DE871908C - Circuit arrangement for television image splitter - Google Patents

Description

Circuit arrangement for television image splitter In a television image splitter with Nipkow disk and selenium cell experience the image brightness signals through the Inertia of the selenium cell, certain blurring compared to the brightness curve in the archetype. It is known to reverse this blurring by that the differential quotient of the rounded signals is formed and the output signals the selenium cell is added.

It is also known to reduce the afterglow from television image decomposers, which generated an image on the luminescent screen of a Braun tube for image decomposition Use the light spot to make it harmless by removing the from the photocell Picked up signals are first fed to two separate tubes, one of which one increases the photocell voltage unchanged, the other on the other hand that of the The part of the signal corresponding to the brightness of the scanned pixel is changed somewhat, leaves the signal part corresponding to the afterglow unchanged, and that then the output voltages of the two tubes are subtracted from each other, so that the voltages corresponding to the afterglow stand out. This method allows only an approximate elimination of the television image decomposers that are used for Image decomposition using a Braun tube, errors that occur.

Also through the additive admixture of the differential quotient of the image brightness signal to the initial margin one - photocell to which the through the moving light spot of a fluorescent screen of a Braun tube generated luminous flux is noticeable, a satisfactory operation cannot yet be achieved without further ado. The output signal of the photocell, which should run as shown in Fig. I a, has namely about the course shown in Fig. - i 1i by a solid line on. By adding the differential quotient, as shown in Fig. I c to the output of the photocell, i.e. H. to the signal course according to Fig. i b, can this distortion. not yet eliminated, namely experience has shown that the size of the distortion shown in Fig Beamstxom of Braun's tube depends, manually or automatically, from different; .Establish. can be changed, strangely enough so that with small Beam currents - a greater deviation from the desired rectangular signal course can be observed than with large jet currents. If you look at the output of the Photocell for small and large: Stralil currents are redrawn at the same amplitudes, as happened in Fig. 2 a to 2 c on the left, Fig. 2 a shows the distortion with small, 2 b with medium and 2 c with high beam current.

According to the invention is intended to completely eliminate the mentioned Distortion of each first differential quotient of the generated image brightness signal proportional voltage with an increasing beam current .in .... of .Bxannschen. Tube with decreasing amplitude are added to the image brightness signals.

One embodiment- the trfindting is shown in Fig. 3 and shows a Braun tube i, on the luminescent screen 2 of the. Spot the for the. Image decomposition required line movement and image or line movement learns. DE-fluorescent screen: by means of a lens 3, the image to be disassembled is which is shown here as a slide 4, shown, and by means of a Field lens 5 is the light passing through 4 onto a secondary emission photocell iö - .collected. Immediately behind the lens 3 there is a small mirror 6, through which part of the light coming from the luminescent screen is branched off and is directed to another photocell 7. In the circle of this photocell, its suction voltage battery is denoted by 8, there is a work resistance, the lower end of which is grounded is and at the upper end of the line indicated by an arrow .mit increasing beam current, decreasing potential can be tapped.

- Instead of the components 6 to g in Fig. 3, where the small Mirror 6 -also through a. Prism or a spread over the entire lens surface extending semi-permeable mirror can be replaced: one can also have one Use resistance in the cathode lead of the Braunsehen = tube i, its lower End - is then earthed and from its upper end again with increasing 'beam current strength -an increasingly negative potential can be tapped.

Using Fig. 4 of the drawing, it should be explained how the errors discussed using Figs. I and 2 can be eliminated with the aid of the voltage taken from resistor g or the cathode series resistor. In Fig. 4, the secondary emission photocell is again designated by io, its output current flowing through a resistor ii on the control grid of a screen grid tube i2. The image brightness signal is also fed to a six-pole tube 13, via the differentiating RC element 16, 17 to the second control grid of this tube, so that on this, since the time könstahte of 16, 17 is approximately the same or slightly larger than the pixel duration of the to decomposing television picture is selected, a voltage which is proportional to the first differential quotient of the picture brightness signal occurs. At the first control grid of the tube 13 is the resistor g from Fig. 3 or the resistor mentioned there in the cathode lead of the Braunse tube. The anode current in the tube 13 is proportional to both the voltage at the first and the voltage at the second control grid, and the differential quotient of this signal with an amplitude inversely proportional to the beam current is therefore added to the image brightness signal amplified by the tube i2, see above that the hand of the. The distortion errors explained in Fig. 2 are eliminated. The corrected signal gb can therefore be taken at the common output resistance 18 of both tubes and fed to further amplifier stages via a line ig.

Claims (3)

PATENT CLAIMS: i-. Circuit arrangement for television image splitters, which, for image decomposition, generated a on the luminescent screen of a Braun tube Use light spot; through this . characterized in that one of the first differential equilibrium the generated image brightness signal corresponding voltage with an increasing Beam current - - the -Braunsehen tube decreasing amplitude the image brightness signals is admixed additively. 2. Circuit arrangement according to claim i, characterized in that that a tube (i2), on whose control grid the whole of the photocell delivered Image brightness signal is, and a tube (i3), on which both one of the -first Differential quotient of the image brightness signal proportional to voltage as well a DC voltage that decreases with increasing beam current is parallel to one another are connected and work on a common anode resistor. 3. Circuit arrangement according to claim i, characterized in that a control voltage proportional to the jet stream is produced by tapping the voltage drop at a resistor located in the cathode lead of the Braunsehen tube, q .. circuit arrangement according to claim r, characterized in that a control voltage proportional to the jet stream is produced by a photocell (7), onto which part of the luminescent screen light is directed, for example by means of a small mirror (6) in front of the center of the objective (3) or by means of a semi-transparent mirror. Cited publications: Swiss patent specification No. 123 830; French patent specification No. 868 878.