JP5087847B2 - Optical viewfinder device and electronic camera - Google Patents

Description

  The present invention relates to an optical viewfinder device and an electronic camera used for observing a subject image projected on a focusing screen.

There is known an optical viewfinder device in which a field frame is arranged in the vicinity of a focusing screen, and an observation range of a subject image is switched according to movement of a plurality of masks constituting the field frame (for example, see Patent Document 1). reference).
JP-A-9-281557

  However, the conventional optical viewfinder device has the following problems because the field frame is arranged in the vicinity of the focusing screen. In other words, if you try to avoid the enlargement of the entire device while avoiding interference between the mask of the field frame and surrounding mechanisms (such as shutters), it is not possible to secure a sufficient space for moving the mask of the field frame, There is a problem that there are few variations when switching the observation range of the subject image.

  An object of the present invention is to provide an optical viewfinder device and an electronic camera that can increase variations when switching the observation range of a subject image while avoiding an increase in size of the entire device.

An optical viewfinder device of the present invention is an optical viewfinder device including a focusing screen and an eyepiece lens, and is disposed between the focusing screen and the eyepiece lens, and provides a secondary image of a subject image formed on the focusing screen. An imaging lens to be formed, and a variable aperture that is disposed between the imaging lens and the eyepiece lens and that can be independently changed in size in two directions orthogonal to each other and disposed on the formation surface of the secondary image. And a field frame that regulates the secondary image by the variable aperture and can shield the entire secondary image, and the field frame has a size for changing a vertical size of the variable aperture. Two masks and two masks for changing the lateral size of the variable opening are provided. The eyepiece is detachable, and the field frame is disposed immediately before the eyepiece, and shields the entire secondary image when the eyepiece is removed .

The two directions preferably correspond to the vertical and horizontal directions of the subject image on the focusing screen.
In addition, the variable aperture of the field frame has a standard state with the same aspect ratio as that when the subject image is substantially maximized on the focusing screen, and has the same diagonal length as the standard state. It is preferable that the aspect ratio can be changed .

In addition, the optical finder device of the present invention includes a display unit that displays predetermined information, and a composition that is arranged between the field frame and the eyepiece, and superimposes the information on a secondary image regulated by the field frame. Means.
Moreover, it is preferable that the said visual field frame shields the whole said secondary image according to the information displayed by the said display means.

An electronic camera according to the present invention includes the above-described optical viewfinder device and an image sensor that captures the subject image .
The electronic camera preferably includes extraction means for extracting data of a portion corresponding to the observation range of the secondary image in the imaging area of the imaging device.
In the above electronic camera, it is preferable that the electronic camera includes a control unit that controls the field frame to shield the entire secondary image when the subject is photographed by a self-timer.

  According to the present invention, it is possible to increase variations when switching the observation range of the subject image while avoiding an increase in the size of the entire optical finder device.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Here, the single-lens reflex type electronic camera 10 of FIG. 1 will be described as an example of the optical viewfinder device of the present embodiment. The electronic camera 10 includes a photographing lens 11, a main mirror 12, a shutter 13, an image sensor 14, an image processing circuit 15, a camera control circuit 16, an operation unit 17, and the optical viewfinder device (18 to 28) of the present embodiment. Provided. The camera control circuit 16 performs overall control of the electronic camera 10.

  The light from the subject passes through the taking lens 11 and is then guided into the camera body 10A. Inside the camera body 10A, the main mirror 12 is flipped up to a dotted line state at the time of shooting, and the shutter 13 is opened at a predetermined exposure timing. For this reason, the light guided into the camera body 10 </ b> A travels straight and enters the imaging surface of the imaging device 14. An optical image of the subject is formed on the imaging surface by the taking lens 11.

