CH190856A - Electronic device, especially for television. - Google Patents

Description

  

  Electronic device, especially for television. Cathode ray oscillographs. for television must meet the following two conditions: (a) provide the projection of a light point using a good electronic system, which is achieved by various known methods; b) providing a linear proportionality between the brightness of the fluorescent screen and the modulation voltage, so as to maintain the fidelity of the reproduction of the initial image.



  The present invention relates to an electronic device, in particular for television, comprising at least one electronic mirror for the electronic reproduction of images.



       Lee fig. 1, 2, 3, 4 and 5 of the accompanying drawing schematically represent embodiments of the object of the invention. A particular embodiment of the device, .serving for electron reflection that can be used for the reproduction of an electronic image by a photoelectric cell (fig. 6).



  In fig. 1, the cathode ray tube T com carries an incandescent cathode C which, under the influence of the positive electrode E1, emits a cathode ray of approximately constant intensity. Between this electrode El and a second electrode, E2, in the form of a metal grid, is disposed a modulation electrode M brought to a negative potential. The modulation voltage is applied to the impedance Rg. The EZ electrode has the shape of a pot pierced with a central hole and covered by a metal grid.

   A coil B 'concentrates the electron rays on the central hole of the second electrode E \. The distance between the two electrodes Ei and EZ being relatively small as well as the distance which exists between the metal grid and the central hole of the anode E2, the modulation voltage M has only a slight influence on the distribution of the speeds. electrons, especially -if the two electrodes El and E 'are plane and parallel.



  The projection of the intermediate image can be done either by an electro-optical system or by a magnetic system; comprising a lens electrode L and a second coil B '. The distribution of the electric fields is controlled by the primary anode A 'and the secondary anode A'.



  The electric source serving to supply the tube T is represented by a high voltage battery B combined with a potentiometer P.



  Fig. 2 shows another embodiment of the same device, in which the coil B 'is replaced by an electric lens L'. The other letters keep the same meaning as in fig. 1. In the two devices which have just been described, the systems ME ', E' play the role of mirrors, that is to say mirrors with variable transparency reflecting part of the rays on El.



  Fig. 3 shows a different arrangement, in which the concentration of the cathode rays is independent of the modulation. The incandescent cathode C is located inside a tube of the anodic type A1 closed on one side by a curved re grid G. Outside and at a short distance from this grid is a second curved electrode. M, 'modulator, negatively charged and, behind it, the second electrode E.

   The incandescent cathode C is activated by an emitting layer on the grid side G, while the fluorescent screen F is on the unactivated side of the cathode.



  The electronic rays emitted. by the cathode are directed first by the positive grid G on the electrode M which rejects them on the fluorescent screen F where they converge towards an electronic focus S. The modulating grid 112 has the properties of a mirror of focus S and variable transparency, thanks to the auxiliary acceleration field .de the positive electrode E, while the angle of reflection remains constant.



  The electron rays rejected through the orifice 0 of the anode A 'pass between the deflection plates <B> Y </B> and Y, can be accelerated by a second anode A'.



  Fig. 4 represents a mode of use of the reflection electrodes for the modulation of cathode rays; a modulating voltage is applied to the resistor Rg which negatively charges the mirror-shaped electrode M; this rejects them. .electrons emitted by the cathode C on the hole of the first anode Al. Thus, in this example, the modulation occurs by more or less perfect reflection on the electrode M functioning as a mirror. The electric lens L projects this hole through the second anode A 'on the fluorescent screen F. The other letters keep the same meaning as in fig. 3.



  Another variant, using the principle of electrodes with mirror effect, is given by fig. 5. The modulating electrode M has the shape of a cylindrical wire mesh tube inside which there is a second cylindrical tube G also formed by a wire mesh. The incandescent electrode C has the shape of a cylindrical tube with an active outer surface. The electron rays are attracted by the first tube Ai, then reflected more or less perfectly by the second tube M.

   These tubes being symmetrical with respect to the cathode, there is always an angle at which the electron ray is reflected in the direction of the hole of the anode. The image of this hole is then projected, as usual, by the electronic lens L. The other elements remain the same as in the previous figures. In five embodiments, the Braun tube is provided with two pairs of customary deflector plates.



  Finally, the possible application of: electronic mirrors to a special photoelectric cell is shown in fig. 6. The optical lens <I> L </I> projects an image h onto the photosensitive layer P located inside a high vacuum tube T. The electrons leave this layer with varying intensity depending on the distribution of the light on the layer, and they are accelerated by the grid G 'of the tubular anode A and arrive at the second curved and oblique grid G2. They pass through this grid and are reflected by the negative field of the electrode M on the screen F;

   this one, is fluorescent or formed by a material of strong secondary emission. If the focal lengths of the electronic mirrors <I> M and </I> GZ coincide with the distances of the fluorescent layer and of the photosensitive layer, a more or less faithful reproduction of the primary image is obtained on the screen F. Ii.



  It is obvious that this system of electronic mirrors can be used several times in succession, or be combined with the usual optical and electronic systems.

 

Claims (1)

CLAIM Electronic device, in particular for television, comprising at least one electronic mirror for the electronic reproduction of images. SUB-CLAIMS 1 Electronic device according to claim, comprising a negative and transparent electrode interposed between two positive electrodes so as to obtain an imperfect reflection system whose transparency can be adjusted, either to obtain a constant degree of transparency, or for .obtain variable transparency. 2 Electronic device according to revendi cation, characterized in, that the electronic mirror is curved so as to obtain a focus determined in advance. 3 Electronic device according to the claim, with several curved electronic mirrors. 4 Electronic device according to claim, comprising an electrode for linear modulation of the intensity of the cathode ray not influencing the electronic focus, this modulation electrode being .disposed between two auxiliary electrodes <B> of </ B > so that the distribution of the axial and radial speeds remains approximately constant. 5 Electronic device according to revendi cation, comprising an electrode for linear modulation of the intensity of the cathode ray not influencing the electronic focus, this modulation electrode being arranged to act on the electrons like an electronic mirror .