DE2017848C3 - optical arrangement for mechanical scanning of an image generated by an objective - Google Patents

Description

The invention relates to an optical arrangement for mechanically scanning one of an objective generated image by rotating a mirror and a reflective polyhedral element over an axis perpendicular to the axis of rotation of the mirror with a mirror arrangement for receiving a Beam from a lens and for reflecting this beam. With known optical In arrangements of this type, the rotating polyhedron-shaped element reflects that of an object coming focused beam, so that the flatness of the reflected image is impaired will. Furthermore, in the known optical arrangement, the rotating polyhedron-shaped Element may be undesirably large if the image is to be scanned over a relatively large area.

The object of the invention is to provide an optical arrangement for mechanically scanning an image generated by an objective by rotating a reflective polyhedron without affecting the flatness of the image Increasing the speed of the rotating polyhedron, ·; and an increase in the scanning line frequency or the frame rate allows.

This object is achieved according to the invention with an optical arrangement of the type described at the outset solved in that in a known manner

ίο a first lens to convert the from the Mirror arrangement reflected beam in a parallel beam, in whose beam path the rotatable polyhedral element is arranged with a plurality of reflective surfaces, and a second Lens for creating a sharp image with the aid of at least one of the reflective Surfaces of the polyhedral element reflected beam are provided that the ratio between the focal length of the first mirror and the

ao first lens large and between the lens and the polyhedron-shaped element with reflective Surfaces an exit pupil is arranged. As in the optical arrangement according to the invention through the rotatable polyhedral element

he parallel bundle of lines is reflected, is the flatness the image generated by the second lens is significantly improved. By the invention In relation to the focal length, the diameter of the parallel bundle of rays is reduced, see above that a smaller rotating element is used to increase the speed of the rotating polyhedron can be.

From DT-PS 6 56 475 is an optical arrangement for image composition or image decomposition

known for television purposes, in which a first lens for converting the from the mirror arrangement reflected beam into a parallel beam, in whose beam path the polyhedral Element with multiple reflective surfaces

Chen is arranged, and a second lens for generating a sharp image using the from at least one of the reflective surfaces of the polyhedron-shaped element reflected beam are provided. This well-known arrangement,

which is to avoid that the lines drawn by the individual mirrors either overlap or gaps remain between them, so that light or dark stripes appear between the lines, In particular, the ratio according to the invention of the focal lengths in the one according to the invention is capable of Combination of characteristics not to be suggested.

The reflective surfaces of the polyhedron-shaped element expediently divide the parallel beam in two partial beams, with mirrors for reflecting and reuniting separately the partial bundle of rays to form a parallel bundle of rays and to direct it onto the second Lens are provided. The division of a parallel beam into two partial beams and their subsequent combination to form a parallel beam is from DT-PS 5 85 700 known per se.

In a further embodiment of the invention, the mirror arrangement consists of a concave mirror with a central Aperture and a pivotable plane, the rays reflected by the concave mirror through the aperture on the mirror projecting the first lens.

Embodiments of the invention are explained in more detail below with reference to the drawing. In this shows

F i g. 1 schematically shows a conventional system in a side view and

FIG. 2 shows the system according to FIG. 1 in a plan view; FIG.

Figs. 3 and 4 show on a larger scale Plan view of part of the system according to FIG. 1 and 2 to explain its mode of operation;

Fig. 5 explains in a schematic representation the principle of an afocal system used according to the invention;

6 shows a schematic plan view of an exemplary embodiment of the invention, x5

Fig. 7 also schematically in plan view further embodiment of the invention and

Fig. 8 is a plan view of a third embodiment of the invention.

F i g. 1 and 2 show a known reflective optical system, but the same principle can be applied to a refractive optical system. The illustrated in Fig. 1 and 2 optical system has a concave mirror 1 α and a first mirror 1 with an aperture 4. The focused by the first mirror 1 radiation beam R is reflected by a flat second mirror 2 and passes through the aperture 4 of the first Mirror 1. A polyhedron-shaped element 5, which is surrounded by a plurality of flat reflective surfaces 6, is arranged in the beam path of the beam that has passed through the aperture 4. The bundle of rays reflected by one of the reflective surfaces 6 generates an image in a suitably dimensioned opening 7, which image is received by an image receiver 8. The second mirror 2 oscillates about a horizontal axis 3 which passes through the intersection of the optical axis with the reflective surface of this mirror 2 and is at right angles to the optical axis. The polyhedral element 5 rotates in the direction of the arrow about a vertical axis 5 a. It can therefore be seen that the beam coming from the object is scanned in the vertical and horizontal directions.

