DE1186102B - High resolution super orthicon tube for television cameras - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school Class: H 04 η

Number:
File number:
Registration date:
Display day:

HOIj
German class: 21 al-32/35

F 38619 VIII a / 21 al
December 20, 1962
January 28, 1965

The invention has the task of resolving superorthicon tubes with a field network to enhance.

When operating superorthicon tubes, an image disturbance occurs, which is caused by that the beam returning from the target is due to a scanning movement caused by the deflection field on the first dynode occasionally hits the diaphragm of the incoming beam. In this In this case, no secondary electrons are released, and a bright spot therefore appears in the image. These A phenomenon known as the "headlight effect" is already found in the earlier superorthicon tubes observed without a field net.

But it is also known, in superorthicon tubes, an electrostatic deflection field with two at a constant Potential to generate lying plates, through which the grid on the first dynode so far is deflected so that the aperture comes to lie outside the grid. In this case there is no disturbing bright spot to be observed. However, in the course of further perfecting the Tube no longer used these baffles due to construction difficulties. Instead of of this, a lens electrode was attached to one of its electron-optically effective edges with such a Provided bevel that thereby a deflection of the grid in what experience has shown necessary Dimensions was achieved.

This electrode was inserted into field network tubes and also served as a braking electrode (Suppressor) to suppress a secondary electron current triggered in the field network.

In the course of the growing demands on the superorthicon tube, an improvement in the resolution is sought, by means of which the picture quality can be adapted with the full efficiency of the television transmission channels. It was found that the previous resolution of the tube of 55 to 60 % of the image amplitude, measured on the black and white jump at 5 MHz, no longer meets these requirements.

In a review of the electron-optical imaging relationships of superorthicons with a field network, which was based on an observation of a burnt-in grid on the first dynode when the tube was overloaded, it was found that the shift in the grid was caused by the aforementioned beveling of the lens electrode, which also acts as a suppressor in field network tubes serves to suppress the secondary electrons, is much larger than this to eliminate the spotlight effect he superorthikonröhre high resolution for
Television cameras

Applicant:

Robert Bosch G. m. B. H.,

Stuttgart 1, Breitscheidstr. 4th

Named as inventor:

Dr. Kurt Frank, Darmstadt

would be necessary, but the grid itself is much smaller than for tubes without a field network. Even though such field net tubes have been on the market for a long time, this fact has apparently been overlooked. Accordingly, the previous tubes of this type are equipped with a suppressor electrode, whose electron-optically effective edge is provided with a bevel of 13 °.

A reduction in the bevel to e.g. B. 10 ° does not bring optimal resolution, but it does some improvement. So far, however, a large bevel angle has always been chosen in practice, in order to comply with the empirical rule obtained with tubes without a field network that also with construction tolerances a coincidence of the dynode grid with the aperture is to be avoided. It was obviously overlooked that in principle the bevel leads to a reduction in the resolution, which is avoided with field network tubes can.

In practicing the invention, it was necessary to take into account that the construction of the superorthicon tube is already practically mature, so that neither additional melts are provided nor principal changes to the lens electrodes of the beam system could be made. Therefore could also not take into account the path, the required deflection field through a to generate additional electrode, which has a special seal with an adjustable Potential is provided. A change to the tube base with the installation of an additional socket pin would make the tube unsuitable for use in existing cameras and therefore a Entail redevelopment of the camera.

In the case of a superorthicon tube for television cameras with line-by-line deflection of the scanning beam,

409 770/143

which is equipped with a field network and with a beam diaphragm, which simultaneously serves as a collecting electrode for the return beam and as a first dynode, and in which at least one electron lens of the beam system has an electrostatic field component acting transversely to the axis of the beam system, according to the invention the transverse field is perpendicular to the line direction effective and of such a size that the aperture is at a distance of a few tenths of a millimeter, preferably less than 0.2 mm, outside (to the side) of the grid written by the return beam on the first dynode. This measure has the advantage that the resolution of the image is improved from 50 to 60% of the black and white jump at 5 MHz to 80 to 90 % without the light spot becoming noticeable. This progress is due to the fact that the transverse electrostatic field used to shift the grid is only as large as is necessary to avoid the dark spot and the symmetry of the electron lens in question is only so little disturbed that practically no astigmatism of this lens occurs. Furthermore, the effectiveness of this measure results from the fact that the grid deflection takes place in the direction of the vertical deflection of the deflection system. In general, the raster on the first dynode does not have the same format as the raster written on the target, but is compressed in the direction of image deflection. If the raster shift were allowed to take place on the first dynode in the direction of the lines, a considerably greater asymmetry of the lens field would be necessary for the effective shift and this would result in greater blurring of the image.