The image sensor 14 is an XY address type image sensor (for example, a CMOS image sensor) and captures an optical image of a subject formed on the imaging surface. The output of the image sensor 14 is processed by the image processing circuit 15 and is output as a captured image to an image memory (not shown) or a display device.
In a normal shooting operation, the signal of each pixel is read from the entire imaging area 4A (FIG. 2) of the imaging device 14, and a captured image is generated. However, since the signal of each pixel of the image sensor 14 can be read out by random access, the signal of each pixel is selectively read out from any part of the imaging area 4A (for example, the partial areas 31 to 33 shown in FIG. 2). It is also possible to generate captured images with different sizes and aspect ratios.

  During the photographing operation, information on an external operation by the photographer is input from the operation unit 17 to the camera control circuit 16. The camera control circuit 16 performs a shooting operation with reference to information from the operation unit 17, and when changing the size or aspect ratio of the captured image, the signal reading area (for example, FIG. 2). Any one of the partial areas 31 to 33 is designated. The designation method is performed by designating the address of each pixel in the readout area.

Further, prior to such a shooting operation, the electronic camera 10 performs subject image focus adjustment, photometry, and the like as follows. Before photographing, the main mirror 12 is held in a solid line state. For this reason, the light guided into the camera body 10A is reflected by the main mirror 12 and then enters the optical finder device (18 to 28) of the present embodiment.
The optical viewfinder device (18 to 28) has a relay system configuration, and includes a focusing screen 18, an imaging lens 19, an erecting mirror 20, a field frame 21, an optical path synthesis element 22, an eyepiece lens 23, a display element 24, and a projection lens. 25, motors 26 and 27, and a display circuit 28.

Of the components of the optical finder device (18 to 28), the optical system portion is shown in the perspective view of FIG. FIG. 3 also shows the taking lens 11 and the main mirror 12. In FIG. 3, the erecting mirror 20 includes three mirrors 20 (1) to 20 (3), and an imaging lens between the second mirror 20 (2) and the third mirror 20 (3). The case where 19 is arrange | positioned was shown.
The light from the main mirror 12 enters the focusing screen 18 of the optical viewfinder device (18 to 28), passes through the focusing screen 18, and then enters the field frame 21 via the imaging lens 19 and the upright mirror 20. Incident. The field frame 21 is provided with a variable aperture 2 </ b> A (FIG. 3), and only light that has passed through the variable aperture 2 </ b> A passes outside the electronic camera 10 (the photographer's pupil) via the optical path synthesis element 22 and the eyepiece 23. Led.

In the above optical path, the position of the focusing screen 18 is substantially conjugate with the imaging device 14, and a subject image is projected onto the focusing screen 18 by the photographing lens 11. The optical viewfinder devices (18 to 28) of the present embodiment are used for observing a subject image projected on the focusing screen 18, and processing such as focus adjustment and photometry is performed based on the subject image.
The imaging lens 19 condenses the transmitted light from the focusing screen 18 and forms a secondary image 10B of the subject image formed on the focusing screen 18 on the arrangement surface of the variable aperture 2A (FIG. 3) of the field frame 21. . Further, the imaging lens 19 has a reduction magnification, and reduces the subject image formed on the focusing screen 18 to form a secondary image 10B.

Further, the imaging lens 19 is capable of zooming, and performs a zooming operation in accordance with the movement of the lenses 9A and 9B shown in FIGS. 4A and 4B in the optical axis direction, and the size of the secondary image 10B. To change. Such a zooming operation is performed by the motor 26 driving the imaging lens 19 based on an instruction from the camera control circuit 16.
In the present embodiment, FIG. 4A is in the standard state, and the diagonal length of the secondary image 10B at this time is S1. Further, in a state where the secondary image 10B is enlarged from the standard state (FIG. 4B), the diagonal length of the secondary image 10B is S2. The diagonal lengths S1 and S2 of the secondary image 10B are smaller than the diagonal length S0 of the subject image formed on the focusing screen 18.

Next, the field frame 21 will be described. The variable aperture 2A (FIG. 3) of the field frame 21 is disposed on the surface on which the secondary image 10B is formed, for example, by two mechanisms (two arrows x ₁ shown in FIGS. 3 and 5) orthogonal to each other by the mechanism shown in FIG. , y ₁ direction) can be changed independently. These two directions correspond to the vertical and horizontal directions of the subject image on the focusing screen 18 (directions of the two arrows x ₂ and y ₂ shown in FIGS. 3 and 4), and the vertical and horizontal directions of the secondary image 10B (shown in FIG. 4). Corresponding to two arrows x ₃ and y ₃ ).

