DE1169498B - Arrangement to increase the edge sharpness in the pre-imaging system of superorthicon tubes - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school KL: H04n;

HOIj

German KL: 21 al - 32/35

Number.
File number:
Registration date:
Display day:

F 36788 VIII a / 21 al

May 12, 1962

May 6, 1964

Arrangement to increase the edge sharpness in the pre-education system of superorthicon tubes

Applicant:
TV G. mb H., Darmstadt, Am Alten Bahnhof 6

Named as inventor:

Dipl.-Ing. Hermann Greiner, Darmstadt

In the case of a modern 3 "orthicon camera, the resolution has the theoretically possible value for 5 MHz almost reached. It is generally in the middle zone at a value of more 80% of the black and white jump at 50OkHz. For the edges, but especially the corners, there is still a certain loss of sharpness. The resolution of the corners is about 50%, based on the black and white jump. It is therefore desirable to match the sharpness of the corners to the sharpness of the center as much as possible.

If the photocathode voltage is set carefully, it can be seen that the sharpness maximum is opposite to that of the previous image for the center
the edges and corners with different control settings, ie with different tensions 15 2
for the photocathode. If you need z. B. for

the optimal focus in the middle of a span, so that the electrons as long as possible voltage Up ₂ = -460 volts, the result for the magnetic lines of force and a spiral corner voltage values of about - 485 volts, that is, orbit the outer electron bundle is avoided, with the given arrangement an image field curvature occurs. In practical operation one will give priority to the formation of knots for a bundle A as well as the middle, so that the effect for a bundle B takes place in the target plane,
the curvature of the field comes into its own. Since the electrical equipotential lines through the

The causes of the aforementioned curvature of the field of view er electrode arrangement in the orthicon result from the following relationships: Due to the complexity of the given electrode arrangement in the entire image converter system today only with great effort part of an orthicon form the equipotential lines
No flat surfaces in the pre-imaging room. she
rather, they run in an approximately bell-shaped curve in front of the photocathode. If the electrons emerge from the 30th
Photocathode off, so they are still due to them
very low speed initially a train
describe that runs exactly perpendicular to the equipotential surfaces. Since the ratio of the electric field strength to the magnetic field strength on the 35 supericonoscope, which has an image converter part with the edge of the photocathode compared to the center of a magnet concentrated near the photocathode, is very high, an electron from the center table has a focussing field, a ferromagnetic (see Fig. 1, point B) on an approximately straight path ring within the magnetic focusing coil to the target, while the electron A, which is ordered, whose inner edge extends to close to the image field of the corner of the photocathode, reaches one after 40. The purpose of this measure consisted of describing outside curved arches. As a result, when a short magnet is used, the path of the electron is initially somewhat lengthened. image distortion caused by a coil, but above all the electron path crosses to eliminate the S-shaped distortion. One has not neglected magnetic field lines also tried to improve the effect by incorporating a permissible angle so that 45 coil windings in the interior of the magnetic core can be assumed that it passes through a certain spiral path, without, however, what is satisfactory significant portion of the lengthening of the track to achieve results. When it comes to superorthicon tubes. The formation of knots in the electron brain was also attempted, so the magnetic field strength in dels A will already take place before the target reaches the plane opposite the photocathode as a whole. This effect can apparently only be eliminated from those in the plane of the storage electrode if it is possible to reduce the electron running heights by placing a main focusing coil on the end face of the super orbit and the magnetic field lines surrounding each other

can be changed, the possibility remains to influence the course of the magnetic lines of force in such a way that that the field curvature is compensated. There are already focusing systems for image converters known from TV recording tubes, in which an additional magnetic field in the vicinity of the photocathode is generated in order to improve the imaging ratios. For example, one has

