JPH09311367A - Real image type finder optical system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To increase the degree of freedom in design, to attain the miniaturization of a system and the reduction of the cost, and also to improve the visibility of the image of displayed information and a finder image. SOLUTION: An erect normal image optical system 2 is constituted as a porro-prism type prism obtained by combining rectangular prisms 2a and 2b, a semitransmissive reflection plane RF-4 is formed on the reflection inclined plane of the rectangular prism 2b-3 positioned on an eyepiece optical axis. The inclined plane of an added prism 6 is bonded to the semitransmissive reflection plane RF-4 so as to be formed into one body, the luminous flux of the displayed information from an information display body 5 is made incident on the added prism 6 and transmitted through the semitransmissive reflection plane RF-4 , then, the image of the displayed information is guided into the observation visual field of an eyepiece optical system 3. At this time, the installation position of the information display body 5 is set so that an optical distance from the eyepiece optical system 3 to the information display body 5 may be almost equal to the optical distance from the eyepiece optical system 3 to the image forming surface of an object optical system 1, then, the visibility of the image of the displayed information is made equal to the visibility of the finder image.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement of a real image type finder optical system mounted on a silver salt photographic camera, an electrophotographic camera or the like.

[0002]

2. Description of the Related Art In a conventional real image type finder optical system, when displaying various information necessary for photographing as display information (image of various information) in the finder field, an information display body including various information is used as an objective optical system. It is placed at the position of the image plane of the system,
This was observed with the eyepiece optical system together with the image plane of the objective optical system. Therefore, the following problems have occurred. (1) Since the space for inserting and installing the information display body must be secured at the position of the image plane of the objective optical system, the degree of freedom in designing the finder optical system becomes low, and further, the entire optical system Makes this difficult when miniaturizing.

(2) Since the information display body is arranged within the range of the image plane of the objective optical system, the finder image formed by the objective optical system is hidden by the presence of the information display body even if the area is small. Will be lost. (3) If an eyepiece optical system with a high finder magnification is adopted, the magnification of display information also increases. Therefore, in order to reduce the display information in the viewfinder field, the size of various information on the information display must be reduced. Disappear. However, this leads to an increase in cost associated with fine processing.

In order to solve such a problem, it is necessary to dispose the information display body at a position other than the position of the image plane of the objective optical system. Therefore, the real image type finder optical system having such a structure is arranged. A system technology has already been proposed as Japanese Patent Laid-Open No. 2-158722. In the technique disclosed in Japanese Patent Application Laid-Open No. 2-158722, first, an erecting erect image optical system in a real image type finder optical system is configured by one prism having two surface anti-slopes and two mirrors, A semi-transmissive reflective surface (half mirror) is formed on a part of the mirror located on the optical axis of the eyepiece optical system.

An information display body is provided in the space above the mirror having the semi-transmissive reflection surface, and a light beam from the information display body is provided in the space area in front of the mirror having the semi-transmission reflection surface with a finder optical system. By providing another mirror for introducing into the inside, it is configured such that the light flux from the information display body is incident on the eyepiece optical system from the back side of the mirror with the semi-transmissive reflection surface via this other mirror. is there.

[0006]

However, this mirror with a semi-transmissive reflective surface is such that a large part of the surface of the plate-like transparent optical element is formed as a reflective surface and a part thereof is a semi-transmissive reflective surface. Therefore, the light flux from the information display body first impinges on the back surface of the mirror having the semi-transmissive reflection surface and then passes through the semi-transmissive reflection surface. Since the mirror with a semi-transmissive reflection surface in this Japanese Patent Laid-Open No. 2-158722 is provided with an inclination of 45 degrees with respect to the optical axis, a mirror having a semi-transmissive reflection surface for the light flux from the information display body. When it hits the back surface of, the reflected light in the direction of 45 degrees is generated. The amount of this reflected light is determined by the back surface reflectance of the transparent optical element, but it may become non-negligible depending on the material and thickness of the transparent optical element.

When the light flux from the information display body is transmitted through the semi-transmissive reflection surface after that, half of the amount of light is lost at the semi-transmissive reflection surface, so that various kinds of light are observed when the eyepiece optical system is used. The result is that the image of information is darker than the viewfinder image. On the other hand, depending on the value of the thickness of the transparent optical element used, the optical axis of the optical path from the information display body to the back surface of the mirror with the semi-transmissive reflective surface and the light of the optical path from the mirror with the semi-transmissive reflective surface to the eyepiece optical system. Since there is a small amount of "deviation" between the shaft and the axis, there is also the problem that when arranging the information display body, the placement position must be set in consideration of this "deviation" amount. Occurs.

In order to prevent these problems from occurring, the material and thickness of the transparent optical element are examined in designing, and the reflectance of the semi-transmissive reflective surface to the reflectance of the reflective surface of the finder image is set to an appropriate ratio. The need arises. As a result,
The degree of freedom in design is narrowed and the cost is increased. The present invention has been made in view of such circumstances, and an object thereof is to provide a degree of freedom in designing when disposing an information display member at a position different from a position of an image forming surface of an objective optical system. It is possible to raise the appearance, and in a state where the image plane of the objective optical system is not hidden, it is possible to set the appearance of the image of the display information from the information display and the appearance of the finder image to be equal. Another object of the present invention is to provide a real image type viewfinder optical system that can reduce the size and cost of the entire optical system.

