JP2012252089A - Photometric device and camera - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a photometric device and a camera in which the chromatic aberrations are corrected properly.SOLUTION: A photometric device includes a photometric sensor 14, a photometric optical system 15 that guides light to the photometric sensor 14, and a lens barrel member 24 that supports the photometric optical system 15. The photometric optical system 15 includes a first optical member 20 having a fixed position with respect to the photometric sensor 14, and a second optical member 22 including a diffraction optical element 21, and the second optical member 22 is held between the lens barrel member 24 and the first optical member 20.

Description

  The present invention relates to a photometric device and a camera.

  Conventionally, a photometry device for performing photometry provided in a camera or the like is known (see, for example, Patent Document 1).

JP 2008-292609 A

However, the conventional photometric device as described above has a photometric sensor and a photometric lens that guides light to the photometric sensor, and there is a problem that chromatic aberration occurs in the photometric lens.
Accordingly, the present invention has been made in view of the above problems, and an object thereof is to provide a photometric device and a camera in which chromatic aberration is corrected favorably.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, but this invention is not limited to this.
The invention of claim 1 is a photometric sensor (14), a photometric optical system (15) for guiding light to the photometric sensor (14), a lens barrel member (24) for supporting the photometric optical system (15), The photometric optical system (15) includes a first optical member (20) whose position is fixed with respect to the photometric sensor (14) and a second optical member (21) including a diffractive optical element (21). 22), wherein the second optical member (22) is sandwiched between the lens barrel member (24) and the first optical member (20). .

According to a second aspect of the present invention, the lens barrel member (24) and the first optical member (20) are bonded by an adhesive member (26), and the adhesive member (26) is the second optical member. The photometric device (2) according to claim 1, characterized in that the adhesiveness with the first optical member (20) is higher than the adhesiveness with (22).
The invention of claim 3 has a support member (16) for supporting the photometric sensor (14), and the first optical member (20) is provided for the photometric optical system (15) with respect to the photometric sensor (14). An adjustment part (20d) for adjusting the position is provided, and the support member (16) has a guide member (16c) for guiding the adjustment part (20d) in the optical axis direction, and the adjustment part (20d). ) Is a photometric device (2) according to claim 1 or 2, characterized in that its position is fixed with respect to the guide member (16c).

According to a fourth aspect of the present invention, the second optical member (22) has a first fitting portion (22f), and the first optical member (20) is third fitted with the second fitting portion (20h). Part (20i), the lens barrel member (24) has a fourth fitting part (24b), and the first fitting part (22f) and the second fitting part (20h) 4. The fitting according to claim 1, wherein the third fitting portion (20 i) and the fourth fitting portion (24 b) are fitted. This is a photometric device (2).
The invention according to claim 5 is the photometric device (2) according to any one of claims 1 to 4, wherein the second optical member (22) is made of a cycloolefin polymer resin. It is.
A sixth aspect of the invention is a camera (1) comprising the photometric device (2) according to any one of the first to fifth aspects.

  ADVANTAGE OF THE INVENTION According to this invention, the photometry apparatus and camera which correct | amended chromatic aberration favorably can be provided.

It is sectional drawing which shows the structure of the camera provided with the photometry apparatus which concerns on embodiment of this invention. It is an expanded sectional view showing composition of a photometry device concerning an embodiment of the present invention. It is A-A 'sectional drawing of FIG. It is a figure which shows the manufacturing method of the 2nd photometry lens of the photometry apparatus which concerns on embodiment of this invention.

A camera provided with a photometric device according to an embodiment of the present invention will be described with reference to the accompanying drawings.
First, the overall configuration of a camera provided with a photometric device according to this embodiment will be described.
As shown in FIG. 1, the camera 1 is a digital single-lens reflex camera including a camera body 3 with a built-in photometric device 2 and a photographing lens 4 attached to the camera body 3 in a replaceable manner.
The camera body 3 includes a quick return mirror 5 and an image sensor 6 in order from the photographing lens 4 side. On the reflected light path of the quick return mirror 5, a screen 7, a condenser lens 8, and a pentaprism. 9 are provided in order. A triangular prism 11, a photometric device 2, and an eyepiece 12 are provided on the back side of the pentaprism 9.