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arranged disc-shaped coil winding through which a controllable current flows. This measure was mainly used with 4V2 "orthicons in order to achieve a diverging magnetic field by which the image scale between the photocathode and the storage electrode is increased. Increasing the corner shafts of the image was not intended with this system and is based on the experience available . not reached Finally, such a lying on the end face of the auxiliary winding Hauptfokussierspule was used to make homogeneous to the magnetic field in the image sensor area as possible. _|

The object of the invention to improve the sharpness of the corners is thereby achieved makes it difficult that the imaging ratio between the photocathode and storage electrode because of the already given optical conditions in television cameras and the fixed size of the grid field very little should be changed on the storage electrode. The use of an iron pole piece, possibly with an additional winding embedded in this or one on the end face The auxiliary coil applied to the deflection coil therefore does not achieve the goal and produces both an undesirable one Change in the aspect ratio as well as only an insufficient reduction in Blurring in the corners.

To solve the problem on which the invention is based, the edge sharpness of the on the storage electrode Improving the designed image in superorthicon camera tubes becomes immediate according to the invention an auxiliary coil of small height is attached to the end face of the tube carrying the photocathode, which is traversed by the current in the same current direction as the main focus coil and is surrounded by this coil. There is preferably between the outer edge of this auxiliary coil and the inside of the main focus coil a distance that is at least as great as the height of the coil winding is the auxiliary coil itself. This arrangement ensures that the magnetic field mainly in the vicinity of the auxiliary coil is changed and a noticeable constriction of the Magnetic field near the corners of the photocathad's field of view occurs while the field strength is changed relatively little in the center of the photocathode.

You can improve this effect by in the space between the Auxiliary coil and the main focus coil still attaches a further auxiliary coil, which is from a current opposite direction as the flow through the first auxiliary coil. This achieves that a radial dipole field is generated, which in the immediate vicinity of the image field edge of the photocathode a high field strength can arise, which decreases too rapidly after the center of the photocathode. Through this simple arrangement one obtains the superposition of a parabolic field course over the essentially constant field strength of the main coil. It has been shown that in the case of the 3 "superorthicon Increasing the field strength for the corners of the image by around 15% compared to the center of the image is necessary in order to achieve the Suppress field curvature. One then obtains one that is suitable for sharpening the center Photocathode voltage a center resolution like. so far τ of more than 80% and a Rafldlösung of at least 65%. The variation in the operating voltage shows that the field curvature is practically made to disappear by the inventive measure, since there is no operating voltage with which the respective corner sharpness still exists could be increased.

The invention is illustrated in more detail with reference to the figures. It shows

1 shows a representation of a superorthicon camera tube in which the force line relationships used up to now and the electron trajectories resulting therefrom are shown, and FIG. 2 shows the image converter part of a 3 "superorthicon camera tube with an additional coil of the optimum dimensions found by experiments. In FIG. 1, 1 is the bulb of a superorthicon tube which is provided with a photocathode at its end face at 2. The tube also contains a storage electrode 3 and an acceleration electrode 4, which is used to generate a suction field for the photoelectrons. The other electrodes contained in the tube for obtaining a scanning beam and for collecting the electrons generating the image signal are not shown, since the construction of a superorthicon is familiar to the person skilled in the art and these The tube is surrounded by a long concentrating coil 5, the field strength of which is such that both the electrons of the pre-imaging space, formed by the electrodes 2, 3 and 4, as well as the electrons of the scanning beam hit the Storage electrode are focused nien the coil 5 are indicated by dashed line α . Furthermore, in FIG. 1 the equipotential areas in front of the photocathode 2 indicated by dashed lines b . These equipotential surfaces are curved in front of the photocathode in the manner of a bell curve. As shown at the beginning, the photoelectrons are accelerated by this field in different ways when they exit the photocathode, depending on whether they exit at the edge of the image field at A or in the middle at B. The edge electrons initially run on an outwardly curved arc, while the center electrons follow a straight path. However, the representation is greatly exaggerated because the curvature is less pronounced than drawn. Due to these field conditions, it is a result of the known arrangements that an edge blurring occurs. The arrangement according to the invention is shown in FIG. 2 shown. This figure shows the image converter part of the tube in an enlarged view, the electrodes being omitted for the sake of simplicity. In this arrangement, on the end face of the piston 1 carrying the photocathode, there is a frame-shaped element 6 which is provided with an auxiliary coil 7, the inner edge of which is close to the image field of the photocathode and the outer edge of which is at a substantial distance from the main focusing coil 5. The frame 6 is provided on its circumference with several projections which engage in corresponding grooves on the main focusing coil 5, so that the frame 6 is firmly anchored to the coil 5. The magnetic field generated by the coil 7 has the same main direction as that of the coil 5. The coil can be dimensioned so that the same focusing current flows through it.

