KR20050099475A - Lens meter - Google Patents

Abstract

The present invention includes an optical system for injecting parallel light beams from a concave surface side of a lens to be examined to obtain a projected image of the lens to be examined, and an arithmetic circuit connected to the optical system, wherein the optical system includes a measuring light source portion 10 having a plurality of light sources. ), A collimator lens 11 positioned in front of the measurement light source unit 10 and condensing parallel light beams incident from the measurement light source unit 10, and an image of a measurement light path in front of the collimator lens 11. An opening target plate 12 positioned at the center opening and positioned around the central opening and configured to be movable in the optical axis direction, and positioned in front of the opening target plate 12, on the optical axis An imaging lens 14 positioned on the optical axis in front of the lens to be positioned such that the projection lens 13 is positioned in front of the projection lens 13 and is positioned at a predetermined position between the projection lens 13 and the projection lens 13. ), And the opening target plate optical axis Direction, the light-receiving sensor 15 'disposed to be in an airspace position with the opening of the opening target plate 12, and moving the opening target plate in the optical axis direction to exit from the light source. The light source is focused on the opening of the opening target plate 12 through the collimator lens 11, and the projection lens 13 moves the light beam passing through the opening target plate 12 to the inspection lens side as parallel light flux. And arithmetic circuit 30 which calculates the apertured image formed on the light receiving sensor to obtain optical characteristics of the lens under test, and turns on the plurality of light sources to bring the apertured image formed on the light receiving sensor to a predetermined position. The aperture target plate 12 is moved in the optical axis direction so as to gather so that the optical characteristic value at the eccentric position of the lens to be examined can be obtained by the difference of the optical characteristic value at each moving position. The meter is provided.

Description

Lens meter {LENS METER}

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a lens meter. More specifically, the optical characteristic of a lens is determined by displacement of the measurement beam after transmission of the lens while the parallel beam as the measurement beam is incident from the convex surface side of the lens to be examined. When the optical characteristic at the eccentric position of the lens to be measured is measured by using a measuring principle type, the target plate is projected so that parallel beams are emitted from the convex surface side while the measurement light beam is incident on the lens to be examined from the concave side of the lens. When the optical characteristic at the eccentric position of the lens to be measured is measured by using a measuring principle type that obtains the optical characteristic of the lens to be measured by the amount of movement of the target plate when it is moved along the measurement optical axis, the optical characteristic is not mismatched. It relates to a lens meter that can be.

As is well known, conventionally, two types of principle are known for lens meters for measuring the frequency of spectacle lenses. 1 shows an optical system of a so-called Infinit on Axis (IOA) type lens meter, in which 1 is a measurement light source consisting of one LED, 2 is a collimator lens, 3 is a pattern plate, and 4 is light receiving. An area sensor as a sensor, 5 is a lens support, 6 is a measurement optical path, TL is a test lens, and O1 is a measurement optical axis. The measurement light source 1 is provided on the optical axis O1 of the collimator lens 2 and at the front focal position thereof.

The collimator lens 2 converts the measurement light beam from the measurement light source 1 into the parallel light beam P1, and the parallel light beam P1 is sent to the test lens TL along the optical axis O1, and the test lens It enters into the to-be-tested lens TL from the convex surface side of TL.

The pattern plate 3 is provided on the rear side (concave side) of the lens TL, and the pattern plate 3 is formed with a plurality of circular openings 3a as shown in FIG. 2, for example. The interval between the openings 3a is called 2h. In addition, the structure in which a microlens is attached to each opening can also be employ | adopted, The shape of an opening is not restrict | limited to circular, either a slit-shaped thing and a rectangular shape can be employ | adopted.

When the lens TL is not set in the measurement light path 6, the parallel light beam P1 emitted from the collimator lens 2 is sent to the pattern plate 3 as it is, and the parallel light beam P1. The silver passes through the opening 3a of the pattern plate 3 to the area sensor 4 without being refracted. Therefore, as shown in FIG. 3, the interval 2h between the opening 2a of the opening projection image 3a 'of the pattern plate 3 projected onto the area sensor 4 and the opening 3a of the pattern plate 3 is shown. ) Is the same.

On the other hand, when the test lens TL, which is positive, is set in the measurement light path 6, the parallel light beam P1 is refracted by the test lens TL to become convergent light. The interval 2H of the aperture projection image 3a 'is reduced as shown in FIG. If the negative lens F is set to the measurement light path 6, the parallel light beam P1 is refracted by the lens TL to be divergent light, and the aperture projection image 3a is used. ') Widen the gap.

