JPH0118369B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a reflective lens eccentricity measuring instrument that can measure the eccentricity of each spherical surface of a lens system.

One of the conventionally known reflective lens eccentricity measuring instruments is one that uses a lens rotation method. In this method, a virtual image of a chart is generated at the center of curvature of the surface to be measured using a collimator lens, and the lens to be measured is rotated while observing this virtual image using an observation system. At this time, if there is eccentricity on the spherical surface of the lens to be tested, the chart image will draw a circle, and the amount of eccentricity can be measured by measuring the diameter of this circle.

However, according to the above-mentioned lens rotation method, if the lens to be tested includes a movable part in the lens system, such as a zoom lens, the part moves due to rotation, so the lens system including the movable part moves. Measurement was impossible.

Therefore, in order to eliminate the above-mentioned drawbacks, measuring instruments such as those shown in FIGS. 1 and 2 are sometimes used.

The example shown in FIG. 1 uses an image rotator, and includes a light source 1, a condenser lens 2, a chart 3, a semi-transparent mirror 4, a collimator lens 5, and an image rotator 6 in this order. A screen 7 and an eyepiece lens 8 are arranged along the reflective surface. The image rotator 6 includes two reflecting mirrors 61 arranged in a V-shape,
62. It consists of a reflecting mirror 63 facing these reflecting mirrors, and two sets of optical wedges 64 and 65, so that the light beam incident from one side along the rotational axis exits from the other accurately along the rotational axis. . A test lens system 9 is arranged in front of the image rotator 6.
To measure with this measuring device, the image of Chart 3
_a1 is imaged at the apparent center of curvature of the lens surface to be tested, and in this state, the image rotator 6 is rotated around its rotation axis. At this time, if there is eccentricity on the lens surface to be tested, the chart image _a2 on the screen 7 will be shifted from the center by an amount commensurate with the amount of eccentricity, and the image _a2 will draw a circle whose radius is this amount of shift.
Therefore, by measuring the diameter of this circle, the amount of eccentricity of the spherical surface of the lens to be tested can be determined.

However, according to this type of measuring instrument, if the rotation accuracy of the image rotator is poor, the measurement accuracy will directly deteriorate. Moreover, the rotational accuracy of current image rotators is around 5μ, which is not necessarily accurate.

The example in FIG. 2 is a test lens non-rotating method using a corner cube, and includes a light source 11, a condenser lens 12, a chart 13, a semi-transparent mirror 14, and a semi-transparent mirror 1.
5 are arranged in this order, and one entrance/exit surface of the corner cube 16 is arranged on the transmission optical path of the semi-transparent mirror 15. A reflecting mirror 17 is disposed at a position facing the other entrance/exit surface of the corner cube 16 . A collimator lens 18 is disposed beside the reflective surface of the semi-transparent mirror 15, and a lens system 21 to be examined is disposed beyond the collimator lens 18. Further, a screen 19 and an eyepiece lens 20 are arranged beside the reflective surface of the semi-transparent mirror 14. To measure the eccentricity of the spherical lens surface using this measuring device, the position of the corner cube 16 is moved on the reference axis, and the image _a1 of the chart 13 is focused on the apparent center of curvature of the surface to be measured. let This image is again formed on the screen 19 as image _a2 . At this time, the effect of the axis deviation or inclination is canceled by the action of the corner cube 16 and the reflecting mirror 17, and the measurement reference axis is kept constant. Therefore, if the spherical surface of the lens to be tested is decentered, the image on the screen 19 will be
Since a ₂ is offset from the center by an amount commensurate with the above eccentricity, the eccentricity can be measured from the amount of this shift.

However, with this type of measuring instrument, reflection by the semi-transparent mirror and transmission by the semi-transparent mirror occur a total of six times, and the amount of light reflected from the spherical surface of the lens to be tested is extremely small, resulting in an extremely small amount of light.
The disadvantage is that it is difficult to observe the optical image.

Furthermore, in both the case of FIG. 1 and the case of FIG. 2, measurement is impossible if the apparent center of curvature of the spherical surface of the lens to be tested is located at a position that cannot be covered by the collimator lens. Furthermore, if even one of the spherical surfaces of the lens system to be tested cannot be measured, it becomes impossible to analyze the eccentricity of the lens spherical surface on the rear surface. Furthermore, there is a drawback that the closer the apparent center of curvature of the spherical surface of the lens to be tested approaches the collimator lens, the more the measurement accuracy deteriorates.

