DE3335466A1 - Microfilm camera - Google Patents

Abstract

A microfilm camera (1) has in the camera housing (2) a light-emitting diode field (9) with light-emitting diodes (10). These light-emitting diodes (10) can be driven individually. The image of the light-emitting diode field (9) is fed into an auxiliary lens (13) via a deflecting mirror (14). As a result, the light-emitting diodes (10) are able to expose the film of a microfiche (4) in the exposure station (6) from the rear of the film, so that a code can be applied to an edge region of the film. This now gives rise to an optical coding which is able to replace the previously undertaken perforation of the microfiche. <IMAGE>

Description

Microfilm camera

The invention relates to a microfilm camera with a individual controllable light-emitting diodes formed light-emitting diode field for exposure of a code on an edge area of the film image. One such microfilm camera is described in the German patent application P 33 16 802.0.

The easiest way to apply an optical coding to a microfilm, which specific information about the respective film image contains, should in it exist, by means of a light-emitting diode field, whose light-emitting diodes can be controlled individually are to generate the desired code. However, if the optical code those It is intended to contain information that was previously stored through the perforation of the microfilm cards then a light-emitting diode field is created with the currently known light-emitting diodes, which is larger than the usual microfilm image in the card.

The aforementioned German patent application P 33 16 B02.O is therefore the Teaching, with a more extensive coding instead of a light-emitting diode field a Cathode ray tube to operate to generate the code. Such a cathode ray tube however does not work without problems. Lead to fluctuations in the supply voltage to different degrees of deflection of the cathode ray, so that the code changes will. It should also be noted that Cathode ray tubes sensitive to aging and change their specific properties through aging.

In order to generate a more compact coding with light-emitting diodes, it is already known to expose only a single line at a time and then the film to advance very small steps and to expose a further line at a time. Such an arrangement is, of course, quite complicated and requires the necessary Accuracy can only be achieved with a roll film because there is a film advance device can reach into the film perforation. In the case of microfilm cards, however, the advance must be can only be achieved frictionally by friction wheels, so that the generation an exact code required small and precise feed steps with justifiable Effort cannot be achieved.

One could also think of a coding device on the master table to be attached, which is photographed with the template. Such a coding device would have to be photographed in daylight, so that the reproduction quality on the Movie would go bad. Apart from this, the controlled luminous dots should be black and the rest of the film will be white, as the film is only transparent there when you take a picture remains where little light is reflected from the original. When there is a change the reduction factor would change the size of the code on the film. For these and other reasons, this type of coding is not practical.

The invention is based on the problem of having a structure as possible to develop simple micro film camera of the type mentioned above, with the on small Film surfaces an optical coding of large information density can be exposed.

This object is achieved in that between the to be encoded film and the light-emitting diode field a reduction device for Reduce the image of the light-emitting diode field to a size suitable for the film is provided.

Such a microfilm camera is very simple in construction and capable to replace the punch card cameras that are widespread today. Since according to the invention between a reduction device for the light-emitting diode field and the film to be exposed is provided, the image created by the lighting up of light emitting diodes can be as follows can be reduced in size so that the coding is as small as possible but still legible high accuracy on the film. If you choose z. B. an Aski code with 700 Points generated by light-emitting diodes, this creates a light-emitting diode field, which is much larger than the film on a microfilm card. Through the reduction device if this light-emitting diode field is reduced to a quarter of its size, for example, so that the coding was lengthened by a quarter on one edge area Films can be accommodated.

The generation of a code by means of light emitting diodes also offers the advantage of that even considerable fluctuations in the supply voltage do not result in any change of the code, which is the case with cathode ray tubes. To be considered is also that light-emitting diodes are insensitive to aging.

An advantageous embodiment of the invention is that the Reduction device is a lens, which in addition to the camera lens is arranged in the camera housing. Such a lens can be designed very simply because the light from the LED field always has the same color and intensity. A cheap, commercially available lens can therefore be used.

The space already available in a microfilm camera above the The camera lens can be used cheaply if the additional lens is on the the side of the film facing away from the camera lens is arranged.

The one specified in claim 4 is particularly expedient in terms of construction Embodiment of the invention.

-The lens for exposing the code does not need a shutter to have if, according to another embodiment of the invention, the control of the Light emitting diode field contains a timing element through which the controlled light emitting diodes light up for a measured period of time for the film to be exposed.

