DE682925C - Process for the television disassembly and for the reconstruction of images - Google Patents

Description

The invention relates to a method and an apparatus for television viewing Disassembly and reconstruction of images by means of two mirror systems that are angularly moved around axes of rotation on different planes and aims to create improvements that make it possible when using two mirror deflection systems a small number of mirror surfaces of the system rotating at high speeds get along, with the number of image lines being changed several times at the same time without changing the structure of the apparatus can.

Another advantage of the invention is that reproduction is as distortion-free as possible to see the light impressions.

In television or in image telegraphy, it is known to use the rays to build up the image of a light beam by moving mirror surfaces around an axis and deflecting them deflected beams to a second mirror deflection system, which is in axis lying perpendicular to the first system is moved. One thing serves here System is known to have a line structure, while the other system is used to advance lines is used.

If in the original arrangements the mirror surfaces were placed on drums are and these drums are rotated about the respective axes of rotation, the main disadvantage of these arrangements results, that for the lowest possible distortion many sub-areas mounted on a drum of larger size that the Mirror planes must be matched to the most precise in their sequence and that nevertheless the image planes are not at a constant mean distance from the lens system can be passed through the beam. The consequence of this is that at the beginning and at the end of the procedure A deflecting mirror plane in the bundle of rays results in focus losses and unevenly shaped, non-parallel or not concentric lines are created. These difficulties are particularly evident when Transmitters and receivers working with the same devices are coordinated with one another . should be, as it is difficult at the sending and receiving location with the same type of deflection errors to build provided mirror drums.

This difficulty arises because the light beam has an angular movement and

■ a linear displacement is given at the same time, the light resulting from the different radii between the axis and the respective point of incidence on dari mirrors. "V ·

Furthermore, the disadvantage of known devices is that according to the desired number of lines to be scanned on a large amount of mirror surfaces ίο These bodies of revolution have to be accommodated with consideration for the limited inertia of the eyes must be moved at high angular velocity.

Attempts have therefore been made to put at least> 5 part of the two-part beam deflection in the rest position and to use only one mirror drum that works with limited mirror surfaces. This arrangement also suffers from the lack of distortion of the light incident on the mirror drum in the reflection, but on the other hand from the very significant disadvantage that the line advancement, i.e. the number of lines, is extremely limited and the angular position of the stationary mirrors to each other for uniform line progression must be adapted to the most accurate, will not suffer _v distortions in the height dimensions.

To avoid the disadvantages of a mirror drum, it is. has already been proposed to use a body of revolution, the one with helically twisted mirror surfaces is working. This body of revolution is intended to be used either on its own or in conjunction with another scanning apparatus come. However, the helical surface, which is used here as a deflecting mirror, is inevitable is used, curved so that the focal point of the incident Ray must change very substantially as it progresses.

The invention now consists in the fact that the rays of the intensity-controlled during the image construction Light beam from one to two or more in different angular positions to the common axis of rotation arranged mirror surfaces divided, oscillating back and forth Mirror system deflected and one of several to the common axis of rotation parallel, but angularly offset mirror lamellae constructed, rotating Mirror system are fed. Those of the mirror surfaces of the swinging 5.5 System are light bundles cut out of the entire beam directed to the axis of the rotating system, and by means of each to the effect They produce the number of sub-surfaces on the coming mirror surface of the rotating system of the oscillating system following each other on the screen. The angular velocities, the divisions, and misalignments are coordinated here and angular positions of the surfaces of the two mirror systems to one another such that kr uninterrupted sequence of the image lines built up by the rotating system from vibrating system are advanced and that in the image decomposition in the reverse Beam path light impressions in a continuous sequence of scanned image points to a light-sensitive Element.

First, the invention eliminates focal errors in that it basically combines all mirror planes with the axes of angular movement. In addition, it enables a reduction in the mirror surfaces of the rotating system which is used for cell construction at a high number of revolutions. According to the invention, the second system, which serves to advance the line, is divided into partial areas which pivot back and forth in an angular position to the axis of movement around the axis of movement so that the light beam cut out of the total light beam from each partial area is fed to the axis of rotation of the rotating system. Characterized in that ausgeschnit- from the incoming light beam different partial light beams _go th and the rotating mirror system are fed, there is the possibility, the mirror surface of the rotating system to have a plurality of successive points of light on the slide to be formed luminous surface. Therefore, it need on the rotating system, only lower masses to be moved, so that errors of rotating at the high rotational speeds systems are due to centrifugal forces, to the smallest possible degree _{ίΟ ο} a limitation experienced. Depending on how many partial areas are used on the oscillating system, the number of pixel rows to be built up per mirror surface of the rotating system can be changed. However, the number of lines can also be determined by the oscillating movement of the oscillating system without changing the mechanical structure of the apparatus, since one is free to choose the ratios of the n ₀ angular movement of the oscillating and rotating system, but only pay attention to that in the event of such a change in this movement ratio, the continuously subsequent succession of individual rows of pixels is guaranteed.