As shown in FIG. 5, the field frame 21, in order to change the size of the longitudinal variable aperture 2A (x ₁ direction), and two masks 41 and 42, a gear 43 for connecting the actuator 44 And are provided. The actuator 44 is attached to _one mask 42 and moves the mask 42 in the x1 direction. When the mask 42 moves, the other mask 41 also moves through the gear 43. Moving direction of the mask 41, 42 is opposite to each other, it is possible to change the size of longitudinal (x ₁ direction) of the variable aperture 2A in accordance with the movement of the mask 41.

Further, the field frame 21, in order to change the size of lateral variable aperture 2A (x ₂ direction), and two masks 45 and 46, a gear 47 for connecting them, and the actuator 48 is provided . The actuator 48 is mounted on one of the mask 46, moving the mask 46 in the x ₂ direction. When the mask 46 moves, the other mask 46 also moves through the gear 47. Moving direction of the mask 45 and 46 are opposite to each other, it is possible to change the size of the lateral variable aperture 2A (x ₂ direction) in response to movement of the mask 45 and 46.

In the field frame 21 configured as described above, the actuators 44 and 48 are connected to the camera control circuit 16, and the actuators 44 and 48 are orthogonal to the size of the variable aperture 2A of the field frame 21 based on an instruction from the camera control circuit 16. 2 direction (x ₁ direction, y ₁ direction) to change independently in. The actuators 44 and 48 correspond to the motor 27 in FIG.
Thus, the variable aperture 2A of the field frame 21, it is possible to change independently the size in two directions (x ₁ direction, y ₁ direction) perpendicular to each other, not only the change of the overall size (diagonal length), The aspect ratio can be changed freely.

When changing the size and aspect ratio of the variable aperture 2A of the field frame 21 (that is, before photographing), information from the operation unit 17 (information of external operation by the photographer) is input to the camera control circuit 16. Then, the camera control circuit 16 refers to the information from the operation unit 17 and changes the size and aspect ratio of the variable aperture 2A of the field frame 21.
FIG. 5 shows a selection dial 51 used as an example of the operation unit 17 to change the size and aspect ratio of a captured image. The selection dial 51 is connected to the camera control circuit 16 via the encoder 52 and the detection contact 53. Based on the signal from the detection contact 53, the camera control circuit 16 can obtain information related to the setting of the size and aspect ratio of the captured image. Based on this information, the size and aspect ratio of the variable aperture 2A of the field frame 21 are changed.

In FIG. 5, the vertical direction masks 41 and 42 and the horizontal direction masks 45 and 46 are illustrated apart from each other in the optical axis direction for easy understanding of the configuration of the field frame 21. Are arranged close to each other. The arrangement surface corresponds to the arrangement surface of the variable aperture 2A and is substantially the same as the formation surface of the secondary image 10B. The four masks 41, 42, 45, 46 are light shielding members.
In the present embodiment, in the secondary image 10B formed on the arrangement surface of the variable aperture 2A of the field frame 21, the portions that overlap the masks 41, 42, 45, and 46 are shielded and only the portions that overlap the variable aperture 2A. Can be passed. That is, the secondary image 10B can be regulated by the variable aperture 2A, and the observation range of the subject image can be switched (trimming). Then, the regulated secondary image 10B is projected by the eyepiece 23 onto the photographer's pupil.

An optical path combining element 22 is disposed between the field frame 21 and the eyepiece lens 23. A projection lens 25 and a display element 24 are disposed on the optical path branched from the optical path synthesizing element 22. Is connected. The display circuit 28 displays predetermined information (such as various control information) on the display element 24 in conjunction with the camera control circuit 16.
The light emitted from the display element 24 according to such information is guided onto the optical path of the eyepiece lens 23 via the projection lens 25 and the optical path synthesis element 22, and is outside the electronic camera 10 (the photographer's pupil). Led to. At this time, the information displayed on the display element 24 can be observed by being superimposed on the secondary image 10 </ b> B regulated by the field frame 21.

