JP3374634B2 - Variable magnification finder device and adjustment method thereof - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable power viewfinder device and an adjusting method thereof, and more particularly to a device suitable for a real image type variable power viewfinder device of a camera and an adjusting method thereof.

[0002]

2. Description of the Related Art In recent years, cameras have become more compact, and for this reason, it is required that the viewfinder device of the camera also has a smaller volume than the conventional one. In order to reduce the volume of the finder device, it is generally effective to shorten the focal length of the objective optical system to reduce the objective image formed by the objective optical system. By adopting this method, the objective image of a recent compact viewfinder device tends to be small.

That is, for example, the focal length Fa of the objective optical system 2a of the finder optical system shown in FIG. 1 (A) is 1/2 as shown in FIG. 1 (B), that is, Fb = Fa / 2.
Then, the objective image 4b formed on the image plane of the objective optical system 2b
Is also half the size of the objective image 4a in FIG. Then, the image inversion system 6b for inverting the objective image 4b, for example, the Porro prism 6 shown in the perspective view of FIG.
If becomes smaller, it can be made smaller accordingly. Therefore, to make the finder device compact, it is very effective to shorten the focal lengths Fa and Fb of the objective optical systems 2a and 2b.

[0004] However, the finder magnification ratio of the focal length F ₁ and the focal length F ₂ of the ocular optical system of the objective optical system, that is determined by the F ₁ / F _2, only has a small objective image of the objective optical system Then, the finder magnification becomes small, and it becomes difficult to observe the finder image. Therefore, in accordance with the focal distance F ₁ of the objective optical system, by increasing the magnification of the eyepiece and shorter focal length F ₂ of the ocular system, it is necessary to prevent a decrease in the finder magnification.

[0005] That is, it is possible to by shortening the focal length F ₂ of the focal length F ₁ and the ocular optical system of the objective optical system, while ensuring the same finder magnification as the conventional device, reduce the size of the finder device .

However, this makes the viewfinder diopter very sensitive to errors. That is, as the focal length becomes shorter, the influence of the error on the viewfinder diopter becomes relatively large. Therefore, in order to keep the influence of the error as in the conventional case, very high precision may be required for the component parts, or it may not be possible to deal with it only by improving the component precision. In this way, when the error sensitivity is high, the adjustment means is generally used.

For example, as a means for correcting the diopter deviation, there are many finder devices each having a diopter adjusting function which can be adjusted by the user. However, since this diopter correction is a diopter correction only for the eyepiece optical system, the diopter shift between the objective image and the field frame or the diopter of the objective image between tele and wide in the variable power finder device. Misalignment and the like are not corrected (here, tele refers to the telephoto side, that is, the long focus side, and wide refers to the wide angle side, that is, the short focus side). Therefore, it is necessary to adjust not only the diopter of the eyepiece optical system but also the diopter of the objective optical system. For example, Japanese Patent Laid-Open No. 5-134
In the device disclosed in Japanese Patent No. 295 and several kinds of commercially available compact cameras, such diopter adjustment of the objective optical system is performed by adjusting one part of the objective optical system. .

However, in recent compact cameras, zoom devices have become the mainstream, and the zoom magnification ratio is being expanded.
As the zoom ratio increases, so does the tele and wide ratio of error sensitivity. In a zoom variable power finder device having a large variable power ratio, as described in Japanese Patent Application Laid-Open No. 5-134295, the telescopic and wide error amounts of diopter are greatly different, and the diopter of only telephoto or wide is set. There may be cases where adjustment is not enough. For example, when the diopter adjustment is performed for the wide angle, the tele adjustment may be insufficient, while when the diopter adjustment is performed for the tele angle, the wide adjustment may be over-adjusted. this is,
This is due to the fact that the diopter error sensitivity changes due to zooming, and this tendency becomes more pronounced as the zoom ratio increases. Therefore, particularly in a variable power finder device having a large variable power ratio, it is not possible to achieve sufficient diopter adjustment only by adjusting one position of the objective optical system as in the conventional case.

[0009]

SUMMARY OF THE INVENTION Therefore, a first technical problem to be solved by the present invention is to provide a variable power finder device capable of excellent diopter correction in the entire finder variable power range. A second technical problem is to provide a simple diopter adjustment method for a variable power device in which the error sensitivity of diopter changes due to zooming.

[0010]

According to the present invention, in order to solve the above technical problems, a variable power finder device having the following structure and a variable power finder device thereof are provided.
And a camera with a device.

The variable power finder device includes an objective optical system and an eyepiece optical system. The variable power finder device includes a first diopter adjusting mechanism that adjusts a diopter difference between the diopter of the finder image in the tele state and the diopter of the finder image in the wide state, and a diopter of the finder image in the tele state and the wide state. And a second diopter adjustment mechanism that uniformly adjusts the diopter of the finder image in FIG.

In the above arrangement, the first diopter adjusting mechanism can adjust the diopter of the finder image in the tele state and the diopter of the finder image in the wide state to be equal. The second diopter adjustment mechanism allows the finder diopter to be uniformly adjusted over the entire zoom range. That is, the finder diopter can be adjusted at the same time in the entire zoom range, and the adjustment amounts are equal or approximately equal in the entire zoom range.

Therefore, the first diopter adjustment for adjusting the diopter difference of the finder image in the tele state and the wide state, and the second diopter adjustment for uniformly adjusting the diopter of the finder image in the tele state and the wide state. By performing the adjustment and the adjustment respectively, it is possible to excellently correct the diopter in the entire range of the magnification change of the finder.

Preferably, the first diopter adjusting mechanism adjusts the diopter change amount of the finder image in the tele state and the diopter change amount of the finder image in the wide state when independently moved in the optical axis direction. It is an adjusting mechanism that moves a part of the constituent group of the objective optical system that causes a difference in the optical axis direction. The second diopter adjusting mechanism is an adjusting mechanism that moves all the constituent groups on the objective side of the moving group of the objective optical system closest to the eyepiece side in the optical axis direction while maintaining the mutual positional relationship.

