DE758468C - Storing image transmission tubes, the mosaic electrode of which is scanned with slow electrons - Google Patents

Description

The well-known picture tubes with one High speed scanning cathode ray, which is more than one at the mosaic electrode Triggers secondary electron per primary electron, -have the following disadvantages:

The secondary electrons released at the mosaic electrode form in front of the mosaic a space charge cloud from which a substantial part of the electrons hit the mosaic falls back and reduces the image signal. This fallback does not happen now

evenly over the entire mosaic electrode surface and thereby causes the well-known interference signal, which is noticeable in the receiver as a shadowy image. Furthermore has the occurrence of a secondary emission factor greater than 1 still has the disadvantage that of the scan the unexposed mosaic elements in the vicinity of the anode potential are brought and that for the photoelectrons released on the elements during exposure only a very low suction

voltage is available, which means that only a very small image signal is generated. These disadvantages can basically be avoided when using a scanning beam from slow Electrons are electrons whose speed is measured in such a way that the secondary emission factor at the mosaic electrode becomes smaller than ι, fix it. As a result, it charges the unexposed mosaic elements scanning cathode ray the same approximately to cathode potential, so that then a high suction voltage for exposure the photoelectrons are available, which means a high image signal and better proportionality between the luminous flux and the charging of the elements.

It is well known that slow electrons can be influenced extremely easily by stray fields and also because of the mutual electron repulsion that occurs during the slow speed is particularly noticeable, difficult to a small Focus point. A known method of operation of storing picture tubes therefore tends to use a high speed scanning beam and that shortly before the impact of a braking electrode arranged in front of it to influence so that the jet speed is slowed down to approximately zero. That way will a beam that is relatively difficult to influence on its long path by interference fields created, but a strong defocusing occurs due to the deceleration of the beam, which makes this process unsuitable for the image resolution that is common today. There are also known storage image transmission tubes, the mosaic electrode with slow Electron is scanned and the one the space between the beam generator and Have a homogeneous longitudinal magnetic field penetrating the mosaic electrode. The beam deflection takes place magnetically in both coordinates. Sweep at these picture tubes both the electrons returning from the mosaic and those released at the mosaic Photoelectrons return to the anode opening and hit there as with the known probe scanners a probe from which the image signal is picked up. Even In this case, the beam electrons emanating from the hot cathode are initially directed to a Speed of 1000 V accelerated and only on the way between the anode opening and the mosaic by negatively biasing the signal plate to a low level Decelerated speed. Despite the bundling property of the magnetic field a strong defocusing occurs, because the electron speed, the-first 1000 V was around 950 V, so it has to be braked to 50 V to get one on the mosaic Secondary emission factor less than 1 to be obtained.

According to the invention, on the other hand, in the case of a storing picture transmitter tube, the mosaic electrode thereof is scanned with slow electrons and the one the space between the beam generator and J having a homogeneous longitudinal magnetic field penetrating the mosaic electrode, entering of the electrons returning from the mosaic electrode into the: opening of the last anode of the beam generator by a static at least in one direction Distraction prevented.

It has been found that with purely magnetic beam deflection, interference signals arise which result from not all returning from the mosaic electrode Electrons reach the last anode, but partly through the anode opening Fly in the direction of the beam generating cathode, turn around near it and now accelerated again through the anode field in the direction of the mosaic electrode will. This disadvantage is eliminated by using at least one static deflection field, because it results in the from Electrons returning to the mosaic are deflected in the opposite direction as those flying towards the mosaic electrode. So while with the magnetic deflection field the path of those flying to the mosaic electrode and of this returning electron is the same, occurs at a static sight Deflection field a path division, so that a passage of the returning electrons through the anode opening of the beam generator not possible. Since the returning electrons are numerically the same as those used for scanning and around electrons necessary to neutralize the charges are reduced, they represent thus represents a direct measure of the pixel brightness. It is therefore of course without further possible, the returning electrons gradually through secondary emission to amplify and to pick up the image signal at the last electrode of this multiplier.