Since the distance Δ from the back vertex position X1 of the lens TL to the pattern plate 3 and the distance d from the pattern plate 3 to the area sensor 4 are already known, the area sensor ( If x is the distance from 4) to the back focus position X1 'of the lens TL,

Δh = h-H

Δh / d = H / x

Because of,

The back focus BF of the lens TL is

It is calculated | required by BF = (d / (DELTA) h) H + (DELTA) + d.

That is, the distance 2H of the aperture projection image 3a 'formed on the area sensor 4 by the spherical frequency S, the circumferential frequency C, and the axial angle A of the optical characteristics of the lens TL. ) Can be calculated and calculated based on this measurement result.

Fig. 5 shows an optical system of an auto lens meter of a type called focal on axis (FOA) used in a manual lens meter and some auto lens meters.

In Fig. 5, reference numeral 10 denotes a measurement light source portion, 11 a collimator lens, 12 a target plate as a pattern plate, 13 a projection lens, 14 an imaging lens, 15 an area sensor, 16 a lens support, and 17 a measurement light path. .

As shown in Fig. 6, the measurement light source section 10 has four measurement light sources (LEDs) 10a to 10d. Each measurement light source 10a-10d is arrange | positioned at the symmetrical position with respect to the measurement optical axis O1. As shown in FIG. 7, the opening 12a is formed in the target plate 12, and the center of the opening 12a coincides with the measurement optical axis O1. The target plate 12 is capable of reciprocating in the optical axis direction from the reference position R1. The shape of the opening 12a is not limited to circular, but may be a slit-shaped or rectangular configuration.

The collimator lens 11 has its front focus f1 coinciding with the arrangement position of the measurement light sources 10a to 10d, and converts the measurement light flux of the measurement light sources 10a to 10d into parallel light flux. The rear focus f1 'of the collimator lens 11 coincides with the reference position R1 of the target plate 12. The projection lens 13 has the front focal position f2 coinciding with the reference position R1, and its rear focal position f2 'coincides with the rear vertex position X1 of the lens TL. The rear vertex position X1 of the measurement light sources 10a to 10d and the test lens TL is conjugate, and the light source image of the measurement light sources 10a to 10d is formed at the rear vertex position X1.

The area sensor 15 is arranged at the rear focusing position f of the imaging lens 14, and the target plate 12 and the area are in a state where the lens TL is not set in the measurement optical path 17. The sensor 15 is airspace when the target plate 12 is at the reference position R1. As shown in FIG. 7, the opening 12a is formed in the center of the target plate 12.

When the lens TL is not set in the measurement light path 17, the measurement light beam passing through the opening 12a of the target plate 12 is projected when the target plate 12 is located at the reference position R1. It becomes parallel light beam P2 by the lens 13, it converges with the imaging lens 14, and it forms an image on the area sensor 15, and shows an aperture projection image on the measurement optical axis of the area sensor 15. 12a) is formed.

On the other hand, when the test lens TL having the positive power is set in the measurement light path 17, the parallel light beam P2 incident from the concave surface side of the test lens TL and passing through the test lens TL is The lens is deflected in the convergence direction by the lens TL, thereby deviating from the conjugate relationship between the target plate 12 and the area sensor 15.

Here, the target plate 12 is moved along the optical axis direction, and as shown in FIG. 8, the target image 12 ′ of the target plate 12 by the projection lens 13 is focused back on the lens TL. The target plate 12 is positioned to coincide with BF.

Then, the target plate 12 and the area sensor 15 are again in air space. Therefore, based on the movement amount from the reference position R1 of the target plate 12, the back focus BF of the lens TL can be obtained by the following equation.

Reference position R1 when the target plate 12 is moved along the measurement optical axis O1 until the focal length of the projection lens 13 is f2 and the target plate 12 becomes conjugate with the area sensor 15. When the movement amount from (the position corresponding to 0 diopter) is Z, the optical characteristic value (frequency) S of the lens TL is

S = Z / f22

Becomes

Similarly, the circumferential frequency C and the axial angle A can be obtained.

Moreover, about the measurement by the auto lens meter of the measuring principle type shown in this FIG. 5, it describes in Unexamined-Japanese-Patent No. 2-216428.

However, as shown in Fig. 1, a lens meter of a type for measuring the frequency of the lens TL by measuring the degree of incidence of the lens TL by injecting the parallel light beam as the measurement light beam from the convex surface side of the lens TL to the lens TL In the lens meter of the type in which the measurement light beam is incident from the concave side of the TL into the test lens TL, and the target plate is moved so that the measurement light beam emitted from the test lens TL becomes a parallel light beam. The same power can be said to be equal to the optical axis of the lens TL in the lens meter of the type shown in FIG. 1 when measuring the frequency of the center portion of the lens TL. When measuring the position X3 eccentric from O2, the parallel light beam P1 incident in parallel along the measurement optical axis O1 is deflected by the lens TL and sent to the area sensor 4. On the focal plane F1 of the lens TL From the axis (O1) to form an image in an eccentric position.