In addition, it should be noted that the feature according to which the transverse field is perpendicular to the line direction should run, through today's standard and fixed construction principles of the superorthicon tube is defined, since the position of the deflection coils in relation to the base arrangement is clearly defined is. There is a special pin on the tube base that shows the position of the deflection coils is oriented. Moreover, a modern superorthicon tube has no rotational symmetry because the inclination of the web webs of the network connected to the target is prescribed below 45 °. Finally, in the case of many tubes, a mask that determines the image format is attached in the photocathode plane or the target plane Defines the position of the deflection coils. For a more detailed explanation of practical embodiments of the invention reference is now made to the accompanying drawings. Of these shows

F i g. 1 is a schematic representation of the most important electrodes of the beam system of known ones Super orthicons,

F i g. 2 the shape of an improved lens electrode,

3 shows the structural design of the jet system with an auxiliary electrode to achieve the desired shift in side view, partially is cut,

F i g. 4 and 5 a view of this jet system from above, a further embodiment of the inventive concept.

In Fig. 1, 1 is a tube casing, on the foot 2 of which the electrodes of the beam system are built, and 3 shows an electron source, the details of which are not shown. It contains in itself known Way, a heated hot cathode and a Wehnelt electrode and at the same time carries the first dynode 4 of the Secondary amplifier 5. This dynode has a very fine hole in its center through which the beam exits in the direction of the target. Also in the direction of the beam are a "persuader" electrode 6, one Shield electrode 7 and a suppressor electrode 8 are provided. The electrode 6 is used to create a suction field for the secondary electrons triggered at the first dynode 4 to create them in the To direct multiplier 5; the electrode 7 is used to establish contact with the wall anode 9. Of essential importance is the electrode 8, whose task, known per se, is the secondary electrons released on the field network (not shown) in front of the target at the entrance to the To prevent the jet system. The electrode is therefore placed at the potential of the beam cathode. To the The suppressor electrode is followed by the wall anode 9, which is almost electrostatically field-free Creates space in which the electrons are subjected to the magnetic deflection fields. The suppressor electrode is, as already stated, provided with a bevel of 13 ° in the known tubes, to ensure that the beam returning from the target is different from the incoming beam is separated so far that the deflection raster described on the first dynode by the returning beam does not coincide with the aperture. A suppressor electrode of this shape was also made Used in cases where there is suitable potential in the vicinity of the field network a return of the secondary electrons from the field network is avoided.

As has been shown, the resolution of this known tube is not satisfactory, so that an increase resolution is desired. It was found that for the insufficient resolution one Blurring of the scanning beam is responsible for the astigmatism caused by the suppressor electrode formed electron lens is related. Experiments have shown that this astigmatism can be reduced to a level that is no longer disturbing if, according to the invention, the The suppressor electrode is provided with a significantly smaller bevel than 13 °, namely about 4 to 8 ° will. In this case, the disturbance of the symmetry of the electron lens is so small that it no longer causes any noteworthy image deterioration. The shift of the on the first dynode 4 grid shown by the return beam has been found to be sufficient for this dimensioning of the bevel proved, so that by redesigning the suppressor electrode a superorthicon tube with a resolution is created that is close to the theoretically possible limit. This theoretical The limit is due to the constant inhomogeneity of the speed of the electron beam conditional.

In Fig. 2 shows a suppressor of the type according to the invention, the one facing the target Edge is beveled at an angle of 5 °.

In Fig. 3 is the electrode arrangement of the superorthicon beam system recognizable in side view. The electrodes 11 to 17 carry the networks of the secondary electron multiplier, the electrode 18 is

the so-called persuader, which is at about 300 V, which carries the beam electrons falling on the first dynode steers into the secondary amplifier. With 19 the suppressor electrode is referred to, which approximately is at cathode potential and is used to release the secondary electrons in the field network to prevent penetration into the jet system. This suppressor electrode is in contrast to the known tubes are designed to be rotationally symmetrical and have no bevel so that they do not have any Disturbance of the symmetry of the electron-optical field causes. At the top of the suppressor 19 is the so-called silver evaporator 10 in the form of a perpendicular to the axis of the tube, the Suppressor built on a circumference of 60 to 90 ° comprehensive wire, on which a Silver bead is located. During the manufacture of the tube, the wire carrying the silver bead is heated, whereby a small amount of silver is evaporated onto the target to reduce the secondary emission coefficient of the target. In Fig. 3 is the suppressor electrode 19 and the silver vaporizer cut so that part of the feed to the heating wire 10 is not visible in the cutting plane. This feed 20 leads to the persuader electrode 18, so that the silver evaporator during operation is at this potential. By using the advanced silver evaporator in In the manner indicated, a pulling field is generated which, to a certain extent, extends over the edge of the Suppressors 19 reaches away into the imaging space and a slight deflection of the electron beam in such a way that the incoming beam by a small amount after the one and the returning beam is deflected by the same amount in the same direction. This achieves the desired shifting of the grid on the first dynode.