Next, the relationship between the magnification of the imaging lens 19 and the change of the field frame 21 in the optical viewfinder device (18 to 28) of the present embodiment will be described.
In the present embodiment, the standard state of the imaging lens 19 is set to a state where the diagonal length of the secondary image 10B is S1 (FIG. 4A).
Further, the standard state of the variable aperture 2A of the field frame 21 is set as follows. In other words, the state of the same size (diagonal length S1) and aspect ratio as the secondary image 10B formed when the imaging lens 19 is in the standard state (FIG. 4A) is the standard state of the variable aperture 2A. The variable opening 2A in the standard state is shown in FIG. The standard state is a state having the same aspect ratio as that when the subject image is substantially maximized on the focusing screen 18.

  As shown in FIG. 6A, when both the imaging lens 19 and the variable aperture 2A of the field frame 21 are in the standard state, the size and aspect ratio of the secondary image 10B and the variable aperture 2A are substantially the same. The state in the viewfinder field is as shown in FIG. That is, the entire screen 60 of the subject image on the focusing screen 18 can be observed inside the field frame image 21A corresponding to the field frame 21 in the standard state, and the superimpose display 61 and the like are observed in addition to this. be able to. Further, the left information display 62, the right information display 63, the lower information display 64, and the like can be observed outside the field frame image 21A.

  On the other hand, when observing the center portion of the subject image (horizontal position enlarged screen 65) on the focusing screen 18, the imaging lens 19 and the variable aperture 2A of the field frame 21 are set to the state shown in FIG. The state in the viewfinder field is as shown in FIG. In this case, the imaging lens 19 is in a state of enlarging the secondary image 10B from the standard state (FIG. 4B), and the variable aperture 2A of the field frame 21 remains in the standard state. Since the diagonal length S1 of the variable aperture 2A is smaller than the diagonal length S2 of the secondary image 10B, the peripheral portion of the secondary image 10B is shielded, and only the central portion of the diagonal length S1 is shown in the field frame image 21A ( The image can be enlarged and observed inside the same screen size as in FIG. Such a horizontal position enlarged screen 65 has a long side that is the same length as the short side of the full screen 60 in FIGS. 6A and 7A, and an aspect ratio that is the same as that of the full screen 60.

  When the central portion of the subject image (vertical position enlarged screen 66) on the focusing screen 18 is observed, the imaging lens 19 and the variable aperture 2A of the field frame 21 are set to the state shown in FIG. The state in the viewfinder field is as shown in FIG. In this case, the state of the imaging lens 19 is the same as in FIG. 6B, and the variable aperture 2A of the field frame 21 is in a vertical position obtained by rotating the variable aperture 2A of FIG. 6B by 90 degrees. The diagonal length S1 of the variable aperture 2A is the same as that in the standard state, and is smaller than the diagonal length S2 of the secondary image 10B. Therefore, the peripheral portion of the secondary image 10B is shielded, and only the central portion of the diagonal length S1 can be enlarged and observed inside the field frame image 21B corresponding to the field frame 21 in the vertical position state. When observing such a lateral position enlargement screen 66, it is preferable to move the left information display 62 and the right information display 63 and arrange them in the vicinity of the field frame image 21B.

