DE1289921B - Method and arrangement for reproducing signals stored on a dielectric recording medium in the form of electrostatic charges - Google Patents

Description

The invention relates to a method for reproducing a dielectric recording medium in the form of electrostatic charges stored signals as well as on devices for carrying out such a method.

For permanent recording of images and the like, it is already known onto a dielectric recording medium, e.g. B. a sheet of paper, electrostatic To generate charges in the pattern of the image and then the recording medium to dust with a charge powder, so that finally a corresponding powder image arises. In order to develop the electrostatic charges in the paper, is it is already known to guide the paper over the front wall of a cathode ray tube, in which several insulated embedded wires are provided that cyclically through the electron beam can be scanned. On the back of the paper is included a counter electrode is provided which is electrically connected to the electron beam source is.

It is also a similar device is already known in which via the end wall of a cathode ray tube with embedded wires a metal paper is guided, which is conductively connected to the electron beam source is so that through the wires scanned by the electron beam the beam current flows to the metal layer and on this a trace due to melting or burning leaves behind.

All of these known arrangements are for recording only of corresponding images on a recording medium.

It is the object of the invention to show a simple method according to which such on a dielectric recording medium in the form of elec- ; Signals stored under static charges can also be reproduced.

In order to achieve this object, according to the invention, the signals in Dielectric recording media that store electrostatic charges via the ends of several protruding from a wall part of a cathode ray tube Insulated wires embedded in the wall, the wires attached to theirs into the inside of the tube protruding wire ends cyclically scanned by the electron beam and that with a Electrode, which is directed by the charges that are in the wires: by the charges of the recording medium are induced, caused changes in the electron beam itself or the potential relationships of a circuit containing the electron beam responds, an electrical corresponding to the charge of the wire being scanned Output signal generated. According to the method according to the invention, for example tape-shaped dielectric recording medium on which signals, for example TV signals or the like are stored in the form of electrostatic charges, can be reproduced practically loss-free and without distortion.

To carry out such a method according to the invention are the most varied of arrangements possible. For example, an arrangement can be used find, in which a collecting electrode is arranged inside the cathode ray tube is to which the electron beam depends on the induced in the wires Charges is directed, and at which the output signal is tapped. It can but also a cathode ray tube use, in the end wall of the wires are embedded insulated, facing away from the end wall of the cathode ray tube The surface of the recording medium presses the recording medium against the wires Outer electrode is arranged, which is connected to an opposite to the electron gun fixed potential is connected, the potential of which is due to the capacitive acting charge of each hit by the electron beam and thereby connected Wire changes, and that the output signal is tapped at this outer electrode. Should z. B. television stills are reproduced on a dielectric Recording media are stored according to the interlace method, so can The method according to the invention also has a number of display tubes corresponding to the number of partial images be arranged along the path of movement of the recording medium.

The invention is described below with reference to schematic drawings explained in more detail using exemplary embodiments.

F i g. 1 to 4 show possible embodiments of a display device in the form of a cathode ray tube with wires inserted in its end wall; F. i g. 5 and 6 show the arrangement for displaying composite television pictures.

F i g. 1 shows a cathode ray tube 310 having a plurality of wires 311 embedded in the end wall and extending outwardly through the end face of the tube. Cathode 312 is grounded on line 314, control grid 316 is connected to voltage divider 318 via line 319 so that a suitable negative bias is present, and accelerating anode 321 is connected to resistor 318 via line 323. The tape 325 can pass over the wires 311 in the direction of arrow 326 and be pressed against the ends of the wires by a knife-edge electrode 328; electrode 328 extends the width of the tape. Electrode 328 can be held at an appropriate positive or negative potential with respect to cathode 312; for this purpose, batteries 330 and 331 are provided which are connected in series and are connected to a resistor 335 to which the electrode 328 is connected via a line 337 and a sliding contact. The batteries 330 and 331 are grounded via a line 339. The cathode 312 emits an electron beam 341 which is reflected by the wires 311 along a return path 342 so that the electrons impinge on a collecting electrode 343. A line 345 leads from the collecting electrode to a suitable amplifier for reproducing the recorded signal. A device is also provided to cause the beam 341 to scan the wires 311 at right angles to the plane of the drawing of FIG. 1 to perform.

When the belt 325 is in operation of the arrangement of FIG. 1 passes the wires 311, the charges on the strip cause brief changes in the potential on the wires 311, these changes e.g. B. correspond to a line of a recorded television signal. The beam is delayed near the row of wires so that it is reflected just before reaching the wires, and the strength of the returning beam varies depending on the potential on each wire 311 during the scan. The reflected beam is picked up by the electrodes 343 and emitted via the line 345 to an external amplifier. Alternatively, an electron beam multiplier can be built into tube 310 in a known manner to amplify the returning beam 342.