In the above structure, a part of the constituent groups of the objective optical system which is moved by the first diopter adjusting mechanism changes the diopter between the tele state and the wide state when only a part of the constituent groups is moved. By choosing the quantities to be very different,
The first adjustment mechanism can efficiently adjust the diopter difference between the tele state and the wide state. On the other hand, since the second diopter adjusting mechanism moves as a whole while maintaining the mutual positional relationship of the moving groups, the diopter change due to the adjustment becomes equal in the tele state and the wide state. That is, when the adjustment is performed by the second diopter adjustment mechanism, this adjustment does not cause a new diopter difference between the tele state and the wide state. Therefore, it is possible to simplify the diopter adjustment process. Preferably, the first diopter adjustment mechanism is an adjustment mechanism that moves the most object-side component group of the objective optical system in the optical axis direction.

In the above structure, the first diopter adjusting mechanism is
Since only the component group closest to the objective is moved, the number of component groups to be moved is small and the configuration is simple. Further, it can be easily configured to be moved from the outside.

The present invention also includes an adjusting method for the variable power finder device and an adjusting method for the variable power finder device.
And a method of adjusting the camera .

This adjusting method is a method of adjusting a variable power finder device having an objective optical system and an eyepiece optical system. In this adjustment method, the objective optical system is set in a wide state, and the movable group closest to the eyepiece side among the movable groups of the objective optical system.
And all structures closer to the objective than the moving group closest to the eyepiece.
The Narugun, by moving in the optical axis direction while maintaining a mutual positional relationship, a first step of adjusting the diopter of the objective optical system in a predetermined diopter, and the objective optical system in the telephoto state, the objective By moving a part of the optical system in the optical axis direction, the predetermined diopter of the objective optical system is a target value when the diopter of the objective optical system is adjusted in the first step. A second step of adjusting the diopter.

In the above structure, the diopter change amount when a part of the objective optical system is moved in the optical axis direction has a large difference between the tele state and the wide state, and the diopter in the tele state is large. In the case of the viewfinder device in which the amount of change is larger than the amount of change in diopter in the wide state, the tele state is adjusted in the first step as the wide state by uniformly adjusting the diopter in the tele state and the diopter in the wide state. It is possible to reduce the influence of the part having high sensitivity. That is, when the positions of some of the constituent groups of the objective optical system deviate from the normal positions and a large difference in diopter change amount occurs between the tele state and the wide state, the diopter shift in the tele state, that is, The degree error is larger than the diopter error in the wide state. Therefore, the influence of the diopter error can be reduced by performing the above adjustment in the wide state. The second step adjusts to the same predetermined diopter as the first step. Therefore, it is possible to simplify the diopter adjustment method of the variable power viewfinder device.

In the above structure, the diopter of the objective optical system in the tele state adjusted in the first step is slightly changed by the adjustment in the wide state in the second step, and the adjustment in the tele state is performed. It may shift.

Preferably, before the first step, there is further provided a first preliminary step for measuring the diopter of the eyepiece optical system. In the first step, the predetermined diopter that is a target when adjusting the diopter of the objective optical system is the diopter of the eyepiece optical system measured in the first preliminary step.

In the above structure, the diopter of the objective optical system can be matched with the diopter of the eyepiece optical system by the first preliminary step. Therefore, there is no difference in diopter between the subject image and the field frame, and it is possible to observe both of them clearly and simultaneously.

Preferably, before the first step, there is further provided a second preliminary step for adjusting, to an initial position, the constituent group of a part of the objective optical system adjusted in the second step.

In the above structure, the initial error can be reduced by adjusting a part of the constituent group of the objective optical system to be adjusted in the second step to the initial position in advance in the second preliminary step. This reduces the adjustment amount in the second step. Therefore, by the adjustment in the second step, it is possible to reduce the deviation of the diopter of the objective optical system in the wide state adjusted in the first step, and it is possible to perform the diopter adjustment with higher accuracy in the entire zoom range. .

The present invention also provides another adjusting method for the variable power finder apparatus.

This adjusting method is a method of adjusting a variable power finder device having an objective optical system and an eyepiece optical system. This adjusting method comprises a first step of measuring the diopter of the objective optical system by setting the objective optical system in a wide state.
By setting the objective optical system in the tele state and moving some of the constituent groups of the objective optical system in the optical axis direction, the diopter of the objective optical system in the wide state measured in the first step is described above. The second step of adjusting the diopter of the objective optical system, and the above- mentioned pair with the objective optical system in the tele state .
Of the moving groups of the object optical system, the moving group closest to the eye and the
Also, the third step of adjusting the diopter of the objective optical system to a predetermined diopter by moving all the constituent groups on the objective side of the moving group on the eyepiece side in the optical axis direction while maintaining the mutual positional relationship. Equipped with.

In the above construction, the diopter difference between the tele state and the wide state is adjusted first, and then the diopter in the tele state and the wide state is uniformly adjusted, so that the diopter can be adjusted with higher precision. Becomes

[0028] Preferably, before the second step,
A first preliminary step of measuring the diopter of the objective optical system by setting the objective optical system in the tele state, and the diopter in the wide state and the tele state measured in the first step and the first preliminary step. First, a difference is obtained, and the diopter of the objective optical system when the difference in diopter is resolved by moving a part of the constituent group of the objective optical system in the optical axis direction as an adjustment target value. 2 preliminary steps are further provided. In the second step, instead of adjusting the diopter of the objective optical system to the diopter of the objective optical system in the wide state measured in the first step, the adjustment target value obtained in the second preliminary step Adjust to.

