DE1081159B - Ribbon storage screen for cathode ray tubes - Google Patents

Description

GERMAN

The main patent application M 34062 VIII c / 21 g relates to a ribbon-shaped storage screen for cathode ray tubes, which is acted upon by the write and read beam from one side, and from one side strip-shaped insulating body, on the back of which there are two signal electrodes isolated from one another are applied in the deflection direction and on the other side facing the beam perpendicular to Deflection direction narrow, insulated, conductive lamellae are applied, the length of which is at least twice the width of the signal electrode on the back.

In the proposed arrangement, the two parts of the cathode ray become independent of each other along straight parallel lines. and distracted. A deflection direction becomes electrical used, the other is the return direction. The necessity of the rewind causes a certain Loss of time and, moreover, the arrangement is prone to interference to a certain extent and the generation of false signals. The purpose of the present invention is to provide an arrangement to provide an improved integration of signals compared to the proposed arrangement, generated at which the crosstalk between the signal input and the signal output is reduced and in which the reflux with its inherent disadvantages is avoided.

The storage screen according to the invention is characterized in that, in order to avoid a Return time is formed endless.

According to a particularly favorable development, the storage screen is designed in the shape of a ring. One Cathode ray tube with the storage screen described can, like any storage arrangement, Use in a DF receiving system with a directional antenna system with rotating directional characteristics Find. If the write beam is deflected at a higher frequency than the read beam, then this is achieved a summation of the received signals and thus a favorable signal-to-interference ratio.

The antenna ratio can be a rotating DF antenna or a fixed DF antenna in conjunction be with a goniometer, in which the change of direction by rotating drive means which move the antenna or the search coil of the goniometer. The one of two predetermined frequencies can be obtained from a generator which by said Drive means is driven, and the other can be obtained from a second generator, the similar to how the first is driven or by frequency multiplication or frequency division from the first. In addition, one of the two deflection

Ribbon-shaped storage screen
for cathode ray tubes

Addition to patent application M 34062 VIIIc / 21g
(Auslegeschrift 1 076 829)

Applicant:

Marconi's Wireless

Telegraph Company Ltd.,

London

Representative: Dr.-Ing. B. Johannesson, patent attorney,
Hanover, Göttinger Chaussee 76

Claimed priority:
Great Britain September 26, 1956 and May 15, 1957

Donald Leopold Plaistowe, Chelmsford, Essex

(Great Britain),
has been named as the inventor

frequencies can be obtained by separating and utilizing a frequency component which is contained in the received signals corresponding to the rotation of the directivity is included, the other is made out the first generated by frequency multiplication.

The arrangement described will be described in more detail below with reference to the drawings which the

Fig. 1 is a general schematic view of an embodiment of a direction finding system with a Electron beam storage tube and the

FIG. 2 shows the target electrode of a storage tube as used in the embodiment of FIG. 1, represents.

The electron beam storage tube as used in the exemplary embodiment in FIG. 1 will first be described with reference to the drawings. This tube has a cathode 1 which, for example, has a potential of 1 kV and which is indirectly heated by a heater 2 and emits an electron beam 3 which successively passes through a beam-shaping electrode 4, an anode screen 5 and a cylindrical anode 6.