[0009]

In order to achieve the above object, the present invention according to claim 1 is a real image system in which an erecting orthoimage optical system is arranged between an objective optical system and an eyepiece optical system. In the finder optical system, it is constructed as an erecting normal image prism in which a plurality of right angle prisms are combined, and the left and right sides of the finder image incident from the objective optical system are inverted 2
An erecting orthoimage optical system in which one image inverting surface of one image inverting surface and two image inverting surfaces that are vertically inverted is formed as a semi-transmissive reflecting surface, and various information necessary for shooting, The position of the outer space of the erecting orthoimage optical system,
And, the information display body arranged at a position where the various information can be displayed in the finder field as display information, and configured as a right-angle prism, so that its incident surface faces the information display body and An additional prism having a reflection slant surface optically joined to the semi-transmissive reflection surface in the erecting orthoimage optical system, and further, the arrangement position of the information display member, the information display The optical distance from the eyepiece optical system to the body is set to a position substantially equivalent to the optical distance from the eyepiece optical system to the image plane of the objective optical system. .

According to a second aspect of the present invention, a plurality of right-angle prisms are combined in a real image type viewfinder optical system in which an erecting erect image optical system is arranged between an objective optical system and an eyepiece optical system. The erect erect image formed as an erect erect image prism and having two image left / right inverted surfaces for inverting the left and right of the finder image incident from the objective optical system and two image up / down inverted surfaces for inverting the finder image. Optical system,
An information display provided with various information necessary for photographing, which is the position of the outer space portion of the erecting normal image optical system and which is capable of displaying the various information as display information in the viewfinder field. Body and a right-angled prism so that its incident surface faces the information display body and its reflection slope is the two image left-right reversal surfaces and the two image up-down surfaces in the erecting normal image optical system. An additional prism configured to be optically joined to one of the image inverting surfaces, and semi-transmissive reflection on the joint surface between the erecting erect image optical system and the additional prism. A surface is formed, the arrangement position of the information display body, the optical distance from the eyepiece optical system to the information display body, the optical distance from the eyepiece optical system to the image plane of the objective optical system and Set to a position where the distance is almost equivalent It is characterized in.

According to a third aspect of the present invention, a plurality of rectangular prisms are combined in a real image type finder optical system in which an erecting erect image optical system is arranged between an objective optical system and an eyepiece optical system. The erect erect image formed as an erect erect image prism and having two image left / right inverted surfaces for inverting the left and right of the finder image incident from the objective optical system and two image up / down inverted surfaces for inverting the finder image. Optical system,
An information display provided with various information necessary for photographing, which is the position of the outer space portion of the erecting normal image optical system and which is capable of displaying the various information as display information in the viewfinder field. And a right-angled prism, and its reflection surface is formed as a semi-transmissive reflection surface such that its incident surface faces the information display body, and the semi-transmissive reflection surface is in the erecting orthoimage optical system. And an additional prism configured to be optically joined to one of the two image inverting surfaces and the one image inverting surface of the two image inverting surfaces. The disposition position is set to a position where the optical distance from the eyepiece optical system to the information display body is substantially equivalent to the optical distance from the eyepiece optical system to the image plane of the objective optical system. It is characterized by .

Further, in the invention described in claim 4, the image of the information display body can be introduced into the observation field of the eyepiece optical system between the information display body and the incident surface of the additional prism. It is characterized in that an optical system is provided.
Further, the invention according to a fifth aspect is characterized in that the additional optical system is configured as an optical system having a positive refractive power. According to a sixth aspect of the invention, the additional optical system is configured as an optical system having an aspherical surface. Further, the invention according to claim 7 is characterized in that the additional optical system is configured as an optical system including one group of lenses.

According to the invention described in claim 8, in a real image type viewfinder optical system in which an erecting erect image optical system is arranged between an objective optical system and an eyepiece optical system, a plurality of right angle prisms are combined. An erecting erecting image prism is provided, and one of two image laterally inverting surfaces for inverting the left and right of the finder image incident from the objective optical system and one image inverting surface for inverting the image vertically is provided. The erecting erect image optical system formed as a semi-transmissive reflecting surface, and various information necessary for photographing, the position of the outer space part of the erecting erect image optical system, and the display information of the various information. As an information display body disposed at a position where it can be displayed in the viewfinder field, and as a right-angle prism, its incident surface faces the information display body, and its reflection slope is the erecting normal image optics. system Of the additional prism configured to be optically joined to the semi-transmissive reflection surface of the optical disc, and the image of the information display body between the information display body and the incident surface of the additional prism, the observation of the eyepiece optical system. An additional optical system having a negative refractive power provided so that it can be introduced into the field of view, and further, the arrangement position of the information display body, the optical from the eyepiece optical system to the information display body. The target distance is set to a position substantially equivalent to the optical distance from the eyepiece optical system to the image plane of the objective optical system.

According to a ninth aspect of the present invention, a plurality of right-angle prisms are combined in a real image type finder optical system in which an erecting erect image optical system is arranged between an objective optical system and an eyepiece optical system. An erecting erect image prism, and two image left-right reversal surfaces for reversing the left and right of the finder image incident from the objective optical system and one image reversal surface of the two image up-and-down reversing surfaces for vertically inverting With the erecting normal image optical system formed with, and various information necessary for shooting,
At the position of the outer space portion of the erecting orthoimage optical system, and, and configured as a right angle prism, an information display disposed at a position where the various information can be displayed in the finder field as display information, One of the two image left-right inverted surfaces and the two image up-down inverted surfaces in the erecting orthoimage optical system is arranged so that its incident surface faces the information display body and its own reflective inclined surface. An image of the information display body is introduced into the observation field of the eyepiece optical system between the additional prism configured to be optically joined to the surface and the incident surface of the information display body and the additional prism. And an additional optical system having a negative refracting power which is provided so that a semi-transmissive reflective surface is formed on a joint surface between the erecting erect image optical system and the additional prism. Place the body in front of the information display Optical distance from the eyepiece optical system,
It is characterized in that it is set at a position which is approximately equivalent to the optical distance from the eyepiece optical system to the image plane of the objective optical system.

