DE2240746A1 - OPTICAL IMAGING DEVICE - Google Patents

Description

Optical Imaging Apparatus The invention relates generally to the field the retrieval of information. In particular, the invention is based on a optical system for use in both observation and reproduction of information directed on a data-carrying medium, for example on a microfilm.

For several years now, the use of microfilms for recording has grown and storage of information rooms more enforced and the areas from which they used to call quickly. One of the consequences of this increasing Use is the increasing need for a facility or a device, with which both the information stored on the microfilm is viewed and high quality printed copies of this information at one Minimum size to know the effort to be made. The devices developed so far, which are in the relevant technology are referred to as reading and Rüchvergrösserungsgerät are however, not fully satisfactory for several reasons.

An obstacle that arises in the creation of reading and re-enlarging devices occurs, the design of the optical system is suitable in many cases must be to rigidly enlarge the information stored on the microfilm while delivering an image of high quality and smoothness. These Difficulty is primarily due to the cos4 law, which says that the Jielligkeit the mapping of an object by the axis of a lens away, depending on the cos4 of the angle of the object with the IJinsenachsa decreases. The effect of this law when copying documents from a microfilm consists in obtaining an image which is around one in its size has much lower brightness than in its center. Such a situation is in totally unacceptable for most applications, especially in reproduction large-scale documents, such as machine drawings or architectural drawings, which have to be copied in sizes of at least 60 cm x 90 cm, at the same time all symbols and thin lines must be present in the reproduction. With the However, most of the devices developed to date can print copies of this size cannot be satisfactorily manufactured with high quality.

In addition to the cos4 law, large-area documents can be printed further problems due to the fact that larger and heavier mirrors than otherwise required will. Through this the problem becomes that the system becomes more uninhabited Maintaining alignment is difficult, especially with devices that use optical Items need to be moved for both viewing and printing too enable.

According to one embodiment of the invention is an optical system intended for use in reading and re-magnification devices, with the bright one enlarged images of high quality and uniform brightness from a microfilm or other data storage media. According to one characteristic According to the invention, the microfilm is illuminated by a light source attached to its The beginning is lighter than in the middle. The light passing through the microfilm is then collected through a suitable lens system and onto an imaging area or projected at an imaging station to provide an image of the microfilm stored data, which image is either viewed or photographed can be. In order to obtain an image that is essentially uniform throughout Brightness, a technique known as vignetting is used and becomes a vignetting ring adjacent the input side of the projection lens system arranged. The combination of the brightness profile of the illuminating light source with the vignetting ring causes a compensation for the cos4 law and results bright, clear images of uniform brightness throughout.

GeYnass. Another feature of the invention, the system is designed so that both viewing and printing are in the same place on the device can be done.

With the conventional systems, one becomes quite complicated optics used to @both allow viewing and making prints, and large movable mirrors or dual optical systems are often required.

For the purposes of the invention, a single beam path with sistionary Mirroring is used, which eliminates the cumbersome adjustment problems and the behavior large motors, which are required to operate large mirrors, are avoided will. In addition, the optical arrangement is more slanted than usual was the case when special consideration @@ gs- and copy areas in connection with moving mirrors had to be used to move the image between viewing and to "steer" copy areas. An optical system is therefore effective through the invention for reading and magnifying devices specified, whichd all the necessary functions performs in a simple and satisfactory manner and in an economical manner Large-scale prints of machine drawings or architectural drawings, posters and the same @ yields without loss of information in reproduction.

In the accompanying drawings: Figure 1 shows a microfilm reading and a back enlarger in which the optical system according to the invention is used can be; Figure 2 and 3 different parts of the optical system according to a preferred embodiment of the invention; Figure 4 shows one for the purposes of the invention used vignetting ring.

In Figure 1, a reading and back enlargement device is shown, in which the optical system according to the invention can be used. In this Device (which is generally denoted by 1), all facilities are built in, the both for viewing those stored on a medium such as a microfilm Information and necessary to obtain fully developed prints from that information are. As can be seen from FIG. 1 ez.b-t, these facilities comprise one facility 2 for inserting and holding the microfilm, an imaging area or

an imaging station 3, a cassette 4 for the supply of photosensitive Paper and a processor 5.