009 508/343

3 4

Beyond the anode 6 is another anode 7 which, if again has the plate and the outer parts of the two adjacent holes 8 and 9, electrodes 22 are located between these parts,
arranged. Behind the anode 7, two pairs of reception is seen by means of a conventionally known the strahlaufspaltenden Platten.10-11 and 10-12 form upstream of a directional antenna with a constantly rotating, of which the plate 10 obtained for both Community 5 directivity. In the depicted Aussam is. This plate lies in a plane that divides the exemplary embodiment, this antenna system consists of a connecting line between the centers of the two pairs of perpendicular holes 8 and 9 and which is at a right angle 26 and 27 in connection with a gonio angle to the surface of the Anode 7 and said meter, which is arranged in two perpendicular lines. The electrodes 4, 5 and 6 act on coils 28, 29 connected to the antennas and one effect that the beam 3 contains a coil 30 rotating onto the holes 8 and 9, which strikes with a suitable one. This, together with the jet-splitting speed, caused by an electric motor 31 on plates, that the jet is essentially driven in two. The mechanical connections with borrowed equal parts 3 α and 3 b is split up. As usual, the motor is controlled by dot-dashed voltages that are indicated by 15 lines in the drawing. The motor 31 taps off potentiometers that are not shown and drives the two generators 32, 33, from which plates 10-11 and 10-12 are supplied. The part 3 α of the generator 33 generates a frequency which passes through two pairs of deflection then the speed of rotation of the coil 30 and the plates 13 and 14 and the beam 3 & runs similar to the generator 32 produces a much lower frequency of rotation through the beam two pairs of baffles 20 quenz. To give practical figures: The Fre-15 and 16. If necessary, between the quenz from the generator 33 can be 100 Hz, that from adjoining plate pairs 13, 15 and 14, 16 from the generator 32 can be 10 Hz. The generators shield plates may be provided. For the sake of simplicity in FIGS. 32 and 33, only one such shielding shape may have been formed in any suitable known drawing, e.g. B. shown as induction generator plate. This is the plate 17 between the 25 gates.

Pairs 13 and 15. The two parts 3 α and 3 b of the output voltage from the generator 32 will fall, after having passed through the deflection plates a phase splitter 34 of any known shape, onto a target electrode 18, which is fed in, which said beam Output voltage in Fig. 1 is shown only schematically. Their construction, two shafts offset by 90 ° in the phase, is shown in more detail in FIG. The 30 amplitude converts. One of these by 90 ° in the target electrode consists of a plate 19 made of glass and phase-shifted output voltages is across the electrodes 22, 24, 25. Close to said plate are line 35 of the plates 15 and the other over the two on the cathode side concentric line 26 fed to the plates 16. The output grids 20 and 21. On the end face of the glass plate, voltage from the generator 33 is passed through a g on which the grids are attached, ie on the 35 suitable phase splitter 37 in two against each other around the end face which faces the cathode is a 90 ° offset components split and a ring of isolated from each other radial strip electric these components is provided on the line 38 the electrodes, which z. B. supplied by gold deposit plates 13, while the other can be formed on the stanchions on the plate. It has reached the plates 14 because of line 39. Appropriate means of the scale of the drawing unsuitable, these electrodes 40 for amplitude control (not shown) can be provided in the correct scale and in the correct number to show the waveforms, because a very large number of them are in front of plate pairs 13 to 16 are supplied, to regulate, is seen and accordingly these are schematically such that the beam parts 3 α, 3 b circularly indicated by some electrodes. In practice, grids with the two frequencies from the generators like e.g. B. about 3000 gold electrodes 22 on the 45 32 and 33 are deflected. The beam part 3 a runs glass plate 19 may be provided. The radial length of each through the outer grid 21 to the outer portions of the gold electrode 22 is equal to or slightly greater than islands 22, and the beam portion 3 & is through which the radial distance between the inner edge of the inner grid 20 to the inner portions of the Islands 22. inner grid 20 and the outer edge of the outer The outer part rotates at 250 revolutions per grid 21, so that when the grids and plates are arranged in 50 seconds around the grid 21, and the inner part 3 b correct mutual spacing that rotates around the grid 20 at 25 revolutions per grid at a small distance above the gold electrodes second.

