DE1572672C - Imaging system with an electro-optical prism chain - Google Patents

Description

Prisms are applied changeable electrical voltages and thereby generate electrical fields, which enable the variable deflection of the light beam passing through to be controlled. A disadvantage of the previous deflection systems with electro-optical prism chains for practice is their extraordinary Length, that is, the large deflection and high resolution required for the large-scale display requiring an extremely long chain made up of a multitude individual prisms. The number of possible red dot positions is displayed under resolution understand the display panel. Since each prism in the chain is very expensive, the cost was low Such arrangements are not to be used in most applications. It is also known that the power requirement required to operate such an arrangement corresponds to the length of the Arrangement is directly proportional, so that powerful power sources in these previously known prism chain systems were required.

It is also an arrangement for light control became known in which, depending on external conditions, the polarization of light rays being affected. The degree of influence is then determined by suitably designed receptors determined and evaluated in terms of an intensity fluctuation. As in the known arrangement a larger number of optically active elements can be connected in series is a parallelization of the light rays passing through is necessary in order to reduce the losses to an acceptable level To keep boundaries. This purpose is served by a focusing optics upstream of the actual arrangement. Measures for the spatial deflection of the light beams are in the known arrangement Just as little planned as measures to shorten the overall length.

The invention is based on the object of providing an imaging system of the type described at the beginning to create that manages with a smaller number and size of the prisms to be used.

This object is achieved according to the invention in that at one end of the chain an optical System for focusing the parallel light beam and also at least on the opposite one At the end of the prism chain is a reflector, which is used to repeat a bundle of rays emerging from the chain Refraction in the chain reflects, are arranged.

In this way it is possible to spatially concentrate the light beam and to "fold" it to let the system pass several times, which is the size of the electro-optical prism chain system reduced and yet enables a large distraction to be achieved, as is the case for the applications mentioned is required. In this way, not only the manufacturing cost but also the operating costs for such a system are significantly reduced, since in operation to achieve the desired Distraction only a relatively small amount of power is required.

In one embodiment of the invention, a the input beam before entering the prism chain in one direction of its cross-sectional plane condensing optics and another after Reflection on the mirror from the system exiting ray bundle back to its original Optics bringing cross-section provided. In this way it is possible to change the dimensions of the prisms to reduce it further without losing any information. As a result of this reduction, both as a result of the lower material requirements, the manufacturing costs and as a result of the lower energy consumption, the operating costs are further reduced.

In a further embodiment of the invention, they are optically aligned with one another in front of the prism chain an an input beam as ordentr

ίο borrowed beam rectilinearly transmitting prism, one condensing and compressing the beam in at least one plane when passing in one direction when passing in the opposite direction, optics expand again and the plane of polarization of the Beam provided by a certain angle rotating device. That shows Prism has an inner reflective surface, which the bundle of rays emerging from the chain again after its second pass through the. Polarization level rotating device and through deflects the optics as an extraordinary ray in an exit direction. In this way it is possible get by with just one optic that is used twice. In addition, this arrangement Build up smaller because of the omission of the additional optics otherwise required on the side of the prism chain than those previously described.

The subject matter of the invention is explained in more detail with reference to the exemplary embodiments shown in the drawing.
It shows

Fig. 1 is a side view of a conventional electro-optical Prism chain,

F i g. 2 a schematic representation of a prism chain arrangement according to the invention with associated optics, with which a first-order beam folding and compression of the beam can be achieved,
. F i g. 3 shows a schematic representation of a preferred embodiment of an electro-optical prism chain arrangement according to the invention, which has an optical system for beam compression and beam folding of theoretically any high order, and

F i g. 4 is a schematic representation of another arrangement according to the invention, with which in a electro-optical prism chain a beam folding at least 1st order can be achieved.

It is known that for electro-optical prism chain systems Crystal prisms made of certain materials are used that not only have the property have the ability to refract a continuous beam of light, but are also able to change their refractive index when on opposite surfaces of the prism crystal a voltage generating an electric field is applied. The change in the index of refraction of the prism under the influence of an electric field is characteristic of ferroelectric Crystals. Various crystals are commonly available which exhibit this described property. One of the cheapest materials is the material known as KDP and its isomorphs, from which has been found to have a high optical quality, easily and with poor quality Cost is available. In detail, KDP is a crystalline substance, more precisely under the name Kaliumdioxidhydrophosphat (Potassium dioxide hydrogen phosphate) is known, but here with its usual name is called KDP. It

It goes without saying, however, that other substances with electro-optical properties can also be used in accordance with the invention Can be used.