The relationships described are illustrated in FIG. 4 explains in more detail, which is a view of the Shows the beam system from above. In the middle of the picture is the first dynode 22 with the central one Diaphragm opening 23. The suppressor electrode 19 is on part of its outer circumference of the silver evaporator 10 surrounded with the recognizable silver pearl. The vaporizer wire is from the Feeders 20 and 21 carried. This evaporator arrangement is located on one side of the suppressor electrode 19, which lies in the plane of the image deflection F. This position is indicated by the arrow. A small hatched rectangle is drawn on the first dynode 23, which indicates the position of the grid drawn by the return beam in a relatively enlarged form. It can be seen that the shift has taken place parallel to the direction of the image.

The invention can be modified in various ways; z. B. May in cases where a Suppressor electrode is not required, the displacement field in the vicinity of another electrode, z. B. the shield electrode 24 are attached. Instead of the silver vaporizer, another one can also be used Component to be attached to the persuader electrode 19, which the suppressor electrode 19 on encompasses its outer circumference.

An even more extensive homogenization of the lens field with simultaneous deflection of the electron beam can be achieved if, according to the exemplary embodiment in FIG. 5 an electron lens, such as the suppressor electrode, consists of two symmetrical halves that have a slightly different potential from one another. In Fig. 5 such an arrangement is shown. The designation of the electrodes is according to FIG. 1 is selected, but instead of a beveled suppressor a lens electrode consisting of two identical half-cylinders 8 α and 8 b is used. As in Fig. 1, a persuader electrode 6, a first dynode 4 and a beam system 3, which comprises a Wehnelt electrode and a cathode 25, are provided. Since it is not possible for structural reasons, the deflection voltage of a few volts, which should lie between the half-cylinders 8 α and 8 b , from the outside via an additional contact, a voltage divider 26 is provided here in the tube, its ends between the potential of the electrode? and the cathode 25 are. The electrode 7 has the potential of the wall anode 9 in FIG. 1, which can be between 100 and 200 volts. To achieve the deflection field between the lens parts 8 a and 8 b , the part 8 α is connected directly to the cathode and the part 8 b is connected to a tap 27 of the voltage divider located in the vicinity of the cathode feed. In this way, the function of the lens electrode 8 a, 8 b as a braking electrode for the secondary electrons returning from the field network can be maintained and at the same time a deflection field of such a size can be superimposed on the lens field that the aperture in the electrode 4 is at a distance of a few tenths of a millimeter lies outside the grid area drawn by the return beam on the first dynode 4. At the same time, the chosen shape of the lens reduces the astigmatism due to the deflection field to a very small degree, so that the sharpness of the scanning beam emanating from the dynode 4 is only negligibly influenced by the lens 8 α, 8 &.

The material of the voltage divider 26 can advantageously be made of one known in the art electronically conductive glass, which heats up the tube when removing the last remaining gas resists. Since only fractions of microampere currents flow in the voltage divider, a relatively high-resistance glass can be selected.

Claims (5)

Patent claims: 1. Superorthicon tube, which is equipped with a field network and a beam diaphragm, which also serves as a collecting electrode for the return beam and as a first dynode, and at the at least one electron lens of the beam system, one transverse to the axis of the beam system having acting electrostatic field component, for television cameras with line-by-line deflection of the scanning beam, dadurchgekennz eich η et that the transverse field is perpendicular to Line direction is effective and is of such magnitude that the aperture is at a distance of a few tenths of a millimeter, preferably less than 0.2 mm, outside (on the side) the raster area drawn by the return beam on the first dynode. 2. Superorthicon tube according to claim 1, characterized in that an auxiliary electrode (10, Fig.4) on part of the outer circumference a lens electrode (19) is attached, one edge of which becomes an electron-optical effective edge of the lens electrode is parallel and on one of the lens electrode different potential. 3. Superorthicon tube according to claim 2, characterized in that the auxiliary electrode is formed by the heating wire (10) of the silver evaporator (10, 20, 21) that the lens electrode (19) is at cathode potential, and that the heating wire of the silver evaporator is inside a tolerance of 1 mm in the plane of the effective edge of the lens electrode and is at the potential of the persuader electrode (18). 4. Superorthicon tube according to claim 1, characterized in that the lens electrode (8, Fig. 5) is divided into two equal halves (8a, Sb) , which with the help of a voltage divider (26) mounted inside the tube to a voltage difference of a few Volts are placed. 5. Superorthikonröhre according to claim 4, characterized in that the voltage divider material known electronically conductive glass is used. Considered publications:
German Patent No. 908 864;
German explanatory documents No. 1033 701, 1033 702. 1 sheet of drawings 409 770 / 14H 1.65 © Bundesdruckerei Berlin