In the above configuration, in the second preliminary step, adjustment is performed to move a part of the objective optical system in the optical axis direction based on the diopter in the wide state and the telephoto state and the adjustment sensitivity characteristic of the objective optical system. By predicting the diopter change of the objective optical system in the tele state and the wide state, the adjustment target value for matching the diopter in the tele state and the wide state is obtained. Since the configuration of the objective optical system to be adjusted is predetermined, the amount of movement of a part of the configuration group of the objective optical system, the diopter change amount of the objective optical system in the wide state and the tele state caused by the movement, , That is, the adjustment sensitivity characteristic is known. Therefore, various values when canceling the diopter difference of the objective optical system in the wide state and the tele state before adjustment, that is, the movement amount of a part of the constituent group of the objective optical system and the objective in the wide state and the tele state The diopter change amount of the optical system and the diopter of the objective optical system after adjustment can be obtained. In the second step, the diopter of the objective optical system after the adjustment is used as the adjustment target value, but the amount of movement of a part of the objective optical system or the diopter change of the objective optical system in the wide state or the tele state. Even if the amount is the adjustment target value, it is substantially the same. In the second step,
The diopter of the objective optical system is adjusted so as to reach the adjustment target value obtained in the second preliminary step. In other words, the adjustment is performed in consideration of the diopter change in the wide state that occurs with the adjustment in the tele state. Therefore, the diopter in the tele state and the diopter in the wide state match with each other more accurately, and the diopter can be adjusted with higher accuracy.

Preferably, before the third step,
The method further comprises a preliminary step of measuring the diopter of the eyepiece optical system. The predetermined diopter, which is a target value for adjusting the diopter of the objective optical system in the third step, is the diopter of the eyepiece optical system measured in the preliminary step.

In the above structure, the preliminary step
It is possible to match the diopter of the objective optical system with the diopter of the eyepiece optical system. Therefore, there is no difference in diopter between the subject image and the field frame, and it is possible to observe both of them clearly and simultaneously.

[0032]

BEST MODE FOR CARRYING OUT THE INVENTION The finder device according to each embodiment of the present invention will be described in detail below with reference to FIGS.

First, the basic principle of the present invention will be described. For simplification, here, as shown in the optical system configuration diagram of FIG. 3, an explanation will be given by taking two groups of objective systems − + as an example.

In general, the finder device is often arranged inside the body of the camera, and in most cases, it does not collapse. Therefore, unlike the shooting optical system,
It is required to have a structure with a short overall length over the entire zoom range. In order to shorten the total length of the objective optical system, in the case of the two-group configuration of − +, the zoom solution of the complete U-turn of one group is the shortest. In the case of other objective optical system configurations as well, in order to shorten the total length of the finder as in this example, when the first group moves, movement close to a U-turn or fixed first group is often used.

The image forming relationship of the objective optical system at this time is shown in FIG.
As shown in. That is, the wide shown in FIG.
In the state, the second group imaging magnification is b_W/ A_WBecomes Where 1
Group 2_SFocal plane 2_CAnd 2 groups 2_TThe distance between_W2 groups 2
_TAnd the distance between the objective image plane 3 and b_WAnd Similarly, FIG.
In the telephoto state shown in (B), the second-group imaging magnification is b_T/ A _TWhen
Become. Where 1 group 2_SFocal plane 2_CAnd 2 groups 2_TBetween
Distance a_T2 groups 2_TAnd the distance between the objective image plane 3 and b_TWhen
To do. a_T= B_W, A_W= B_TWhen, 1 group 2_SIs a cam song
Line 2_XAs shown in, it makes a U-turn.

[0036] As indicated by the dotted line in the optical system configuration diagram of FIG. 4, misalignment of the first group 2 _S, i.e. 1 group 2 focal point of _S 2
_{When D} is displaced, the position of the objective image plane 3 is displaced. Due to this change in the position of the objective image plane 3, the eyepiece optical system 5
As a result, the direction of the light beam 7 that reaches the observer's pupil 8 changes, and the viewfinder diopter changes. In this way, the amount of displacement of the objective image plane 3, which causes the change in the finder diopter, is determined by the second group imaging magnification in each of the tele state and the wide state. The ratio of the amount of deviation of the objective image plane 3 between the tele state and the wide state is 2 between the tele state and the wide state.
It is proportional to the square of the ratio of the group imaging magnification.

When the position of the first group 2 _S is the same in the telephoto state and in the wide-angle state, the ratio of the image forming magnification of the second group is equal to the viewfinder variable magnification ratio. Therefore, the diopter change amount between the tele state and the wide state due to the position degree of the first group 2 _S (in this case, the interval error between the first group 2 _{S and the} second group 2 _T ) is proportional to the square of the viewfinder magnification ratio. To do. As described above, in the case of the finder device, the position of the first lens group 2 _S does not change much between the telephoto state and the wide-angle state, so the above relationship is substantially established.

Therefore, as is apparent from the configuration diagram of the optical system of FIG. 4, the adjustment for moving the entire objective optical system (in this case, the movement of the set of the first group 2 _S and the second group 2 _T ) is variable. Uniform diopter correction is performed over the entire area. In addition, adjustment to move a part of the objective optical system (in this case, move only 1 group 2 _S )
Is a diopter correction of a diopter difference due to zooming between the tele state and the wide state.

Next, the configuration of the finder apparatus 1 according to the first embodiment of the present invention will be described with reference to FIGS.

This finder device 1 is a real image type variable magnification finder device of a camera. As shown in the optical system configuration diagram of FIG. 5, the finder optical system 10a of the finder device 1 includes an objective optical system 12a that forms a subject image on an image forming surface 16a and an object optical system 12a that magnifies the subject image. Pupil 18
The eyepiece optical system 14a can be broadly divided into two types.