According to a tenth aspect of the present invention, in the real image type viewfinder optical system in which the erecting erect image optical system is arranged between the objective optical system and the eyepiece optical system, a plurality of right angle prisms are combined. Configured as an erecting image prism,
In addition, two image left / right inversion planes for inverting the left and right of the viewfinder image incident from the objective optical system and 2 for inverting the image upside down
The erecting erect image optical system having two image upside-down surfaces and various information necessary at the time of shooting, the position of the outer space part of the erecting erect image optical system, and the various information. An information display disposed at a position where it can be displayed in the finder field as display information and a right-angle prism, and its reflection surface is semi-transmissive so that its incident surface faces the information display. So that the semi-transmissive reflection surface is optically joined to the two image laterally inverted surfaces in the erecting orthoimage optical system and one image inverted surface of the two vertically inverted surfaces. A negative prism provided between the information display body and the incident surface of the additional prism configured so as to introduce an image of the information display body into the observation visual field of the eyepiece optical system. An additional optical system having a refractive power, In the arrangement position of the information display body, the optical distance from the eyepiece optical system to the information display body is substantially equivalent to the optical distance from the eyepiece optical system to the image plane of the objective optical system. It is characterized in that it is set at a position that becomes a distance.

The invention according to claim 11 is characterized in that the additional optical system is constructed as an optical system having an aspherical surface. Furthermore, the invention according to claim 12 is characterized in that the additional optical system is configured as an optical system including one group of lenses.

[0017]

According to the present invention constructed as described above, first, the erecting erect image optical system disposed between the objective optical system of the real image type finder optical system and the eyepiece optical system is combined with a plurality of right-angle prisms. It is configured as an erecting image prism. Then, one of the two image horizontal inversion surfaces for inverting the left and right of the finder image incident from the objective optical system and the two image vertical inversion surfaces for inverting the image finder image, or the reflection slope of the additional prism which is a right-angle prism. One of the two is formed as a semi-transmissive reflecting surface, and the reflecting slope of the additional prism is joined to the one image inverting surface to integrate the additional prism and the erecting normal image prism.

On the other hand, an information display body for displaying various kinds of information necessary for photographing as display information in the field of view of the finder is provided at a position outside the additional prism where the display information can be incident on the additional prism. At the same time as disposing the information display body, the optical distance from the eyepiece optical system to the information display body is approximately equal to the optical distance from the eyepiece optical system to the image plane of the objective optical system. Set to the position. In this way, the appearance of the display information that is incident on the additional prism from the information display body and transmitted through the semi-transmissive reflection surface and reaches the eyepiece optical system is set to be equal to that of the viewfinder image. .

Further, by providing an additional optical system having a positive refractive power between the information display body and the incident surface of the additional prism, in a state where the image plane of the objective optical system is not hidden,
While satisfying the condition that the appearance of the display information from the information display body and the appearance of the finder image are set equal, the arrangement position of the information display body is set to a position near the eyepiece optical system, The miniaturization of the entire spectroscopic system has been realized. On the other hand, instead of the optical system having a positive refractive power, an additional optical system having a negative refractive power is provided between the information display and the incident surface of the additional prism to provide an eyepiece optical system for the information display. Is maintained at a position that is optically equivalent to the distance from the eyepiece optical system with respect to the real image plane by the objective optical system, and the degree of freedom in designing is increased with respect to the arrangement position of the information display body.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the first embodiment in which the present invention is applied to a zoom type objective optical system will be taken as an example to describe the real image type finder optical system described in claims 1 and 8 of the present invention. The configuration and operation will be described. 1 to 5, reference numeral 1 denotes, for example, a zoom objective optical system (hereinafter, simply referred to as "objective optical system") having an appropriate focal length variable range,
It is configured as a finder optical axis first group 1a~ optical system of the 4-group 5-lens configuration comprising a fourth lens group 1d, which are aligned on O _F.

In this case, the first lens group 1a arranged closest to the object side is composed of a positive single lens, and the second lens group 1b arranged behind the first lens group 1a has a negative surface with a convex surface facing the object side. No. 2 meniscus lens and a negative meniscus lens having a convex surface facing the image side, the third lens group 1c arranged behind the second lens group 1b is composed of a positive single lens,
The fourth lens group 1d arranged behind the third lens group 1c is constituted by a positive single lens. Reference numeral 2 denotes an erecting normal image optical system configured as a Porro prism type erecting normal image prism in which a plurality of right-angled prisms are combined. For example, the erecting normal image prism has the following structure.

[0022] (which is also the erecting prism) This erecting optical system 2 includes a first rectangular prism 2a arranged an incident surface of itself in the finder optical axis on O _F to direct the objective optical system 1 side , Which is optically combined to the rear of the optical axis, and the information display optical axis (eyepiece optical axis and its extension optical axis) O _D
The final exit surface of itself set above is used by the eyepiece optical system 3
The second right-angled prism 2b (2b
_{-1 to} 2b _-3 ).

In this case, the first right-angled prism 2a is constructed as an independent right-angled prism having, for example, one reflection slope RF _-1 and the finder image (light flux) incident from the objective optical system 1 is reflected by the reflection slope RF. _In order to be able to output the reflected light flux in the direction of the first incident surface of the second rectangular prism 2b (2b _{-1 to} 2b _-3 ) while inverting the left and right in FIG. It is arranged.

On the other hand, the second right-angled prism 2b (2b _-1 to 2b)
b _-3 ) is too complicated in shape to be manufactured as one prism. Therefore, in order to avoid the difficulty in manufacturing the prism, first, in the illustrated example, each one of the reflecting slopes (R
F _{-2 to} RF _-4 ) three unit right-angle prisms, the first unit right-angle prism 2b _-1 , the middle unit right-angle prism 2
b _-2 , the final unit right-angle prism 2b _-3 is manufactured, and these unit right-angle prisms are optically bonded (hereinafter simply referred to as "bonding") in a state as described below to obtain a desired shape. It will be constructed using the method of making a junction prism structure.

