DE1099576B - Sampling method and arrangement for generating a television signal of low bandwidth - Google Patents

Description

Scanning method and arrangement for generating a television signal less Bandwidth The fact that television is of high definition only by means of high frequency or ultra-high frequency carrier waves can be carried out, results from the procedure used in scanning. With this procedure, the Image point by point along a line and line by line along an image field scanned. This entails a series of successive pulses, with the occurring The higher the resolution, the larger the maximum frequencies and the bandwidth of the picture is.

To get a significant reduction in video bandwidth, one has to depart from the immediately successive scanning, at least what is concerned with scanning from line to line. So you get several lines at the same time transferred, using means in such a multiple line transfer must to separate the lines in the receiver and each line its due space assign in the picture; this assignment must be made in such a way that there is no overlap or confusion of the lines occurs.

Such a procedure is possible if you can do each of the at the same time periodically scans transmitted lines at a frequency that deviates on the frequency of every other line. A periodic signal has a frequency spectrum which is composed of individual frequencies during a disturbance or an oscillation process has a band spectrum. The arrangement will therefore be made in such a way that every line is sampled periodically at a characteristic frequency. the Fundamental frequencies will not influence each other, nor will the harmonics, when the fundamental frequency is restricted to a range smaller than one Octave.

The periodicity is achieved with a mechanical perforated disk scanner by drilling the holes equidistantly on concentric circles. A multiple-line scanning hole disk will thus have so many of these circles in the same Spaced like the lines in the picture. The number of holes is on each circle different (Fig. 1).

With such an arrangement, the bandwidth is not the sum of the bandwidth of the individual lines, as is the case with normal scanning, but only the bandwidth of an individual line, specifically that line which has the highest frequency. In this way, the bandwidth is reduced by a factor that is numerically equal to the number of lines transmitted at the same time. At 625 lines and 25 frames per second, the bandwidth in normal scanning is approximately 6 MHz. If, on the other hand, 625 lines are transmitted simultaneously, the bandwidth is reduced to the -th part reduced, ie to less than 10 kHz. So you can transmit a 625-line image on a medium frequency carrier wave. It must be pointed out here that if a number of lines are transmitted at the same time, the repetition frequency of the scanning must be sufficiently different from each of the other lines. There are two reasons for this: 1. The usual tolerance when drilling the holes must be taken into account, unless the frequency difference is so great that the tolerance of the holes is irrelevant. There will be no frequency difference with regard to some holes on different circles with a detrimental effect on the lines concerned.

2. The stroboscopes which make up the scanning arrangement have one great similarity in their effect to sharply tuned mechanical resonators, and the further apart the recurring frequencies of their holes are thus the discrete intensity components of the frequency in the resulting one become more pure Be spectrum.

There should be a minimal difference in frequency between the individual stroboscopes exist; this limits the number of lines that can be transmitted at the same time can be. This limitation results from the above-mentioned difference between the highest and the lowest strobe frequency, which - as mentioned - lower than should be an octave. One can avoid this difficulty if one divides the disk into a number of sectors and a smaller number concentric arcs are used in each sector, these arcs being a number of Have holes whose-number-differs from the number of holes on each sheet in the same Sector differs.

Fig. 2 shows such an arrangement. It should be noted that no two Arcs on the whole disc have the same radial distance and that therefore during one revolution of the disk a number of lines can be used which is equal the total number of arcs on the disc. The lines are layered what is generally referred to as "multiple: image decomposition". This multiple image decomposition reduces the minimum refresh rate that is necessary to prevent flicker turn off. It therefore helps to save bandwidth. While at Interlace process with two images, the frequency reduced from 50 to 25, there is a further reduction in an interlaced process with three images, namely to -162 / s. In the method according to the present invention, in which the Multiple decomposition can extend over 20 lines or more, it is possible reduce the frame rate to 10 or even less.

An image of a scene to be shown on television is thrown onto the pane by means of a converging lens, through a window, the width of which should not exceed AB (Fig. 1), which is the smallest distance between two adjacent holes of any circle ( or circular arc), and its height extends perpendicular to AB to the next hole circle (or circular arc). A photocell is installed on the other side of the pane opposite the window.