Furthermore, the device according to the invention possesses both in the e device 2 as well as an optical system built into the main body for forming an image of the data stored on the microfilm on the imaging steel 3. The invention is specifically directed to this optical system while the @ details further features of the reading and zooming device in the patent. ... ... +) (Patent application) are described In Figures 2 and 3 is an optical system in accordance with the presently preferred embodiment of the invention.

As shown in Figure 2, within device 2 is a picture window 10 is provided, which is used to hold the data-carrying medium, which the to Contains reproductive information. This medium can conveniently take the form of a Have film punch cards 15 by 35 mm, although also any various others storage media known per se, such as microfilm rolls and the like can be. These punch cards can be placed inside the slot by hand or an additional device can be provided if necessary +) of the same day, reference number of the applicant: JFS-9553 the through which the cards are entered automatically.

Suitable for the arrangement of the cards within the slot Guided tours are provided.

With 11 is generally the light source or lamp for illuminating the Called microfilms. This lamp has a light bulb 12, which of a Reflector 13 is surrounded, which is preferably substantially elliptical in cross section and is provided with a circular opening about 5 cm in diameter. One lamp that is suitable for the intended purpose is the EKX 200 model Watt, 21. volt "Quartzlne" lamp, ie from The General Company.

Electrie Company can be obtained. This lamp makes you easy diverging light beam that around its circumference is about 20% brighter than at its center is at the same time a high illuminance with a small Incandescent bulb is achieved, whereby the heat generation problems are reduced. The inner surface of the reflector is also preferably somewhat pebbled, about the formation of a ring pattern in the emitted light beam due to its size avoiding the light bulb placed at the focal point of the reflector. Here It should be mentioned that other light sources can also be used, whereby the The main concern is that the microfilm is thicker around its edges is lit as at its center.

As can be seen from Figure 2, the emitted by the lamp 11 is Light beam articulated by a mirror 17 around 900 and through a condenser 18 directed. This condenser is placed next to the microfilm slide, so that the through this passing diverging beam to a beam of light is concentrated, the cross-sectional area of which extends straight ahead, to cover the data on the back-producing microfilm. To regulate the Cross-section of the illuminating beam, the lamp 11 is suitably on a Guide 11 for forward and backward movement along the optical axis 16 of the System arranged. This enables the system to be set in dependency from the orientation of the data on the microfilm as well as a certain regulation of the Evenness of the final image. The one passing through the Mi @ rofilm slide Light then fül @ the film projection window of the projection lens system 19 and is on the imaging area 3 by means of stationary mirrors. 21 and 22 (see Fig 3) shown.

In the preferred embodiment, the projection lens system formed by an ilex 75 mm, f = 5.6 six-membered lens system, although natural other project management systems can also be used.

The system described so far is such that an overcompensation for the loss is obtained by the cos4 law so that the corners of the image are lighter than the scope and use a known technique of vignetting n; d e t to a substantially uniform brightness over the image field to achieve high quality prints. So far has been the vignetting in optical systems is generally considered to be disadvantageous, since it, like the cos4 law, also has the effect that the holiness of the axis of the lens system away, is reduced. In the present invention, however the vignetting applied to the advantage. Like Figure 2 shows is a vignetting ring 23 on the projection lens system in front of the first lens 24 of the System, although if desired, it is also provided at a different location can be. This vignetting ring causes the suppression of light rays, the to the lens system with an oblique angle with respect to the op-tische Acl1sc of the system are directed and wonn the correct position and size of the ring is chosen with reference to the projection lens system, it is easy to take an image to get at the imaging station 3, which consistently of uniform brightness is. In the preferred embodiment, the lens system has an opening of 3d, 13 rn (I and 11/32 in.), while the vignetting ring has an opening 25.4 mm (1 in.) Has. This vignetting ring is shown in more detail in FIG.