That is, the frontmost unit right-angle prism 2b _-1 located at the forefront has its entrance surface facing the exit surface of the above-described first right-angle prism 2a with an air gap, and its exit surface. The structure and arrangement are such that they are joined to the incident surface of the intermediate unit right-angle prism 2b _-2 .
Then, the left-right inverted viewfinder image incident from the first right-angled prism 2a is reflected by its own reflection slope RF _{-2 in} FIG.
At 90 °, the light is reflected upward by 90 ° while being turned upside down, and can be made incident on the junction incident surface of the intermediate unit right-angle prism 2b ₋₂ .

In the case of the illustrated example, for the purpose of shortening the total length of the real image type finder optical system, the entrance surface of the front unit right-angle prism 2b _-1 is a spherical surface having a convex surface facing the object side. Is forming. The intermediate unit right-angle prism 2b _-2 located next has its own exit surface joined to the exit surface of the earliest unit right-angle prism 2b _-1 as described above, and its own exit surface is the last. Unit of right angle prism 2b
It is constructed so that it will be joined to the _-3 entrance surface.

Then, the finder image that has been incident from the earliest unit right-angle prism 2b _-1 and has been inverted upside down is reflected 90 ° to the right while being inverted upside down again in FIG. 1 by its own reflection slope RF _-3 . The final unit right-angle prism 2b _-3 is configured to be incident on the cemented incident surface. The final unit right-angle prism 2b _-3 located at the rearmost position
As described above, the entrance surface of itself is joined to the exit surface of the intermediate unit right-angle prism 2b _-2 , and the exit surface of the erecting erect image optical system 2 is the final exit surface. It is structured and arranged so as to face the eyepiece optical system 3 side on the display optical axis O _D.

Then, the finder light flux from the intermediate unit right-angle prism 2b- ₂ , which is incident as a normal image in the vertical direction by the image upside-down operation performed twice, reflects its own reflection slope RF.
_-4 is reversed right and left in FIG. 1 is reflected 90 degrees toward the lateral direction while also brought to normal image ocular optical system 3 by the vertical and horizontal with a finder image became normal image, the information display on the optical axis O _D It is configured such that it can be emitted to the eyepiece optical system 3 from its own emission surface located at. The final reflection slope RF- ₄ of the unit right-angle prism 2b- ₃ is formed as a semi-transmissive reflection surface by using a method of providing a semi-transmissive film layer (not shown).

Reference numeral 3 denotes an eyepiece optical system which is arranged behind the final exit surface of the erecting normal image optical system 2, and is constructed as a positive single lens in the illustrated example. Reference numeral 4 denotes an eye point of this real image type finder optical system set behind the eyepiece optical system 3. Then, the zoom objective optical system 1, the erecting normal image optical system 2, the eyepiece optical system 3 and the eye point 4 constitute a finder optical system. Reference numeral 5 denotes an information display body which is provided with various information necessary for photographing and is displayed in an observation visual field (hereinafter, referred to as "eyepiece visual field") when viewed by the eyepiece optical system 3 as display information. It is arranged on the extension axis of the information display optical axis O _D opposite to the position of 3.

In this case, the position of the information display body 5 is such that the optical distance (optical path length) from the eyepiece optical system 3 to the information display body 5 is an eyepiece with respect to the image plane (not shown) of the objective optical system 1. It is preferable to set the position such that the distance is almost equivalent to the optical distance from the optical system 3. The information display body 5 is configured as, for example, a plate-shaped member (mask plate, liquid crystal display body, light emitting element, etc.), and is appropriately illuminated by appropriate transmission or reflection illumination means (not shown) by natural light or artificial light. It is assumed that it is configured to be.
Reference numeral 6 denotes an additional prism provided on the information display optical axis O _D in order to introduce the image of the information display 5 into the eyepiece field (also in the viewfinder field) and has the structure and arrangement as described below. It is configured as a right angle prism.

[0031] That is, the additional prism 6 are opposed to the incident surface of the own information display 5 (in other words, are perpendicular to the information display axis O _D), erecting optical system a reflection slope own 2
The final unit right-angled prism 2b _{-3 in} the inside is structured so as to be bonded to the semi-transmissive reflection surface RF _-4 . Then, the information display body 5 that has entered the incident surface of itself
The light flux (image) from is incident on the final unit right-angle prism 2b _-3 via the semi-transmissive reflecting surface RF _-4 , and then can be introduced into the eyepiece visual field.

Reference numeral 7 denotes an additional optical system (lighting optical system) for introducing the image of the information display 5 into the eyepiece field of view.
And the incident surface of the additional prism 6 are arranged on the information display optical axis O _D. In the first embodiment shown in FIGS. 1 and 5, the additional optical system 7 is configured as a positive single meniscus lens having a convex surface facing the image side.
The optical system is composed of one lens group having a positive refracting power or a single lens, and is preferably an optical system having an aspherical surface or a single lens.

Since the additional optical system 7 is independent of the zoom objective optical system 1, it does not depend on the type and configuration of the zoom objective optical system 1. The presence of the additional optical system 7 does not become an essential condition in the case of the invention of claim 1, but becomes an essential condition only in the inventions of claims 2 and below. The information display 5, the additional prism 6, the additional optical system 7, the erecting normal image optical system 2, the eyepiece optical system 3, and the eye point 4 constitute an information display optical system. In the first embodiment, the semi-transmissive reflection surface is the reflection slope R of the final unit right-angle prism 2b- _3.
F- ₄ was formed, but instead of this, as shown in FIG.
A semi-transmissive reflection surface may be formed on the reflection slope 6a 'of the additional prism 6', and the reflection slopes RF- ₄ and 6a 'may be joined together.