A particularly compact microfilm camera results when the Reduction device are optical fibers, which from the light-emitting diode field to are guided immediately in front of the film, the ends of the optical fibers one have such a mutual distance that one for the affixing of the information certain area is covered on the film. The optical fibers mainly offer the advantage of using a multiple curved path on existing built-in parts of the camera to be guided past to the front of the film, so that conventional cameras only relatively slightly must be converted in order to convert them into cameras according to the invention to convert.

The invention allows numerous possible embodiments. For clarification their basic principle, two of them are shown very schematically in the drawing and are described below.

They show: FIG. 1 - a first embodiment of one according to the invention designed microfilm camera; Figure 2 - the essential components of a second embodiment a microfilm camera designed according to the invention.

FIG. 1 shows a microfilm camera 1 which has a camera housing 2 with a camera lens 3 has. Microfilm cards 4 to be exposed arrive from a stack 5 to an exposure station 6 above the camera lens 3 and then in a developing and fixing station 7. Then they get into a Card outlet 8, where the finished microfilm cards 4 ″ can be removed.

Important for the invention is a light-emitting diode field 9, which is next to one another has a plurality of individually controllable light-emitting diodes 10. To create a Codes an input keyboard 11 is provided, from which commands to a controller 12 arrive. This controller 12 initially stores the commands and leaves the light-emitting diodes 10 light up for a period of time measured to expose the code as soon as Cait, h a microfilm card 4 'in the exposure station 6 is located.

To expose the light emitting diode field on the film of a microfilm card 4r to be able to, an additional lens 13 is arranged in the camera housing 2, which in the exposure station 6 above the camera lens 3 axially parallel to it is slightly offset to the side. Above the objective 13 is a deflecting mirror 14 arranged at an angle of 45 degrees. This will make the image of the side above of the camera lens 3 arranged light-emitting diode field 9 reflected into the lens 13 and projected onto the film.

When filming z. B. Drawings are entered via the input keyboard 11 enter the data to be encoded. While the film of a microfilm card 4 'in the Exposure station 6 is exposed, the light-emitting diodes 10 of the light-emitting diode field light up 9 for a short time so that the code is exposed from the back of the film onto the film.

In the embodiment according to FIG. 2, there is also a light-emitting diode field 9 provided with light emitting diodes 10.

However, optical fibers 15 lead from these light-emitting diodes 10 to the film of the microfilm card 4 '. It can be seen that the optical fibers 15 immediately before Microfilm card 4 'ends and are bundled there. Thereby a downsizing takes place of the code generated by the light-emitting diode field 9 instead. A lens like the one embodiment described first is not required. That from the optical fibers 15 emerging light can expose the film of the microfilm card 4 'directly.

Claims (6)

Claims 1. microfilm camera with one of individually controllable light emitting diodes formed light-emitting diode field for exposing a code on an edge area of the Film image, d u r c h g e -k e n n n z e i c h n e t that between the to be coded Film the microfilm card (4) and the light-emitting diode field (9) a plant refining device (Lens 13, optical fibers 15) to reduce the image of the light-emitting diode field (9) is provided to a size suitable for the film. 2. Microfilm camera according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the reduction device is an objective (13) which additionally is arranged to the camera lens (3) in the camera housing (2). 3. Microfilm camera according to claim 1 or one of the following, d a d u'r c h e k e n n -z e i c h n e t that the additional lens (13) on the the side of the film facing away from the camera lens is arranged. 4. Microfilm camera according to claim 1 or one of the following, d a d u r c h e k e n n -z e i c h n e t that the additional lens (13) is axially parallel is arranged to the camera lens (3) and the light-emitting diode field (9) laterally offset above the lens (3) and that the LED image has a Deflection mirror (14) is reflected into the lens (13). 5. microfilm camera according to claim 1 or one of the following, d a d u r c h g e k e n n -z e i c h n e t that the control (12) of the light-emitting diode field (9) contains a timing element through which the controlled light emitting diodes (10) have a for the exposure of the film to light up. 6. microfilm camera according to claim 1 or one of the following, d a d u r c h g e k e n n -z e i c h n e t that the reduction device optical fibers (15) are, which led from the light-emitting diode field (9) to immediately in front of the film are, wherein the ends of the optical fibers (15) such a mutual distance have an area intended for the application of the information on the film is covered.