An object of the present invention is to provide a reflective lens eccentricity measuring device that has good measurement accuracy, can measure any type of lens system or lens with any radius of curvature, and has less decrease in light amount. It is in.

The present invention will be explained below with reference to the embodiments shown in FIGS. 3 to 5.

In FIG. 3, a light source 31, a condenser lens 32, a chart 33, a semi-transparent mirror 34, a first collimator lens 35, a second collimator lens 36,
The semi-transparent mirror 37 and the auxiliary lens 38 are arranged in this order on a common axis. A screen 39 and an eyepiece lens 40 are arranged beside the reflective surface of the semi-transparent mirror 34. On the other side of the reflective surface of the semi-transparent mirror 37,
One entrance/exit surface of the corner cube 41 is located, and a concave mirror 42 is fixed to an appropriate immovable part facing the other entrance/exit surface of the corner cube 41. The second collimator lens 36 and the corner cube 41 can move in conjunction with each other in the optical axis direction, and the interlocking relationship is such that if the amount of movement of the collimator lens 36 is 1, then the corner cube 41 It is assumed that the relationship is such that the amount of movement is 1/2. Further, the collimator lens 36 can be moved vertically and horizontally in directions perpendicular to the optical axis by an attachment stage 36a.
The lens system 43 to be tested is attached to a measuring table 44 behind the auxiliary lens 38. The auxiliary lens 38 is movable in the optical axis direction by a moving device 45, and is also removable and replaceable as necessary.

In this embodiment, a light source 31 illuminates a chart 33 through a condenser lens 32. The transmitted light of the chart 33 passes through a semi-transparent mirror 34, is made into a parallel light beam by a first collimator lens 35, and is further focused by a second collimator lens 36. A part of this focused light is reflected by a semi-transparent mirror 37 and then focused on _one point a. On the other hand, the position of the corner cube 41 is adjusted in advance so that the center of curvature of the concave mirror 42 coincides with point _a , and therefore the image focused on point _a by the collimator lens 36 is It passes through the corner cube 41, is reflected by the concave mirror 42, passes through the corner cube 41 again, and then focuses on point _a again. The image of this point _a is formed by a semi-transparent mirror 37, two collimator lenses 36 and 35,
An image is formed at point _a2 on the screen 39 through the semi-transparent mirror 34, and can be observed through the eyepiece lens 40.

In addition, a part of the light focused by the second collimator lens 36 that has passed through the semi-transparent mirror 37 tries to travel toward point b ₂ which is conjugate with point _a , but on the way, it passes through the auxiliary lens 38. , is refracted when passing through a part of the lens system 43 to be measured, is reflected by the spherical surface of the lens to be measured, and forms a virtual image at _one point b. The light reflected by the spherical surface of the lens to be measured passes through the front lens of the lens system 43 to be measured, the auxiliary lens 38, the semi-transparent mirror 37, the two collimator lenses 36 and 35, and the semi-transparent mirror 34 to a point b ₃ on the screen 39. This image can be observed through the eyepiece lens 40.

Therefore, in order to measure the amount of eccentricity of each spherical surface of the lens system using such a measuring device, it is performed as follows. That is, the second collimator lens 36 is moved in the optical axis direction so that the imaging point _b1 generated by the reflected light on the spherical surface of the lens to be measured coincides with the center of curvature of the spherical surface of the lens to be measured. Since the corner cube 41 also moves in a fixed relationship in conjunction with the movement of the second collimator lens 36, the center of curvature position a ₁ of the concave mirror 42 from the collimator lens 36
The distance from the collimator lens 36 to _point b, which is the apparent center of curvature of the spherical surface to be measured, is always equal.

Next, when the second collimator lens 36 is moved vertically and horizontally in a direction perpendicular to the optical axis, the screen 39
Since the image points a ₂ and b ₂ above move, the image point
The collimator lens 36 is moved vertically and horizontally so that a ₂ coincides with the center of the optical axis, in other words, so that the imaging point a ₁ coincides with the center of the optical axis. By doing this, the optical axes of the collimator lens 36 are aligned. The field of view of the eyepiece 40 at this time is as shown in FIG.
Since the position _of light image b ₃ due to reflection on the spherical surface to be measured is shifted relative to light image _{a 2 formed} by the optical axis alignment system consisting of The amount of eccentricity of the measuring sphere can be determined.

