JPH0554332B2 - - Google Patents

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention projects a measurement target image onto the fundus of the eye and photoelectrically detects the focused state of this measurement target image to measure the ocular refractive power of the eye to be examined. The present invention relates to an objective eye refractive power measuring device for measurement.

(Prior art) Conventionally, an objective refractive power measuring device divides a light beam from a measurement target into two light beams and projects them onto the fundus of the examinee's eye, and when the projected measurement target image is not in focus, An apparatus is known which is configured to form a measurement target image split in a predetermined direction, and which measures the eye refractive power by photoelectrically detecting the amount of the split.

Further, as another conventional apparatus, there is also known an apparatus configured to measure the refractive power of the eye by detecting the amount of defocusing of the measurement target image on the fundus of the eye to be examined using appropriate means.

(Problems with the prior art) In this type of device, in order to improve photoelectric detection accuracy, the magnification of the light receiving system for projecting the measurement target image on the photoelectric conversion section is basically increased. There is a need to.

However, simply increasing the magnification has the drawback that the brightness per unit area of the measurement target image on the photoconductor converter decreases and the S/N ratio of the detection signal deteriorates.

In order to correct this drawback, it is necessary to increase the brightness of the measurement target image on the fundus by using a high-intensity light source as the light source for the measurement target image. However, replacing the light source with a high-intensity light source is not only a cost compensation due to a structural change, but also has the problem that the amount of light incident on the eye to be examined increases, which may have an adverse effect on the eye to be examined.

(Means for Solving the Problems) The present invention has been made for the purpose of solving the above problems, and includes a projection system for projecting a measurement target image onto the fundus of the eye to be examined, and a photoelectric system for projecting this measurement target image. and a light receiving system formed on the conversion section, and an anamorphic optical system is arranged in the optical path of at least one of these systems.

This makes it possible to improve measurement accuracy by improving the S/N ratio without changing the amount of light projected onto the eye to be examined.

(Function) A pair of parallel slit-shaped target images projected onto the fundus of the subject's eye are compressed only in the longitudinal direction of the slit through the intervention of the anamorphic optical system, and are formed on the image pickup tube, which is the photoelectric conversion unit. This makes it possible to increase the brightness of the measurement target image while maintaining the light source brightness, thereby improving the S/N ratio.

(Example) Hereinafter, an example of the objective eye refractive power measuring device according to the present invention will be described based on the drawings.

In FIG. 1, 1 is a target image projection system, and this target image projection system 1 has a function of projecting a measurement target image formed by irradiating an index plate for measurement with invisible light onto the fundus of an eye 2 to be examined. 3 is a light-receiving optical system, and this light-receiving optical system 3
has a function of forming a reflected image of the measurement target image projected by the measurement target image projection system 1 on the fundus of the eye to be examined 2 on the imaging surface 4a of the imaging device 4, and 5 is a gaze target projection system. This gaze target projection system 5 has a function of projecting a gaze target onto the eye 2 to be examined when performing objective measurement.

The target image projection system 1 includes a light source, for example an LED.
(Light emitting diode) 6, this light source 6
emits infrared light, which is invisible light, in order to prevent miosis of the eye 2 to be examined. The infrared light from this light source 6 is irradiated onto a measurement index plate 8 through a condenser lens 7, and the measurement index plate 8 is movable in the optical axis x direction. As shown in FIG. 2, this measurement index plate 8 is in contact with a thin plate 8a having four slits (two sets of parallel upper and lower slits with the same interval l), and the light passing through the slits is in contact with the thin plate 8a. It is composed of four deflection prisms 8b to 8e that deflect the light beam in a direction perpendicular to the longitudinal direction. Two sets of parallel measurement target lights made of invisible light irradiated onto the measurement index plate 8 pass through the reflection prism 9 via the collimator lens 38.