The photometric device 2 is for measuring the brightness of a subject (not shown), and includes a photometric sensor 14 that receives light from the subject, and a photometric optical system 15 that guides light from the subject to the photometric sensor 14. Have. The detailed configuration of the photometric device 2 will be described later.
The camera body 3 includes a control unit that controls each unit of the camera 1, a memory, an autofocus unit, and the like (all not shown). In addition, various switches including a release button, a monitor, and the like (all not shown) are provided outside the camera body 3.

In the camera 1 configured as described above, when a release button (not shown) is pressed halfway by the photographer, light from a subject (not shown) guided into the camera body 3 via the shooting lens 4 is transmitted by the quick return mirror 5. The light is reflected and imaged on the diffusion surface of the screen 7. This light is reflected in the pentaprism 9 through the condenser lens 8 and guided to the eyepiece lens 12. Thus, the photographer can observe the subject image via the eyepiece 12.
Here, a part of the light reflected in the pentaprism 9 is guided to the photometric device 2 via the triangular prism 11. This light is imaged on the light receiving surface 14 a of the photometric sensor 14 via the photometric optical system 15 and received by the photometric sensor 14. Thereby, a control unit (not shown) calculates an optimum exposure value for photographing from the luminance information of the subject image based on the output of the photometric sensor 14, and adjusts the aperture amount and shutter speed of the photographing lens 4 according to the exposure value. That is, automatic exposure control can be performed.

  When the release button is fully pressed by the photographer, the quick return mirror 5 is retracted out of the optical path, and the light from the subject reaches the image sensor 6. Thereby, the light from the subject is picked up by the image pickup device 6 and stored as a subject image in a memory (not shown). As described above, the photographer can shoot the subject while performing automatic exposure control with the camera 1.

Next, the photometric device 2 according to the present embodiment will be described in detail with reference to FIGS.
The photometric sensor 14 in the photometric device 2 is preferably a two-dimensional image sensor having a large number of pixels, and a CCD is used in this embodiment. For this reason, the photometric device 2 according to the present embodiment can be used for face detection, subject tracking, and the like in addition to the photometry for automatic exposure control as described above.
Such a photometric sensor 14 is mounted on a substantially plate-shaped photometric block 16 having a circular opening 16a formed at the center.

The photometric block 16 is preferably made of a material that can be easily bonded with an adhesive, and is made of polycarbonate in this embodiment. The photometric block 16 and the photometric sensor 14 are fixed by an adhesive 17 after adjusting the position so that the center of the opening 16a of the photometric block 16 and the center of the light receiving surface 14a of the photometric sensor 14 are aligned.
An IR cut filter 18 is provided in the opening 16 a of the photometry block 16. As shown in FIG. 3, cylindrical bosses 16b and 16c extending downward are formed on the lower surface of the photometry block 16 at positions facing each other across the center of the opening 16a. The photometric block 16 having such a configuration is fixed inside the camera body 3.

The photometric optical system 15 includes, in order from the photometric sensor 14 side, a first photometric lens 20 and a second photometric lens 22 including a diffractive optical element 21. In addition, by configuring the photometric optical system 15 with two lenses in this way, it is possible to ensure high optical performance commensurate with the photometric sensor 14 having a large number of pixels.
The first photometric lens 20 includes a lens portion 20a and a support portion 20b that is integrally formed over the entire circumference of the lens portion 20a and extends in the outer peripheral direction of the lens portion 20a.
As shown in FIG. 3, the support portion 20b has a protruding portion 20c protruding in the outer peripheral direction at a position facing the optical axis of the lens portion 20a, and a cylindrical portion 20d extending in a direction parallel to the optical axis. Are integrally formed. An annular groove 20e is formed on the lower surface of the support portion 20b along the outer shape of the lens portion 20a.

The protruding portion 20c penetrates in a direction parallel to the optical axis, and is formed with a substantially oval through hole 20f. The boss 16b of the photometry block 16 is inserted into the through hole 20f.
The cylindrical portion 20d is formed with a through hole 20g penetrating in a direction parallel to the optical axis, and a boss 16c of the photometry block 16 is removably fitted into the through hole 20g. The cylindrical portion 20d and the photometric block 16 are connected by a spring 23, and the cylindrical portion 20d is urged toward the photometric block 16 side. The axial length of the cylindrical portion 20d is set to be approximately the same as the length of the boss 16c of the photometry block 16. Thereby, since the fitting length of the through-hole 20g of the cylindrical part 20d and the boss | hub 16c can fully be ensured, the photometry block 16 can support the 1st photometry lens 20 stably.

