DE1221097B - Exposure control device in cinematographic cameras - Google Patents

Description

Exposure control device in cinematographic cameras The invention relates to an exposure control device in cinematographic cameras in which the photoelectric converter on the side of the image-side emerging from the taking lens The bundle of rays is arranged and the light measurement after reffexion of the rays on the mirrored sector cover.

In order to achieve dieseseitliche deflection of the beams, it has been found, either the sector shutter at all inclined in the beam path, or have been provided the perpendicular sector shutter having a V-shaped bead concentrically to the diaphragm axis of rotation. If one wants to capture the entire beam, this inclination or the bead must be so large that a relatively long focal length of the lens on the image side is required in order to accommodate the sector diaphragm.

Sector diaphragms have therefore already been proposed which are beaded in a V-shape that the apex of the V-shaped cross-section lies on the optical axis and the side surfaces reflect the beam half to one side and the other half to the other side . In this case, considerable space is saved because the bead of the sector diaphragm no longer needs to be so large. Another space saving is brought about by a proposal, which has also become known, according to which, instead of a relatively large bead, several smaller ones are arranged, d. H. part of the sector diaphragm is shaped into a so-called stepped mirror.

However, the two last-mentioned arrangements have the disadvantage that only half of the beam is deflected to one side and that a measurement of this partial beam does not provide any information about the total brightness of the object. In order to detect this overall brightness, it is necessary to mount a photoelectric converter in each of the two deflection directions and to connect the two together in a suitable manner. However, this approach, which is practicable per se, has the serious disadvantage that no two photoelectric converters, be it photoresistors or photocells, have the same characteristics. This results in the total measurement deviations according to one or the other side, d. In other words, one half of the beam with its brightness is preferred or disadvantaged in the overall measurement. It would be much better if, with a small three-dimensional V-shaped mirror, the entire bundle of rays were captured and reflected to only one side, in which only one transducer would then have to be arranged.

According to the invention this is achieved in that the side surface capture only part of the cross-section of the receiving beam at the same time can, the bead on the sector diaphragm is so eccentric to the diaphragm axis, that the side surface receives the receiving rays during a complete rotation of the diaphragm captured once from each area of the entire bundle cross-section and sent to the transducer distracts.

As a result, despite the relatively flat design of the sector diaphragm, that the light from the entire cross-section of the bundle reaches the one transducer. It is true that the transducer does not come out of all parts of the cross-section at the same time applied, but so briefly one after the other that the measuring mechanism as a result can adjust its inertia to an integrating value.

With such a design of the sector diaphragm or the entire exposure control device, however, it should be noted that the photoelectric converter must be dimensioned relatively large, because due to the geometric center of the bead, which is eccentric to the axis of rotation of the sector diaphragm, the reflected beam oscillates slightly back and forth, namely parallel to the diaphragm plane when the side surface of the bead is inclined at 45 'to this plane. The reason for this is that the center ray of the reflected beam, which is referred to below as the surface normal, with its rearward extension always runs through the center of the circle formed by the bead. Since this center point does not lie in the sector diaphragm rotation axis, but moves around this axis once when the sector diaphragm is rotated, the reflected beam also swings back and forth once during a sector diaphragm rotation. The photoelectric converter must therefore be large enough that the beam does not leave its surface during this migration.

This oscillation of the reflected beam can, however avoid, as is also proposed according to the invention, the eccentric The bead is composed of several short circular arcs around the sector aperture axis of rotation, however, the arcs all have a different radius.

When the sector diaphragm is stationary, it is of course expedient if the reflective side surface of the bead runs through the center of the beam, since a brightness component that is representative of the overall brightness of the object is most likely to be expected there.

If the sector diaphragm is at a standstill with the center of its Dark sector would stand in front of the picture window, would result in terms of the arrangement the V-shaped bead no problem. It would just have to be ensured that in the The middle of the curve slope of the bead would also be arranged in the middle of the dark sector. With one rotation of the sector diaphragm, the side surface of the bead would then move one side out of the beam and then again from the other side run into the middle of the bundle.

However, for reasons of quick camera start-up, a position is usually chosen for the standstill of the sector diaphragm in which the sector diaphragm - of course - while maintaining the light tightness - just barely covers the picture window. When the sector diaphragm starts to rotate, the light sector first passes the image window. If, in this standstill position, the side surface of the bead passes through the center of the beam and is also intended to sweep the entire cross-section of the bundle when the diaphragm is rotated, the bead can no longer rise continuously. Rather, at some point in the bead there must be a kink or crack in this rise, i.e. That is, the bead must consist of two branches, one of which is at. the rotation of the sector diaphragm increases from the center of the beam to the one edge of the beam and the other from the other edge of the beam to the center of the beam. Both branches can be connected by a short curve piece, but they can also be located next to each other separately.