An embodiment of the invention will now be explained in more detail with reference to the drawings. In the case of the image transmission tube shown in longitudinal section (Fig. 1) and in cross section (Fig. 2) , the Λ-Iosaic electrode 2 is arranged in the vacuum vessel 1 at one end. Opposite it is the scanning beam generation system, consisting of the cathode 3, the control electrode 4 and the anodes 5 and 6. The Mosaike.lektrode is on its side facing the beam generator with a multitude of mutually isolated photo-

elements ίο covered, which are on an insulating plate 8, e.g. B. made of mica. The image is thrown from the mosaic elements opposite side by a signal plate arranged on the dielectric 9. The voltages of all electrodes are chosen so that the electrons of the Scanning beam hit the mosaic elements with extremely low speed (almost zero).

If the unexposed mosaic electrode is scanned by the scanning beam, all of them receive Elements have a negative charge compared to the cathode; Scanning electrons takes place. If the image is now thrown, the exposed elements take more or less positive charges, which are returned to the by the scanning beam original value can be returned. The electrons of the not used here The scanning beam is reversed and arrives at the suction electrode. 16, which is disc-shaped can be and the opening is slightly larger than. that of the last anode 6 of the jet generator.

The entire space between the beam generator and the mosaic electrode is homogeneous A longitudinal magnetic field which is generated by the coil 13 is penetrated. The beam deflection occurs through the interaction of this magnetic field with an electrostatic one as. an electromagnetic deflection field. The baffles are 14 and denoted by 15 the deflection coils. The electrostatic and the electromagnetic Deflection field. are preferably one behind the other arranged.

The direction of deflection of the static deflection field would actually lie in the plane of the drawing ¹ of Fig. Ι, but due to the interaction of this field with the field of the coil 13, the deflection is perpendicular to the plane of the drawing. Without using a homogeneous magnetic. Field, the electrons are at a certain angle. deflected from their original flight direction and continue to travel in this deflected direction even after they have left the electrostatic field. In the case of the picture tube according to the invention, however, in which a superposition of the field of the coil 13 and the field of the deflection plates 14 takes place, the electrons are first deflected from their normal axial direction of movement by the electrostatic field, whereupon they. after leaving this field parallel to the axial direction of the tube, ie parallel to its previous flight direction, continue to run, due to the influence of the coil 13. Thereafter, the electrons are deflected perpendicular to the direction of this first deflection by the field, the deflection coils 15, while they are at the same time still in the homogeneous field of the coil 13. The electrons, which do not reach the mosaic electrode, return approximately on their previous path, namely until they enter the field of deflection plates 14: whereupon they deviate from this path by an angle equal to the first Deflection angle is. These returning electrons therefore run along different paths and no longer follow their original path, that is to say they no longer reach the anode opening of the scanning beam generating system, but strike the suction electrode 16. This must be between the last anode 6 and the baffles 14 so that it is outside the path of the electrons between the scanning gun and the mosaic electrode, but within the path of the electrons returning from the mosaic electrode. The image signals can optionally also be picked up from this electrode instead of the signal plate 9.

In the embodiment according to Fig. 1, that part of the electrons to which the electrostatic field of the baffles 14 exerts no influence, return to the Kaithode and acts as a very weak interfering signal. This interfering signal is on a only one. Line, which is in a plane parallel to the two baffle surfaces, and lies in the middle between them. This interference signal can in the embodiment can be reduced to a picture element area according to Fig. 3.

In the case of the picture transmission tube according to the invention, a subsequent Perform secondary electron amplification of the image signal. This should also be on hand an example can be shown in connection with Fig. 3. This embodiment initially differs from the embodiment according to Fig. 1 that the beam deflection is static in both directions takes place. The baffles 17 are arranged in the same place as the plates 14. An electrostatic deflector in which the plates are made of resistive material exist, which are connected to one another at the longitudinal edges, is particularly suitable.