With such a configuration, the cylindrical portion 20d can be moved in a direction parallel to the optical axis with the boss 16c of the photometric block 16 as a guide axis, that is, the first photometric lens 20 can be moved in the optical axis direction. The boss 16c and the cylindrical portion 20d are fixed by the adhesive 19 after adjusting the position of the first photometric lens 20 in the optical axis direction, that is, adjusting the focus, which will be described later.
The first photometric lens 20 described above is preferably made of a material that is easy to adhere an adhesive like the photometric block 16, and in this embodiment is made of polycarbonate.

The second photometric lens 22 includes a lens portion 22a and a substantially cylindrical support portion 22b that is integrally formed over the entire circumference of the lens portion 22a and extends toward the first photometric lens 20 side. .
The lens portion 22a has a plano-convex shape with the plane 22e facing the triangular prism 11, and the diffractive optical element 21 is formed on the plane 22e. The diffractive optical element 21 can satisfactorily correct chromatic aberration generated in the first photometric lens 20 and the second photometric lens 22.

The substantially cylindrical support portion 22b is inserted into a groove portion 20e formed in the support portion 20b of the first photometric lens 20, and the inner peripheral surface 22f of the support portion 22b and the inner wall surface 20h of the groove portion 20e are fitted. ing. Thus, by fitting the inner peripheral surface 22f concentric with the lens portion 22a of the second photometric lens 22 and the inner wall surface 20h concentric with the lens portion 20a of the first photometric lens 20, the lens portion 20a. The second photometric lens 22 can be attached to the first photometric lens 20 by aligning the center of the lens and the center of the lens portion 22a.
The lens portion 22a and the support portion 22b are preferably made of a material having a small water absorption and a small shape change in order to form the diffractive optical element 21 in the lens portion 22a. In this embodiment, the lens portion 22a and the support portion 22b are made of a cycloolefin polymer resin. It is configured.

The second photometric lens 22 is covered with a lens barrel 24 having a larger diameter than the support portion 22b of the second photometric lens 22 and a substantially cylindrical shape.
A step surface 24 a perpendicular to the optical axis of the second photometric lens 22 is formed inside the lens barrel 24. At the end of the lens barrel 24 on the triangular prism 11 side, a photometric aperture 25 formed by forming a circular opening in a thin sheet material, the center of the aperture of the lens barrel 24 and the center of the aperture of the photometric aperture 25 It is fixed by adhesion so that
The lens barrel 24 is preferably made of a material that is easy to adhere an adhesive, like the first photometric lens 20 and the photometric block 16, and is made of polycarbonate in this embodiment.

In such a lens barrel 24, the stepped surface 24 a of the lens barrel 24 and the end face 22 c on the triangular prism 11 side of the support portion 22 b of the second photometric lens 22 come into contact with each other, and the support portion 20 b of the first photometric lens 20 is in contact. The bottom surface 20j of the formed groove portion 20e and the end surface 22d on the photometric sensor 14 side of the support portion 22b are inserted into the groove portion 20e, and the outer peripheral surface 24b of the lens barrel 24 and the outer wall surface 20i of the groove portion 20e. And are fitted. In this state, the lens barrel 24 and the first photometric lens 20 are bonded by an adhesive 26. As the adhesive 26, an adhesive having higher adhesiveness with the first photometric lens 20 than adhesiveness with the second photometric lens 22 is used.
As described above, by fitting the outer peripheral surface 24b concentric with the opening of the photometric diaphragm 25 of the lens barrel 24 and the outer wall surface 20i concentric with the lens portion 20a of the first photometric lens 20, the lens portion The lens barrel 24 can be attached to the first photometric lens 20 by aligning the center of 20a with the center of the aperture of the photometric aperture 25. Then, the second photometric lens 22 made of a cycloolefin polymer resin that is difficult to adhere with the adhesive 26 can be appropriately sandwiched between the first photometric lens 20 and the lens barrel 24.

  Under the above configuration, in the photometric device 2 according to the present embodiment, the first photometric lens 20 and the second photometric lens 20 are moved together with the first photometric lens 20 by moving the first photometric lens 20 in the optical axis direction using the boss 16c of the photometric block 16 as a guide axis. The lens 22 and the lens barrel 24 can be integrally moved in the optical axis direction, whereby the subject image formed on the light receiving surface 14a of the photometric sensor 14 can be adjusted with high accuracy. Therefore, the photometric device 2 according to the present embodiment fixes the boss 16c of the photometric block 16 and the cylindrical portion 20d of the first photometric lens 20 with the adhesive 19 after performing the focus adjustment with high accuracy at the time of manufacture. can do.

