DE1009664B - Color television reproduction method - Google Patents

Description

Color television reproduction methods Color television methods are known in which the signals corresponding to the individual colors in the simultaneous process transmitted and then played back. Such a color television process exists for example, that on the receiving side a colored image by means of a arranged in the vicinity of the imaging lens and a primary color filter disk the collecting surface of the cutting tube upstream of the strip or lens grid is resolved point by point into adjacent color elements of the basic colors. A control signal is assigned to each of these color element complexes, which by the illustration of an additional one contained in the primary color filter disc uncolored segment arises, this control signal after filtering out of the Signal mixture, possibly after limitation, a chain of delay elements is fed. With the help of these delay elements, the control signal is in each case delayed by a time corresponding to the width of a color element, from which the after the individual delay elements occurring control signal from each one locked amplifiers that are assigned to the individual colors, existing color selectors is fed. The supplied pulses make these color selectors short-term unlocked. The color signals are then passed in the color selectors contained low-pass filters from their originally discontinuous state into continuous color separations transformed and then fed to the transmitter.

These color signals are then displayed on the playback side by means of direct view or projection color tubes. Great difficulty in getting through it the need for the electron beam, depending on the location of its impact on the luminescent layer to control with the assigned color signal.

It is known to be on the fluorescent screen between the individual color strips Conductive elements (wire, charcoal lines or the like) to be provided in which when overpainting of the electron beam voltages are generated, which after appropriate amplification and limiting delay lines are fed and associated with corresponding Gate circuits the color signals available in the receiver in separate channels accordingly control so that they are each in the correct time interval of the control electrode of the cathode ray tube are fed.

A disadvantage of this method of generating the color change signals is the large capacity of the conductor network due to the large number of wires to be used. Under certain circumstances, deformations occur due to heating, static charges or the like, Vibrations, etc., which call the proper functioning of the tube into question.

To avoid these difficulties it is known to only use every second or the third group of colored stripes, a conductor for generating the color change signal assign. However, the number of conductors can only be restricted with this tube can be achieved in that the number of delay stages in the same ratio increases as the number of conductors decreases. This is limiting the number the ladder set a quick limit. As the number of conductors decreases, so does the Switching effort increases quickly. A second, unmodulated cathode ray is also used needed to generate the color change signals, otherwise as a result of the image modulation color change signals can fail on the beam.

According to the invention, the disadvantages of these known methods are thereby eliminated avoided that, although only every nth group of colored stripes is a conductor of the Lattice is assigned; however, the pulses taken from this grid for synchronization a generator at n times the frequency and this generator change the color controls.

Such a training of the ladder system on the one hand his Capacity lowered to a practically manageable level, moreover, it results in significant improvements in the manufacture of the picture tube.

On the other hand, by gaining the compared to the frequency of the from the conductor system picked up pulse train n-times the pulse train frequency by means of a synchronizable generator a significant saving in switching means and simplification the circuit achieved compared to the known arrangements. For use as a generator according to of the invention are above all such arrangements known per se suitable in which a self-oscillating oscillator of the type of automatic Frequency control (AFC) by means of one obtained from a phase comparison circuit Control voltage is regulated to a setpoint frequency.

This ensures perfect generation of the color change control signals guaranteed and at the same time the guarantee that the individual basic colors can be controlled with the corresponding intensity supplied by the transmitter.

For a color television recording method, it is already known in a optical strip filters of each strip group running perpendicular to the row direction to assign an additional clear stripe to derive index signals from these stripes and using these index signals to keep a local oscillator in motion, the controls the conversion of the dot sequence signals into three simultaneous primary color signals.

The design of a display tube according to the invention is on independent of the way in which the image signal is generated on the recording side. It can thus be used in the various known color television recording methods can be used with equal success.

Claims (1)

PATENT CLAIM: Color television reproduction method with a cathode ray tube, phosphors corresponding to the individual primary colors alternately on their luminescent screen are attached in strip form and in which the cathode ray the strips transversely to their direction scanned one after the other and a grid with to the fluorescent strips substantially parallel conductors for deriving a color change control signal is used, characterized in that in a known manner only every n-th group of strips a conductor of the grid is assigned and that the pulses picked up by the grid serve to synchronize a generator to n times the frequency and this Generator controls the color change. References Considered: U.S. Patents No. 2 545 325, 2 fi31 259.