DE4042529C2 - Range finder for camera with zoom lens - Google Patents

Abstract

A camera has vario-objective with variable focal length, auto-focusser and auxiliary pattern light projector onto subject concerned. A device (121,122) can vary the enlargement of the pattern image as a function of objective focal length variation and is adapted to this accordingly, the device forming part of a viewfinder provided. The auxiliary light projection system projects an auxiliary light pattern (127) with the aid of the viewfinder lens system (121,122) to give variably enlarged patterns. This auxiliary projection system directs its light from emitter (116) through the pattern (127) and so via a semi-transparent mirror (125) onto the lens system (121,122). A prism (124) forming part of the viewfinder is used to project the specified light pattern as required. Convergence is small in wide-angle lens setting and vice versa in the telephone setting, thus giving wide or narrow angle pictures as selected.

Description

The present invention relates to a camera according to the Preamble of claim 1.

A generic camera with a variable lens Focal length, an autofocus device and an auxiliary light projection system is already from US 4,801,963 A known. US 4,801,963 A describes a distance measurement system for a camera, with an auxiliary light projection system, which is a pattern of light-dark changes to the projected photographing object. To even when using a telephoto lens or one in the telephoto position sensitive zoom lens despite the high object image magnification sufficient with the help of the auxiliary light pattern Creating contrast on the object becomes special Patterns projected onto the object in that of the object  tiv with a small field angle detected near-axis area of the Field of view has a more frequent light-dark change than in the area of the image field remote from the axis. When using Ob High-focal length lenses therefore occur here a Be outside of the distance measurement zone apply light / dark changes with less frequency.

In a camera with such a known distance measuring system and auxiliary light projection system is the distance measurement zone diameter for a wide-angle shot larger than a telephoto picture. So there is one unnecessarily high exposure to low-contrast objects This is particularly the case when taking a telephoto outside edge area of the measuring area is irradiated or because with a wide-angle shot the central area of the measuring zone is irradiated unnecessarily.

US 4,804,991 A describes a camera with an automobile kus facility and an auxiliary light projection system where ver with camera lenses with different focal lengths are reversible. The auxiliary light projection system contains here with an optical system that is independent of the current Focal length of the taking lens a larger area Ver division of the pattern to be projected.

The present invention has for its object a Camera with zoom lens, autofocus device and auxiliary light projection system for projecting a specific one To provide patterns on the object to be photographed, where the working area of the auxiliary light projection system mes in which at different focal lengths of the shot objective a good contrast can be achieved eats is. This object is achieved by the invention Camera with the features of claim 1. Cheap Embodiments of the invention are the subject of the Unteran sayings 2 to 5.  

According to the invention, an autofocus camera is created with:
a lens whose focal length is variable; and
an auxiliary light projection system for projecting a predetermined pattern image onto the object to be photographed, the magnification of the pattern image changing in accordance with the change in the focal length of the lens.

Further advantages, features and possible applications The present invention results from the following description in conjunction with the drawing.  

Show it:

FIGS. 1A and 1B are diagrams showing the optical paths of an auxiliary light projector according to the invention,

FIG. 2 is a perspective view of the prism of the auxiliary light projector according to FIGS. 1A and 1B; and

Fig. 3 is a front view of a camera equipped with a passive distance measuring device.

The present invention can be used in any conventional camera with any conventional auxiliary light range finder system. In the following, a viewfinder camera with zoom lens and passive distance measuring device is briefly described as an exemplary embodiment with reference to FIG. 3.

A shooting lens 12 , a viewfinder 14 , the lens window of which can be seen in the front view, and a light exit window 16 for a built-in flash are provided on the front of a camera housing 10 . A release button 18 is provided on the top of the camera housing 10 . In addition, two autofocus lenses 22 and 23 of a distance measuring device 20 are arranged above the lens 12 on the front of the camera housing 10 .

Passive distance measuring devices 20 , as can be used in a camera according to FIG. 3, are known, inter alia, from US Pat. No. 4,544,848 and US Pat. No. 4,334,151.

A passive range finder offers poorer range finding accuracy for a dark object (the brightness of which is less than a predetermined value) or one that lacks contrast against a background such as a white wall. In the following embodiment, which is shown in Figs. 1A and 1B, therefore, an auxiliary projector element is placed near the viewfinder.