Next, the operation of the real image type finder optical system will be described. A viewfinder light beam from an object such as a landscape or a person enters the real image type viewfinder optical system through the zoom type objective optical system 1. At this time, the viewfinder image is first inverted by the zoom type objective optical system 1. And forms an image on an image forming surface (not shown). This inverted image reaches the eyepiece optical system 3 in a state where it is inverted left / right and up / down by the three reflecting slopes RF _{−1 to} RF ₋₃ and one semi-transmissive reflecting surface RF ₋₄ of the erecting normal image optical system 2. It will be observed at the eye point 4 as a normal finder image.

This explanation is based on the case where the inverted image is formed at a position before reaching the first reflection slope RF _-1 of the erecting normal image optical system 2. Generally, the inverted image is the first image. Since the image is often formed in the vicinity of the air space between the first right-angled prism 2a and the earliest unit right-angled prism 2b- _{1 of} the second right-angled prism 2b, the inverted image is actually the first reflection slope. R
The image is formed on the image plane with the left and right sides being inverted at F ₋₁ , which is a win. On the other hand, the light flux from various information on the information display body 5 illuminated by an appropriate transmission or reflection illumination means (not shown) passes through the additional optical system 7 and the additional prism 6.
The light enters the inside, passes through the semi-transmissive reflection surface RF _-4 of the final unit right-angle prism 2b _-3 , reaches the eyepiece optical system 3, and is observed at the eyepoint 4 as an image of various information at the same time as the finder image. Become.

Therefore, the display information can be displayed in the viewfinder field without hiding the viewfinder image at all. Moreover, the optical distance from the eyepiece optical system 3 to the information display body 5 and the optical distance from the eyepiece optical system 3 to the image plane of the zoom objective optical system 1 are set to be substantially equivalent distances. Therefore, there is an effect that the appearance of the finder image and the appearance of various information images when observed by the eyepiece optical system 3 can be made equal. Next, detailed data according to a specific example of the real image type finder optical system of the present invention having the configuration of FIG. 2 will be described in a state of being divided into a finder optical system and an information display optical system.

[0037]

【Example】

<< Detailed data of finder optical system >> The meanings of the symbols used in this data table are as follows. In this data table, the second rectangular prism 2b is regarded as one prism having a cemented prism structure. R _{i (i} = 1~16): counted from the object side to the eyepiece direction, the i-th optical surface radius of curvature D _{i (i} = 1~15): counted from the object side to the eyepiece direction, the i-th Surface distance between the optical surface of the optical element and the optical surface of the (i + 1) th optical axis _Nj (j = 1 to 8): Refractive index of the material of the optical element located at the jth position, counting from the object side in the eye direction, ν _j (j = 1 to 8): Abbe number of the material of the optical element located at the j-th position, counting from the object side in the eye direction

[0038]

[Table 1] In the finder optical system listed in the above data table, the 1st, 4th, 5th,
An "aspherical surface" is adopted for each of the 10th and 13th surfaces, and the conical constant K of each surface and the numerical values of higher-order aspherical surface coefficients are shown below.

[0039]

[Table 2] In this case, the "aspherical surface" is the radius of curvature on the optical axis, the height from the optical axis is H, the coordinate in the optical axis direction corresponding to this H is X, the conic constant is K, and the quadratic / quartic order.・ When the 6th and 8th order aspherical coefficients are A, B, C and D respectively,

[0040]

[Equation 1] It is a curved surface expressed by the following equation. Then, for each of the above-mentioned aspherical surfaces, the conical constant K and a high-order aspherical surface coefficient are given to specify each surface shape.

[E-number] in the display of high-order aspherical coefficients represents "power". For example, [E-10]
If so, this means [1/10 ¹⁰ ] and this number will be multiplied by the number preceding it. Finder optical system in this embodiment is a zoom type objective optical system, the lens distance D ₂ between the first group 1a and the second group 1b, the lens distance D ₆ between the second group 1b and the third group 1c , Third group 1
c and the lens distance D ₈ between the fourth group 1d, surface distance D ₁₀ between the incident surface of the fourth lens group 1d and the first rectangular prism 2a, the intermediate focal length from the state of the shortest focal length (WIDE) (MEA
When the state of the longest focal length (TELE) is reached through the state of N), the state changes as shown in Table 3 below.

[0042]

[Table 3]

<< Detailed Data of Information Display Optical System >> First Example Meanings of symbols used in this data table are as follows. In this data table, the additional prism 6 and the final unit right-angle prism 2b _{-3 in} the second right-angle prism are treated as one prism as shown in FIG. r _i (i = 1 to 6): radius of curvature of the i-th optical surface counting from the information display side in the eye direction d _i (i = 1 to 5): from the information display side to the eye direction Counting, the surface distance on the optical axis between the i-th optical surface and the (i + 1) th optical surface N _j (j = 1 to 3): The j-th position, counting from the information display side in the eye direction. Refractive index of the material of the optical element ν _j (j = 1 to 3): Abbe number of the material of the optical element located at the j-th position counting from the information display side in the eye direction

[0044]

[Table 4] In the information display optical system of the first example listed in the above data table, the "aspherical surface" is adopted as the first surface, counting from the information display side in the eye direction, Regarding this "aspherical surface", the surface shape of the curved surface is specified according to the aspherical surface formula given in the section of the finder optical system described above.

[0045]

[Table 5] By the way, the spherical aberration, astigmatism, and distortion associated with the finder optical system in the real-image finder optical system having such detailed data are as shown in the aberration diagram of FIG.
All the aberrations are well corrected, which shows the superiority of the real image type finder optical system of the present invention.