The part of the side surface of the bead standing in the beam during standstill of the sector diaphragm does not need to be connected , it can rather be interrupted and the individual parts can be arranged in such a way that parts of the beam at different distances from the optical axis are reflected out. As a result of this subdivision, a part of the bundle of rays that is even more representative of the overall brightness of the object can possibly be detected and reflected out than is the center of the bundle of rays. In particular, it is proposed for this purpose that the individual parts of the bead or its reflective side surface be offset from one another in a stepped manner.

In the drawing, the invention is explained in more detail using an exemplary embodiment. 1 schematically shows a cinema camera with a mirrored sector shutter shaped in a known manner and an exposure control circuit, FIGS. 2 and 3 schematically a mirrored sector shutter according to the invention in view and cross section, FIG. 4 to 6 schematically illustrates a reflective mirror shutter according to the invention in elevation and cross-section, wherein the V-shaped bead during the aperture standstill passing through the center of the recording beam, Fig. 7 shows schematically a reflective mirror shutter, wherein the V-shaped bead of individual, is composed of sectors concentric to the aperture axis of rotation.

The cinema camera contains the picture window plate 2 with picture window 3 and the pressure plate 4 in its housing. The film 6 runs from the supply reel 5 to the picture window and pressure plate through to the take-up reel 7. The lens 8 ' through which the recording beams fall on the film or on the sector diaphragm 9 , which is driven in a known manner by its axis 10, is firmly seated on the housing 1 will.

For the correct exposure, the camera has a device consisting of the photoresistor 11 arranged to the side of the image-side recording beam path, the battery 12 and the measuring mechanism 13. Since the latter directly drives the aperture vanes 13a and 13b of the lens diaphragm and the photoresistor 11 is arranged in the direction of light behind the lens diaphragm , the device is therefore a closed control loop.

The sector diaphragm 9 is reflective on its side facing the objective 8 and reflects the image-side recording beams onto the photoresistor 11. For this purpose, it is provided with an asymmetrical, V-shaped bead 9a in the objective direction. The resulting side surface14 is the actual reflection surface. If the entire cross-section of the bundle is to be detected and reflected onto a photoresistor, this side surface 14 must be relatively long, as FIG. 1 shows. Such a sector diaphragm therefore requires a large overall depth.

This is avoided when the sector diaphragm is designed according to the branch of the sector diaphragm 18 in FIG. 2. The latter is provided with the asymmetrical V-shaped bead 19 which runs as a strip over the dark sector of the sector diaphragm. The side surface 20 formed by the bead 19 is, however, much shorter or lower than z. B. the one shown in Fig. 1 and consequently detects only part of the cross-section of the recording beam at standstill and at every moment of the rotation of the sector diaphragm. However, the strip does not run concentrically to the diaphragm axis 21, but in such an eccentric or spiral shape that each time the sector diaphragm 18 is rotated in the direction of arrow A, the side surface 20 wanders once through the beam cross-section, of course sweeping once across the image window 22 at the same time.

As a result of this design of the mirror shutter 18 you can get along well in their reduced depth with a single photoresist and yet receives a control of the lens iris according to the total brightness of the object. The circular center line of the side surface 20 is designated by 28, the geometric center of which is located at 28a. When the sector diaphragm 18 is rotated, the latter describes the circle 28 b about the diaphragm axis of rotation. As a result, the surface normal of the side surface 20 fluctuates when the diaphragm is rotated by the angle * by which the reflected beam also oscillates back and forth, which must be taken into account when dimensioning the photoelectric converter, not shown.

In Fig. 4, the sector diaphragm 25 has two branches 26 and 27 of the proposed bead. When the diaphragm is at a standstill, the branch 26 is in the middle in front of the image window 22. In this position, its side surface therefore reflects rays from the center of the beam or the image window to the photoresistor. This part of the beam can be expected to represent a part that is representative of the overall brightness of the object. However, with this arrangement, the bead cannot be continued continuously over the entire sector diaphragm. Rather, the bead must have a shoulder or bend in its course, which can be at any point in the bead course, which is shown in FIG . 4 is shown as lying in the middle for the sake of simplicity. The two branches 26 and 27 are therefore approximately the same length.

