DE677334C - Device for the simultaneous evaluation of all point elements of an entire image line by a corresponding number of scanning photo cells - Google Patents

Description

Device for the simultaneous evaluation of all point elements of an entire image line by a corresponding number of scanning photo cells Die Invention is based on the knowledge that for good television there is a fineness of decomposition is required, which corresponds to a grid of 100 image lines and more. Next to according to the corresponding development of the devices and the transmission methods higher number of lines has recently been a decisive expansion of the The permeability of electrical telegraph channels has become visible. It is clear, that both on ultra-short waves and on special cable lines frequency bands of ioss Hz width can be transmitted with good ranges without regarding to make too great demands of the expenditure on reinforcing agents. Through this Wendung has given the television problem a new face.

Furthermore, one had to be aware of the limited frequency permeability of the Telegraphing channels run out and the options available here, the fineness of the breakdown, d. H. adjust the number of image lines. So you couldn't get over proportionately to get out rough grids, with which it wasn't too difficult to find objects to transmit with moderate illuminance or to obtain sufficiently bright distant images. When the need for much finer grids became unavoidable, I switched one in view of the changed permeability of the telegraphic channels A plurality of these in parallel and transmitted a section of the image in each channel. In contrast, today we have the option of using the entire frequency band of a with an almost arbitrarily high number of lines decomposed image on a single modulated To transmit carrier wave or in a single cable core.

The invention is based on the last mentioned fact and relates on a television system in which, according to the above, the image modulation from Send to the receiving device on a single modulated carrier wave or through a only line reached while at the sending or at the receiving point or if required, the simultaneous sampling or reproduction of a multitude of both at the same time of picture elements takes place. On the one hand, this achieves such a high level of operational reliability of the transmission, as it is when several telegraphing channels are operated in parallel because of the Difficulty matching the same would not be achievable. On the other hand, there is the possibility of transferring scenes and images as a result of multiple scanning with lower illuminance or with a larger number of lines than before, while when receiving, accordingly, the advantages of greater brightness of the distant image or finer rasterization of the same result. Only on this one Ways will z. B. the fineness of the resolution required today in the scanning of living people made possible at all.

In television it is known per se, the whole picture area or one To divide individual image lines into cells and to expose these cells at the same time, while evaluating the photoelectric currents or voltages generated in them takes place one after the other. The arrangements proposed for this exist but considerable disadvantages, since they consistently convert the light values into a continuous series of power surges directly from the photo elements themselves make. Because the tensions come into effect, especially when the tensions are weak Image brightness, are very low, there is a relatively high level of glare. on the other hand In a screen mosaic, the high frequency of the line switching causes one low coupling resistance at the input of the modulation amplifier and thus for the transmission process has an unfavorable relationship between the useful amplitude and the interference mirror. With such arrangements it is currently still impossible to achieve sufficient uniformity the photoelectric sensitivity over the entire cell sequence with simple means to secure.

The invention aims to overcome these deficiencies in that the sequential 'scanning of light values along a individual photocells are not combined with the vanishingly small ones Individual voltages of these cells themselves take place, rather through one behind each Cell-switched amplification device for sufficient pre-amplification of the Signal amplitude is taken care of. This results in far more favorable conditions regarding the mirror as well as the light utilization and also the possibility of the sensitivity differences by regulating the sensitivity of the individual amplifiers to balance the photocells.

According to the invention, the optical transmitter moves the image to be transmitted line by line over a linear grater of photocells which extends in the direction of the line and contains a number of individual cells which is equal to the number of picture elements allotted to the whole line. Let this number be denoted by p. To disassemble the archetype in the imaginary way, z. B. a projection device in connection with a mirror wheel of a known type. Here-all p pixels of the line are now scanned photoelectrically at the same time and thus p different current or voltage values. educated. This must be used for the duration 1 available for an image line to control the transmitter. For this purpose, a fast-working, inertia-free switching element scans the p different (sufficiently amplified) voltages in time t and thus converts the transmission values that are present in chronological order into a sequence of corresponding telegraphing pulses.

