DE4143421C2 - Real-image type finder device - Google Patents

Abstract

A real image is formed by an objective optical system and can be observed through an ocular optical system. A prism (P1) with a reflecting surface (311) is provided in the objective optical system to bend an optical path of light incident on it.The prism is rotatable about a shaft (312) associated with the reflecting surface and substantially normal to a plane which includes optical axes of light incident upon and reflected by the surface

Description

The invention relates to a camera the preamble of patent claim 1. A camera this type is known from DE 25 26 847 A1.  

With the macro shooting function of a zoom lens camera, in which the lens group is partially or completely behind or in two extremes of the zoom range (usually in telephoto extreme) is moved so that an image of an object can be taken, which at a shorter distance than the shortest object distance Normally located in the regular zoom range just an image of an object within the limits of the Macro recording area. So no picture of an object can be taken, which is closer to the camera than the limit mentioned.

The known camera enables this, however with difficult operation when measuring distance and focus.

The object of the present invention is in specifying a camera with a macro recording function, in which an image of an object can be taken as simply as possible, which is closer to the camera than the limit of the macro shooting range.

The invention solves this problem by the features of Claim 1. Advantageous further developments are Subject of the subclaims.

In addition to a simplified Lens setting achieved in the second Macro shooting mode no distance measurement and no focusing is necessary. So that results a corresponding improvement in a camera of the type mentioned at the beginning.

The invention is described below with reference described on the attached drawing.

Fig. 1 is a schematic view of a zoom shooting system as well as an optical viewfinder system in a zoom lens camera with a macro shooting function;

Fig. 2 is a front view of a viewfinder and shows several possible viewfinder frames;

Fig. 3 is a schematic illustration of a lens barrel with the optical zoom pickup system shown in Fig. 1;

FIGS. 4A, 4B and 4C are sectional views of the upper half of the lens barrel shown in Figure 3, in a retracted position, a position having the shortest focal length and a position at the longest focal length.

Fig. 5 is a development view of cam grooves of a cam ring, of a linear motion guide tracks and a first ring of rollers, a second and a third lens group;

Fig. 6 is a developed view of a third lens frame and a second lens moving ring;

Fig. 7 is a perspective view of a third lens frame;

Fig. 8 is an exploded perspective view of a viewfinder optical system;

Fig. 9 is a top view of a cam plate; and

Fig. 10 is the side view of a camera in a second macro shooting mode.

Fig. 1, the lens arrays shows an example of a zoom imaging system T and a finder system of a zoom lens F in camera in different positions.

The recording system T has a first lens group A, a second lens group B and a third lens group C. The first and the third lens group A and C move together, and the second lens group B moves relative to the first and the third lens groups A and C to the  to change the spatial distance between them, and causes the focal length change between a tele-extreme and a wide-angle extreme. If only that second lens group B from the tele extreme Moving one step forward, the shooting mode changes in a first macro recording mode in which a close up run can. Another forward movement of the second lens group B causes the shooting mode to switch to a second Macro shooting mode changes in which an image of a closer object than in the first macro shooting mode. Increased in detail the magnification in the direction of the tele-extreme in this order first macro area and second macro area. The movement focuses or focuses the second lens group B in the direction of the optical Axis.

The viewfinder system F contains a first lens group L1, a second lens group L2, a third lens group L3 and a fourth L4 lens group. The first lens group L1 and the fourth lens group L4 are stationary Lenses and the second lens group L2 and the third lens group L3 are movable lenses that the Change refractive power. The second and the third lens group L2 and L3 are assigned to that Zoom operation of the recording system T in the regular Zoom range between the tele extreme and  the wide-angle extreme. With a transition from the tele-extreme in the first macro range the second and third lens groups L2 and L3 into one Direction that reduces viewfinder magnification, contrary to the optical recording system T. Bei there is a transition to the second macro area further movement of the second and the third Lens group L2 and L3 take place in a direction that the Viewfinder enlargement reduced.

Fig. 2 shows the viewfinder image field that is changed between the tele-extreme, the first macro area and the second macro area. The size of the viewfinder itself is not changed mechanically. The normal viewfinder image field is shown in the tele-extreme with a dashed line t, in the first macro area with a solid line m1 and in the second macro area with a double-dotted and dashed line m2. The shooting areas by the optical shooting system T in the first macro shooting mode and the second macro shooting mode may be included in the enlarged viewfinder fields m1 and m2. A first macro frame m1f and a second macro frame m2f are provided in the viewfinder to display the shooting areas of the first macro shooting mode and the second macro shooting mode within the enlarged viewfinder frames. The first and second macro frames m1f and m2f are usually somewhat smaller than a real image field. The character "sf" denotes an object distance measuring frame, which represents an object distance measuring area during automatic focusing.