Second Embodiment Although the additional optical system 7 in the information display optical system in the first embodiment described above is constructed as an optical system having a positive refractive power, it has a negative refraction power. A second embodiment constructed by replacing the optical system with power will be described below. FIG. 7 shows a second embodiment of the present invention corresponding to this second embodiment.
FIG. 2 is a perspective view showing the overall configuration of the embodiment of the present invention. The difference from the first embodiment shown in FIG. 1 is that the addition optical system 17 is replaced with an addition optical system 7 having a positive refractive power, and The only difference is that the optical system has a refractive power.

FIG. 8 is an optical configuration diagram showing the configuration of the second embodiment of the information display optical system in the present invention corresponding to the second embodiment, which is the first embodiment. 5 is different from that shown in FIG. 5 in that the additional optical system 17 is a meniscus lens having a negative refractive power, the convex surface facing the image side. Therefore, the finder optical system according to the second embodiment is the same as the embodiment shown in FIGS. 1 to 3, and the finder optical system according to the second example is the same as the first embodiment. Tables 1 to 3 of the finder optical system according to the example
Since it is common (identical) to the detailed data shown in (3), the description of these is incorporated, and the duplicate description of the detailed data of the second example of the finder optical system is omitted.

Therefore, in the following, only detailed data of the information display optical system of the second embodiment are listed in Tables 6 and 7. The symbols used in the data table of the second embodiment have the same meanings as those used in the data table of the first embodiment. Table 6 below shows detailed data of the radius of curvature r _i of the lens surface of each optical member of the information display optical system of the second embodiment, the inter-lens distance d _i , the refractive power N _j, and the Appe number ν _i. Is.

[0049]

[Table 6] As can be seen from Table 6 above, in the second embodiment, the radius of curvature r ₁ of the first surface and the radius of curvature r ₂ of the second surface of the additional optical system 17, and the second surface of the additional optical system 17 are used. Only the axial distance d ₂ between the first prism and the first surface of the additional prism 6 is different from that of the first embodiment. In addition, in the additional optical system 17 of the second example, the first surface is formed as an aspherical surface, and the "aspherical surface" has a radius of curvature R on the optical axis, a height H from the optical axis, The coordinate in the direction of the optical axis corresponding to this H is X, the conical constant is K, and the aspherical coefficients of the 2nd, 4th, 6th, and 8th orders are AB.
When C and D, the curved surface is represented by the aspherical expression of the above-mentioned mathematical expression 1. Then, the conical constant K of the "aspherical surface" and the aspherical surface coefficients A, B, C, D are given the numerical values in Table 7 below to specify the shape.

[0050]

[Table 7] By the way, the spherical aberration, astigmatism, and distortion of the information display optical system in the real image finder optical system according to the second example having such detailed data are as shown in the aberration diagram of FIG. However, all the aberrations are well corrected, which shows the superiority of the real image type finder optical system of the present invention.

Comparing the second embodiment thus constructed with the first embodiment described above, the first embodiment uses the additional optical system 7 having a positive refractive power. Since the arrangement position of the information display body 5 can be closer to the eyepiece optical system 3, there is an effect that the entire optical system can be downsized. On the contrary, the position of the information display body 5 is arranged closer to the eyepiece optical system. Therefore, the degree of freedom in design is low. On the other hand, in the case of the second embodiment,
Since the additional optical system 17 having a negative refractive power is used,
The information display body 5 can be separated from the eyepiece optical system 3, and the degree of freedom in design can be further improved.

Although the above description has been made based on the illustrated first and second embodiments and the first and second examples, the present invention is not limited to this, and does not depart from the scope of the invention. Various modifications can be made within. For example, in the illustrated embodiment, the additional prism 6
The semi-transmissive reflective surface RF _-4 of the final unit right-angle prism 2b _-3
The image of the information display body 5 is displayed in the eyepiece field by being joined to the above. However, the present invention is not limited to this, and for example, there are circumstances such as matching the finder optical system to the shape of the camera body. In some cases, information display 5
Image may be introduced into the viewfinder field from any one of the other reflection slopes RF _-1 , RF _-2 , and RF _-3 of the erecting erecting optical system (erecting erecting prism) 2. .

In the illustrated embodiment, the information display body 5 is arranged on the optical axis O _D extending from the eyepiece optical axis. However, depending on the circumstances, the information display body 5 and the additional prism 6 are arranged. It is also possible to dispose the optical axis direction conversion means between and and to dispose the information display body 6 at an arbitrary position. On the other hand, in the illustrated embodiment, the objective optical system is configured as a zoom type objective optical system, but it may be configured as an objective optical system having a predetermined focal length. Further, although the eyepiece optical system is configured as a single lens, it can be configured as a plurality of lens groups or as a variable power type eyepiece optical system.

[0054]

As described above, according to the inventions of claims 1 and 2, it is possible to increase the degree of freedom in designing when disposing the information display body at a position different from the position of the image plane of the objective optical system. Real image finder optics capable of setting the appearance of the display information from the information display and the appearance of the finder image to be equal in a state where the image plane of the objective optical system is not hidden. It has an excellent effect of realizing a system.

According to the third aspect of the present invention, in particular, the semi-transmissive reflecting surface is formed on the reflecting slanting surface side of the additional prism, and this reflecting slanting surface is joined to one image inverting surface of the erecting erect image optical system. When forming the semi-transmissive reflective surface, the additional prism having a small shape can process more prisms at the same time, and the cost can be reduced accordingly.
Further, in the invention of claim 4, by providing the additional optical system, the appearance of the display information from the information display and the appearance of the finder image can be obtained in a state where the image plane of the objective optical system is not hidden. The effect that the degree of freedom in design can be further increased while satisfying the condition of being set equally.