  In the photometric device 2 according to the present embodiment, the boss 16b of the photometric block 16 is inserted into the substantially oval through hole 20f formed in the protruding portion 20c of the first photometric lens 20 as described above. For this reason, the rotation of the first photometric lens 20 with the boss 16c of the photometric block 16 as a rotation axis is restricted, whereby the optical axis and the photometry of the second photometric lens 22 and the lens barrel 24 together with the first photometric lens 20. The center of the light receiving surface 14a of the sensor 14 can be accurately aligned.

Here, the manufacturing method of the 2nd photometry lens 22 in this embodiment is demonstrated based on FIG.
For the production of the second photometric lens 22, as shown in FIG. 4, a mold 30 holding the lens portion 22a and the support portion 22b of the second photometry lens 22, and the lens portion 22a and the support portion 22b with respect to the mold 30 A first jig 33 and a second core 34 for forming the diffractive optical element 21 on the lens portion 22a are used.
The mold 30 is formed with a cylindrical large-diameter opening 30a concentric with the lens portion 22a. Further, the bottom surface 30b of the large-diameter opening 30a is concentric with the lens portion 22a and below the mold 30. A penetrating cylindrical small-diameter opening 30c is formed. The inner diameter of the large-diameter opening 30a is larger than the outer shape of the support part 22b, and the inner diameter of the small-diameter opening 30c is smaller than the diameter of the lens part 22a.

The fast jig 32 is a plate-like member formed with a cylindrical portion 32a that is concentric with the large-diameter opening 30a of the mold 30 and has a circular through-hole having substantially the same diameter as the lens portion 22a. A stepped portion 32b extending in the outer peripheral direction of the cylindrical portion 32a is formed on the lower surface of the plate-like member.
The first core 33 is a cylindrical member that is concentric with the small-diameter opening 30c of the mold 30 and is removably fitted into the small-diameter opening 30c. A transfer surface for transferring the diffraction surface is formed.
The second core 34 is a cylindrical member that is removably fitted into the small-diameter opening 30c of the mold 30 in the same manner as the first core 33. The second core 34 has a second resin 21b, which will be described later, on its upper surface. A transfer surface (plane) for transferring the plane is formed.

In manufacturing the second photometric lens 22, a plano-convex lens portion 22a and a substantially cylindrical support portion 22b are integrally manufactured in advance by injection molding. In the present embodiment, the cycloolefin polymer resin is used as the material for the lens portion 22a and the support portion 22b as described above.
Procedure 1: The lens portion 22a and the support portion 22b are placed in the mold 30 and fixed with a quick jig 32. Specifically, in the fast jig 32, the lower surface 32c of the stepped portion 32b of the fast jig 32 and the end surface 22d of the support portion 22b come into contact with each other, and the edge portion 22g of the flat surface 22e of the lens portion 22a and the size of the mold 30 are large. It is attached to the upper side of the mold 30 so that the bottom surface 30b of the diameter opening 30a abuts. Thereby, the outer peripheral surface 32d of the cylindrical portion 32a of the fast jig 32 and the inner peripheral surface 22f of the support portion 22b concentric with the lens portion 22a are fitted. Further, the side surface 32e of the stepped portion 32b concentric with the cylindrical portion 32a and the inner peripheral surface 30d of the large diameter opening 30a concentric with the small diameter opening 30c of the mold 30 are fitted. That is, the lens portion 22 a and the support portion 22 b can be fixed to the mold 30 after aligning the center of the lens portion 22 a with the center of the small-diameter opening 30 c of the mold 30.