On the other hand, in the lens meter of the type shown in FIG. 5, when measuring the position X3 which is eccentric from the optical axis O2 of the lens TL, the target plate 12 and the area sensor 15 are in the airspace position. When the target plate 12 is positioned so that it is, as shown in FIG. 10, the measurement light beam emitted from the opening image 12 ′ a of the target image 12 ′ of the target plate 12 is the test lens TL. This forms the parallel light beam P2 'inclined with respect to the measurement optical axis O1, and is imaged by the imaging lens 14 at a position eccentric from the center of the area sensor 15 (measurement optical axis O1).

Therefore, the convex side and the concave side of the lens TL shown in FIG. 5 are reversed while the traveling direction of the measurement light beam P2 'shown in FIG. 5 is reversed, and the lens meter of the type shown in FIG. The imaging luminous flux (indicated by the solid line) (P1) and the measurement luminous flux (indicated by the broken line) (P2) by the lens meter of the type shown in FIG. 5 are shown as shown in FIG. The back focus value BF measured by the lens meter of the type shown is different from the back focus value BF 'measured by the lens meter of the type shown in Fig. 5, so that the eccentric position X3 of the lens TL is to be measured. Difference occurs when the frequency S is measured at.

However, it is not preferable that a difference occurs due to different measurement principles of the lens meter.

Thus, in the lens meter shown in Fig. 1, a prism conpenser in which two prisms are combined on the front surface of the lens TL is arranged, and is shown in Fig. 5 at an eccentric position X3 of the lens TL. It is conceivable to obtain the same power as the lens meter shown, but adopting such a configuration not only complicates the configuration and increases the cost, but also the measurement light flux emitted from the lens TL to be measured with the measurement optical axis O1. The prism compensator needs to be rotated until it matches, so the measurement becomes cumbersome and time consuming to measure.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described prior art, and the optical characteristics of a lens are determined by the displacement of the measurement beam after transmission of the lens while the parallel beam as the measurement beam is incident from the convex surface side of the lens. When the optical characteristic at the eccentric position of the lens to be measured is measured by using a measuring principle type, the target plate is projected so that parallel beams are emitted from the convex surface side while the measurement light beam is incident on the lens to be examined from the concave side of the lens. Lens meter which can eliminate the discrepancy of the optical characteristics when measuring the optical characteristics at the eccentric position of the lens by measuring the optical characteristic value of the lens under examination by the amount of movement of the target plate when it is moved along the measurement optical axis The purpose is to provide.

In order to achieve the above object, according to a preferred embodiment of the present invention, there is provided an optical system for injecting parallel light beams from a concave surface side of a lens to obtain a projection image of the lens, and an arithmetic circuit connected to the optical system. The optical system includes a measurement light source unit 10 having a plurality of light sources, a collimator lens 11 positioned at the front of the measurement light source unit 10 and condensing parallel light beams incident from the measurement light source unit 10, An opening target plate 12 positioned on the measurement optical path in front of the collimator lens 11 and having a central opening and a plurality of openings arranged around the collimating lens 11 and configured to be movable in the optical axis direction; The test lens 13 positioned in front of the plate 12 and positioned on the optical axis, and the test lens positioned at a predetermined position between the projection lens 13 and the front of the projection lens 13. In front of the lens An imaging lens 14 disposed on the optical axis, and a light receiving sensor 15 'disposed to be in an airspace position with the opening of the opening target plate 12 by moving the opening target plate in the optical axis direction. By moving the opening target plate in the optical axis direction, the light source emitted from the light source is focused on the opening of the opening target plate 12 through the collimator lens 11, and the projection lens 13 The calculation circuit 30 guides the light beam passing through the opening target plate 12 to the lens side to be parallel with the light beam, and calculates the aperture projection image formed in the light receiving sensor to obtain the optical characteristics of the lens under test. The opening target plate 12 is moved in the optical axis direction so that the opening projection image formed on the light receiving sensor is turned on by turning on a plurality of light sources, and the eccentricity of the lens to be inspected is caused by the difference in optical characteristics at each moving position. In one location A lens meter is provided, characterized in that to obtain an optical characteristic value.

Preferably, the light receiving sensor is provided with a lens meter, characterized in that any one of the area sensor or line sensor.

More preferably, the opening of the target plate is provided with a lens meter, characterized in that a combination of a plurality of slits.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail with reference to drawings.