According to the fifth aspect of the present invention, since the positive optical power is given to the additional optical system, the image of the display information from the information display is displayed in a state where the image plane of the objective optical system is not hidden. It becomes possible to set the position of disposition of the information display at a position closer to the eyepiece optical system while satisfying the condition that the appearance to the eye and the appearance of the finder image are set to be equal. This has the effect of reducing the size of the entire device. According to the invention of claim 6, the additional optical system is an optical system having an aspherical surface, so that the appearance of the display information from the information display body with respect to the image and the appearance of the finder image are set to be equal. While satisfying the above condition, it is possible to secure the optical performance that cannot be achieved only by the spherical lens.

According to the invention of claim 7, the additional optical system is a group of lenses, so that the appearance of the display information from the information display body with respect to the image and the appearance of the finder image are set to be equal. While satisfying the conditions, there is an effect that the manufacturing cost of the optical system can be reduced. Also,
According to the eighth and ninth aspects of the present invention, the additional prism is provided with a negative refracting power, so that the appearance of the display information from the information display body with respect to the image can be improved in a state where the image plane of the objective optical system is not hidden. While satisfying the condition that the appearance of the finder image is set to be equal, it becomes possible to separate the position where the information display body is arranged from the eyepiece optical system, and as a result, compared with the inventions according to claims 1 to 7. This has the effect of further improving the degree of freedom in design.

According to the tenth aspect of the present invention, in particular, the semi-transmissive reflection surface is formed on the reflection slope side of the additional prism, and the reflection slope is formed by joining any one of the image inverting surfaces of the erecting image forming optical system. Therefore, when forming the semi-transmissive reflective surface, it is possible to process more prisms at the same time with the additional prism having a small shape, and the cost can be reduced accordingly.

In the eleventh aspect of the invention, the additional optical system is an optical system having an aspherical surface, so that the appearance of the display information from the information display body and the appearance of the finder image are set to be equal. While satisfying the condition, the effect that the optical performance that cannot be achieved by only the spherical lens can be ensured is exhibited. Claim 1
According to the second aspect of the invention, since the additional optical system is a group of lenses, it is possible to satisfy the condition that the appearance of the display information from the information display body with respect to the image and the appearance of the finder image are set equally. This has the effect of reducing the manufacturing cost of the system.

[Brief description of drawings]

FIG. 1 is an optical configuration diagram perspectively showing a schematic configuration of a real image type finder optical system according to a first embodiment of the present invention.

FIG. 2 is an optical configuration diagram when the real image type finder optical system of FIG. 1 is developed and shown in an extended state of the erecting erect image optical system in each of the WIDE state and the TELE state.

FIG. 3 is a perspective view showing an external configuration of a second right-angle prism of an erecting erect image optical system in the real image type finder optical system of FIG.

FIG. 4 is a perspective view showing an additional prism similar to the additional prism in the information display optical system of the real image type finder optical system of FIG. 1, in which a semi-transmissive reflection surface is formed as a reflection slope. .

5 is an optical configuration diagram showing a schematic configuration of an information display optical system in the real image type finder optical system of FIG.

FIG. 6 is an aberration diagram showing spherical aberration, astigmatism, and distortion of an example of the finder optical system in the real-image finder optical system shown in FIG.

FIG. 7 is an optical configuration diagram perspectively showing a schematic configuration of a real image type finder optical system according to a second embodiment of the present invention.

8 is an optical configuration diagram showing a schematic configuration of an information display optical system in the real image finder optical system of FIG.

FIG. 9 is an aberration diagram showing spherical aberration, astigmatism, and distortion of the example related to the information display optical system shown in FIG.

[Explanation of symbols]

1 Zoom type objective optical system 1a 1st group 1b 2nd group 1c 3rd group 1d 4th group 2 Erect erect image optical system (erect erect image prism) 2a 1st right angle prism 2b _{-1 to} 2b _-3 2nd right angle prism 2b _-1 Earliest unit right-angle prism 2b _-2 Intermediate unit right-angle prism 2b _-3 Final unit right-angle prism RF _-1 , RF _-2 , RF _-3 Reflective slope RF _-4 Reflective slope (semi-transmissive reflective surface) 3 eyepiece optical system 4 eyepoint 5 information display 6, 6 'added prism 7,17 additional optical system O _F finder optical axis O _D display optical axis (ocular optical axis and its extension the optical axis)

Claims (12)