In such an optical system, when the optical distance between the aperture 4 in the first mirror 1 and the opening 7, in which the image is generated, becomes too large, the second must Mirror 2 very large or the distance between the first mirror 1 and the second mirror 2 be small, when the system has a high light intensity or that arranged centrally in the curved mirror 1 Aperture is relatively large. Therefore, the aperture 4 of the first mirror 1 and the opening 7 are placed at a relatively short distance from each other and must be reflective Surface 6 of the rotating element 5 and the opening? be arranged at an even smaller distance from each other. With such a small distance The following occur between the reflective surface 6 of the rotating element 5 and the opening 7 Disadvantages on:

From FIG. 3 shows that the optical image 9 of an object before its reflection on the reflective surface 6 of the rotating element 5 has the required extent and the reflected central beam 10 of this optical image 9 in the opening 7 generates an image when the reflective surface 6 is inclined at an angle of 45 ° to the optical axis. 4, the reflective surface 6 must be rotated through an angle θ. This angle of rotation θ must of course become adhesive with increasing image angle or with increasing distance between the central beam 10 and the marginal beam 11 and with decreasing distance α between the reflection point on the reflective surface 6 and the opening 7. When the reflective surface 6 has been rotated through an angle θ , the point assigned to the opening 7 is not located at the location of the marginal ray 11, but according to FIG. 4 at location 12. In a coordinate system, the zero point of which lies on the central ray 10, the position of this point 12 is indicated with the help of the coordinates x, y as follows:

χ = - 2a sin ² θ
y = 2a sin Θ cos θ

As a result, the point 12 in the opening 7 is sharply imaged, while the marginal ray 11 in the opening 7 produces only a blurred image. When the angle θ is large as stated above, the value χ becomes considerably large and exceeds the practically allowable limit.

In addition to the above problem, another problem arises. So that the marginal ray 11 is reflected lossless, the reflective surface 6 must be so large that it is the whole optical image 9 can record, as shown in FIG. 4 clearly shows.

The problem of the flatness of the image can be solved by adding the reflective surface not at a point where the rays of light converge, but at a point where the rays of light are parallel, rotated or moved back and forth. In a place where the rays of light are parallel, namely, there is no image and the distance becomes an outside of the optical Axis arranged object point from the optical axis only by the angle of inclination of the from the beam emitted from the object point lying outside the optical axis the optical axis is determined.

F i g. Fig. 5 shows an afocal optical system in which a parallel beam is used.

According to FIG. 5 is from a point on the optical axis of a distant object emitted a beam 13 which passes through the afocal optical system and as Parallel beam 13 'is projected. One from one lying off the optical axis The beam 14 emitted at a point is projected as a parallel beam 14 '. So if that the aforementioned rotating polyhedron is arranged in front of or behind the afocal optical system, the scanning of an object with a certain extent takes place only through the change the angular position of the reflecting surface, so that the flatness of the image can be improved can. An arrangement of the reflective surface in front of the lens, however, generally has the Disadvantage that the reflective surface is relatively large

must be, making rapid scanning difficult, and located relatively close to the system Object the parallelism of the rays is impaired.

In preferred embodiments of the invention, therefore, an afocal lens is used the exit side of which is arranged a rotating polyhedron which is used for scanning.

F i g. 6 shows an embodiment of the invention. The optical system according to FIG. 6 has similar features to the system according to FIG. 1 and 2 a first mirror 1 with a concave reflective surface la and an aperture 4. The beam R is reflected from the reflective surface la of the first mirror 1 onto a second mirror 2, which has a flat reflective surface, and to generate an image 15 used at the focal point. From the image 15, the bundle of rays passes through the aperture 4 in the first mirror 1 and is converted into a parallel bundle of rays by an objective 16 adjacent to the aperture 4. A rotating polyhedron-shaped element 17, which has a plurality of reflective surfaces 10, is arranged in the beam path of the parallel beam emitted by the objective 16. The parallel beam is reflected by one of the reflective surfaces 10 and passes through an imaging lens 19 which generates an image in the opening 7 that is received by an image receiver 8.