The receiver scanner is the same as that of the transmitter and works in sync with this. It also has a window that meets the same conditions.

As the disc rotates, each generates a strobe from the respective one Image element that it exposes, light fluctuations, the frequency of which depends on the repetition frequency of the holes in the strobe. The various fluctuations the intensity frequency caused by the various strobes, superimpose and influence the photocell, which generates an image current that is called a replica of the light fluctuations can be assessed. The image stream modulates after it has been amplified, the carrier frequency and is broadcast. In the receiver is after the rectification of the light modulator, z. B. a glow lamp, a Kerr cell or cathode ray tube, powered by a current or voltage fluctuation, which is an image of the image current of the photocell. The receiving stroboscopes receive a complex light fluctuation, which again is an image of the image stream of the photocell is, and these strobes, each of which acts as a filter for a specific fluctuation frequency acts, separate the light and the shadow from the intensity-frequency mixture its corresponding place in the picture thanks to the well-known stroboscopic effect.

Regarding the disk scanner, it should also be noted that the new system it is possible to use smaller discs for high definition television, without reducing the size of the image. This is a consequence of the fact that the lines are scanned independently of one another. That is the difference from the usual method of scanning a single line, where - if a single Disk is used for high resolution - the disk must be annoyingly large because otherwise the large number of openings they accommodate and that of the number of rows must come to lie very close to one another. With the new system, which causing multiple image decomposition, the flicker is by a low repetition rate switched off. In this way a new situation arises; namely, it becomes the repetition frequency increased and at the same time reduced the number of openings in the same ratio. The bandwidth does not suffer any change in this way. This is how the ability remains the recurring openings to act as an intermediate carrier of the light modulation, unchanged, and the details along a line remain the same as before.

In the new system, mechanical devices other than the Disc can be used. Only the simple mirror wheel is excluded here, there it is as good as unsuitable for high resolution scanning. On the other hand, suitable the Mihaly-Traub system, although it is a variant of the mirror wheel, is advantageous for high resolution, and it is also very suitable for large screen projection. from of the two rotating polygons, the one with the higher speed will be the largest Experience changes. The construction of a combination of rotating elements is required Polygons, which are arranged in a spiral along the axis of the cotation, and their Weight is low enough. This high speed combination works in Connection to a low speed polygon. As with the rotating one Disk, the principle here too is to ensure periodicity with every line. The same conditions that must be observed in the case of the disc are also required here.

The device for electronic television is shown schematically in FIG shown. H is the filament of the oxide cathode. From the figure you can see that he is much longer than that of a vacuum tube or a cathode ray tube because it has to heat a number of electron sources and not just a single one. C is the composite cathode. It is attached parallel to the filament and has a series of side-by-side depressions, all on a straight line. Each is filled with a mixture of oxides to emit electrons in large numbers, when heated by the adjacent filament.

G is the composite control grid with negative bias, it consists of a metallic hollow cylinder whose axis coincides with the axis of the cathode ray tube matches and which ends with two discs, each of which is provided along the diameter with a slit that is parallel to the row of the indentations in the cathode. This is how the electrons come out the cathode as parallel rays, which form a continuous, elongated, thin Form a band of electrons.

Al is the first anode or the accelerating electrode. she is a composite anode consisting of a hollow cylinder connected by two Discs is covered, the aperture gaps similar to those of the control grid.

F is a pair of focusing coils whose axis is common to the axis the cathode ray tube collapses. The distance between the two centers of these coils corresponds to the radius of each coil. That is the Helmholtz condition for the arrangement of the coils, a condition, their application necessary is, around an enlarged homogeneous magnetic field around the axis of the cathode ray tube to obtain.

Dl is a pair of deflection coils for horizontal deflection. With help the sawtooth current flowing through these coils becomes the amplified electron beam, which is emitted by the electron gun, causes it to become evenly horizontal to move and then to return quickly, etc. Again, these coils should be designed accordingly the Helmholtz method be arranged to ensure a uniform deflection in the further Secure fields.

P is a so-called fixed scanner. He has a large number of openings, which are arranged according to a certain plan, which is subsequently is explained. Since P is not covered with a fluorescent material, the density can of the incident electron beam, and it will be shown later that the width of the openings in P should be greater than the width of the electron beam, who meets them.

