DE495546C - Arrangement for television using the principle of the rotating perforated disc - Google Patents

Description

Arrangement for television using the principle of rotating Perforated disc Most of the known television methods are used on the receiving side the perforated disk specified by N i p k o w, which when passing through the image area releases the individual pixels one after the other. When looking at the rotating Disc, the gaze falls through the holes wandering past the modulated light source. With this method there must therefore be a modulated light field behind the image area located, which is the same size or larger than the viewing area. at The use of modulated glow light is therefore placed behind the pane Glow lamp on, the cathode of which is appropriately sized somewhat larger than the image area. With one revolution of the disk, only one point is modulated as a whole If the glow layer is touched, there are no significant sanctities involved in this process let reach. Furthermore, the size of the transferred images is limited, because the production and modulation of larger glowing surfaces encounters difficulties.

The invention relates to an arrangement which also permits with modulated glow light, significantly greater brightness and image sizes than with to achieve the previously known method. The arrangement according to the invention is characterized in that behind the holes of the perforated disc or on the Place mirrors, which are arranged so that one in the line of sight the ray of light cast by these mirrors into one of them of the observing eye is reflected on all surfaces passed through. Examples of this are shown in the figures.

In Fig. I a Nipkow perforated disk is drawn, which is for simplicity only has six holes. In the side elevation (Fig. Z) are for hole i and hole q. the mirrors 7 and 8 arranged according to the invention can be seen. When walking through of the indicated image field io becomes the viewing direction - or, more precisely, a light beam thrown in the viewing direction -of the according to the invention under q.5 ° arranged mirrors in a surface 9 (Fig. 2) reflected, namely this is Area for all holes and mirrors during the period in which they are in the field of view go through the same.

While in the already known method the holes when passing through of the image field scan a luminous surface, feel it in the inventive Arrangement the projection of a surface, d. H. practically a straight line. That modulated The light field no longer needs a Represent area, but can in the method according to the invention from a line-shaped light source or, if it is arranged in the axis of the disc, may even consist of a point light source. The highest Efficiency results when you place a rotating mirror polygon on the axis of the disk puts, , which is the collected light of a modulated light source on the pixel mirror 7, 8 steers. This mirror polygon is allowed (if the light source is outside the axis) of course only rotate at half the speed like the image splitting disk, since the rotation of a mirror produces the reflected beam always deflects by twice the angle by which the mirror is rotated.

The arrangement according to the invention shows very considerable advantages Use of modulated glow light. The cathode of the glow lamp used needs no longer to be the same or larger than the image field io, but it can a smaller sized cathode can be placed in plane 9 so that only the image their glow layer from the mirrors 7, 8 of the disk into the eye of the beholder is reflected. It is also evident in the arrangement according to the invention a significantly greater brightness is achieved, as there is not only one point of the glowing Cathode, but its entire depth, almost its entire surface for effectiveness comes. You can also work with a partially covered cathode, if necessary, where the control is known to be the cheapest.

It is readily apparent that when using the invention Arrangement can also be achieved significantly larger image areas than before, since only the length of the glow path or its position requires an adjustment to the image size, while their depth only determines the brightness of the image that appears is.

Instead of using a disc provided with holes in which mirrors are located behind the holes, it is of course just as possible to use the mirror surfaces 7, 8 themselves to define the pixel size. In doing so, it is possible in a simple manner to achieve greater scattering, so that a bright image still appears even when the pane is viewed from an angle. This is done by making the mirror surface 13 slightly convexly curved as shown in FIG. If you illuminate a convexly curved mirror with parallel or central light, only one point appears bright to the viewer from every direction, while the rest of the mirror appears dark. Thus in Fig. 3 the observer a sees only the point A of the mirror 13, the observer b only the point B as a luminous point within the relatively much larger hole opening 12 of the Nipkow disk i i.

It is of course advisable to use the modulated light source if possible to get close to the image field io within which the image appears, so that the image point mirrors 7, 8, 13 each have a radiation angle that is as large as possible be able to absorb and pass on. You can use the modulated light source either below or to the side of the image field i o, with of course the image point mirror must be aligned accordingly. Particularly It is useful to arrange the modulated light source above or below the image field, because then, due to their horizontal expansion, even when viewed at an angle Still a bright image appears provided the observer's eye level is the same remain. However, it is easier to achieve the same eye level when there are several observers like the same direction of observation, which latter also applies to the per se possible lateral arrangement of the light source is a prerequisite for a clear picture would be.

The invention makes it possible, among other things, to increase the number of pixels, the image brightness or the transmission speed by modulating several light sources at the same time and allowing only part of the resulting image to be generated from each of them (see Fig. Q.). So you can z. B. modify the arrangement of Fig. 2 in the simplest case so that one half of the mirrors 7, 8 along the axis i q. to, ie inward, the other half 17, 18 is directed outward and a light source 15 and 16 is arranged both above and below the image area io. In this way, the rays of one light source 15 are intercepted by the inwardly directed mirrors 7, 8, the rays of the other light source 16 by the outwardly directed mirrors 17, 18 and guided into the eye of the beholder. There can then always be a mirror vision of the group 7, 8 and 17, 18 illuminated by the first, 15, and a mirror vision of the second, 16, light source at the same time in the image field, and since the number of pixels transmitted per second is is limited essentially only by the inertia of the modulated light source or the operating speed of the image splitter, which both fall out here, you get a doubling of the possible number of pixels even in this simplest form.

A somewhat modified embodiment of the pixel mirrors 7, 8, 13 Figure 5 shows. This represents a glass body i 9, which at one end at 2o is ground at a prismatic angle. The vitreous is in the holes to think of a Nipkow disk inserted so that its longitudinal axis is perpendicular to the plane of the pane. The radiated parallel to the plane of the pane light the modulated light source is then through total reflection at the prismatic Ground surface 2o deflected in the longitudinal direction of the glass body and occurs on the other end of the glass body, which can be flat or curved, more or less perpendicular to the plane of the disk in order to then get into the eye of the observer.

A perforated cylinder can of course also be used in place of the perforated disk or the like. Use. Are at the same time again line-shaped light sources is used, it is useful to adapt it to the curvature of the image decomposer.

Claims (1)

PATENT CLAIMS: i. Arrangement for television using the principle the rotating perforated disk according to N i p k o w, in particular using modulated glow light, characterized in that the light openings (holes) the rotating disk with small mirrors (7, ä, 13) and these mirrors are oriented so that a cast in the direction of the observing eye Light beam is reflected in a surface traversed jointly by these mirrors will. a. Arrangement according to claim i, characterized in that the mirrors in one At an angle of 4.5 ° against the rotating disk. 3. Arrangement according to claim i using modulated glow light, characterized in that in the Area, which is caused by the reflected line of sight when walking through the viewing area is traversed, the areally formed modulated glow layer is arranged is. Arrangement according to claim i and following, characterized in that, the mirrors are assigned to different light sources in groups.