If the lens arranged on the exit side of an afocal optical system consists of a If there is a convex lens, an exit pupil can be seen behind this lens through which the entire bundle of rays passes occurs. One can reduce the diameter of the exit pupil if the ratio between the focal length of the entrance lens and the focal length of the lens on the exit side of the System is great. This exit pupil is shown in FIG. 5 denoted by 20. In the arrangement according to FIG. 6 is the reflective surface 18 of a rotating polyhedron hair dryer Element 17 arranged at the location of the exit pupil of an afocal system that consists of a first mirror 1, a second mirror 2 and an objective 16, and is the ratio between the focal length of the first mirror 1 and the lens 16 large, so that the rotating polyhedron-shaped Element 17 can be relatively small.

The afocal system also has the following advantages: Even if the beam is at the exit pupil in two or more Heinere Teflstranlenbundel shared, all of these can be smaller Partial beams of rays are imaged at a point scfaaif if they are simultaneously and below the same Angle of incidence enter the lens. This measure enables a procedure to be carried out in which the bundle of rays through the simultaneous use of two or more reflective Surfaces of the rotating polyhedral element instead of just one reflective surface in two or more several smaller partial beams are split, which are then combined again. At the same time

ίο use of two or more reflective Surfaces for a bundle of rays of a fixed size can of course be made by the individual reflecting surface be smaller, so that the rotating polyhedron-shaped element can be made considerably smaller.

This facilitates the spatial layout of the entire optical system and enables the rotating polyhedral element with the help of a weak motor with such a high one To rotate the speed as it would with a large rotary

ao generating element could not be achieved. This increases the scanning speed. Man can therefore obtain an advantage that the scanning line frequency or the frame frequency can be increased can.

as an embodiment with these advantageous Features is shown in FIG. 7 shown. The parallel bundle of rays emitted by the objective 16 is here from the reflective surfaces 21 and 22 of a small rotating polyhedral element 17 ' divided into two reflected beams, which are reflected by the fixed mirrors 23, 24 and 25 and are reunited to form a single bundle of rays, which is taken from the imaging objective 19 is used to generate an image in the opening 7.

In the exemplary embodiments according to FIGS and 7, the rotating polyhedron-shaped elements are in the shape of tetrahedra, but understand it that the above feature can also be used in systems in which the polyhedral element another shape, e.g. B. according to FIG. 8 has the shape of a hexahedron.

From the above description it can be seen that when mechanically scanning an optical image the flatness of the image improved and a slightly smaller rotating polyhedral element can be used when using an afocal optical system. Furthermore, it goes without saying that the size of the rotating polyhedron

so the element can be considerably reduced and its speed increased when one has two or more reflective surfaces of this element are used at the same time to split the beam.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Optical arrangement for mechanically scanning an image generated by an objective by rotating a mirror and a reflective polyhedral element about an axis perpendicular to the axis of rotation of the mirror with a mirror arrangement for receiving a beam from an objective and for reflecting this beam, characterized in that in a manner known per se a first objective (16) for converting the beam reflected by the mirror arrangement (1, 2) into a parallel beam, in whose beam path the rotatable polyhedral element (17, IT) with several reflecting surfaces (21) is arranged, and a second objective (19) for generating a sharp image with the aid of the bundle of rays reflected from at least one of the reflecting surfaces of the polyhedral element (17, 17 ') are provided that the ratio between the focal length of the first mirror (1) and the first Lens (16) large and between the ob jective (16) and the polyhedron-shaped element (17, 17 ') with reflective surfaces (21) an exit pupil is arranged. 2. Optical arrangement according to claim 1, characterized in that the reflective Areas (21) of the polyhedron-shaped element (17 ') split the parallel beam into two partial beams divide and that mirror (23,24,25) to reflect and reunite separately the partial beam 7U a parallel beam and are provided for directing it onto the second objective (19). 3. Optical arrangement according to claim 1 or 2, characterized in that the mirror arrangement (1) from a concave mirror (la) with a central aperture (4) and a pivotable, planes, the rays reflected by the concave mirror (la) through the aperture (4) on the first lens (16) throwing mirror (2).