If the sector diaphragm rotates in the direction of arrow A, the image window 22 is immediately released. If the dark sector then again steps in front of the picture window, the bead with its branch 27 runs in front of the picture window until shortly before its center during a quarter turn of the diaphragm in the direction of arrow B. During the next quarter turn, the other branch 26 then runs in the direction of arrow C in front of the image window, specifically right up to the middle, and when the camera is switched off, it remains, as in FIG. 4, stand in the middle of the image window.

Of course, the two branches 26 and 27 do not have to be so abruptly set off from one another as shown in the figure;

The probability of reflecting a cross-section from the bundle of rays that is representative of the overall brightness when the sector diaphragm is stationary can possibly be increased if the exact center rays of the bundle are dispensed with and rays that lie a little further to the outside of the bundle are included. A sector diaphragm, which reflects these rays to the photoresistor, is shown in FIGS. 5 and 6. The branches 36 and 37 of the V-shaped bead again lie on the sector diaphragm 30. One end of branch 36 is in the center of the beam when the sector diaphragm is stationary. At this end, the reflecting side surface is divided into the partial surfaces 36a and 36b . The area size of these two partial areas corresponds to the size of another, not divided piece of the side area of the same length. Between the two partial surfaces 36 a and 36 b there is a piece of non-reflective surface 38 which just intersects the optical axis of the beam or is in front of the center of the image window. In cross section, the partial areas 36 a, 36 b can be arranged in a stepped manner, the area 38 running as a connecting area between the two parallel to the diaphragm plane.

In order to have the same aperture control with stationary and running sector diaphragm to get that part of the side surface, which at standstill in the beam path is, in a known manner, be designed to be less reflective than the rest Side face. This correction is used to ensure that in the unit of time the same amount of light energy when the sector diaphragm is running and at a standstill gets to the photoresistor. However, it is also known to perform the correction Switching off a resistor from the control circuit when the sector shutter begins to run to undertake.

The above with reference to FIG. 2 described oscillations of the reflected beam can be avoided if the sector diaphragm with beads, as in FIG. 7 shown, provides. The two branches of the bead z. B. the F i g. 4 are divided into three sectors 40 to 42 and 43 to 45 each. These sectors differ in the size of their radii r, but up to r .. are concentric to the axis of rotation of the sector diaphragm 46. As a result, the surface normal of all these sectors runs through the sector diaphragm axis of rotation, so that the direction of reflection of the reflected beam remains constant.

Finally, it should be mentioned that it makes sense to any person skilled in the art is that the above-described V-shaped beads of the sector diaphragms through strips of sheet metal or other suitable strips placed on the faceplate Can replace material. It just depends on the reflective side surfaces with the required inclination and its required course.

Claims (2)

Claims: 1. Exposure control device in cinematographic cameras, in which the photoelectric converter is arranged to the side of the image-side beam emerging from the taking lens and the light measurement behind the taking lens after reflection of the image-side receiving rays on the mirrored side surface of a V-shaped bead of the sector diaphragm bent in the direction of the lens is carried out on the photoelectric converter, d ABy in that the side surface (20, 27, 36, 37, 26) only a part of the cross section can detect from the receiving bundle of rays at the same time, the bead on the mirror shutter (18, 25, 30) in such a way runs eccentrically to the diaphragm axis (21) so that the side surface (20, 26, 27, 36, 37) detects the receiving rays from each area of the entire bundle cross-section once during a complete rotation of the diaphragm and deflects them to the transducer. 2. Exposure control device according to claim 1, characterized in that the V-förnugt bead runs spirally on the sector diaphragm. 3. Exposure control device according to claims 1 and 2, characterized in that the V-shaped bead of the sector diaphragm (46) is composed of individual sectors (40 to 45) which are arranged concentrically to the axis of rotation of the sector diaphragm and whose radii (r1 to r6) are so different are large that all sectors (40 to 45) together reflect once the entire recording beam when the diaphragm is rotated. 4. Exposure control device according to claims 1 to 3, characterized in that in the rest position of the sector diaphragm the V-shaped bead runs through the center of the beam and the bead on the sector diaphragm (25, 30) in two branches (26, 27, 36 37) is present, one of which rises when the sector diaphragm is rotated from the center of the beam to one edge of the beam and the other rises from the other edge of the beam to the center of the band. 5. Exposure control device according to claims 1 to 4, characterized in that the part of the bead (36) extending through the center of the beam when the sector diaphragm (30) is in the rest position is offset in a step-like manner in such a way that the side surface is divided into at least two parts (36a, 36b ) , which together correspond in their area size to the size of the rest of the side area and are arranged at a distance symmetrically to the optical axis.