The objective optical system 12a has a three-group structure of −, +, +, and has a first lens group 22a having negative power, a second lens group 24a having positive power, and positive power. The objective side inversion system 31a. That is, the positive power of the three groups of the objective optical system 12a is the objective side inversion system 31a.
It is integrated with. The eyepiece optical system 14a includes an eyepiece side reversing system 32a and an eyepiece lens 42a. The first lens group 22a and the second lens group 24a form an objective system 20a. The objective side inversion system 31a and the eyepiece side objective system 32a are
Inversion system 3 for inverting the subject image on the image plane 16a
Make up 0a. In this finder optical system 10a, the first and second lens groups 22a and 24a are
It moves as shown by the cam curves 22x and 24x between the wide state shown in FIG. 5 (A) and the tele state shown in FIG. 5 (B). The finder magnification of the finder optical system 10a having the above configuration is 1.23 in the tele state, 0.46 in the wide state, and the zoom ratio thereof is 2.67.

In the finder optical system 10a having the above structure, if an error occurs in the distance between the adjacent components in the optical axis direction, the finder diopter changes. FIG. 6 shows that the distance between adjacent components is 0 in the wide state and the tele state.
It is a graph showing the result of analyzing how the viewfinder diopter changes with respect to the design value when an error of 1 mm is given. The unit of the vertical axis in the figure is diopter. As can be seen from this graph, the diopter change amount in the wide state is the smallest between the first and second groups 23a. The diopter change in the tele state is 23a between the first group and the second group.
Is the largest in. Then, between the first group 2 and the second group 23a, the diopter change amount in the tele state is the square of the viewfinder magnification of the diopter change amount in the wide state (that is, 2.67 ² =
It is about 7.1 times), and the difference in diopter change amount between tele and wide is very large. On the other hand, between the second group and the inversion 34a, between the image planes 3
8a, between the reversal and the eyepiece 44a, the diopter change amount is the same in the wide state and the tele state.

From this result, for the first diopter adjustment for adjusting the diopter difference between the wide state and the tele state, a difference in the amount of diopter change occurs between the tele state and the wide state. ~ 2
It can be seen that it is sufficient to change the distance between the groups 23a. That is, the first lens group 22a may be configured to be independently movable in the optical axis direction.

On the other hand, for the second diopter adjustment for uniformly adjusting the diopter of the objective image and the field frame to be the same in the entire range from telephoto to wide zooming, the telescopic state and the wide state are used for visual adjustment. It can be seen that the interval between the second group and the inversion 34a having the same degree of change may be changed. That is, the first lens group 2
2a and the second lens group 24a may be configured to be integrally movable in the optical axis direction while maintaining the relative positional relationship.
It is possible to perform the second diopter adjustment depending on the distance between the image planes 38a, but if this is done, the number of moving constituent elements increases and the configuration becomes complicated. Therefore, it is preferable to adjust the interval between the second group and the inversion 34a.

Next, a specific structure of the finder device 1 will be described with reference to FIGS.

In the finder device 1, the first lens group 22a, the second lens group 24a, and the objective side reversing system 31a are housed inside the base plate 50, as shown in the sectional view of the main part of FIG. It A viewfinder window 54 is provided on the front wall 54 of the base plate 50.
a is open, and the first lens group 22a faces the finder window 54a. The first lens group 22a is supported by the first lens group holder 60, the second lens group 24a is supported by the second lens group holder 62, and the objective side inversion system 3
1a is supported by the intermediate wall 56 of the base plate 50. A protrusion 60 is provided on the first and second lens group holders 60 and 62.
a and 62a are formed, and through holes 60b and 62b are formed in the lower part. First and second lens group holders 60, 6
The two protrusions 60a and 62a slidably fit into the straight guide grooves 52a and 52b formed in the upper wall 52 of the base plate 50 in the optical axis direction, while the through holes 60b and 62b include the base plate 50. A guide shaft 68, which is supported by the front wall 54 and the intermediate wall 56 and extends in the optical axis direction, is inserted. As a result, the first and second lens group holders 60 and 62 can be moved in the optical axis direction without rotating in the circumferential direction. Also,
First lens group holder 60 and second lens group holder 62
Are connected by a biasing spring 66 and are biased so as to approach each other. Further, the first lens group holder 60 has an engaging hole 60d formed in the rear surface in the vicinity of the through hole 60b, and has a female screw portion 60c penetrating in the optical axis direction at the lower portion. An adjusting screw 70 is screwed into the female screw portion 60c from the front, and the screw head 7 of the adjusting screw 70 is provided on the front side of the female screw portion 60c.
0b, the tip 70a of the adjusting screw 70 is arranged on the rear side.
A through hole 54b is formed in the front wall 54 of the base plate 50 so that the screw head 70b of the adjusting screw 70 can be accessed from the outside. Further, the second lens group holder 62 is
It has a cam follower portion 62c at its lower portion.

A cam follower member 64 is arranged between the first lens group holder 60 and the second lens group holder 62. The cam follower member 64 has a through hole 64a,
It has an engagement protrusion 64b that protrudes to the front side in the optical axis direction, a cam follower portion 64c formed on the lower portion of the rear surface, and a screw contact portion 64d formed on the lower portion of the front surface. Cam follower member 6
4, the guide shaft 68 is inserted into the through hole 64a, and the cam follower member 6 is inserted into the engaging hole 60d of the first lens group holder 60.
The engaging protrusion 64b of No. 4 engages. The tip 70a of the adjusting screw 70 screwed into the female screw portion 60c of the first lens group holder 60 has a screw contact portion 64d of the cam follower member 64.
Abut.