With the arrangement according to the invention, the mirror surfaces are included from the start If the axes of rotation of the rotary motion are brought into agreement, differences can easily occur between transmitter and receiver by means of simple speed controls on the

rotating and the vibrating system are balanced, so that a distortion-free Image can be both scanned and reproduced. In the drawings is an arrangement shown according to the invention.

Fig. Ι shows a plan view of a device, which can be used both for scanning and for image construction. ίο Fig. 2 shows a side view of the same Contraption.

Fig. 3 shows the optical scheme of the method according to the invention.

From the converging lens CL according to FIG. 3, the area of the light from a point of light Li is thrown onto an oscillating system OD , which is divided into individual partial mirror surfaces A ₁ B ₁ C in the space of the light bundle SB . These dividing surfaces A ₁ B, C oscillate about a common oscillation axis so that this axis passes through the vertical center lines of the mirror planes, while the mirror planes themselves are in this position with their narrow sides at an angle to the oscillation axis. For example, three mirror surfaces A ₁ B ₁ C are shown in the diagram of FIG. 3, which in the arrangement shown oscillate uniformly to and fro about these oscillation axes which are common to all three.

For this purpose, according to the embodiments of FIGS. 1 and 2, three mirror surfaces 13 of a pivoting device 31, 32 are embedded in such a way that they are held by brackets 15 which are fastened to a support frame 19 in such a way that they can be adjusted by means of adjusting screws or any other setting means 27 the precise adjustment of the center lines of the mirror surfaces 13 to match the axis of rotation is made possible. At the same time, these mirror surfaces are held by ball joints in the frame 19 that they are able to assume any adjustable angular position relative to the pivot axis. A further setting of this mirror support frame 19 with respect to the axis of the pivoting device 31, 32 is provided with the retractable holder 33, with which the support frame 19 is attached to a crank-shaped support arm 31. This crank support arm 31 is pivotably mounted in bearings 32 and has a pivot arm 46 for controlling its pivoting movement, which is controlled by a pivot lever via a coupling member 45. This pivot lever 41 is mounted in support bearings 43 of the overall housing 12 and, under the pressure of the leaf spring 41 ^s, inevitably rests against an eccentric 40, which is attached to a continuously rotating shaft 40 ° and causes the oscillating back and forth movement of the oscillating arm 46 and thus the oscillating device 31 . The inclined position of the oscillation axis to the incident light SB and the angular position of the individual mirror surfaces 13 and A ₁ B ₁ C to the oscillation axis is chosen so that the light beam a, b, c (Fig. 3) cut from the light beam SB each on the axis of a is aligned on the same base plate 12 mounted rotating mirror deflection system RD. This rotating system consists of a support body 47, in the interior of which mirror surfaces 52 offset at an angle to one another are arranged one below the other so that the axis of rotation of the support body 47 passes through the central planes of the mirror bodies 52. These mirror bodies 52 are also provided with mirror surfaces on their rear side and are kept thin-walled, so that in this double-sided mirroring embodiment the deviation of the reflection plane from the axis of rotation is only slight. In the case of one-sided mirroring and a correspondingly larger number of mirrors used, possibly also a higher speed of the system 47, the mirror lamellas can be brought with their planes exactly in accordance with the axis of rotation of the rotating support body 47. This support body 47 is connected at its base 48 to a shaft 51 of the rotary drive of the device. The upper part 47 of this support body is provided with window openings in accordance with the incidence of the partial bundles of rays a, b, c deflected by the oscillating device or is made of transparent material as a support body with its entire wall.

The light strips a, b, c cut out of the light bundle SB by the mirror subdivision on the oscillating system OD are brought together on a single narrow light bundle which coincides with the rotation axis O (Fig. 3) of the rotation system RD in the central axis, but according to the »05 Number of sub-surfaces impinging at different angles of incidence. If several partial mirror surfaces are arranged one below the other on the axis of rotation O of the rotating mirror system RD , these mirrors, which are attached one below the other and in a progressively angular position to one another, cut out bundles of rays one after the other in their mirror planes and concentrate these bundles of rays after reflection, thanks to the converging lens effect CL, to form a reproduction image point that wanders over the image area of the display screen S. Thanks to the different setting angles of the light strips a, b, c on the rotating mirror surfaces K ₁ L ₁ M ₁ N , however, a bundle of rays from each of these rotating mirror surfaces does not become a point

Concentrated guided over the image surface, but as many image points as partial mirror surfaces are arranged on the oscillation system OD. These pixels follow one another at a certain distance. The distance between the image points depends on the distance of the oscillation system ÖD from the rotation systemi? D and the resulting angular position of the partial mirror surfaces A ₁ E ₁ C to one another, and also depends on the focal point of the converging lens CL, which in turn determines the image distance of the surface S from the rotary mirror system RD . If, for example, in FIG. 3 the mirror surface K has its three pixels ak, bk, ck passed over the image surface 6 ″, the next mirror surface following in a cyclic arrangement, for example N, with the same pixel spacing, as shown in FIG new transport of three new, to successive pixels, but according to the lower position of the reflection surface N in relation to the reflection surface K in a lower plane, in the example of FIG. 3, the deepest level of the image 5. ¹ in this transport of three to successive pixels the image points in the next higher level follow the mirror surface M, the mirror surface L and then in turn the mirror surface K.