It will so the recording area by reducing the Magnification of the viewfinder optical system F at Transition to the macro shooting area appears and it occurs accordingly not only no deterioration in the Figure on, but it will also be the diopter number in the Macro shooting mode in which an object is observed which is closer to the camera than that Reference object distance is automatically by the Movement of the second and third lens groups L2 and L3 corrected.

Drive mechanism of the zoom recording system T

In the following, an embodiment of the drive mechanism of the lens group of the zoom recording system T will be described with reference to FIGS . 3 to 7.

One of the most significant features of this embodiment relates to the construction of the zoom pickup system in which the housing length of the lens group is shortened. FIGS. 4A, 4B and 4C show a retracted position is a position of the shortest focal length (wide angle) and a position of the longest focal length (Tele).

Fig. 3 shows the main components of the zoom lens barrel 50th

The first and third lens groups A and C move together within a zoom range from the wide-angle extreme shown in FIG. 4B to the telephoto extreme shown in FIG. 4C, and the second lens group B changes the spatial distance relative to the first and third lens groups A. and C to change the focal length. The second lens group B is used for focusing. The first macro exposure mode is given when only the second lens group B is moved forward in the telephoto extreme shown in FIG. 4C. The shooting mode is switched to the second macro shooting mode by further advancing the second lens group B, as shown in FIG. 1. In the illustrated embodiment, upon transition to the retracted position shown in Fig. 4A, in which the first, second and third lens groups A, B and C are withdrawn from the wide angle extreme shown in Fig. 4B, the first lens group A is opposed of the third lens group C so that the first and second lens groups A and B are moved so that they come closer to the third lens group C, thereby reducing the length of the lens groups.

A ring 11 which is stationary on the camera housing is provided with an outer screw surface (inner circumferential screw surface) 12 which is fixed on the front side thereof. An inner screw surface (outer peripheral screw surface) 13 engages the outer screw surface 12 . A cam ring 14 is fixed to the inner screw surface 13 . As conceptually shown in Fig. 3, the cam ring 14 has a toothing 15 which is in engagement with a pinion 16 a of a zoom motor 16 . When the zoom motor 16 is turned on, the cam ring 14 is rotated and moved in accordance with the thread of the inner screw surface 13 in the direction of the optical axis. The toothing 15 is preferably inclined in the same direction as the threads of the inner screw surface 13 . The reference numeral 17 shows a front cover which surrounds the outer screw surface 12 .

A linear motion ring 18 is fitted in the inner peripheral surface of the cam ring 14 . The linear movement ring 18 is provided at its rear end with a linear guide plate 19 which partially engages on its outer peripheral surface in a linear guide groove 11 a, which is formed in the stationary ring 11 . The linear movement ring 18 has an outer flange 18 d on its front side, so that the cam ring 14 is rotatably held between the outer flange 18 d and the linear guide plate 19 so that it does not move in the direction of the optical axis. Accordingly, the linear movement ring 18 is prevented from rotating by the linear guide plate 19 and is movable together with the cam ring 14 in the direction of the optical axis. The cam ring 14 is rotatable relative to the linear movement ring 18 . A cylindrical lens cover 21 is fixed to the outer flange 18 d.

A first lens frame 22 , which holds the first lens group A, is attached to a first lens movement ring 23 with an adjusting screw 22 a. The first lens movement ring 23 is provided at its rear end with a first roller A 'for the first lens group A. The first roller A 'extends through the linear guide groove 18 a ( Fig. 3), which is formed in a linear movement ring 18 , and is fitted into a first cam recess 14 a of the cam ring 14 .

A second lens frame 25 , which holds the second lens group B, is screwed to the inner screw surface 27 of a closure unit 26 . The shutter unit 26 is attached to a second lens movement ring 28 which is provided at its rear end with a second roller B 'for the second lens group B. The second roller B 'extends through a linear guide groove 18 b ( Fig. 3) which is formed in the linear movement ring 18 , and is fitted into a second cam recess 14 b of the cam ring 14 .

A third lens frame 30 , which holds the third lens group C, is provided with a third roller C 'for the third lens group C. The third roller C 'is fitted into a linear guide groove 18 c of the linear movement ring 18 , but in contrast to the first roller A' and the second roller B 'is not fitted into a cam recess.

Referring to FIG. 5, the first cam recesses 14 have a, and the second cam recesses 14 have b collection portions l0, zoom sections l1, l2 first macro transition sections and second macro transition sections l3. The zoom sections l1 correspond to the area shown in FIG. 1 and the feed sections l0 are sections into which the first, the second and the third lens groups A, B and C are retracted behind the wide-angle extreme. The first macro transfer sections l2 are sections in which only the second lens group B is advanced by a slight offset from the telephoto extreme, while the first and third lens groups A and C are held in fixed positions so that the first macro mode is obtained. The second macro transfer sections 13 are sections in which only the second lens group B is moved out of the first macro mode while the first and third lens groups A and C are held in fixed positions.