  Further, when magnifying and observing the entire screen 60 (FIG. 6A) of the subject image on the focusing screen 18, the imaging lens 19 and the variable aperture 2A of the field frame 21 are in the state shown in FIG. 6D. The state in the finder field is as shown in FIG. In this case, the state of the imaging lens 19 is the same as in FIGS. 6B and 6C, and the variable aperture 2A of the field frame 21 is in a lateral position in which the variable aperture 2A of FIG. 6B is enlarged. The variable aperture 2A and the secondary image 10B have substantially the same diagonal length S2. Therefore, the entire screen 60 of the subject image on the focusing screen 18 can be enlarged and observed inside the field frame image 21C corresponding to the enlarged lateral position state. That is, it is possible to obtain the same observation state when the magnification of the eyepiece lens 23 is increased while maintaining the state of the imaging lens 19 and the field frame 21 in the state of FIG. However, in the case of FIGS. 6D and 7D, the entire screen 60 is enlarged without enlarging the size of the viewfinder field (corresponding to the field of view of the eyepiece lens 23). The information displays 62 and 63 may not be arranged.

  Further, in the optical viewfinder device (18 to 28) of the present embodiment, the variable aperture 2A of the field frame 21 is set in a square shape, and inside the field frame image 21D (FIG. 7 (e)) corresponding to this state, It is also possible to observe the central portion (square enlarged screen 67) of the subject image on the focusing screen 18. At this time, the size of the variable opening 2A is, for example, from the vertical position state of FIG. 6C, the vertical size is narrowed while the horizontal size is widened, and the diagonal length is the same as the diagonal length S1 in the standard state. It is preferable to adjust so that it becomes. The imaging lens 19 is preferably set in the middle of the states shown in FIGS. 6 (a) and 6 (c).

  As described above, when the aspect ratio of the variable aperture 2A is changed to an aspect ratio different from the standard state, the diagonal length of the variable aperture 2A is maintained at the same diagonal length S1 as that in the standard state, so that an optical image is displayed in the viewfinder field. And information display can be arranged without difficulty. The other aspect ratio state having the same diagonal length S1 as the standard state is not limited to the example of FIG. 7 (e), and the state of FIG. 7 (f) is also possible.

  In FIG. 7 (f), the variable aperture 2A of the field frame 21 is set in a horizontally long shape such as a cinemascope / panorama size, and the center of the subject image on the focusing screen 18 inside the field frame image 21E corresponding to this state. This is an example of observing a portion (horizontal enlarged screen 68). Also in this case, it is preferable to set the diagonal length of the variable opening 2A to the same diagonal length S1 as in the standard state. In order to obtain this state, for example, from the state of FIG. 6A, the size in the horizontal direction may be increased while the size in the vertical direction of the variable opening 2A is reduced. Further, it is preferable to enlarge the magnification of the imaging lens 19 so that the long side of the entire screen 60 overlaps the long side of the variable aperture 2A. Further, the left and right information displays 62 and 63 are preferably reduced. Even when observing such a horizontally enlarged screen 68, the optical image and the information display can be arranged without difficulty in the viewfinder field. In order to further enlarge the whole, it is only necessary to reduce only the size of the variable opening 2A in the vertical direction from the enlarged observation state of FIG. In this case, there is a possibility that information on the left and right sides of the screen cannot be displayed.

  As described above, in the optical viewfinder device (18 to 28) of the present embodiment, the imaging lens 19 is disposed between the focusing screen 18 and the eyepiece lens 23, and between the imaging lens 19 and the eyepiece lens 23. Since the field frame 21 is arranged on the screen, the degree of freedom of the arrangement of the field frame 21 is improved, and a sufficient space for moving the masks 41, 42, 45, 46 of the field frame 21 is secured, and an increase in the size of the entire apparatus is avoided. can do. Of course, interference between the masks 41, 42, 45, 46 of the field frame 21 and the shutter 13 can also be avoided. Therefore, it is possible to increase variations when switching the observation range of the subject image on the focusing screen 18 while avoiding an increase in the size of the entire apparatus.

  Further, when the photographing operation is performed using the image sensor 14 after the observation of the subject image by the optical viewfinder device (18 to 28) of the present embodiment, the set magnification of the imaging lens 19 and the field frame 21 are variable. It is preferable to perform readout control of the image sensor 14 in accordance with the state of the opening 2A. It is conceivable to extract data of a part corresponding to the observation range of the subject image (either the whole area of the imaging area 4A or the partial areas 31 to 33) in the imaging area 4A (FIG. 2) of the imaging element 14.