Below the guide shaft 68, a cam member 72 having a cam portion 72b which is in sliding contact with the cam follower portion 64c of the cam follower member 64 and the cam follower portion 62c of the second lens group holder 62 is arranged. This cam member 72
Has a cam portion 72b and a gear portion 72a, as shown in the perspective views of FIGS. 13 and 15, and the cam portion 72b is shown in FIG.
As shown in the cam development diagram of FIG.
Cam surfaces 72c and 72d corresponding to the cam curves 22x and 24x of 2a and 24a (see FIG. 5) are formed. The cam member 72 is fixed to the intermediate shaft portion 74b of the cam shaft 74 extending in the optical axis direction by E-rings 78a and 78b so that the cam member 72 cannot move axially and is rotatable. Specifically, the cam shaft 74 is the intermediate shaft portion 7.
It has a screw portion 74a and a screw head 74c in front of and behind 4b.
The screw portion 74a of the cam shaft 74 is screwed into the female screw portion 76a of the nut member 76 fixed to the intermediate wall 56 of the base plate 50, while the screw head 74c side of the intermediate shaft portion 74b is the front wall of the base plate 50. The screw head 74c is supported by the base plate 54 and is disposed outside the front wall 54 of the base plate 50. On the front wall 54 of the base plate 50,
A drive gear 80 that is screwed into the gear portion 72a of the cam member 72 is arranged. The drive gear 80 is connected to a lens driving device (not shown).

In the above structure, the first lens group holder 60 and the second lens group holder 62 are biased by the biasing spring 66 so as to approach each other. The first lens group holder 60 urges the cam follower member 64 toward the second lens group folder 62 side via the adjusting screw 70 screwed to the female screw portion 60c. Therefore, the cam follower portion 64c of the cam follower member 64 and the cam follower portion 62c of the second lens group holder 62 always hold the cam portion 72b of the cam member 72, and the cam surfaces 72c, 72d of the cam portion 72b of the cam member 72 are held. Slide on. Therefore,
When the cam member 72 is rotated by the drive gear 80, the first and second lens group holders 60 and 62 move along the cam surfaces 72c and 72d of the cam portion 72a of the cam member 72. That is, the finder device 1 is zoomed.

In the above structure, the diopter adjustment of the finder device 1 is performed from the front of the finder device 1 by the adjusting screw 70 and the cam shaft 74.

That is, the through hole 54 in the front wall 54 of the base plate 50 of the finder device 1 shown in the side view of the main part of FIG.
When the screw head 70b of the adjusting screw 70 is accessed from b and the adjusting screw 70 is rotated, the protrusion amount of the tip 70 of the adjusting screw 70 is changed, and the relative distance between the first lens group holder 60 and the cam follower member 64 is changed. Change. As a result, only the first lens group 22a moves in the optical axis direction with respect to the other elements of the finder optical system 10a. That is, 1 group to 2
The distance between the groups 23a can be changed. Therefore, it is possible to perform the first diopter adjustment by rotating the adjusting screw 70.

On the other hand, when the screw head 74c of the cam shaft 74 on the outside of the base plate 50 is rotated, the cam shaft 74 moves in the axial direction due to the screw engagement with the nut member 76. As a result, the cam member 72 is moved in the axial direction, so that the first and second
The lens group holders 60, 62 are moved in the optical axis direction as a whole while maintaining a mutual interval. That is, the interval between the second group and the inversion 34a can be changed. Therefore, it is possible to perform the second diopter adjustment by rotating the screw head 74c of the cam shaft 74.

Next, the finder device of the second embodiment having another finder optical system 10b will be described with reference to FIGS. The second embodiment is
Since the configuration is substantially similar to that of the first embodiment, the differences will be mainly described below.

The objective optical system 12b of this embodiment has +,
The first lens group 22b has a positive power, and the second lens group 24b has a negative power.
A third lens group 26b having a negative power, a fourth lens group 28b having a positive power, and an objective side inversion system 31b.
Consists of. The eyepiece optical system 14b is an eyepiece side inversion system 32b.
And an eyepiece lens 42b. As a result of zooming, the second and third lens groups 24b and 26b are moved to the position shown in FIG.
It moves as shown by the cam curves 24y and 26y between the wide state shown in Fig. 7 and the tele state shown in Fig. 7B. The finder magnification of the finder optical system 10b configured as described above is 1.3 in the telephoto state, and 0.1 in the wide state.
4, and the zoom ratio is 3.25.

With respect to the finder optical system 10b having the above-described structure, when the error of 0.1 mm is given to the distance between the adjacent components in the wide state and the tele state, how is the finder diopter against the designed value? The result of analyzing whether it changes is shown in the graph of FIG. As can be seen from this graph, between the first and second groups 23b,
The difference in the amount of diopter change between the wide state and the tele state is the largest. In addition, 25b between the second and third groups, 27b and 4b between the third and fourth groups.
In the group-reversal 34b, the image plane 38b, and the reversal-eyepiece 44b, the diopter change amount between the wide state and the tele state is the same or the difference is very small.

From this result, in the first diopter adjustment for adjusting the diopter difference between the wide state and the tele state, the first group having the largest difference in diopter change amount between the tele state and the wide state can be used. It can be seen that it is sufficient to change the distance between the two groups 23b. That is, the first lens group 22b may be moved alone in the optical axis direction.

On the other hand, for the second diopter adjustment that uniformly adjusts the diopter of the objective image and the field frame to be the same in the entire range from telephoto to wide zoom, 27b between the third group and the fourth group, It can be seen that the distance between the fourth group and the inversion 34b or the distance between the image planes 38b may be changed, but it is preferable to change the distance between the third group and the fourth group 27b having the smallest number of moving constituent elements. That is, the first, second and third lens groups 22b, 24
It is sufficient to move b and 26b integrally in the optical axis direction while maintaining the relative positional relationship.

Such first and second diopter adjustments are
This can be achieved by configuring the finder device 1 as in the first embodiment described above, and thus detailed description thereof will be omitted.

Next, the finder device of the third embodiment having another finder optical system 10c will be described with reference to FIGS. Since the third embodiment is also configured substantially the same as the first embodiment, the difference will be mainly described below.