The viewfinder is a variable, driven viewfinder, the field enlargement locked changes with the zooming of the zoom lens. The objective has two variable focusing lenses 121 , 122 which can be moved back and forth against one another, and an eyepiece consists of a fixed lens 123 . Between the variable len, driven lens 122 and the fixed lens 123 , a prism 124 and a semi-transparent mirror 125 are arranged. Furthermore, outside the optical path of the finder, a light emission element (e.g. infrared emission element) 126 with a wavelength of over 700 nm (nanometers) is directed onto the semitransparent mirror 125 . A pattern 127 , which forms a stripe pattern, is arranged between the light emission element 126 and the mirror 125 . The effectiveness of this arrangement is increased if the semitransparent mirror reflects 125 wavelengths over 700 nm at an angle of 45 ° and transmits visible light.

The variable, driven lenses 121 , 122 are locked to the zoom lens via a locking mechanism and change the field magnification of the viewfinder in proportion to the focal length of the zoom lens by being moved back and forth relative to one another. In spite of the zooming, the viewfinder field can thus be set in such a way that it coincides with the photographic imaging plane or is somewhat smaller. The locking mechanism can be such that the variable, driven lenses 121 , 122 are displaced relative to one another by displacing a cam plate, which is provided with a cam recess, by means of a zoom motor, using cam tappet pins which are attached to the variable, driven lenses 121 , 122 are attached and engage in the cam recess.

In the following, the optical paths will be described with reference to the drawings. The prism 124 consists of three triangular prisms (see Fig. 2). The light beam coming from the variable, driven lenses 121 , 122 is introduced via a plane 124 a of the prism 124 and is reflected by an inclined plane 124 b at a right angle downwards, viewed from above on the drawing through an inclined surface 124 c reflected from behind, reflected upwards from an inclined surface 124d and reflected again at right angles from an inclined plane 124e to the right and emitted via a plane 124f . The light beam thus emitted is guided through the semi-transparent mirror 125 and the fixed lens 123 to the photographer's eye.

An auxiliary light beam emitted by the light emission element 126 is reflected by the semitransparent mirror 125 in the direction of the prism 124 , introduced into the prism 124 via the plane 124 f and guided via an optical path opposite to the path described above, before it passes the plane 124 a is emitted. This light beam is then passed through the variable, driven lenses 122 , 121 and emitted from the camera to irradiate the object. The auxiliary light beams emitted by the light receiving element 126 are bundled by the variable, driven lenses 122 , 121 to irradiate the object.

The degree of convergence mediated by the variable, driven lenses 122 , 121 is low with a wide-angle setting and high with a telephoto setting. Thus, a wide area is irradiated with the wide-angle setting, whereas a narrow area is irradiated with the telephoto setting. Thus, an object can be irradiated in correspondence to the light receiving area, which is selected proportional to the focal length. Since the irradiation area is narrowed with the telephoto setting, an object can be irradiated at a great distance.

In the auxiliary projector according to the invention there is light using the variable powered lenses in the variable powered viewfinder used to view the Radiation area proportional to the magnification change, which ent a distance measuring zone ent speaking area can be irradiated.

Claims (5)

1. Camera with a lens ( 12 ) with a variable focal length, with an autofocus device ( 20 ) and with an auxiliary light projection system ( 121 , 122 , 124 , 125 , 126 , 127 ) for projecting a specific pattern image onto that Object to be photographed, characterized by a device ( 121 , 122 ) for varying the magnification of the optical pattern image, the magnification of the pattern image depending on the variation in the focal length of the objective ( 12 ) being changed and adapted to this. 2. Camera according to claim 1, characterized by a viewfinder ( 14 ) with a lens system ( 121 , 122 ) with variable magnification, which varies depending on the focal length of the lens ( 12 ) and is adapted to this. 3. Camera according to claim 2, characterized in that the auxiliary light projection system projects an auxiliary light pattern ( 127 ) using the viewfinder lens system ( 121 , 122 ) with variable magnification. 4. Camera according to claim 3, characterized in that the auxiliary light projection system, the light of a Lichtemis sionselementes ( 126 ) via a pattern ( 127 ) through a semi-transparent mirror ( 125 ) on the viewfinder lens system ( 121 , 122 ). 5. Camera according to claim 2, 3 or 4, characterized in that the viewfinder contains a prism ( 124 ) through which the specific pattern image is projected.