 10. The objective lenses 11 are provided in this order.

Optical components from the polygon mirror 4 to the galvano mirror 7 constitute an optical scanning device A. still.

In the figure, P indicates a position conjugate to 1111Ep (Pa) of the eye E to be examined, and R indicates a position conjugate to the fundus E7 (RO) of the eye E to be examined.

The laser light emitted from the laser oscillator l of such an illumination optical system passes through the lens 2. After passing through beam splitter 3,
The light enters the polygon mirror 4. This polygon mirror 4 rotates at high speed and horizontally scans the incident laser light. This scanned laser beam is transmitted through the variable magnification lenses 5, 6. Galvano mirror 7, relay lens 8. The light is guided in the order of the focus lens 99 and the reflection mirror 10, and is projected from the objective lens 11 onto the fundus EJ of the eye E to be examined. At this time, the galvanometer mirror 7 is rotated by a predetermined angle for each horizontal scan of the laser beam by the polygon mirror 4, and moves the horizontal scanning position of the laser beam in the vertical direction. Such scanning forms a scanning plane on the fundus E of the eye E to be examined.

The light receiving optical system includes an optical system from the beam splitter 3 to the objective lens 11, a beam expander 12 as a beam diameter adjusting means, a condenser lens 13, and a pinhole plate 1.
4. A photodiode 15 is provided as a light receiving section. The reflected light beam reflected by the fundus E is then transmitted to the objective lens 112, the reflecting mirror 10. Focus lens 9. Relay lens 8. Galvano mirror 7, variable magnification lens 6.5. The beam is guided through the polygon mirror 4, enters the beam splitter 3, and is reflected by the beam splitter 3 toward the beam expander 12. After the diameter of this reflected light beam is changed and adjusted by the beam expander 12, it is passed through the pinhole 14a of the pinhole plate 14 by the condenser lens 13.
The light is focused onto the photodiode 15.

At this time, the pupil diameter of the light receiving optical system for receiving the reflected light beam is defined by the effective diameter of the beam expander 12 if there is no vignetting in the scanning device A or the lens. Therefore, if you prepare several beam expanders 12 with different magnification ratios, by converting them,
It is possible to convert the pupil diameter.

Here, the pinhole plate 1 just before the photodiode 15
When the pinhole 14a of No. 4 is geometrically projected onto the fundus E through the light-receiving optical system, the projection magnification is the magnification at which this pinhole 14a is projected onto the fundus E by diffraction of the light-receiving optical system. The resolving power changes as follows by adjusting the beam expander 12.

That is, when the pupil diameter of the light-receiving optical system is increased by the beam expander 12, the diameter of the pinhole plate 14 immediately in front of the photodiode 15 decreases the projection magnification onto the fundus E, improving resolution, but the depth of field decreases. It becomes shallow. Conversely, if the beam expander 12 is used to reduce the diameter, the projection magnification increases and the resolution decreases, but the depth of field increases.

Therefore, the examiner can utilize this property to select the pupil diameter by the examinee or by the observation magnification to observe the examinee's eye E in the easiest way for observation. Further, since the received light i changes due to the variable pupil diameter, it is preferable to adjust the amount of illumination light in order to correct this.

Incidentally, FIG. 3 schematically shows the optical system shown in FIGS. 1 and 2. The optical scanning device 1A shown in FIG. Has parts. Further, in FIG. 3, illustration of the optical components from the above-mentioned relay lens 8 to the objective lens 11 is omitted.

In the embodiment described above, an example was shown in which the beam expander 12 was provided as a beam diameter adjusting means, but the beam expander 12 is not necessarily limited to this.For example, as shown in FIG. A stepped aperture plate 16 having different aperture holes 16a arranged in the circumferential direction may be disposed between the beam splitter 3 and the lens 13, and this aperture plate 16 may be used as a beam diameter adjusting means.

5 to 8 show a fundus camera having a configuration in which one optical scanning device A is disposed in the common optical path of the illumination optical system and the light receiving optical system, as in the first embodiment, as a beam diameter adjusting means. An example of the arrangement of the beam expander 12 is shown. It should be noted that illustration of the optical components from the relay lens 8 to the objective lens 11 described above is also omitted in these embodiments.

FIG. 5 shows an example in which the beam expander 12 between the beam splitter 3 and the lens 14 is omitted, and the beam expander 12' is arranged between the beam splitter 3 and the optical scanning device A. be. In this embodiment, both the spot diameter of the laser beam projected onto the fundus E from the laser oscillator 1 and the beam diameter of the reflected light from the fundus E can be adjusted by one beam expander 12.