In each of the embodiments shown in the figures, the distance between the baffles, so the plates 14 in Fig. ibzw. plates 14 and 17 in Fig. 3, at least as * large as the one in question Dimension of the area to be scanned on the mosaic electrode. It is even useful to make the plate spacing larger than the Moisaic electrode. That arises from the fact that the electrons

let the deflection field continue to run parallel to the tube axis and thus already theirs have reached maximum distraction.

In the embodiment according to paragraph 3, the coming from the mosaic electrode Electrons multiplied by secondary emission. On the way of the returning electrons, preferably between the baffles 14, 17 and the scanning beam generating system, lies a series of reticulated anodes, which are equipped with central openings, the diameter of which is the same or slightly larger than the diameter of the one exiting the scanning beam generation system Electron beam is. The net-like electrodes are denoted by 18 to 21 and lie on increasing potentials. From the collecting electrode or anode 21 this becomes Image signal removed. This is at a positive potential compared to the anode 6. The Reticulated anode 21 can also consist of a disc drilled through in the middle. The anodes 18, 19 and 20 are preferably made of a high secondary material emission coefficient produced.

In the device according to Fig. 1 and 2 it has been shown that a weak interfering signal can still arise, but that this interference signal is limited to a very narrow strip is, which can have a maximum of the width of the anode opening. When arranging according to Fig. 3, showing two pairs of baffles are used and these plates are in a homogeneous magnetic field, that is Noise signal is confined to a very small area the size of the anode opening. this is due to the fact that the electrons returning from the mosaic electrode run in the axis of the tube only when both deflection fields are zero; This is is known to be the case only once during each image period. At any other point in time the cathode ray is scanned through a baffle array throughout the image period bent and reaches the suction electrode 16 in Fig. 1 or after multiplying secondary emissions the suction electrode 21 in Fig. 3.

It is highly desirable that the electrons returning from the mosaic electrode impinge on the collecting electrode and not on one electrode or the other of the cathode ray generator. If the signal is obtained when the returning electrons hit an electrode of the cathode ray generator, the signal current also depends on the current consumption of this electrode by the hot cathode and thus also on the irregularities of the cathode emission. However, if, according to the invention, an electrostatic deflection is used, an electrode which is no longer part of the cathode ray generator can be used as a collecting electrode, thereby avoiding the aforementioned disturbance occurring on the cathode ray generator electrodes. A signal which reproduces the brightness distribution and is free from interference is thus obtained.

Claims (8)

Patent claims: 1. Storing picture tube with a mosaic electrode with slow electrons is scanned and the one the space between the beam generator and mosaic electrode having penetrating homogeneous longitudinal magnetic field, characterized in that an entry of the Mosaic electrode returning electrons into the opening of the last anode of the beam generator is prevented by a static beam deflection occurring at least in one direction. 2. Storage image transmission tube according to claim i, characterized in that the electrostatic deflection field in the vicinity of the cathode ray generator the magnetic deflection field between the electrostatic deflection field and the mosaic electrode and a collecting electrode between the cathode ray generator and the electrostatic deflection field are. 3. Storage image transmission tube according to claim i, characterized in that the Deflection by two preferably acting at the same point on the beam path electrostatic fields takes place. 4. Storage image transmission tube according to Claims 1 and 3, characterized in that that the image signal is picked up at the collecting electrode. 5. Storage picture tube according to claim i, characterized in that the electrons returning from the mosaic electrode into a secondary electron multiplier reach. 6. storing picture tube according to claim 5, characterized in that the "o Multiplier is mounted between the deflectors and the cathode ray generator. 7. Storage image transmission tube according to claim 5, characterized in that the Multiply from a number symmetrically to the undeflected beam is composed of nets which ·. with a central opening are provided for the passage of the scanning beam. 8. storing picture tube according to claim 2 or 3, characterized in that that the longitudinal extent of the deflection fields is smaller than the distance between the last electrode of the beam generator and the mosaic electrode. To distinguish the object of the invention from the state of the art, the grant notice procedure, the following publications have been considered: British Patent Specification No. 446 66i, 10 446664; French patents No. 808 937, 720441, 816963; . U.S. Patent No. 2,087,683. 1 sheet of drawings © 5279 6.52