Between each photocell and the associated sensing element (switching photocell or contact of a cathode ray switch, see later) is an on or multi-stage adjustable tube amplifier with such a high grid resistance, that the time constant of the input circle is of the order of magnitude of the line duration t is. This means that the input resistance of the adjustable amplifier is essential can be made larger than if the time constant is smaller, about the order of magnitude is the duration of a pixel scan. However, a large input resistance means with one and the same lighting a stronger electrical signal, so that through the dimensioning of the input circle according to the invention a much stronger symbol than with other arrangements. Many times for the reason described stronger signal is now with the help of regulated amplification on such Brought amplitudes that even with low light intensity of the original and with large Inequality of sensitivity of p. Scanning photocells very strong, balanced and symbols that are far above the interference mirror can be obtained. Because of the temporal The p photocells @ working in parallel is the maximum frequency of the change in brightness only 1 / t, while it was p / t with the previously customary decomposition. Accordingly you can increase the grid resistances on which the individual cells work, because with the reduced frequency of the photocurrent the damaging circuit capacities as shunt resistors are no longer so important. The control voltage the I'liotocell is already multiplied as 3 at the input grid of the p amplifier; However, it only reaches usable, brightness-accurate values through the downstream adjustable single amplifier.

Viewed from a different point of view, the invention provides Optiinal solution in terms of efficiency and cost of switching elements, if you An arrangement is used for comparison, Bernur uses a photocell for evaluation of all image brightness values is used or an arrangement in which each A photocell is assigned to the pixel. With an arrangement n-iit only one photocell would be because of the low time constants of the amplifier input resistance, which is of the order of magnitude of the duration of a pixel scan, only a very weak one electrical signal expected. In the case of a two-dimensional photocell grid, Although the time constant of the input resistance can be chosen to be larger, the effort at the same time, the number of switching elements would be enormously large.

That which is necessary for the execution of the invention on the special as well as the recipient side Inertia-free high-speed switch that controls the transmission values during the line duration t all p picture elements are scanned one after the other, can be designed differently. It is Z. B. possible, at the transmitter an intense light beam of constant intensity at a corresponding speed over a row of p photoelectric switching cells move away conjugating the p scan photocells of the image line, d. H. with appropriately connected to the outputs of the amplifiers they control and so by making them permeable to current one after the other at the incidence of the light beam trigger dosed voltage surges, which correspond to the different brightnesses of the p pixels are proportional along the line. These successive control pulses act on the control grid via a series resistance common to all p discharge paths an electron tube that forms the input of the transmitter amplifier. The trigger Switching light beam can by a mirror wheel arrangement of a known type over the cells be diverted.

Another way is to replace the light beam with the transmitter a constant strength cathode ray. This cathode ray is expediently through Devices of known type rotating over a circular sequence of make contacts out whose number is equal to the number p of picture elements along the line. He causes in a basically the same switching arrangement as described above, the transfer of the light effect in the p scan cells at the same time and amplified voltages in a time series of pulses for controlling the television transmitter.

Cathode ray switching and photoelectric triggering can also be combined in such a way that the luminaire excited under the influence of the electron impact in a phosphorescent surface acts on a row of photocells arranged opposite this screen. The cathode ray, which is constant in intensity, is expediently guided in a circular path; The photocells are arranged along the light track generated in the process. The means for rapidly scanning the line values discussed above do not exhaust all possibilities. One could e.g. B. think the p switching photocells or the p switching contacts of the cathode ray tube is replaced by p anode side operated by the increased photoelectric voltages locked electron tubes, which control grids are supplied in time series of short duration positive, opening surges z. B. by a traveling wave whose transit time is along the p control grid t and whose periodic triggering is synchronized with the image decomposition. If one forms the mentioned electron tubes with two multiplicative acting control grids, z. B. in the form of hexodes, the p second control grids can be supplied with a constant anode voltage directly or via a preamplifier, the brightness voltages excited by the p scanning photo cells. These then determine the respective strength of the anode current impulse, which is simultaneously amplified by the switching process, in accordance with the amplifier function of the tube, while the p first grids merely exercise the function of opening or closing the discharge path. All discharge current surges have a controlling effect on the input tube of the transmitter amplifier via a common series resistor. The tube circuit described can be modified in various ways according to known principles.