Procedure 2: The first resin 21a is applied to the flat surface 22e of the lens portion 22a. Then, the first core 33 is inserted into the small diameter opening 30c of the mold 30 from below and pressed against the first resin 21a. After the first resin 21a is cured in this state, the first core 33 is removed. Thereby, the diffraction surface can be transferred onto the surface of the first resin 21a. At this time, as described above, the first core 33 is concentric with the small-diameter opening 30c, and the center of the lens portion 22a and the center of the small-diameter opening 30c are aligned in the above procedure 1, and therefore the center of the lens portion 22a. And the center of the diffraction surface can be matched with high accuracy.
Procedure 3: The second resin 21b is applied to the first resin 21a to which the shape of the diffractive optical element is transferred in Procedure 2. Then, the second core 34 is inserted into the small-diameter opening 30c of the mold 30 from below and pressed against the second resin 21b. After the second resin 21b is cured in this state, the second core 34 is removed. Thereby, a plane can be transferred onto the surface of the second resin 21b. In the present embodiment, for example, an ultraviolet curable resin is used as the first resin 21a and the second resin 21b.

According to the above procedure, the diffractive optical element 21 composed of the first resin 21a and the second resin 21b can be integrally formed on the flat surface 22e of the lens portion 22a of the second photometric lens 22, The two-photometric lens 22 can be completed.
In addition, in order to correct chromatic aberration more satisfactorily by the diffractive optical element 21, it is necessary that the center of the diffractive optical element 21 of the second photometric lens 22 and the center of the lens portion 22a are aligned with high accuracy. In this embodiment, as described in the procedure 2 above, the center of the lens portion 22a and the center of the diffractive surface of the diffractive optical element 21 can be aligned with high accuracy, so that the diffractive optical element 21 corrects chromatic aberration better. can do.
In addition, the photometric optical system 15 in the present embodiment has a configuration in which a complicated mechanism for adjusting the focus of the cylindrical portion 20d or the like is provided in the first photometric lens 20, and the diffractive optical element 21 is provided in the second photometric lens 22. Thus, the shapes of the lens portion 22a and the support portion 22b of the second photometric lens 22 are simplified. Therefore, when the diffractive optical element 21 is molded on the lens portion 22a by the mold 30, the complicated mechanism does not get in the way. That is, the structure of the mold 30 can be simplified, and higher molding accuracy can be realized.

As described above, according to the present embodiment, the photometric device 2 that satisfactorily corrects chromatic aberration generated in the lens portion 20a of the first photometric lens 20 and the lens portion 22a of the second photometric lens 22 in the photometric optical system 15, and the photometric device 2 Can be realized.
In the present embodiment, the photometric device 2 is applied to a lens interchangeable digital single-lens reflex camera. However, the present invention is not limited to this, and the photometric device 2 may be applied to a film camera or other optical device. Is possible.
Further, the configuration of the photometric optical system 15 is not limited to the above. For example, the photometric optical system 15 may further include at least one lens in addition to the first photometric lens 20 and the second photometric lens 22. In addition, the lens portion 22a of the second photometric lens 22 may have a parallel plate shape. Further, a parallel plate provided with a diffractive optical element may be disposed between the second photometric lens 22 and the lens barrel 24. In addition, the diffractive optical element 21 may be a multilayer in order to correct chromatic aberration better.

DESCRIPTION OF SYMBOLS 1 Camera 2 Photometry apparatus 14 Photometry sensor 15 Photometry optical system 16 Photometry block 20 1st photometry lens 21 Diffractive optical element 22 2nd photometry lens 24 Lens barrel

Claims (6)

A photometric sensor;
A photometric optical system for guiding light to the photometric sensor;
A lens barrel member that supports the photometric optical system,
The photometric optical system includes a first optical member whose position is fixed with respect to the photometric sensor, and a second optical member including a diffractive optical element,
The photometric device characterized in that the second optical member is sandwiched between the lens barrel member and the first optical member. The lens barrel member and the first optical member are bonded by an adhesive member,
The photometric device according to claim 1, wherein the adhesive member has higher adhesiveness with the first optical member than adhesiveness with the second optical member. A support member for supporting the photometric sensor;
The first optical member has an adjustment unit for adjusting the position of the photometric optical system with respect to the photometric sensor,
The support member includes a guide member that guides the adjustment unit in the optical axis direction.
The photometric device according to claim 1, wherein a position of the adjustment unit is fixed with respect to the guide member. The second optical member has a first fitting portion;
The first optical member has a second fitting portion and a third fitting portion,
The lens barrel member has a fourth fitting portion,
The first fitting portion and the second fitting portion are fitted, and the third fitting portion and the fourth fitting portion are fitted. The photometric device according to claim 3.   The photometric device according to any one of claims 1 to 4, wherein the second optical member is made of a cycloolefin polymer resin.   A camera comprising the photometric device according to any one of claims 1 to 5.

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