Fig. 1 shows one typical of the prior art electro-optical prism chain. A plurality of prisms 10 are arranged adjacent to each other so that that their C-axes alternately point into and out of the plane of the drawing. Electric Lines 12 are used to apply voltages and generate suitable electrical Fields on opposite surfaces of the prisms. Of course, they must be opposite to each other Surfaces of the prisms covered with a suitable and customary electrically conductive material to which the voltage can be applied. Instead, a known other arrangement can also be used can be used in which the prisms are arranged with their C-axes in one direction, for example into the plane of the drawing. However, this arrangement requires that each prism 10 a receives independent electric field, and has the disadvantage that one on both sides of the arrangement Interference field occurs.

A beam of light 14 enters the system at the left interface and is continuous to broken to the exit point at surface 16; the maximum deflection of the beam is given by the The exit direction of a beam 18 is shown. The respective beam deflection of each system is easily done by changing the electrical applied to the prisms within the system Fields controllable so that the deflection of the occurring beam in the plane of the drawing Wish is adjustable.

As already mentioned, these systems are because of the large number of individual prisms that are used to achieve the resolution as required for use in display devices with a large image field is required is extremely expensive. The multiplicity of prism units also requires a high one Feeding power.

In Fig. Figure 2 illustrates a first order convolution of the beam. A beam 20 occurs in a consisting of the lenses 22 and 24 optical system that the beam in a Compressed direction that is perpendicular to the plane in which the beams are deflected target. So leaves a rather thick cylindrical light beam 20 with a uniform circular cross-section the lens 24 as a radiation beam 26 with a rectangular cross-section, which is in the plane of the drawing for reduction its vertical extent was condensed. An electro-optic prism chain 28 includes Prisms 30 in the arrangement already described. Is adjacent to the exit surface 34 of the system 28 a mirror reflector 32 is arranged. The beam 26 enters the system 28 through the surface 36, experiences a first deflection, leaves the system through surface 34, mirror 32 in the system 28 is thrown back and exits again at the surface 36 as a beam 40. At the second passing the system 28, the beam is deflected a second time, so that the entrance beam 26 experiences a total distraction that is the sum of the distractions on each pass composed. It can be said that the beam passes through the electro-optical Prism chain is »folded through«. The emerging beam 40 is from a mirror 42 thrown into an optical system consisting of lenses 44 and 46, which the bundle of rays in the Expands in the direction in which it was compressed, so that an output beam 48 results which the has the same cross-sectional size and shape as the input beam 20. It becomes special pointed out that when the beam is compressed in a direction perpendicular to the plane of deflection the resulting resolution for display purposes is not affected.

F i g. 3 shows a folding system in which one can speak of an n-th order convolution. Again, an input beam 50 is condensed in one dimension by optical lenses 54 and 56 and then results in the bundle of rays 52. The bundle of rays 52 passes through a surface 58 into the an electro-optical prism chain 60 and traverses it as a narrow bundle of rays pointing to the upper

so meets part of the surface of a mirror 62, which in is located near the surface 64 of the chain 60. A second mirror 66 covers a section of the Surface 58 of the prism system and receives the beam reflected from the mirror 62, which it in turn reflected back to the mirror 62. The folding and repeated sending of the The bundle of rays through the chain 60 can take place as often as desired. A small portion 68 of surface 58 is located below the reflective surface of mirror 66. That incident on this section folded beams 70 can exit the system and fall on a reflective surface 72, which is optically aligned with lenses 74 and 76, which again the bundle of rays condensed in one direction expand and provide an output beam 78, whose cross-sectional size and shape that of the. Entrance beams 70 are the same. It is clear that use of the system of FIG. 2 dem. Gives the designer the opportunity to provide as many passages or deflections of the beam, as needed to achieve the desired total distraction.

F i g. 4 shows a comparison with the arrangement according to FIG. 3 somewhat modified system, which is a Gran - Thompson prism 82 has. In this system: the prism allows parallel input beams 80

, ^! pass in a straight line as an ordinary jet and exit at a surface 84 so that it

Lenses 86 and 88 pass through its cross-section. In the path of the condensed bundle of rays there is a device which rotates the plane of polarization and controls the plane of polarization of the light rotates by 45 °. The rotated light beam is now directed onto an electro-optical prism chain 94, that it passes to achieve a suitable deflection and at the end of which it passes through a mirror 96 is reflected. The mirror 96 sends the beam back through the system 94, whereupon the The beam again passes the device 90 which rotates the plane of polarization so that its plane of polarization is rotated again by 45 °. The beam is then through the lenses 88 and 86 re-. V brought to its original cross-section * ;; and then penetrates as an extraordinary ray a plane of polarization rotated by 90 ° with respect to the ordinary beam 80 into the prism 82, so that it is reflected on the angled surface 98 due to the properties of the prism. After that, will

the output beam 100, which in its cross-sectional dimensions corresponds to the input beam 80 is the same, projected. The use of a device that rotates the plane of polarization enables it, to achieve the desired deflection by the fact that the bundles of rays the chain 94 in opposite directions Simultaneously traverse directions. It can be seen that an apparatus with a Electro-optical prism chain was created in which the number of individual prisms needed to achieve a high deflection is required is substantially reduced. The system results in those for large display devices of the aforementioned type required total distraction. This total distraction will reached without loss of resolution, although the beam condenses in one of its transverse dimensions will. The multiple successive passing of the beam through the optical deflection device and then restoring it to its size enables the final projection on the appropriately arranged and improved display area. The facilities shown are both economical and advantageous as compared to known such devices with regard to the set-up effort as well as with regard to the power consumption during operation.