The reverse conversion of the pulse train of the transmission on the receiving end in a temporally parallel control of p channels can basically do the same Scheme as on the special page. The switching beam constant in its intensity of the encoder then corresponds to one of electrical signals in intensity modulated switching beam. .

In Fig. Ia and ib embodiments of the invention are shown schematically. The scanning photo cells are indicated by i, z, 3, 4 ... p; they are hit by the light of the projected image line in the direction of the arrows. 5, 6, 7, S ... denote p individually controllable amplifiers, 9, 1 0, 1 1, iz ... resistors whose voltage drop is caused by the excitation. of cells 1,2,3,4 ... is determined. Parallel. these resistors 9, io, ii, 12 ... can be additional capacitances. It is assumed in Fig. Ia that the rapid scanning of the line values is done by light. For this purpose, the free ends of the unipolar through-connected resistors 9, io, ii, 1a ... are connected to the p switching photocells i ', z', 3 ', 4'. . . p ', the active cathodes of which are opposite the anodes connected to one another by line t3. The switching photo cells fall in the direction of arrows a, b, c, d. . . x is the constant luminous flux of the optical switch in such a way that the excitation propagating in the direction of the horizontal arrow A recurs cyclically with the duration of the period (line duration). The photoelectric discharge current surges of variable amplitude, which occur one after the other at equal time intervals t / p, flow via the common resistor 15 and the return line 14, and the voltage drop occurring at 15 controls the input tube 16 of the transmitter amplifier.

In Fig. 1b, the switching photo cells are replaced by the closure sections of a rotating cathode ray 25, while the input circuit of the transmitter amplifier (parts 13, 15, 16) has remained unchanged. , 9, io, ii, 12 ... in turn denote the output resistances of the amplifiers 5, 6, 7, 8 ... at which the photoelectrically controlled brightness voltages of the pixel line are located. The free ends of the resistors are connected to the p electrode 17, 1 8, 19, 2o ... the cathode ray tube to which p grid-like counter electrodes 2 i, 22, 23, 2 ¢ face associated with .... These systems act like p Faraday cages, the interiors of which are made temporarily conductive by the penetrating cathode ray 25 one after the other. Each such individual cell supplies a current impulse, the strength of which depends on the voltage drop prevailing at the associated resistor 9, io, ii, 12.

Claims (6)

PATENT CLAIMS: i. Device for the simultaneous evaluation of all Point elements of an entire image line by a corresponding number of scanning photo cells, their current values one after the other through an inertia-free periodic high-speed switch tapped and transmitted, characterized in that between the scanning photocells and the high-speed switch adjustable individual amplifiers are connected, their input circuits have a time constant of the order of magnitude of the line duration. 2. Establishment according to claim i, characterized in that the quick switch is a photoelectric Beam of light moved away from switching cells is used. 3. Device according to claim i, characterized by a cathode ray tube as a quick switch, which is one of the points of the picture line has the same number of closing contacts or systems via which the power surges controlling the transmitter. q .. Cathode ray high-speed switch according to claim 3, characterized in that the expediently in a closed circular path moving electron focal point of a Braun tube only generates light that hits a Outside in front of the screen, the light trail clinging to the row of switching photo cells works. 5. Device according to claim i, characterized in that as a quick changeover switch a series of interlocked electron tubes is used that passes through their control grid periodic positive traveling wave impulses synchronized with the image decomposition opened briefly one after the other, while the brightness values on the anode side the scanned image line controlled voltages are effective. 6. Modification of the High-speed switch according to claim 5, characterized in that electron tubes, z. B. Hetoden are provided with two multiplicative acting control grids, whose one by the traveling wave impulse and the second by the brightness voltage is influenced while the anode DC voltage remains constant.