In the case of the in FIG. In the modified display tube shown in FIG. 2, the beam 360 follows a curved path in the tube 361; this is due to the fact that a steady magnetic field is perpendicular to the plane of the drawing of FIG. 2 works. A suitable deflecting magnetic field can also be provided so that the beam 360 deflects the wires 362 in a plane perpendicular to the plane of the drawing. The outer electrode 364 presses the moving belt 365 against the wires 362 as in the arrangements already described, and the belt can move in the direction of the arrow 366.

The outer electrode 364 is connected by means of a circuit according to FIG. 1 held at a suitable potential; in Fig. 2, the corresponding parts are denoted by the same reference numerals as in FIG. 1. As the beam moves past the row of wires 362, it is deflected to a greater or lesser extent as a result of the charges imparted to the wires by belt 365. The beam then strikes the collecting electrode 370, and electrons strike the plate 370 in greater or lesser numbers, depending on the amount of deflection the beam experiences in the vicinity of the wires 362. The collecting electrode 371 serves to collect the remaining electrons of the beam and can be connected to a source of a suitable positive voltage. The electron current coming from the collecting plate 370 is applied to the grid of the amplifier tube 373 via a coupling capacitor 374. If necessary, the two collecting plates can be arranged in a push-pull circuit, so that an increase in the number of electrons on one plate and a decrease in the number of electrons on the other plate results in a symmetrical output signal.

F i g. 3 shows a further embodiment of a display device with a tube 380; this tube has an electron gun 382 for generating a relatively narrow but perpendicularly elongated electron beam 383. Suitable shielding plates 385 and 386 can limit the portion of the beam reaching the secondary emitter plate 388. The ribbon 390 is free to move in the direction of arrow 391 past a set of wires 392 arranged on a line across the length of the ribbon, as is the case with the arrangements previously described. The ray 383 becomes perpendicular to the plane of the drawing of FIG. 3 is cyclically deflected in synchronism with the line frequency of the television signal to scan the wires 392 one by one. The briefly generated charges on the wires 392 serve to deflect the beam more or less strongly in the plane of the drawing, so that the shielding plate 386 intercepts a larger or smaller number of electrons. The number of electrons reaching the secondary emitter 388 is thus a function of the on tape 390 and the secondary electrons reaching collector plate 395 are also a function of the recorded signal. The line 396 can according to FIG. 2 can be connected to a suitable amplifier circuit, or a set of electron multipliers can be provided in place of the collector plate 395 in order to effect further amplification within the tube 380. The outer electrode 398 is designed in the same way as the outer electrodes already described, and it can be connected to a circuit by means of which its potential is regulated; for this purpose it can be connected to a circuit according to FIG. 1 and 2, respectively, the line 399 being the one shown in FIG. 1 and 2 correspond to lines 337 shown.

The arrangement according to FIG. 3 offers the advantage that the secondary emitter 388 amplifies the electron beam signal to produce a larger output signal and that it is also not necessary to provide a field for bending the beam as is the case with the arrangement of FIG. 2 is required. The plates 385 and 386 delimit a path of the beam which is relatively insensitive to fluctuations in the supply voltage and to interference fields. An undesired absorption of disturbances can be further restricted by arranging the plates at a smaller distance from one another and from the donor organ. If necessary, the shielding electrodes can be connected to an automatic control system in order to control the electron beam.

F i g. 4 shows another display tube 405 with a cathode 406, a control grid 407 and an anode 408, by means of which an electron beam 410 is projected against a set of electrically conductive wires 412 . The line 413 connects the cathode to the voltage divider 417, while the control grid 407 is also connected to the voltage divider via a line 415. The anode 408 is connected to the voltage divider 417 by a lead 419 and a conductive coating on the inner wall of the tube, shown in FIG. 4, denoted by 420 , is connected by a line 421 to a point of the voltage divider 417 which has a higher positive voltage. Magnetic deflection windings 425 and 426 serve to make the beam 410 perpendicular to the plane of the drawing of FIG. 4 and deflect synchronously with the line frequency of a television signal. The tape 428 runs in the direction of arrow 429 and is pressed against the ends of the wires 412 by an outer electrode 430; the outer electrode can comprise a thin layer of electrically conductive material which extends over the entire width of the strip and is embedded in an insulating housing 431 made of epoxy resin or the like. Alternatively, the outer electrode can take the form of a resilient pad, the pad being impregnated with a conductive material.