D2 is another pair of Helmholtz horizontal deflection coils. The frequency of the deflection generator connected to D2 is greater than that of the deflection generator connected to D1.

The system works as follows: The ribbon-shaped electron beam of high electron density and small cross section moves horizontally over the stationary scanner, which is divided into a number of sections (Fig. 4), analogous to the sectors in Fig. 2. As soon as the electron beam hits an opening meets (the width of the openings is four times as large in the horizontal direction like the width of the electron beam, the underlying idea being that this is is intended to mask the first and the last part of the beam, since the Intensity is increased in the first case and weakened in the second case. and so to use only the middle part, which has a uniform intensity), it penetrates the scanner and comes under the influence of the horizontal deflection D2. The openings in each row are arranged so that the deflection D2 either causes the beam to sweep the screen a characteristic number of times for each Row to sweep or in the event that the repetition frequency of the beam the same is for a number of rows, the openings are then placed so that they cause a phase difference.

This shows Fig. 4 where the first row in each section of openings consists of twelve unit squares apart. The second is of holes that are similarly separated from each other, but in a different one Arrangement of the first etc. In this way six groups of rows are obtained, each of which consists of thirteen rows, making 6 -13 = 78 rows obtained (where the number of vertical sections of the fixed scanner is six is).

Using the same method for holes, the eleven unit squares are apart, there is the possibility of 6 - 12 = 72 additional lines etc., until you get to the group where the distance is six squares and then the sum of lines 6 (13 + 12 + 11 + 10 + 9 + 8 + 7) = 420.

When the frequency of the time base D1 is 50 and the number of squares In the stationary scanner 200 there is a frequency of the time deflection D2 from 50 - 200 = 10000 Hz.

Claims (5)

PATENT CLAIMS: 1. Scanning method for generating a television signal of low bandwidth, characterized in that a circular disc is divided into a number of sectors (S), each of which has holes which are arranged in a known manner on concentric circular arcs and wherein the circular arcs on the Disc all have a different radial distance, the number of equally spaced holes on each sheet is different from that of any other sheet of the corresponding sector, and that according to the invention the ratio of the number of holes on any two sheets is either less than 2: 1 or is more than 1: 2, and that with such a disk a picture window (BF) releases the entire picture to be transmitted. which is dimensioned so that its width is not greater than the smallest distance between any two adjacent holes on any arc and its height lies within the arc closest to the center of the disk and the arc furthest away from it, so that a photocell can pass through this image window picks up light flux and that the image is reproduced by means of a synchronously running analog scanning disk due to the known stroboscopic effect. 2. Scanning method for generating a television signal of low bandwidth, thereby characterized that in analogy to the method according to claim 1 in a television recording and reproducing means, instead of a scanning beam, an electron scanning tape an equivalent in its structure to the scanning hole disc characterized in claim 1 Perforated plate (P) sweeps over periodically so that a simultaneous scanning of all lines takes place, that also the holes in the scanning plate (P) arriving electrons are also deflected in a sawtooth shape (D2), with those middle surfaces of the screens of the recording and playback devices as picture windows serve, which of all the electrons emerging from the holes in the screen be coated. 3. The method according to claim 1, characterized in that for Scanning a known Mihaly-Traub mirror drum is used that is designed in such a way that it consists of a combination of rotating polygons, which are arranged in a spiral along the axis of rotation. 4. Cathode ray tube for carrying out the method according to claim 2, characterized in that by means of a beam generating system (H, C, G, A1) an electron scanning band is generated and that behind the usual focusing coil (F) two one behind the other in the direction of the beam horizontal deflection coils (D1, D2) are provided and one between them in the way of the electron scanning band lying in its entire width from the electron scanning band Painted perforated plate (P) made of insulating material, the arrangement of the holes is designed analogously to the scanning hole disc characterized in claim 1. 5. Cathode ray tube according to claim 4, characterized in that the additional sawtooth-shaped deflection of the electrons taking place by the deflection coil (D2) takes place at a much higher frequency than the deflection of the electron scanning belt. Considered publications: German Patent Nos. 591583, 618 381, 768 048; "Television technology" by F. Schröter, R. Thiele, G. Wendt, Verlag Springer, 1956, p.4.