If the oscillation system OD were at rest, then exactly as many image point lines would arise on the screen in a cyclical sequence in accordance with the number of mirror surfaces arranged spirally one below the other on the rotation system RD. Thus, according to the example in FIG. 3, the image S would only be rasterized by four pixel lines, that is to say four lines. In order to avoid this coarse rasterization, ie to reduce the line spacing, the oscillation system OD can oscillate about the common oscillation axis. From the sequence of the partial surface K, L ₁ M ₁ N assigned to each mirror, one after the other

: the following image points a, b, c with the corresponding index, it is understandable that one aligns the oscillating movement according to the desired line spacing. The visual swinging movement can be adjusted, for example, so that the beam bk reflected by the surface K and concentrated as a pixel records a new light line when it hits the screen S above the line of light recorded by ak. Correspondingly, if the oscillation system OD continues to oscillate, the subsequent light point ck would record a line of light beginning on the screen 6 ¹ that is just as much higher. With the setting of the oscillation system, one has to change the spacing of the lines which are recorded on the screen by the passing of the successive points ak, bk, ck and thus with the simultaneous aid of the known light point concentrations through the converging lens CL den from the mirror surface K swept strip section of the picture 6 * to meet as evenly as possible. The limits within which the oscillation of the oscillation system OD is carried out lie in the sufficient illumination of a partial mirror surface of the rotating mirror system RD. Depending on the oscillation speed selected, the successive image points a, b, c with index either in increasing or decreasing order or even in cyclic interchanging of the lines of the painted image points over the image area '^. A firm instruction is not given for this, as it is up to the person presenting the picture to use the most varied of options depending on the lighting and the desired grid pattern. The rotating and oscillating systems only have to be placed on top of one another with respect to their mirror rotation or inclination and with respect to their movements so that uninterrupted scanning or scanning of the image surface is made possible.

The same optical conditions for the construction of an image, as described above, apply in reverse order to the decomposition of an image illuminated on the image surface 5 of FIG. 3. In this case, in reverse order, the beams ak, bk, ck uninterruptedly scan the image surface one after the other in a cyclical sequence. The light of the scanned image point is fed from the rotating system RD to the respective partial mirror surfaces A ₁ B ₁ C of the oscillating system and fed from this system OD and with concentration to the converging lens CL of the light-sensitive cell or the like.

The device described can also be used for checking the transmitter by then appropriately set a modulated light source and the coming from it Light is thrown onto the oscillating and rotating deflector, from where it is then onto a test screen for assessment the quality of the image transmission.

Claims (4)

Patent claims: i. Method for the television disassembly and for the reconstruction of images by means of two mirror systems moving around axes of rotation on different levels, characterized in that the rays of the intensity-controlled during image construction Beam of light from one in two or several arranged in different angular positions to the common axis of rotation Divided, back and forth swinging mirror system deflected and one of several to the common axis of rotation parallel, but angularly offset mirror lamellae built, rotating mirror system that the to from the mirror surfaces of the oscillating system from the total beam cut out light bundles are each directed to the axis of the rotating system and by means of the respective to Effect coming mirror surface of the rotating system in the number of partial surfaces of the oscillating system each other The following rows of pixels produce on the screen that the coordination of the angular velocities, the divisions, Displacements and angular positions of the surfaces of the two mirror systems to one another takes place in such a way that in uninterrupted Follow the image lines built up by the rotating system from the oscillating one System are advanced and that with the image decomposition in the reverse beam path light impressions in running Sequence of scanned pixels are fed to a light-sensitive element. 2. Apparatus for carrying out the method according to claim 1, characterized in that side by side mirror partial surfaces (A ₁ B, C) of an oscillating device (31) are arranged adjustable so that the common oscillation axis of the mirror planes oscillating in different angular positions to the oscillation axis (13) goes through the vertical center line of the mirror planes. 3. Apparatus for carrying out the method according to claim 1, characterized in that that one below the other arranged, angularly offset mirror lamellae (52) a rotatable carrier (47) are so adjustable that the 'axis of rotation of the carrier lies in the mirror planes of the mirror blades. 4. Apparatus according to claim 3, characterized in that reflective on both sides Mirror slats (52,53) a windowed or transparent one Carrier (47) are stored so adjustable that the axis of rotation of the carrier (47) in the central planes of the mirror body (52, 53) lies. 1 sheet of drawings