Finder optical system 10c of the third embodiment
The objective optical system 12c has a four-group structure of +, −, +, −,
A first lens group 22c having a positive power, a second lens group 24c having a negative power, a third lens group 26c having a positive power, and an objective side inversion system 31c having four groups of negative powers. Consists of. The eyepiece optical system 14c includes an eyepiece side inversion system 32c and an eyepiece lens 42c. Due to the magnification change, the second and third lens groups 24c and 26c are moved to the positions shown in FIG.
It moves as shown by the cam curves 24z and 26z between the wide state shown in FIG. 9 and the tele state shown in FIG. The finder magnification of the finder optical system 10c configured as described above is 2.0 in the tele state and is 0.0 in the wide state.
57, and the zoom ratio is 3.5.

In the finder optical system 10c having the above-described structure, when an error of 0.1 mm is given to the distance between adjacent components, how the finder diopter changes with respect to the design value in the wide state and the tele state. The result of analyzing whether or not to perform is shown in the graph of FIG. As can be seen from this graph, the difference in the diopter change amount between the first group and the second group 23c in the wide state and the tele state is the largest. Further, between the second group and the third group 25c, between the third group and the reversal 34c, between the image plane 38c, and between the reversal and the eyepiece 44c, the diopter change amount is the same in the wide state and the tele state, or Even if they are not the same, the difference is very small.

From this result, similarly, in the first diopter adjustment for adjusting the diopter difference between the wide state and the tele state, the difference in the diopter change amount between the tele state and the wide state is the largest. 1
It can be seen that it is only necessary to change the distance between the groups 2 to 23c. That is, the first lens group 22c may be independently moved in the optical axis direction.

On the other hand, for the second diopter adjustment for uniformly adjusting the diopter of the objective image and the field frame to be the same over the entire range from telephoto to wide magnification, in the fixed state of reversal to eyepiece. Other than that, that is, it is conceivable to change the distance between the second group to the third group 25c, the third group to the inversion 34c, or the image plane distance 38c. However, between the second group and the third group 25c, the amount of change differs between the wide state and the tele state, and the amount of change is small, and between the image planes 38c, the amount of change is small and the number of moving components increases, so the third group. It can be seen that it is sufficient to change the interval between the inversions 34c to 34c. That is, the first, second and third
The lens groups 22c, 24c, 26c may be moved integrally in the optical axis direction while maintaining the relative positional relationship.

Such first and second diopter adjustments are
This can be achieved by configuring the finder device 1 as in the first embodiment described above, and thus detailed description thereof will be omitted.

In each of the above embodiments, the first diopter adjustment is performed by moving the first lens groups 22a, 22b, 22c independently in the optical axis direction, and the second diopter adjustment is performed by the objective system 2
This is common in that all or part of the lens groups 0a, 20b, and 20c are moved in the optical axis direction while maintaining their relative positions. Therefore, the adjustment of the finder device 1 of each of the above-described embodiments will be described next. The procedure will be described collectively.

First, a diopter adjustment procedure in which the adjustment process is simple will be described with reference to the flowchart of FIG.

When the diopter adjusting step is started in step # 100, first, in step # 110, the first lens group 22a, which is a lens group independently moved by the rotation of the adjusting screw 70 which is the first adjusting mechanism. , 22b, 22c
Roughly adjust the initial position of. That is, the protrusion amount of the adjusting screw 70 is adjusted so that the relative distance between the first lens group holder 60 and the cam follower member 64 becomes a predetermined initial value. This enables highly accurate diopter adjustment. However, this step # 110 may be omitted. Next, in step # 112, the eyepiece optical system 14
The diopter of a, 14b, 14c is measured. This is to obtain the adjustment target value in the subsequent step # 130 .

Next, at step # 120, the objective optical systems 12a, 12b, 12c are set to the wide state. Next, in step # 130, the diopter adjustment of the objective optical systems 12a, 12b, 12c is performed by the second adjusting mechanism, that is, the cam shaft 74. Specifically, the rotation of the cam shaft 74 causes the lens groups 22a, 24a; 22b, 24b, 26b; 22c, 24c, 2 to move.
6c is moved as a whole, and the objective optical system 12a, 12b, 12c is moved.
Is adjusted so that it matches the diopter of the eyepiece optical systems 14a, 14b, 14c measured in step # 112 .

Next, at step # 140, the objective optical systems 12a, 12b and 12c are set to the tele state. Next, in step # 150, the diopter of the objective optical systems 12a, 12b, 12c is adjusted by the first adjusting mechanism, that is, the adjusting screw 70. At this time, the objective optical systems 12a, 12b, 12c in the wide state after adjustment in step # 130
The diopter is adjusted with the diopter as the target. by this,
The diopter in the tele state and the wide state substantially match.
That is, the diopter adjustment in the tele state in step # 150 causes the diopter in the wide state adjusted in step # 130 to shift. However, the deviation amount of the diopter in the wide state due to the diopter change in the tele state is approximately 1 / (finder magnification change ratio) ² of the diopter change amount in the tele state, as shown in FIGS. As shown in, the amount of diopter change in the tele state is very small. Therefore, even if the diopter in the telescopic state is deviated, it can be covered by the diopter adjusting power of the human eye. Next, in step # 160,
The diopter adjustment process ends.

In the diopter adjustment procedure of steps # 100 to # 160 described above, there is a large difference between the wide state and the tele state in the sensitivity of the diopter amount change to the adjustment of the distance between the first and second groups 23a and 23b. This is a simple adjustment procedure that has been successfully used.

Next, an adjustment procedure for performing more accurate adjustment will be described with reference to the flowchart of FIG.

When the diopter adjusting step is started in step # 200, first, in step # 210, the diopter of the eyepiece optical systems 14a, 14b, 14c is measured. This is to obtain the adjustment target value in the subsequent step # 280. However, this step # 210 may be omitted.