The advantage of the invention is obtained in that a magnetic field with a radial component is generated by the near field of the auxiliary coil 7 opposite the edge parts of the image field of the photocathode, which causes a constriction of the main magnetic field. As a result of this constriction, the lines of magnetic force at the edge are curved in a similar manner to the path of the edge electrons shown in FIG. 1 at A. What is achieved in this way is that the electrons are imaged both at the edge and in the center in the plane of the storage electrode 3 if the magnetic field strength is correctly measured, so that the field curvature is essentially eliminated. For further improvement, with certain types of tubes in which the smallest possible change in the image scale between the photocathode and storage electrode is important, the focusing field generated by the auxiliary coil 7 at least for the electrons exiting in the center of the photocathode can be replaced by one in the space 8 between the auxiliary coil 7 and the edge of the frame 6 attached further auxiliary coil are compensated. In the previous 3 "superorthicon cameras, an image field 10 of about 45 mm diagonal and a grid 11 on the storage electrode 3 of about 35 mm have been established with a distance between photocathode and storage electrode of 60 mm. This condition arises with regard to the fact That the magnetic field of the main focusing coil 5 is already somewhat divergent in the image converter space. However, since experience has shown that the lines of force of the coil 5 often diverge too much due to unavoidable winding tolerances, a certain reduction in divergence is desirable. This is also achieved by the field of the auxiliary coil when the The dimensions given below must be adhered to: outer diameter of the coil = distance between photocathode and target; ratio of height to width of the cross-winding section = 5: 2; height of the winding = 4 to 5 mm.

Claims (6)

Patent claims: 1. Arrangement to increase the edge sharpness in pre-imaging systems of superorthicon tubes, where the pre-imaging system is surrounded by a magnetic focus coil and an auxiliary coil in the vicinity of the photocathode for increasing the magnetic field strength is used in the photocathode plane, characterized in that immediately in front of the photocathode (2) carrying End face of the tube an auxiliary coil (7) is attached low height, which in the same Direction of current as the main focus coil is traversed by the current and its inner edge is close the corners of the image field (10) provided on the photocathode and its outer edge in a distance from the main focus coil which is at least as great as the height the coil winding is the auxiliary coil itself. 2. Arrangement according to claim 1, characterized in that the auxiliary coil at a 3 "-Or1hikonkamerarube a height of about 5 mm and a distance from its outer edge from the inside of the main focus coil (5) of about 15 mm. 3. Arrangement according to claim 1 or 2, characterized in that between the main focusing coil and a further auxiliary coil is arranged on the auxiliary coil, which has a magnetic field opposite to that of the main focusing coil generated. 4. Arrangement according to one of the preceding claims, characterized in that a frame is used for the auxiliary coil windings, which is attached to the inside of the main focusing coil is attached and against which the face of the Superorthikonröhre rests. 5. Arrangement according to claim 1, characterized in that the outer diameter of the Coil (7) is practically equal to the distance between storage electrode (3) and photocathode (2). 6. Arrangement according to claims 1 and 5, characterized in that the ratio Height to width of the winding cross-section is as 1: 5. Considered publications:
German interpretative document No. 1030 389. 1 sheet of drawings 409 588/166 4.64 © Bundesdruckerei Berlin