Figure 6 shows an example in which beam expanders 12 and 12' are provided between beam splitter 3 and lens 13 and between beam splitter 3 and lens 2, respectively. For example, the spot diameter of the laser beam projected from the laser oscillator 1 onto the fundus E, and the fundus E,
The luminous flux diameter of the reflected light can be adjusted separately.

Figure 7 shows the beam splitter 3 in the configuration of Figure 5.
, lens 13. Pinhole plate 14. Photodiode 1
5 is arranged between the optical scanning device A and the eye E to be examined. In this case, the reflecting mirror 1 shown in FIG.
0 may be replaced with beam splitter 3.

Figure 8 shows the beam splitter 3 and lens 13 in Figure 6.
This shows an example in which the beam expander 12 between the two is omitted.

9 to 11, the beam splitter 3 is arranged between the relay lens 8 shown in FIG. and the lens 13, there are optical scanning devices A,
This figure shows an example in which the arrangement of the beam expander 12 is changed in a fundus camera equipped with a retinal camera. It should be noted that illustration of the optical components from the relay lens 8 to the objective lens 11 described above is also omitted in these embodiments. Also,
In these cases, the reflecting mirror 10 shown in FIG. 1 may be replaced with a beam splitter 3.

FIG. 9 shows an example in which the beam expander 12' is arranged between the optical scanning device A and the lens 2, and the beam expander 12 is arranged between the optical scanning device KA' and the lens 13. be.

FIG. 10 shows an example in which the beam expander 12' of FIG. 9 is omitted.

FIG. 11 shows an example in which the beam expander 12 in FIG. 9 is omitted.

(Effects of the Invention) As described above, the present invention includes an illumination optical system that scans and irradiates the fundus with laser light from a light source using a light scanning device, and a light scanning device that transmits reflected light from the fundus to a light receiving unit. In the optical system of the laser scanning fundus camera, which includes a light receiving optical system that guides light through Alternatively, even if there are individual differences in conditions such as the test subject's familiarity with the test and the structure of the fundus, by adjusting the diameter of the optical system with the beam diameter adjustment means, variations in the test due to age and conditions can be reduced. Depth of field can be adjusted.

Further, when at least the light receiving optical system is provided with a light flux diameter adjusting means for adjusting the light flux diameter of the reflected light from the fundus of the laser beam, the diameter of the light receiving optical system may be adjusted depending on the age of the subject or the diameter of the light receiving optical system. Since it can be adjusted according to conditions such as the person's familiarity with examinations and the structure of the fundus, the depth of field can be easily adjusted as appropriate to adjust the resolution and to easily adjust the focus on the entire fundus of the subject's eye, which has irregularities. I can do it.

[Brief explanation of the drawing]

FIG. 1 is a plan layout diagram showing an optical system of a laser scanning fundus camera according to the present invention. FIG. 2 is a side view of a part of the optical system shown in FIG. 1. FIG. 3 is a schematic explanatory diagram of the optical system shown in FIGS. 1 and 2. FIG. FIG. 4 is an explanatory diagram showing another example of the beam diameter adjusting means shown in FIG. 1. 5 to 11 are schematic explanatory diagrams showing other examples of the optical system of the laser scan fundus camera according to the present invention. 1... Laser oscillator (light source) l... Lens 3... Beam splitter 8... Relay lens 9... Focus lens IO... Reflection mirror 11... Objective lens 12.12'. ...Beam expander (luminous flux diameter adjusting means) 13...Lens 14...Pinhole plate 15...Photodiode (light receiving section) 16...Aperture plate (luminous flux diameter adjusting means) A, A'...・Optical scanning device E...Eye to be examined E,...fundus Fig. 3 Fig. 4 Fig. 5 Fig. 6 Fig. 8

Claims (2)

[Claims] (1) Laser scan comprising an illumination optical system that scans and irradiates the fundus with laser light from a light source using a light scanning device, and a light receiving optical system that guides the reflected light from the fundus to a light receiving section via the light scanning device. An optical system for a laser scanning fundus camera, characterized in that the optical system is provided with a beam diameter adjusting means for adjusting a beam diameter of the laser beam. (2) The optical system of a laser scanning fundus camera according to claim 1, wherein at least the light receiving optical system is provided with a beam diameter adjusting means for adjusting the beam diameter of the laser beam reflected from the fundus.