Next, in step # 220, the objective optical systems 12a, 12b, 12c are set to the wide state, and step #
At 230, the diopter of the objective optical system 12a, 12b, 12c is measured. The measurement data is used as data for calculating an adjustment target value at the time of diopter adjustment in step # 270 in step # 260 described later. Step # 26
If 0 is omitted, it is used as the adjustment target value in step # 270.

Next, in step # 240, the objective optical systems 12a, 12b, 12c are set in the tele state, and step # 2 is executed.
At 50, the diopter of the objective optical system 12a, 12b, 12c is measured. This measurement data is used in the next step # 260 as data for calculating the adjustment target value at the time of the diopter adjustment in step # 270. Next, in step # 260, the diopter of the objective optical systems 12a, 12b, 12c in the wide state and the tele state measured in step # 230 and step # 250, and the objective optical system 1
Based on the adjustment sensitivity characteristics of 2a, 12b, and 12c, the adjustment target value used in the diopter adjustment in step # 270 is calculated. The adjustment target value is adjusted by using the first adjustment mechanism so that the objective optical systems 12a, 12 in the wide state and the tele state can be adjusted.
It is obtained as the diopter when the diopters of b and 12c match. That is, by using the first adjusting mechanism, the objective optical systems 12a and 12a
The diopter change amount of the objective optical system 12a, 12b, 12c in the wide state and the tele state that changes when b and 12c are adjusted, and the objective optical system 12a, 12b, 12c in the wide state and the tele state caused by the adjustment. The diopter difference can be predicted based on the adjustment sensitivity characteristic that is predetermined by the configuration of the objective optical systems 12a, 12b, 12c. Therefore,
The diopter difference is obtained from the measured diopter in the tele state and the wide state, and the diopter difference required to cancel the diopter difference by the first adjusting mechanism and the diopter change amount in the wide state and the tele state are calculated. The diopter after the adjustment may be obtained as the adjustment target value from the measured diopter before the adjustment and the diopter change amount due to the adjustment. However, step # 250 and step # 260 may be omitted.

Next, in step # 270, the objective optical system 12a, 1 is set to the adjustment target value calculated in step # 260 by rotating the adjusting screw 70 which is the first adjusting mechanism.
Adjust the diopter of 2b and 12c. At this time, since the adjustment target value allows for the diopter change in the wide state associated with the adjustment, the diopter in the tele state and the wide state exactly match. When step # 250 and step # 260 are omitted, the diopter data in the wide state measured in step # 230 is used as the adjustment target value in step # 270. In this case, the diopter changes in the wide state due to the adjustment, but the process can be simplified.

Next, in step # 280, the cam shaft 74, which is the second adjusting mechanism, is rotated, and the above step # 2 is performed.
The diopters of the objective optical systems 12a, 12b, 12c are adjusted so as to match the diopters of the eyepiece optical systems 14a, 14b, 14c measured in 10. If step # 210 is omitted, the adjustment is made to match the predetermined diopter. Next, in step # 290, the diopter adjustment process is ended.

According to the above diopter adjustment procedure, the diopter difference between the wide state and the telephoto state is adjusted in step # 270. At this time, if the adjustment target value obtained in step # 260 is used, the diopter difference between the wide state and the tele state is completely eliminated, and more accurate adjustment can be performed over the entire zoom range.

The present invention is not limited to the above embodiments, but can be implemented in various other modes.
For example, it can be applied to a finder device having a finder optical system having another configuration.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of an optical system of a real image type finder device.

FIG. 2 is a perspective view of a Porro prism that constitutes the image inversion system of FIG.

FIG. 3 is a configuration diagram of an optical system of a real image type finder device.

FIG. 4 is a configuration diagram of an optical system of a real image type finder device.

FIG. 5 is an optical system configuration diagram of the finder device according to the first embodiment of the present invention.

FIG. 6 is a graph showing the influence of the error of each component of the finder device of FIG. 5 on the diopter.

FIG. 7 is an optical system configuration diagram of a finder device according to a second embodiment of the present invention.

8 is a graph showing the effect of errors of each component of the finder device of FIG. 7 on diopter.

FIG. 9 is an optical system configuration diagram of a finder device according to a third embodiment of the present invention.

FIG. 10 is a graph showing the influence of the error of each component of the finder device of FIG. 9 on the diopter.

FIG. 11 is a flowchart of a diopter adjustment procedure in which the adjustment process is simple.

FIG. 12 is a flowchart of a diopter adjustment procedure that enables more accurate adjustment.

13 is a cross-sectional view of a main part of the finder device in FIG.

14 is a side view of the finder device shown in FIG. 13. FIG.

FIG. 15 is a perspective view of a cam member of the finder device of FIG.

16 is a cam development view of the cam member of FIG. 15. FIG.

[Explanation of symbols]

1 Finder device 10a, 10b, 10c finder optical system 12a, 12b, 12c Objective optical system 14a, 14b, 14c Eyepiece optical system 16a, 16b, 16c Image plane 18 pupils 20a, 20b, 20c Objective system 22a, 22b, 22c First lens group 22x cam curve 23a, 23b, 23c between 1 group and 2 groups 24a, 24b, 24c Second lens group 24x, 24y, 24z cam curve 25b, 25c between 2 and 3 groups 26b, 26c Third lens group 26y, 26z cam curve 27b Between 3 and 4 groups 28b Fourth lens group 30a, 30b, 30c Inversion system 31a, 31b, 31c Objective side inversion system 32a, 32b, 32c Eyepiece side inversion system 34a between 2 groups and inversion 34b 4th group-inversion 34c between 3 groups and reversal 38a, 38b, 38c between image planes 40a, 40b, 40c eyepiece system 42a, 42b, 42c eyepieces 44a, 44b, 44c Inversion to eyepiece 50 base plate 52 Upper wall 52a, 52b Straight guide groove 54 front wall 54a viewfinder window 54b through hole 56 Middle wall 60 First lens group holder 60a protrusion 60b through hole 60c female thread 60d engagement hole 62 Second lens group holder 62a protrusion 62b through hole 62c Cam follower section 64 Cam follower member 64a through hole 64b engagement protrusion 64c Cam follower section 64d screw contact part 66 biasing spring 68 Guide shaft 70 Adjustment screw 70a tip 70b screw head 72 Cam member 72a gear part 72b Cam section 72c, 72d cam surface 74 Cam shaft 74a screw part 74b Intermediate shaft 74c screw head 76 Nut member 76a Female thread 78a, 78b E-ring 80 drive gear