The measurement target light that has passed through the reflection prism 9 forms a measurement target image once through the anamorphic optical system 39 and the relay lens 11. This anamorphic optical system 39
As shown in the figure, a positive cylindrical lens 39 ₁ with a focal length f ₁ and a positive cylindrical lens 39 ₂ with a focal length f ₂ are arranged with an interval of (f ₁ + f ₂ ), and each cylindrical lens 39 The cylinder axes of ₁ and 39 ₂ are set parallel to the longitudinal direction of the slit of the measurement index plate 8. With this configuration, in a plane perpendicular to the longitudinal direction of the slit, the measurement target light from the measurement index plate 8 placed at point P ₁ is converted into a parallel beam by the collimator lens 38, and is directly transmitted to point P ₂ by the relay lens 11. The light is focused.

On the other hand, in a plane parallel to the longitudinal direction of the slit, the measurement target light that has been made into a parallel beam by the collimator lens 38 is once condensed by the cylindrical lens 39 ₁ and then again made into a parallel beam by the cylindrical lens 39 ₂ . , the light is focused on point P ₂ by the relay lens 11. Therefore, the magnification of the measurement target image formed at point P ₂ in the longitudinal direction of the slit is f ₁ /f ₂ (<1) times the magnification in the direction perpendicular to the longitudinal direction of the slit _. A measurement target image compressed only in the longitudinal direction of the slit is formed.

FIG. 4 shows an example of the configuration of another anamorphic optical system 39', and the focal length -f ₁ '(f ₁ '>
A negative cylindrical lens 39 ₁ ′ with a focal length of 0) and a positive cylindrical lens 39 ₂ ′ with a focal length of f ₂ ′ are arranged with an interval of (f ₂ ′−f ₁ ′). In this case as well, point P ₂
A measurement target image compressed only in the longitudinal direction of the slit is formed.

Furthermore, the measurement target light that has passed through the anamorphic optical system 39 is transferred to a reflecting prism 10, a relay lens 11, a reflecting prism 12, a semicircular diaphragm 13 having two semicircular openings, and a slit-shaped hole 14a.
a slit prism 14, an image rotator 15, an objective lens 16, and a beam splitter 1.
7 and are projected onto the fundus of the eye 2 through the pupil of the eye 2 to be examined. Note that the half-moon diaphragm 13 is arranged at a position conjugate with the pupil of the eye 2 to be examined. The image rotator 15 is arranged rotatably around the optical axis y in order to rotate the measurement target image projected onto the fundus of the eye 2 to be examined in a predetermined meridian direction of the eye 2 to be examined, and the rotation angle of the image rotator 15 is The measurement target image projected onto the fundus of the eye to be examined is rotated by θ degrees with respect to θ/2. The beam splitter 17 has a characteristic of transmitting infrared light and reflecting visible light.

In the light receiving optical system 3, the measurement target image reflected on the fundus of the eye 2 to be examined is transmitted through the beam splitter 17, the objective lens 16, the image rotator 15, and the slit-shaped hole 1 of the slit prism 14.
4a, aperture stop 1 having a circular opening 18a;
8, relay lens 19, reflective prism 20, 2
1, sunspot plate 22, moving lens 23, reflective mirror 2
4. An image is formed on the imaging surface 4a via the imaging lens 25. Note that the aperture stop 18 is arranged at a position conjugate with the pupil of the eye 2 to be examined, and the aperture 18a allows only light that passes through the pupil of the eye 2 to be examined to pass through. The black spot plate 22 removes light reflected by the objective lens 16 that is harmful to the measurement. The movable lens 23 is movable along the optical axis Z together with the black spot plate 22 and the measurement index plate 8. The measurement index plate 8 and the imaging surface 4a are always maintained in a conjugate positional relationship.

Since the measurement target image formed on the imaging surface 4a passes through the image rotator 15 again, it is rotated by the same angle in the opposite direction to the measurement target image projected onto the fundus of the eye 2 to be examined. Therefore, this imaging surface 4
Regardless of the rotation angle of the image rotator 15, the measurement target image formed at point a has the same orientation of the slit of the measurement target image formed by the measurement index plate 8, and is always held in a constant direction. On the other hand, the imaging device 4 as a photoelectric conversion unit has an imaging surface 4
A video signal is output in accordance with the measurement target image formed at a. This video signal causes the display device 26 to
displays a slit measurement target image (an image reflected from the fundus of the eye 2 to be examined) formed on the imaging surface 4a.