  For example, when the entire screen 60 of the subject image is set as the observation range (FIGS. 7A and 7D), the signal reading area of the image sensor 14 is the entire imaging area 4A. When the central portion of the subject image (horizontal position enlarged screen 65) is set as the observation range (FIG. 7B), the signal reading area of the image sensor 14 is set as the partial area 31. Furthermore, when the central portion (vertical position enlarged screen 66) of the subject image is the observation range (FIG. 7C), the readout area of the image sensor 14 is the partial area 32. Further, in the case of the horizontally long enlarged screen 68 (FIG. 7F) of the subject image, the readout area of the image sensor 14 is the partial area 33.

  In the optical finder device (18 to 28) of the present embodiment, the variable aperture 2A of the field frame 21 can be completely blocked, and the entire secondary image 10B can be blocked. For example, in the mechanism of FIG. 5, the entire secondary image 10 </ b> B can be shielded by moving the vertical masks 41 and 42 in the direction of the arrow in FIG. 8 by the actuator 44. The same shielding may be performed using the masks 45 and 46 for the horizontal direction. In order to reliably shield the secondary image 10B as a whole, it is preferable to make the shielding area by the masks 41 and 42 (or masks 45 and 46) larger than the entire secondary image 10B.

  Thus, by shielding the entire secondary image 10B, the optical path between the imaging lens 19 and the eyepiece lens 23 can be blocked, and only information display by the display element 24 is observed within the viewfinder field. be able to. Accordingly, the shielding operation by the field frame 21 is performed according to the information displayed by the display element 24, the background is cut by shielding the entire secondary image 10B, and the information display by the display element 24 is favorably observed. Can do.

  In addition, the shielding operation by the visual field frame 21 is preferably performed when the photographer takes his eyes off the eyepiece lens 23 (for example, when taking a self-timer image of a subject). If the optical path is blocked by the field frame 21, it is possible to avoid a situation in which unnecessary light (reverse incident light) entering from the eyepiece lens 23 side is incident on the focusing screen 18 side from the field frame 21. For this reason, it is possible to prevent adverse effects such as stray light incident on a photometric system (not shown) installed in the optical viewfinder device (18-28). Self-timer photographing of the subject may be determined by the camera control circuit 16 in accordance with information from the operation unit 17 of the electronic camera 10, and the entire secondary image 10B may be blocked by controlling the field frame 21.

  Further, in the optical finder device (18 to 28) of the present embodiment, since the imaging lens 19 has a reduction magnification, the masks 41 and 42 (or masks 45 and 46) necessary to shield the entire secondary image 10B. ) Can be reduced, and the entire apparatus can be reduced in size. For example, if the magnification of the imaging lens 19 is 1/2 and the size of the entire screen 60 of the subject image on the focusing screen 18 is L, the size of the secondary image 10B is (1/2) × L. Even if the field frame 21 capable of shielding the entire screen is arranged, the entire size of the field frame 21 may be L. If it is not necessary to shield the entire screen, further downsizing is possible.

Furthermore, in the optical viewfinder device (18 to 28) of the present embodiment, since the imaging lens 19 can be scaled, the size and aspect ratio of the variable aperture 2A of the field frame 21 are changed, and at the same time, the imaging lens 19 is changed. By performing the doubling operation, only a necessary region on the focusing screen 18 can be enlarged and observed.
(Modification)
In the above-described embodiment, the field frame 21 is disposed between the imaging lens 19 and the optical path combining element 22 (FIGS. 1 and 3), but the present invention is not limited to this. In addition, as shown in FIG. 9, the field frame 21 may be disposed between the optical path synthesis element 22 and the eyepiece lens 23.

  Further, when the field frame 21 is arranged immediately before the eyepiece lens 23 as shown in FIG. 9, the eyepiece lens 23 is made detachable, and when the eyepiece lens 23 is removed, a shielding operation by the field frame 21 is performed. It is preferable to shield the entire secondary image 10B. The attachment / detachment state of the eyepiece 23 may be determined by the camera control circuit 16 in accordance with information from the operation unit 17 of the electronic camera 10, and the field frame 21 may be controlled to block the entire secondary image 10B.