Continuation of the front page (56) Reference JP-A-2-188732 (JP, A) JP-A-7-218986 (JP, A) JP-A-1-207727 (JP, A) JP-A-2-213811 (JP , A) Actual development Sho 61-2611 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB name) G03B 13/00-13/28 G02B 7/02

Claims (6)

(57) [Claims] 1. A method of adjusting a variable power finder device (1) comprising an objective optical system (12a, 12b, 12c) and an eyepiece optical system (14a, 14b, 14c), said objective optical system (12a , 12b, 12c) is set to a wide state, and the objective optical system (12a, 12b, 12c) is moved to the movable group.
The most moving group (24a; 26b; 26c) on the eyepiece side and
Is closer to the objective side than the moving group (24a; 26b; 26c) on the eyepiece side.
All constituent groups (22a, 24a; 22b, 24b, 26b; 22
(c, 24c, 26c) are moved in the optical axis direction while maintaining the mutual positional relationship, whereby the objective optical system (12a, 12c)
b, 12c) first step (#)
120, # 130) and the objective optical system (12a, 12b, 12c) in a tele state, and a part of the constituent group (22a, 22b, 22c) of the objective optical system (12a, 12b, 12c) is irradiated with light. By moving the objective optical system (12a, 12b, 12c) in the axial direction,
Second step (#) in which the diopter of the objective optical system (12a, 12b, 12c) is adjusted to the predetermined diopter which is a target value in the first step (# 120, # 130)
140, # 150) and before the first step (# 120, # 130), a first preliminary step (# 112) for measuring the diopter of the eyepiece optical system (14a, 14b, 14c) is performed. Further, in the first step (# 120, # 130), the predetermined diopter that is a target when adjusting the diopter of the objective optical system (12a, 12b, 12c) is the first preliminary step.
(# 112), the eyepiece optical system (14a, 1)
4b, 14c) is the above diopter, and a method of adjusting a variable power finder device is characterized. 2. The first step (# 120, # 130)
Before, the part of the constituent group (22a, 22b, 22c) of the objective optical system (12a, 12b, 12c) adjusted in the second step (# 140, # 150) is adjusted to the initial position. and further comprising a second preliminary step (# 110), the adjustment method of claim 1. 3. A method for adjusting a variable power finder device (1) comprising an objective optical system (12a, 12b, 12c) and an eyepiece optical system (14a, 14b, 14c), said objective optical system (12a , 12b, 12c) to a wide state and the first step (# 220, # 230) of measuring the diopter of the objective optical system (12a, 12b, 12c), and the objective optical system (12a, 12b, 12c). ) Is set in a tele state, and a part of the constituent groups (22a, 22b, 22c) of the objective optical system (12a, 12b, 12c) is moved in the optical axis direction, so that the objective optical system (12a, 12b, 12c) diopter
A second step (# 270) of adjusting the diopter of the objective optical system (12a, 12b, 12c) in the wide state measured in the first step (# 220, # 230), and the objective optical system (12a, 12b, 12c) in the tele state, the moving group of the objective optical system (12a, 12b, 12c)
Of these, the eyepiece side moving group (24a; 26b; 26c) and
The objective side from the moving group (24a; 26b; 26c) closest to the eyepiece side
All constituent groups of (22a, 24a; 22b, 24b, 26b; 2
2c, 24c, 26c) are moved in the direction of the optical axis while maintaining the mutual positional relationship, whereby the objective optical system (12a, 1c)
2b, 12c) third step of adjusting the diopter to a predetermined diopter
(# 280) is provided. A method for adjusting a magnification finder device, comprising: 4. Before the second step (# 270),
A first preliminary step (# 250) of measuring the diopter of the objective optical system (12a, 12b, 12c) with the objective optical system (12a, 12b, 12c) in a tele state, and the first step (# 220, # 230) and the above first
The difference in diopter between the wide state and the telephoto state measured in the preliminary step (# 250) is obtained, and the difference in diopter is a part of the configuration group of the objective optical system (12a, 12b, 12c).
The objective optical system (12a, 12b, 22c) is eliminated by moving (22a; 22b; 22c) in the optical axis direction.
2nd preliminary step of obtaining the diopter of 2c) as the adjustment target value
(# 260), and in the second step (# 270), the objective optical system
The diopter of (12a, 12b, 12c) is set to the first step (# 2
20, # 230), instead of adjusting the diopter of the objective optical system (12a, 12b, 12c) in the wide state, the adjustment target value obtained in the second preliminary step (# 260) is adjusted. The adjusting method according to claim 3 , wherein: 5. Prior to the third step (# 280),
The eyepiece optical system (14a, 14b, 14c) further comprises a preliminary step (# 210) for measuring the diopter, and the objective optical system is used in the third step (# 280).
The predetermined diopter, which is a target value for adjusting the diopter of (12a, 12b, 12c), is the diopter of the eyepiece optical system (14a, 14b, 14c) measured in the preliminary step (# 210). The adjusting method according to claim 3 , wherein: 6. including adjustment method according to any one of claims 1 to 5, the camera adjustment method.