In these target image projection system 1 and light receiving optical system 3, when the measurement index plate 8 moves and the measurement target image is focused on the fundus of the eye 2 to be examined, the movement of the movable lens 23 changes the focused state to the imaging surface 4a. is imaged.

In the gaze target projection system 5 , light from a light source 27 that emits visible light is irradiated onto a gaze target plate 30 through a color correction filter 28 and a condenser lens 29 . A gaze target is formed on the gaze target board 30. A gaze target image formed by the gaze target plate 30 by irradiation of light from the light source 27 is formed by a collimator lens 31, a moving lens 32, and a reflecting mirror 3.
3, 34, relay lens 35, reflective mirror 36,
The light is projected onto the fundus of the eye 2 to be examined via the objective lens 37, reflection mirror 38, and beam splitter 17.
Note that the movable lens 32 is movable along the optical axis, and in the case of objective measurement, is set at a position that causes the subject to see fog according to the refractive power of the subject's eye 2.
Accommodative power of the eye 2 to be examined is removed to enable accurate objective measurement.

With this configuration, the upper and lower 2 areas of the measurement target image are determined based on the video signal from the imaging device 4.
The measurement index plate 8, the black dot plate 22, and the moving lens 23 are moved until the slit intervals Q ₁ and Q ₂ of the pair become equal.
are moved along the optical axes X and Y, respectively. Then, the refractive power of the eye 2 to be examined is measured from the amount of movement of the measurement index plate 8.

In this case, when comparing the state before (see Fig. 5) and the state after (see Fig. 6) the measurement target image passes through the anamorphic optical system 39, the amount of splitting (intervals Q ₁ , Q ₂ ) changes. However, the length in the longitudinal direction is shorter than the former (that is, n1>n2).

In the above embodiment, the anamorphic optical system 39 is arranged in the target projection system 1, but the measurement target image is ultimately projected onto the eye to be examined and formed on the imaging device 4. The in-focus state is detected based on the video signal of the imaging device 4, and the anamorphic optical system 39 may be arranged in the light receiving optical system 3, for example, between the reflecting mirror 24 and the imaging lens 25. In this case, the brightness of the measurement target image on the imaging device 4 can be increased without changing the brightness of the measurement target image projected onto the fundus of the eye to be examined.

(Effects of the Invention) As described above, according to the present invention, since the anamorphic optical system is disposed in at least one of the measurement target image projection system and the light receiving system,
For example, when the measurement target is formed by a pair of upper and lower slits, the measurement target image on the fundus of the eye to be examined is compressed in the longitudinal direction of the slit, increasing the brightness of the image without considering the brightness of the light source. Moreover, since the direction perpendicular to the longitudinal direction of the slit has no effect on the magnification of the image, it is possible to easily improve the S/N ratio and improve measurement accuracy by adding a simple configuration. I can do it.

[Brief explanation of drawings]

FIG. 1 is an optical system layout diagram showing an embodiment of the objective eye refractive power measuring device according to the present invention, FIG. 2 is a perspective view showing an enlarged index plate shown in FIG. 1, and FIGS. Fig. 4 is a schematic perspective view of the anamorphic optical system shown in Fig. 1, Fig. 5 is a plan view illustrating the measurement target image before passing through the anamorphic optical system, and Fig. 6 is a plan view illustrating the measurement target image after passing through the anamorphic optical system. FIG. 1... Measurement target image projection system, 2... Eye to be examined, 3
... Light receiving optical system (light receiving system), 4... Imaging device (photoelectric conversion section), 39, 39'... Anamorphic optical system.

Claims (1)

[Scope of Claims] 1. A projection system for projecting a measurement target image onto the fundus of the eye to be examined; and a light receiving system for receiving reflected light from the measurement target image and forming the measurement target image on a photoelectric conversion unit. An objective eye refractive power measuring apparatus comprising: an anamorphic optical system disposed in the optical path of at least one of the projection system and the light receiving system. 2. The measurement target image is a vertically elongated image formed in the shape of a slit, and the anamorphic optical system is characterized in that the measurement target image is compressed in the longitudinal direction and formed on the photoelectric conversion section. An objective eye refractive power measuring device according to claim 1. 3. The objective eye refractive power measuring device according to claim 2, wherein the anamorphic optical system includes a cylindrical lens.