In this manner, in the present invention, the amount of eccentricity is measured after aligning the optical axis of the collimator lens every time each lens surface is measured. The amount of eccentricity on the rear surface of the lens system 43 to be tested is determined by calculating the amount of eccentricity on the front surface already measured from the measured value. In addition, by moving the auxiliary lens 38 in the optical axis direction according to the position of the center of curvature of the spherical surface to be measured, or replacing it as appropriate, the apparent center of curvature of any lens spherical surface can be positioned at a position where it can be covered by the collimator lens. Therefore, it is possible to measure all kinds of lenses.

Incidentally, the reflectance of the lens surface to be measured is less than 1% recently because it is coated.
Further, the reflectance of the concave mirror 42 is about 90%. The transmittance of the semi-transparent mirror 37 is preferably 90% or more in order to ensure a sufficient amount of light for the measurement system. Therefore, if the transmittance of the semi-transparent mirror 37 is 96% and the reflectance is 4%, the light amount of the measurement system is 1 (%) x 0.96 = 0.96 (%) The light amount of the alignment system is 90 (%) x 0.04 = 3.6 (%). Therefore, there is no practical problem in using a transparent glass plate without coating in place of the semi-transparent mirror 37. However, as long as even a transparent glass plate reflects a small amount of light, there is no problem in considering it to be included in the scope of the semi-transparent mirror of the present invention.

Note that the screen 39 in the embodiment of FIG.
Instead, a light receiving element 46 may be placed as shown in FIG. 5, and this signal may be reproduced by the ITV 47.

According to the present invention, there are the following effects. first,
The alignment accuracy of the collimator lens is extremely improved, and the auxiliary lens allows the apparent center of curvature of the spherical surface of the lens to be measured to be placed far from the position of the collimator lens, improving the accuracy of eccentricity measurement. be able to. Furthermore, even if the center of curvature of the spherical surface of the lens to be measured is at a position close to infinity, the auxiliary lens brings the apparent center of curvature of the spherical surface of the lens to be measured to a position that can be encompassed by the collimator lens. Therefore, any type of lens can be measured. Furthermore, since the number of reflections by the semi-transparent mirror and the number of transmissions through the semi-transparent mirror are reduced, a sufficient amount of light is ensured and measurement is easy.

In addition, a moire fringe is placed at the position of the chart in the above embodiment, and the reflected light from the measurement optical system and the reflected light from the axis alignment optical system are caused to interfere with each other, and this interference fringe is observed on the screen. You can.

[Brief explanation of drawings]

FIG. 1 is an optical layout diagram showing an example of a conventional lens eccentricity measuring device, FIG. 2 is an optical layout diagram showing another example of a conventional lens eccentricity measuring device, and FIG. 3 is an optical layout diagram showing an example of the present invention. FIG. 4 is a front view showing an example of the observation field according to the above embodiment, and FIG. 5 is a front view showing another example of the observation system that can be used in the present invention. 31...Light source, 32...Condenser lens, 3
3...Chart, 35, 36...Collimator lens, 37...Semi-transparent mirror, 38...Auxiliary lens, 3
9...screen, 40...eyepiece, 41...
... Corner cube, 42 ... Spherical reflector, 43
...Test lens system.

Claims (1)

[Scope of Claims] 1. A collimator system having a light source, a chart, and a collimator lens, and a semi-transparent mirror installed obliquely in the collimator system, so that the reflected light from the spherical surface of the test lens can be observed. an observation system, a semi-transparent mirror for bringing the chart image formation position by the collimator lens to the side, and forming a chart image again at the chart imaging position; and a corner cube for introducing this image into the observation system via a collimator lens, and the collimator lens and the corner cube have a certain relationship and are interlocked in the optical axis direction. Measuring instrument. 2. The collimator lens is provided so as to be movable vertically and horizontally in a direction perpendicular to the optical axis.
Reflection type lens eccentricity measuring device as described in section. 3 Between the collimator lens and the test lens,
A reflective lens eccentricity measuring instrument according to claim 1, wherein an auxiliary lens is inserted. 4. The reflective lens eccentricity measuring device according to claim 3, wherein the auxiliary lens is replaceable.