The reasons that the first cam recesses 14 a and the second cam recesses 14 b have a slight inclination, and that the inclinations of the first and second cam recesses 14 a and 14 b in the first and second macro transition sections l2 and l3 are directed in opposite directions are that cam ring 14 itself is advanced by outer screw surface 12 (inner screw surface 13 ). The offset of the first lens group A (the third lens group C) and the second lens group B is namely determined by the resulting slope of the outer screw surface 12 and the slopes of the first cam recess 14 a and the second cam recess 14 b. The slope of the first cam recess 14 a in the first macro transfer sections l2 and the second macro transfer sections l3 are identical, so that an offset of the first and third lens groups A and C does not take place. Namely, the angle of inclination of the first cam recesses 14 a in the first macro transfer sections l2 and the second macro transfer sections l3 is the same as that of the screw surfaces 12 and 13 , but the directions are opposite to each other.

Between the third lens frame 20 and the first lens movement ring 23 , engagement sections 30 a and 23 a are provided, which during the movement of the first lens movement ring 23 from the retracted position shown in FIG. 4A into the wide-angle position shown in FIG. 4B according to the profile of the retracted sections 10 of the first cam recesses 14 a engage in one another, as can be seen from FIGS . 6 and 7. When the cam ring 14 rotates, the first lens movement ring 23 moves in the direction of the optical axis according to the relation between the first roller A 'and the associated first cam recess 14 a. However, if the first roller A 'is held between the zoom section l1 and the second macro transfer section l3 of the assigned first cam recess 14 a, the engagement sections 30 a and 23 a always engage with one another. As a result, the first lens moving ring 23 (first lens group A) and the third lens frame 30 (third lens group C) move together. In contrast, if the first roller A 'comes into the feed section l0 of the associated first cam recess 14 a, the third lens frame 30 stops when the third roller C' comes into contact with the rear end of the associated linear guide groove 18 c, and the engagement section 23 a becomes from the engagement section 30 b disengaged to be withdrawn alone. In this state, the second lens group B is retracted according to the relation of the second roller B 'and the associated second cam recess 14 b. As a result, the first, second and third lens groups A, B and C are withdrawn altogether, which leads to a shortened retraction length of the lens group. FIGS. 3 and 6 correspond to Fig. 4A (loading position). In the receiving position shown in FIGS. 4B and 4C, the engaging portions 23 a and 30 a touch each other.

Between the second lens movement ring 28 and the third lens frame 30 , a plurality of circumferentially spaced compression springs 31 are provided, which continuously tension the third lens frame 30 backwards, ie in a direction in which the engagement section 30 a in contact with the engagement section 23 a of the first lens movement ring 23 would like to come.

As is known, the shutter unit 26 rotates a drive pin 26 a through an angle corresponding to the distance of an object to. The drive pin 26 a is operationally assigned to a connecting ring 33 which is attached to the second lens frame 25 , so that when the drive pin 26 a rotates, the second lens group B is moved in the direction of the optical axis on the inner screw surface 27 . The connecting ring 33 is fixed to the second lens frame 25 after the adjustment (focus adjustment) of the axial position of the second lens frame 25 is completed. The shutter unit 26 opens and closes shutter blades 26 b in accordance with the brightness signal of an object to be recorded.

When the cam ring 14 is rotated in the forward or backward direction by the zoom motor 16 , it is also moved in the direction of the optical axis, because the inner screw surface 13 is in engagement with the stationary outer screw surface 12 . The linear movement ring 18 is thus moved in the direction of the optical axis. Since the linear movement ring 18 by the linear guide plate 19 and the Linearführungsnut 11 a can not be rotated, relative movement between the cam ring 14 and the linear movement of ring 18 takes place, as a result, so that the first and the second lens group A and B in the optical axis direction according to the cam profiles of the first and second cam recess 14 a and 14 b are moved.

The third lens group C stops before the first cam recesses 14 a of the cam ring 14 cause the first lens movement ring 23 to move into the pull-in sections 10 to thereby engage the engaging section 23 a with the engaging section 30 a of the third lens frame 30 , since the third roller C 'abuts against the rear end of the associated linear guide groove 18 c. After the engagement sections 23 a and 30 a engage in one another and rotate on the zoom section l1, the third lens group C begins to move together with the first lens group A. Accordingly move in the zoom section l1 the first, second and third lens groups A, B and C in the optical axis direction according to a predetermined relation of the first and second cam grooves 14 a and 14 b, in order to change the focal length.

At a transition from the zoom section L1 in the first macro transfer section l2 the second lens group B b is moved in accordance with the second cam recesses fourteenth During this movement of the second lens group B, the first and third lens groups A and C do not move.