In Figure 3, forner is the imaging station used for the invention 3 shown. As mentioned, this imaging station serves both. for viewing as well as for the production of prints as a difference to most known devices, in which viewing and making prints in different places of the device happens. The imaging station shown has an observation screen 26 made of translucent material, for example a screen or a covered screen Glass pane on which a clear image can be created. In practice the image is projected from the mirror 22 in FIG. 3 onto the underside of this plate and looking down from the top of the plate. Even though this image is seen as a mirror image of the information on the microfilm is it is appropriate for most viewing purposes and suitable to ensure that the microfilm is properly aligned and in focus, whether a print desired will or not. Of course, if only one consideration if the filJn is desired to be turned so that a correct picture is obtained will.

A second see-through screen 27 is also at the imaging station provided, which is used to support a photosensitive printing paper that is in the narrow space 28 between the two discs is arranged. Since he's transparent is-t, the viewing of the image on the disk 26 is made possible by this slide not impaired, but it can lead to; storage of the light-sensitive material in serve as a layer for printing. The facility for entering the non-sensitive Material between the panes as well as to entnaJune the same after it has been exposed does not form part of the present invention, but is the subject matter of the patent mentioned. ... .... It should only be mentioned here that if photosensitive Paper is not available, the imaging area can be used for viewing can, and that if a picture or a print is to be obtained, it is only necessary is to lower the lid 6 (Figure 1), a photosensitive material between-the To arrange slices and to expose this.

With the help of the optical system described, it is therefore easy to Imprints of where quality and uniform density in a much larger one Format as-known reading and re-enlarging devices in an appropriate manner can deliver, achieve. By - the optical system according to the invention is the Microfilm storage technology available for new forms of application, for example for Reproduction of large machine drawings and architectural drawings, posters and the same. The system is from fairly compact design and of simple construction, which keeps costs and space requirements to a minimum and easy to use.

Although a preferred embodiment of the invention has been described above it can undergo numerous changes within its framework.

Claims (11)

P a t e n t a n s p r ü c h e 1. Optical imaging device, characterized by a device (10) for receiving a data-carrying medium, which contains the data to be mapped contains a lighting device (11) for lighting the data-carrying medium around its circumference with greater brightness than in its center, an imaging station (3), a projection direction (19) for projecting the data from the data-carrying medium received light to the imaging station (3). wn to get a picture of the mentioned data on this, and a device in the beam path from the data-carrying medium for reduction the brightness of the image around its perimeter by an amount sufficient Obtain an image at the imaging station that is essentially insignificant throughout is of uniform brightness. 2. Apparatus according to claim 1, characterized in that the lighting device is formed by a light source (12, 13), which a Lich-tstranl on the data-carrying Medium directs, whereby the brightness of the light beam is greater around its circumference than is at its center. 3. Apparatus according to claim 2, characterized by. An institution (14) to adjust the position of the light source to change the lighting of the data-carrying medium. 4. Device @@ ch Ansp @@@ ch 2 or 3, characterized in that the Lichtouelle an essentially elliptical reflector (13) for forming the light beam having. 5. Device avenged the claims 2 to 4, characterized in that the light source generates a light beam that is divergent, and further a Condenser (18) is provided, which is arranged in the course of the diverging light beam is and da @ u serves to concentrate the light beam before it leaves the data-bearing Medium is recorded. 6. Device @@ ch claim 5, characterized in that the data-carrying The medium is on the slide and the concentrated light beam through this slide passes through. 7. Device according to claims 1 to 6, characterized in that the Linridrtung to reduce the brightness by a vignetting device (23) is formed between the data-bearing medium and the imaging station (3) is arranged. 8. Apparatus according to claim 7, characterized in that the projection device is formed by a projection lens system (19) and the vignetting device (23) is formed by a vignetting ring which is adjacent to the projection lens system is arranged and suppresses those light rays that go to the projection lens, stem with a sloping angle with respect to the optical axis of the lens system are directed. 9. Apparatus according to claims 1 to 8, characterized in that the imaging station (3) has a translucent observation screen (26) and the image on the underside of this screen for viewing from the top the same is projected. 10. Apparatus according to claim 9, characterized in that the imaging station also has a support (27) below the translucent plate (26) and for supporting a photosensitive medium at the imaging station serves in a print position. 11. Apparatus according to claim 10, characterized in that the support (27) is formed by a see-through screen below the observation screen (26) is arranged to accommodate a narrow space (28) between the two screens of the photosensitive medium.