lie. A metal goniometer is placed around the circumference of the plate 19 and on the same side as the gold electrodes is grounded and which is insulated from the electrodes 22 on the back of the target electrode 19 supplied. On the back of the plate 19, ie to be. The inner end face facing away from the cathode, arranged on the rear side, is ring 24 is connected to an amplifier 41 and its two concentric gold ring electrodes 24 and 25, aisle connected to a detector 42, the escape of which is indicated by dashed lines in FIG. 60 output voltage are again shown in a further multiplier of circles in FIG. 1. The inner stronger 43 reinforced and on an indicating instrument ring 24 is of a diameter which corresponds approximately to the 44 or on a cathode ray display tube 45 average diameter of the grid 20 , - in the embodiment shown, while the diameter of the outer ring 25 is approximately both a display instrument and equal to the mean diameter of the outer grid illustrated display tube 65, wherein both is parallel-21st If the parts of the arrangement are fed correctly. The electron beam of the display tube are assembled, the ring 24 is centered on 45 is due to the amplified signals from the Verdem grid 20, whereby the plate and the inner parts are more controlled 45 and circular in synchronism of the electrodes 22 between them, as is with the Rotation of the directional effect of the antenna of the ring 25 concentric to the grating 21, with the planar system by means of perpendicular spacing

Claims (4)

1 081 1B9 deflected steering coils, to which the two output voltages of the phase splitter 34, which are phase-shifted by 90 ° with respect to one another, are fed via the lines 46, 47. A suitable bias voltage from a voltage source 48 is applied to the outer grid 21 and the high frequency vibrations from the source 49 to the inner grid 20. In this arrangement, the target electrode consists of a mosaic-like storage electrode in which signals from the directional antenna system are stored and the outer cathode ray rotates. The numbers given in the exemplary embodiment are used to write, i.e. H. the storage process 250 times per second. The stored signals on the ring of electrodes 22 will show defined minima on the electrodes at the end of the diameter corresponding to the minimum reception direction. The stored or written signals are read by the relatively slowly rotating part of the electron beam and the signals resulting therefrom are fed from the ring 24 to the amplifier 41. Since the high frequency oscillations from the generator 49 are fed to the grating 20, the output signals which the amplifier 41 receives are high frequency signals which are modulated by the read stored signals and the amplifier 41 is designed in such a way that it is selective for this high frequency. The cathode ray tube 45 will provide a display which directly indicates the direction of the incoming signals. Of course, other means known per se can also be used to determine the direction from the signals which are picked up by the ring 24. As a result of the storage process and the signal-integrating effect, a very good overall signal-to-noise ratio can be obtained from the writing process taking place at high speed and the reading process taking place at slow speed, with no loss of time due to return in the tube and a minimum of Crosstalk occurs. It can also e.g. B. from each other by 90 ° offset antennas and a goniometer existing directional antenna system by another known system, such. B. a rotating bearing frame or dipole, can be replaced. In addition, the deflection frequencies do not have to be generated by means of the generators 13 and 33 shown. It should also be mentioned that the rotation of the directional characteristic generates a frequency component which corresponds to the speed of rotation of the directional characteristic. This component can, if desired, be received from the received signals in any convenient manner and used to provide one of the deflection frequencies for the tube. The other is obtained from said component by frequency multiplication. PITENT APPROACH: 1. Ribbon-shaped storage screen for cathode ray tubes, which can be used by the write and read beam from is applied to one side and which consists of a strip-shaped insulating body on which Rear side two signal electrodes isolated from one another are applied in the deflection direction and on the other side facing the beam, perpendicular to the deflection direction, narrow from one another insulated conductive lamellas are applied, the length of which is at least twice the width corresponds to the signal electrode on the back, according to patent application M 34062 VIIIc / 21g, characterized in that the Storage screen is designed to be endless in order to avoid a return time. 2. Storage screen according to claim 1, characterized in that it is annular. 3. Storage screen according to claim 2, characterized in that on the radially extending Strip of the storage screen, but isolated from these, two ring-shaped, from each other isolated grid electrodes are arranged concentrically. 4. Cathode ray tube with a storage screen according to one of claims 1 to 3, characterized characterized in that when used in a DF receiving system to achieve a summation of the received signals, the write beam is deflected at a higher frequency than the read beam. Considered publications: German interpretation document C 11076 VIIIc / 21g
made known on September 13, 1956). 1 sheet of drawings