Fig. 12 shows an optical system of a lens meter of a type in which a measurement light beam is incident from the concave side of the lens TL toward the lens TL, and the parallel light beam P2 is emitted from the convex surface side of the lens TL. It is shown. In FIG. 12, the same components as those in FIG. 5 will be described with the same reference numerals.

Five openings 12a-12e are formed in the target plate 12 as shown in FIG. The opening 12a is located on the measurement optical axis O1, and four openings 12b to 12e are formed at regular intervals around the opening 12a. 15 'is a light receiving sensor 15 (area sensor or line sensor).

It is assumed that each of the LEDs 10a to 10e is turned on, and the measurement light beam is sent to the target plate 12 by the collimator lens 1. In addition, it is assumed that the inspection lens TL has its eccentric position X3 on the measurement optical axis O1.

When the target plate 12 is in the position indicated by the solid line in Fig. 12, the opening 12a in the center thereof is assumed to be in air space with the light receiving sensor 15 '. Here, when the LEDs 10b or 10d are turned on separately, five aperture projection images 12a ', 12b', 12d ', 2c', and 12e 'of the target plate 12, as shown in Fig. 14A, are shown. It is formed on this area sensor 15 '. Since the lens TL is eccentric only in the up-down direction and not eccentrically in the left-right direction, the aperture projection image when the LED 10b or 10d is turned on coincides.

When the LED 10 is turned on, the opening projection images 12a 'to 12e' shown in Fig. 14B are formed on the light receiving sensor 15 '. In the left and right directions, the aperture projection images 12a ', 12c', and 12e 'coincide with each other. The opening projection images 12b ', 12a', and 12d 'are out of the vertical direction.

This is because the measurement is performed by eccentricizing the test lens TL only in the vertical direction.

In addition, when the LED 10c is turned on, the opening projection images 12a 'to 12e' shown in Fig. 14C are generated. Therefore, when the LEDs 10a to 10d are turned on at the same time, the opening projection surfaces 12a 'to 12e' are formed in the light receiving sensor 15 'as shown in Fig. 14 (d).

When the target plate 12 is moved along the measurement optical axis O1 and the opening 12b is brought into the airspace position with the area sensor 15 ', each of the LEDs 10a to 10d is attached to the light receiving sensor 15'. At the same time, the aperture projection image shown in Fig. 14E is formed. On the light receiving sensor 15, a point where five aperture projection images 12a 'to 12e' are superimposed at a position eccentric from the measurement optical axis O1 is obtained. In addition, the aperture projection images 12b ', 12a', and 12d 'are projected on the measurement optical axis O1 in the vertical direction.

The left and right apertured images 12c '12e' are superimposed on the apertured images 12a '.

Therefore, the difference in the amount of movement when the target plate 12 is moved becomes the difference in frequency due to the angle of incidence of the lens TL, and the aperture projection images 12a ', 12c', 12d 'in the light receiving sensor 15'. The target lens 12 is moved so as to overlap one point, and the aberration at each moving position is obtained, so that the target lens TL can be obtained by using a type of injecting parallel light beams from the convex surface side of the lens to be examined. The frequency at the time of measuring at the eccentric position of can be calculated | required by conversion.

The prism amount is obtained as the distance between the center positions of the four projection images and the measurement optical axis O1 obtained when the LEDs 10a to 10d are turned on at the same time. The arithmetic circuit 30 shown in the figure moves the target plate 12 so that the aperture projection image formed on the light receiving sensor 15 'is collected at a predetermined position by turning on the plurality of light sources. The optical characteristic value at the eccentric position of the lens to be examined is obtained based on the difference between the optical characteristic value in, i.e., the back focus value BF "

The light receiving sensor 15 'is a sensor for detecting a light receiving position, and uses an area sensor or a line sensor, but these sensors are all one of various sensors for detecting the light receiving position, and each of these sensors is known. The detailed description is omitted since it is a part of.

In this embodiment, although the configuration of obtaining the center positions of the four projection images by using the light receiving sensor 15 'is adopted, it is assumed that a line sensor is used instead of the light receiving sensor 15', and the opening of the target plate 12 is used. As a configuration, a plurality of slits may be combined.

On the other hand, the lens meter according to the embodiment of the present invention is not limited only to the above-described embodiment, various modifications are possible within the scope not departing from the technical gist.