During a transition from the first macro transfer section l2 to the second macro transfer section l3, the second lens group B moves further according to the second cam recesses 14 b. During this transfer, the first and third lens groups A and C do not move.

In contrast, the first and third lens groups A and C move together during a transfer from the zoom section l1 to the draw-in section l0 when the engagement sections 23 a and 30 a engage with one another.

However, when the rearward movement of the third lens group C is restricted by the linear guide grooves 18 c, only the first lens group A is withdrawn to come close to the third lens group C. In this state, the second lens group B is withdrawn b in accordance with the second cam grooves 14 so as to come close to the third lens group C, so that the draw length of the lens group is effectively reduced, as shown in Fig. 4A.

Drive mechanism for the viewfinder optical system F

The following description relates to the drive mechanism for moving the second and third lens groups L2 and L3 of the finder optical system F along predetermined paths with reference to FIGS. 8 and 9.

The arrangement shown in Fig. 8 includes a compound lens prism P1 and a lens prism P2, in addition to the viewfinder optical system F shown in Fig. 2 to provide the necessary optical path length of a real viewfinder. The second and third lens groups L2 and L3 are attached to respective movable frames 111 and 112 which are provided with drive pins 113 and 114 on their upper surfaces. A field glass (transparent) frame L5 is provided between the compound lens prism P1 and the lens prism P2, on which the first macro frame m1f, the second macro frame m2f and the object distance measuring frame sf are drawn. An image of the objective lens system formed by the lens groups L1, L2, L3 and the lens prism P2 is formed on the field glass frame L5 so that it can be observed by the optical eyepiece system formed by the compound lens prism P1 and the lens group L4 is.

The movable frames 111 and 112 are movable in a viewfinder unit in the direction of the optical axis. The finder unit includes laterally movable cam plate 116 ( FIG. 9) in which cam recesses 117 and 118 are formed, into which the drive pins 113 and 114 are fitted. The cam plate 116 is provided at its rear end with a laterally extending toothing 119 on which a pinion (not shown) engages. The pinion is rotated in association with the zoom operation of the zoom optical pickup system T and the transition to macro mode to laterally move the cam plate 116 .

As can be seen from FIG. 9, each of the cam recesses 117 and 118 has a feed section l0, a zoom section l1, a first macro transfer section l2 and a second macro transfer section l3 for moving the first and second movable frames 111 and 112 as shown in FIG Fig. 1 is shown. The ends (boundaries) of these sections determine the wide-angle extreme, the telephoto extreme, the first macro setting and the second macro setting. Accordingly, when the cam plate 116 is moved laterally, the second and third lens groups L2 and L3 are moved along the tracks as shown in FIG. 1. The sections 10 to 13 of the cam recesses of the cam plate 116 correspond to the sections 10 to 13 of the cam recesses of the cam ring 14 shown in FIG. 5. As a result, the viewfinder image field is obtained in the zoom portions corresponding to the focal length, and it is enlarged in the first and second macro shooting modes.

Although the viewfinder magnification is shown in the Embodiments of both the first and the second macro shooting mode is reduced, it is too possible to enlarge the viewfinder only at the first or the second macro shooting mode.

Automatic focusing is possible by the shutter unit 26 in the first macro shooting mode in accordance with the object distance signals. However, since the object distance is very small, it is difficult to obtain an accurate object distance signal. For this purpose, as shown in FIG. 10, a bracket S, which is provided on the camera housing CA, can be used as a measure for the object distance. When an object to be photographed is arranged in a position P defined by the length of the bracket S, the second lens group B is moved into the position in which the position P is focused.

Claims (4)

1. A camera with a zoom lens that has a macro recording mode in which the zoom lens can be adjusted at least partially beyond a limit position of the zoom area in order to take an image of an object with a smaller object distance than an object distance in which an object is recorded in the zoom area , and which has a second macro shooting mode in which it is at least partially adjustable further beyond an axial position corresponding to the first macro shooting mode to take an image of an object at a smaller object distance than the object distance at which an image was shot in the first macro shooting mode can be characterized in that a fixed focus is provided for a predetermined object distance for the second macro shooting mode. 2. Camera according to claim 1, characterized by a camera housing with a forward protruding bracket predetermined Length corresponding to the predetermined object distance corresponds. 3. Camera according to claim 1 or 2, characterized by one Zoom viewfinder, separate from the zoom lens, for changing the viewfinder image field according to the respective focal length the zoom lens by changing the viewfinder image magnification according to the adjustment movement of the zoom lens. 4. Camera according to claim 3, characterized in that the Zoom finder the magnification in association with the movement the zoom lens in the first macro shooting mode or reduced the second macro shooting mode.