1 sheet of drawings

Claims (7)

in the one with an electro-optical prism chain, the ■ '.. · .. from a number spatially arranged next to each other. Imaging system is using abge _r neter optically series-connected electro-deflected light beams in which, with an electro-optical prism, an optical prism chain in the prism chain which incident parallel light beam into minderäumlich juxtaposed optically least one dimension deflected from a number 5 controllable will,
series-connected electro-optical Pris- Such imaging systems, which with the usual men, an incident or coherent one in the prism chain. Light can be operated, parallel light beams in at least are particularly suitable for controllable large-area one dimension is controllably deflected, so representations. characterized by the fact that such display systems can be used to At the end of the chain an optical system (22, 24) can be used to detect messages or other information Focussing the parallel bundle of light rays from organizing groups that are far from each other (20) and continue to be directed at least on the opposite side, which is subject to a central management The end of the prism chain (28) is a reflector 15. So far, such systems have predominantly (32), a radiating cathode ray tube emerging from the chain for visual display bundle inserted into the chain for repeated breaking. A disadvantage of the systems with cathodes, are arranged. ray tubes is their relatively small display area. 2. Imaging system according to claim 1, that such systems can also color display impermeably marked that the optical input ao gene not exactly .reproduzieren. On the other hand, they are sufficient system (22, 24) the cross-section of the entrance- the requirements for high deflection speed beam (20) before focusing in speed, high resolution and more precisely in a direction of its cross-sectional plane display control. ringert and another optical system (44, 46) To achieve larger display areas, were which, after the reflection of FIG. 25, various mechanical and other display methods is arranged the beam exiting the system (40) as proposed. Most mechanical systems which brings to the original cross-section. are unable to get the required high 3. Imaging system according to claim 1 or 2, to realize working speeds. Known, characterized in that having implemented non-mechanical devices at both ends the prism chain (60) the bundle of rays again- 30 is expensive in terms of purchase and as fetches conductive reflectors made unwieldy in operation due to the arrangement. (62 and 66) are arranged. A non-mechanical system used for large 4. The imaging system can be used according to one of the previous positions and is color-efficient going. Claims, characterized, is made by an electro-optical prism chain that the optical axis of the input system and 35 uses. Electro-optical prisms are in the the longitudinal axis of the prism chain is known to a blunt specialist world and have a beWinkel in cross section form with each other. seeks triangular prisms made of certain fabrics 5. Imaging system according to one of the previous ones, which has a light beam passing through going claims, characterized in deflecting refraction. These substances also have the that a radiation emanating from the system is a property that it passes through under the influence of a bundle to another optical system (74, 76) applying a voltage to opposite ends directing reflector (72) is provided. the electric field generated by the prism 6. Change the imaging system according to one of the forecast indexes proportional to the field strength, billowing Claims, characterized by the deflection of the passing light beam that the juxtaposed prism 45 is changed. Therefore, by appropriate touch the men (30) of the chain (28). Control of the electro-optical prisms 7. Imaging system according to claim 1, the field acting there, the deflection of the light beam, characterized in that change in front of the prism chain. In this way, the emerging (94) optically aligned with one another a single light beam can be directed onto each of a multiplicity of point-entry beam bundles (80) as a regular beam 50 of a display panel. A prism (82) that allows axially straight transmission, a characteristic of an electro-optical prism, the bundle of rays in at least one plane mas or such a prism chain is condensed when passing in one direction that a ray is deflected only along a line, ends and when passing in opposite. so that optics (86, 88) which expand into a two-dimensional light beam direction and an angle on a display field of several such chains of polarization planes of the beam (92) must be arranged optically one after the other. The deflection planes rotating a certain angle must be perpendicular to each other, (90) provided and that the prism has a beam bundle which, with coordinated control of the respective inner reflective surface (98), gives the system a two-dimensional display field either again exiting the chain 6 ° after a grid or in any way after its second passage through which the can be scanned or swept over.
Devices and systems that rotate the plane of polarization and have electro-optical prism chains around a large number of electro-optical prisms that steer through the optics in an output direction. are optically arranged next to each other in series. the 65 C-axes of neighboring prisms run parallel to each other in alternately opposite rich dies Invention relates to imaging in order to achieve the desired effect. On system using deflected light rays, opposing surfaces of each