As described above, the measurement principle type is obtained by obtaining the optical characteristics of the lens under examination by the displacement of the measurement beam after transmission of the lens while the parallel beam as the measurement beam from the convex surface side of the lens according to the present invention is incident on the lens. The target plate was moved along the measurement optical axis to measure the optical characteristics at the eccentric position of the lens under test, and to output the parallel beam from the convex surface while injecting the measurement beam from the concave side of the lens to the test lens. By determining the optical characteristics of the lens under test by the amount of movement of the target plate at the time, the discrepancy of the optical characteristics can be eliminated when the scientific characteristic at the eccentric position of the lens under test is measured.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic diagram showing an optical system of a lens meter of a type in which parallel light beams are incident from a convex surface side of a test lens and a scientific characteristic of a test lens is obtained by displacement of a measuring light beam after light transmission of the test lens.

FIG. 2 is a parallel view of the pattern plate shown in FIG. 1.

FIG. 3 is an explanatory view showing an aperture projection image formed in an area sensor when a test lens is not set in the measurement optical path of the optical system shown in FIG. 1.

4 is an explanatory diagram of an aperture projection image formed in an area sensor when a lens having positive power is set in a measurement optical path of the optical system shown in FIG. 1.

FIG. 5 is a schematic diagram showing an optical system of a lens meter of a type in which the parallel beam is emitted from the convex surface side of the lens under test while the target plate is moved along the measurement optical axis, and the optical characteristics of the lens under test are obtained by the amount of movement of the target plate.

FIG. 6 is a plan view for explaining an arrangement of the measurement light sources shown in FIG. 5.

FIG. 7 is a plan view of the target plate shown in FIG. 5. FIG.

FIG. 8 is a schematic diagram for explaining a state in which a test lens is set in a measuring light path of a lens meter of the measuring principle type shown in FIG. 5, and the target plate is moved along the measuring light path such that parallel beams are emitted from the convex surface side of the lens. to be.

FIG. 9 is a schematic diagram for explaining a back focus value obtained when the lens is measured toward an eccentric position of the lens to be measured in the measurement light path of the lens meter of the measuring principle type shown in FIG. 1.

FIG. 10 is a schematic diagram for explaining a back focus value obtained when the lens is measured toward the eccentric position of the lens to be measured in the measuring optical path of the lens meter of the measuring principle type shown in FIG. 5.

11 shows a back focus value at an eccentric position of a test lens obtained when measured using a lens meter of the measuring principle type shown in FIG. 1 and a test obtained when measured using a lens meter of the measuring principle type shown in FIG. In order to explain the difference of the back focus value in the eccentric position of a lens, it is a schematic diagram which overlapped both.

It is explanatory drawing for demonstrating attaching the target plate which has several opening to an optical system.

FIG. 13 is a plan view of the target plate shown in FIG. 12.

It is a schematic diagram for demonstrating the aperture projection image formed on an area sensor based on the light beam which passed through the target board.

* Description of the symbols for the main parts of the drawings *

O1: measuring optical axis, TL: lens under test,

X3: Eccentric position, P1, P1 ', P1 ": Parallel beam.

Claims (3)

An optical system for injecting parallel light beams from the concave surface side of the lens to be inspected to obtain a projection image of the lens to be inspected, and an arithmetic circuit connected to the optical system, The optical system includes a measurement light source unit 10 having a plurality of light sources, a collimator lens 11 positioned in front of the measurement light source unit 10 and condensing parallel light beams incident from the measurement light source unit 10, and An opening target plate 12 positioned on the measurement optical path in front of the collimator lens 11 and provided with a plurality of openings positioned around the central opening and configured to be movable in the optical axis direction; A projection lens 13 positioned in front of the opening target plate 12 and positioned on an optical axis; An imaging lens 14 positioned in front of the projection lens 13 and disposed on the optical axis in front of the lens to be arranged at a predetermined position between the projection lens 13, By moving the opening target plate in the optical axis direction, a light receiving sensor 15 'disposed to be in an airspace position with the opening of the opening target plate 12, By moving the opening target plate in the optical axis direction, the light source emitted from the light source is focused on the opening of the opening target plate 12 through the collimator lens 11, and the projection lens 13 is The light beam passing through the opening target plate 12 is guided to the inspection lens side as parallel light flux, The calculation circuit 30 for calculating the aperture characteristic image formed in the light receiving sensor to obtain the optical characteristics of the lens under test, turns on the plurality of light sources so that the apertured image formed in the light receiving sensor is collected at a predetermined position. The aperture meter plate (12) is moved to an optical axis direction, and the optical characteristic value in the eccentric position of the said lens to be examined can be calculated | required by the optical characteristic value difference in each moving position. The lens meter of claim 1, wherein the light receiving sensor is any one of an area sensor and a line sensor. The lens meter according to claim 1, wherein the opening of the target plate is configured by combining a plurality of slits.