[Claims] 1. A real image finder optical system comprising an erecting erect image optical system arranged between an objective optical system and an eyepiece optical system, wherein the erecting erect image prism is formed by combining a plurality of right-angle prisms. The image inverting surface out of the two image laterally inverting surfaces for inverting the left and right of the finder image incident from the objective optical system and the two image vertically inverting surfaces for inverting the finder image is formed as a semi-transmissive reflecting surface. An erecting normal image optical system and various information necessary for photographing, a position of the outer space of the erecting normal image optical system, and a position where the various information can be displayed as display information in the viewfinder field. And an information display member disposed in the right-angle prism, and its own incident surface faces the information display member, and its reflection slope is the same as the semi-transmissive reflection surface in the erecting erect image optical system. Contact An additional prism configured to be combined, and further, the arrangement position of the information display body, the optical distance from the eyepiece optical system to the information display body, the image formation of the objective optical system A real image type finder optical system, which is set at a position that is approximately equivalent to an optical distance from the eyepiece optical system to the surface. 2. A real image finder optical system comprising an erecting erect image optical system disposed between an objective optical system and an eyepiece optical system, wherein the erecting erect image prism is formed by combining a plurality of right-angle prisms. , The erecting normal image optical system in which two image horizontal inversion surfaces for inverting the left and right of the finder image incident from the objective optical system and two image upside down surfaces for vertically inverting are formed; An information display body, which is provided with information, at a position in the outer space of the erecting orthoimage optical system, and at a position where the various information can be displayed as display information in the viewfinder field; Of the two image right / left inversion surfaces and the two image up / down inversion surfaces in the erecting erect image optical system so that its incident surface faces the information display body. One statue An additional prism configured to be optically joined to the inversion surface, and a semi-transmissive reflective surface is formed on a joint surface between the erecting image forming optical system and the additional prism, Is set to a position where the optical distance from the eyepiece optical system to the information display body is approximately equivalent to the optical distance from the eyepiece optical system to the image plane of the objective optical system. A real image finder optical system characterized by the above. 3. A real image finder optical system comprising an erecting erect image optical system arranged between an objective optical system and an eyepiece optical system, wherein the erecting erect image prism is formed by combining a plurality of right angle prisms. , The erecting normal image optical system in which two image horizontal inversion surfaces for inverting the left and right of the finder image incident from the objective optical system and two image upside down surfaces for vertically inverting are formed; An information display body, which is provided with information, at a position in the outer space of the erecting orthoimage optical system, and at a position where the various information can be displayed as display information in the viewfinder field; The two images in the erecting erect image optical system are formed so that their incident surface is opposed to the information display body, and their reflective inclined surface is formed as a semi-transmissive reflective surface. left A right inversion surface and an additional prism configured to be optically joined to one of the two image upside down surfaces, and an arrangement position of the information display body. The optical distance from the eyepiece optical system to the information display is set to a position that is approximately equivalent to the optical distance from the eyepiece optical system to the image plane of the objective optical system. Real image type finder optical system. 4. An additional optical system capable of introducing an image of the information display body into an observation visual field of the eyepiece optical system is provided between the information display body and an incident surface of the additional prism. The real image type finder optical system according to claim 1. 5. The real image finder optical system according to claim 4, wherein the additional optical system is configured as an optical system having a positive refractive power. 6. The real image finder optical system according to claim 4, wherein the additional optical system is configured as an optical system having an aspherical surface. 7. The real image type finder optical system according to claim 4, wherein the additional optical system is configured as an optical system including one group of lenses. 8. A real image type viewfinder optical system comprising an erecting erect image optical system arranged between an objective optical system and an eyepiece optical system, wherein the erecting erect image prism is formed by combining a plurality of right-angle prisms, and The image inverting surface out of the two image laterally inverting surfaces for inverting the left and right of the finder image incident from the objective optical system and the two image vertically inverting surfaces for inverting the finder image is formed as a semi-transmissive reflecting surface. An erecting normal image optical system and various information necessary for photographing, a position of the outer space of the erecting normal image optical system, and a position where the various information can be displayed as display information in the viewfinder field. And an information display member disposed in the right-angle prism, and its own incident surface faces the information display member, and its reflection slope is the same as the semi-transmissive reflection surface in the erecting erect image optical system. Contact An additional prism configured to be combined, between the information display and the incident surface of the additional prism,
An additional optical system having a negative refractive power provided so that an image of the information display body can be introduced into the observation field of view of the eyepiece optical system; and The optical distance from the eyepiece optical system to the information display is set to a position that is approximately equivalent to the optical distance from the eyepiece optical system to the image plane of the objective optical system. Real image type finder optical system. 9. A real image finder optical system comprising an erecting erect image optical system arranged between an objective optical system and an eyepiece optical system, wherein the erecting erect image prism is formed by combining a plurality of right-angle prisms, and , The erecting orthoimage optics in which two image left / right inversion planes for inverting the left and right of the finder image incident from the objective optical system and one image inversion plane of the two image up / down inversion planes for vertically inverting are formed. The system and various information necessary for photographing are arranged at the position of the outer space of the erecting orthoimage optical system and at a position where the various information can be displayed as display information in the viewfinder field. And an information display body, which is configured as a right-angle prism, and has its own incident surface facing the information display body and its own reflection slant surface and the two image left-right reversal surfaces in the erecting normal image optical system and the two Two statues up and down Between an additional prism configured to be optically joined to one image inverting surface of the inverting surface, and between the information display and the incident surface of the additional prism,
An additional optical system having a negative refractive power, which is provided so that the image of the information display body can be introduced into the observation visual field of the eyepiece optical system, and the erecting erect image optical system and the additional optical system. A semi-transmissive reflective surface is formed on a joint surface with a prism, an arrangement position of the information display body, an optical distance from the eyepiece optical system with respect to the information display body, relative to the image plane of the objective optical system. A real-image viewfinder optical system characterized by being set at a position that is approximately equivalent to the optical distance from the eyepiece optical system. 10. A real image type viewfinder optical system comprising an erecting erect image optical system arranged between an objective optical system and an eyepiece optical system, wherein the erecting erect image prism is formed by combining a plurality of right angle prisms. , The erecting normal image optical system in which two image horizontal inversion surfaces for inverting the left and right of the finder image incident from the objective optical system and two image upside down surfaces for vertically inverting are formed; An information display body, which is provided with information, at a position in the outer space of the erecting orthoimage optical system, and at a position where the various information can be displayed as display information in the viewfinder field; The two images in the erecting erect image optical system are formed so that their incident surface is opposed to the information display body, and their reflective inclined surface is formed as a semi-transmissive reflective surface. Between the left-right reversing surface and one image reversing surface of the two up-and-down reversing surfaces, an additional prism configured to be optically joined, and between the information display and the incident surface of the additional prism,
An additional optical system having a negative refractive power provided so that the image of the information display body can be introduced into the observation field of view of the eyepiece optical system; and The optical distance from the eyepiece optical system to the information display is set to a position that is approximately equivalent to the optical distance from the eyepiece optical system to the image plane of the objective optical system. Real image type finder optical system. 11. The additional optical system is configured as an optical system having an aspherical surface.
The real image finder optical system according to any one of 1. 12. The real image type finder optical system according to claim 8, wherein the additional optical system is configured as an optical system including a group of lenses.