The outer electrode 430 is biased with respect to the electron beam voltage via the adjustable contact of the line 440 from the voltage divider 417. This voltage can be positive or negative or equal to zero. A shielding element 441, which is brought to the same voltage as the grid, surrounds the sensitive electrode 430 in order to neutralize its capacitance. The output voltage is developed across resistor 444 and applied to the grid of amplifier tube 446 through a coupling capacitor 445. The output of the amplifier is passed through capacitor 448 and output lines 449 and 450 to a suitable device, e.g. B. a television playback device issued. The conductive connection between the outer electrode 430 and the grid of the tube 446 can be shielded in the manner indicated at 452; the shield 452 can be connected to the cathode of the tube as shown, as well as to the shield 441 to maintain the shield at the cathode voltage.

With all the arrangements described so far, you can get through this the tube wall extending wire system by photoetching and with the help of Produce vapor deposition process; this is a suitable material in the with the help openings formed in the tube according to this method. For example Indium or indium solder is suitable for producing conductive tracks that use the Push through the wall of the tube.

In Fig. 5 the three cathode ray tubes 280, 281 and 282 are shown, each having wire systems 284 or 285 or 286 and outer electrodes 288 or 289 or 290 , the latter pressing the band 291 against the wires. The direction of travel of the belt 291 is indicated by the arrow 293 ; in Fig. 6 the position of the wire systems 284, 285 and 286 with respect to the band is indicated. The arrangement according to FIG. 5 and 6 make it possible to reproduce three fields of a television signal using the interlace method; in this case the first partial image is displayed with the aid of the tube 280, the second partial image with the aid of the tube 281 and the third with the aid of the tube 282, with suitable electronic switching means controlling the successive switching on of the tubes in accordance with the television signal.

According to FIG. 6, the wires 284 are used to reproduce the lines reproduced as solid lines at 295 , the wires 285 for the lines indicated by dashed lines at 296 , and the wires 286 for the lines reproduced at 297 as dash-dotted lines. In a color television system one could e.g. B. associate wire system 284 with the red image, wire system 285 with the green image, and wire system 286 with the blue image. As before, wire systems 285, 284, and 286 would be spaced a distance equal to the length of an image minus one line on tape 291. Furthermore, one can see that in FIG. Extend the methods illustrated in FIGS. 5 and 6 to interlaced display of color television images, and so on.

Claims (6)

Claims: 1. Method for reproducing on a dielectric Recording media in the form of signals stored in the form of electrostatic charges, characterized in that the recording medium consists of a wall part a cathode ray tube isolated from several ends in the wall embedded wires that the wires are attached to their inside the tube protruding wire ends are cyclically scanned by the electron beam and that with an electrode that points to the from the charges that are in the wires through the Charges of the recording medium are induced, caused changes in the electron beam itself or the potential relationships of a circuit containing the electron beam responds, an electrical corresponding to the charge of the wire being scanned Output signal is generated. 2. Arrangement for carrying out the method according to claim 1, characterized by a collecting electrode arranged within the cathode ray tube (343, 370, 395) on which the electron beam is directed depending on the in the Wires induced charges is directed and at which the output signal is tapped (Figs. 1, 2 and 3). 3. Arrangement according to claim 2, characterized in that on the surface of the recording medium facing away from the cathode ray tube (e.g. 325) an external electrode (e.g. 328) is arranged which, the recording medium against the outwardly protruding ends of the wires (z. B. 311), a DC voltage (z. B. 330, 331) being placed between this outer electrode and the electron gun (z. B. cathode 312). 4. Arrangement according to claim 3, characterized in that the outer electrode (z. B. 328) pressing on the recording medium consists of a resilient, essentially non-conductive material impregnated with a conductive material. 5. Arrangement for carrying out the method according to claim 1 with a cathode ray tube, in the end wall of which the wires are insulated embedded, characterized in that an outer electrode (430) pressing the recording medium against the wires is arranged on the surface of the recording medium facing away from the end wall of the cathode ray tube , which is biased with respect to the electron gun, its potential changing due to the capacitive charge of the wire hit by the electron beam and thereby connected via the recording medium, and that the output signal is tapped at this outer electrode (FIG. 4). 6. Arrangement for carrying out the method according to claim 1, characterized characterized in that for reproducing on a dielectric recording medium stored and interlaced composite television frames the number of partial images corresponding to the number of cathode ray tubes along the movement path of the recording medium are arranged.