Further, the shielding operation by the visual field frame 21 may be performed when it is considered that the photographer's eyes have moved away from the eyepiece 23, such as when a remote control input is made to the electronic camera 10, or by manual operation. Depending on
In the above-described embodiment, the example in which the image sensor 14 is an XY address type image sensor (for example, a CMOS image sensor) has been described, but the present invention is not limited to this. The present invention can also be applied when the image sensor 14 is a CCD image sensor. In the case of a CCD image pickup device, signals of all pixels are always read out, and during processing in the image processing circuit 15, data of a portion corresponding to the observation range of the subject image is extracted, and captured images having different sizes and aspect ratios are extracted. Just generate.

  Furthermore, the present invention can also be applied to the case where the imaging lens 19 has an enlargement magnification or the magnification of the imaging lens 19 is 1. The present invention can also be applied when the magnification of the imaging lens 19 is fixed. Furthermore, the present invention can also be applied to a single-lens reflex camera in which a silver salt film is disposed instead of the image sensor 14.

1 is a diagram illustrating a configuration of an electronic camera 10. FIG. 3 is a diagram illustrating a reading area of the image sensor 14. It is a perspective view which shows the structure of the optical finder apparatus (18-28) of this embodiment. FIG. 6 is a diagram for explaining a scaling operation by the imaging lens 19; 3 is a perspective view illustrating a configuration example of a field frame 21. FIG. It is a figure explaining the relationship between the magnification of the imaging lens 19 and the change of the field frame 21. FIG. It is a figure which shows the variation of the optical image in a finder visual field, and information display. It is a figure explaining the shielding operation by the visual field frame. It is a perspective view which shows the modification of arrangement | positioning of the visual field frame.

Explanation of symbols

10 electronic camera; 18 focusing plate; 19 imaging lens; 21 field frame; 2A variable aperture;
23 eyepieces; 24 display elements; 18-28 optical viewfinder device; 10B secondary image;
14 image sensors; 15 image processing circuits; 16 camera control circuits

Claims (7)

In an optical viewfinder device including a focusing screen and an eyepiece,
An imaging lens disposed between the focusing screen and the eyepiece, and forming a secondary image of a subject image formed on the focusing screen;
A variable aperture disposed between the imaging lens and the eyepiece lens, disposed on the secondary image forming surface and capable of independently changing the sizes in two directions perpendicular to each other; A field frame that regulates the secondary image and can shield the entire secondary image ;
The field frame is provided with two masks for changing the vertical size of the variable aperture, and two masks for changing the horizontal size of the variable aperture ,
The eyepiece is detachable,
The optical field finder device , wherein the field frame is disposed immediately before the eyepiece lens and shields the entire secondary image when the eyepiece lens is removed . The optical finder apparatus according to claim 1,
The two directions correspond to the vertical and horizontal directions of the subject image on the focusing screen. The optical finder apparatus according to claim 1 or 2,
The variable aperture of the field frame has a standard state having the same aspect ratio as the aspect ratio when the subject image is substantially maximized on the focusing screen, and another aspect having the same diagonal length as the standard state. An optical finder device that can be changed to a ratio state. In the optical finder device according to any one of claims 1 to 3,
Display means for displaying predetermined information;
A combining unit disposed between the field frame and the eyepiece, and superimposing the information on a secondary image regulated by the field frame;
The optical viewfinder device , wherein the field frame blocks the entire secondary image according to information displayed by the display means . An optical finder device according to any one of claims 1 to 4 ,
An electronic camera comprising: an image sensor that captures the subject image . The electronic camera according to claim 5,
An electronic camera comprising extraction means for extracting data of a portion corresponding to the observation range of the secondary image in the imaging area of the imaging device . The electronic camera according to claim 5 or 6 ,
An electronic camera comprising control means for controlling the field frame to shield the entire secondary image when a subject is photographed by a self-timer .

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