DE901797C - Electronic device for receiving and storing symbols - Google Patents

Description

Electronic device for receiving and storing symbols The invention concerns an electronic device that triggers electrical, various symbols according to the number of pulses a triggering receives pulses representing, in understandable Converts representations of the symbols represented by the pulses and those received Stores information. The device responds to signals that are triggered by a trigger similar impulses to which a different one indicating the termination of the triggering Identification impulse follows, exist.

Since the number of pulses, not the position of the pulses in a cycle, is decisive the receiving device does not need to be matched to the device sending the impulses to become. The invention comprises an apparatus having multiple banks of electronic tubes, which, when they are effective, transform the impulses' solutions into real representations serve the symbols, and is characterized in that each bank of electron tubes a normally ineffective relay device and a common input circuit are assigned, which sends the received pulses to one of the relay device as well a control device that is only responsive to the identification pulses passes on, the control device when effective by the identification pulses is made, also makes one relay device after another effective. the The invention will now be explained using an exemplary embodiment and the drawings, namely, Fig. r to 5 show parts of the conversion and symbol storage means in Receiving device; this remedy consists of groups or banks of symbolic representations Tubes that correspond to the symbols that correspond to the pulses sent by the transmitter, are optionally adjustable; Fig. 6 shows relay means for selective alignment of pulses to various conversion and symbol storage means groups, Fig.7 an instruction control device with several tubes that can be operated one after the other, which are controlled by the identification signals so that they in turn the relay means control which the various symbols representing the impulses in the correct Routes conversion and symbol storage means groups, and Fig. 8 means of the receiving device to distinguish the symbol-representing impulses from the identification impulses and to control of the receiving device according to the importance of the impulses.

The pulses picked up by the receiving device can be any selected information., e.g. B. the digits of a number system or the letters of the alphabet.

The embodiment shown has a capacity for automatic Record and save five consecutive symbols on the letters of the alphabet.

For the purpose of this illustration, signals representing symbols those chosen from separate, rapidly recurring, over a wire on the receiving device transmitted pulse releases exist. The invention is intended, however in no way limited to this particular type of signal and transmission medium will. every impulse release contains a number of impulses of small amplitude, followed by a Yennimp: uls., large amplitude. The receiving device contains a means of distinguishing that receives the pulses, and those with small amplitudes from those with large ones Amplitude differs. There are also a briefing agent and several conversion and symbol storage means are provided consisting of groups or banks of gas electron tubes to convert pulse releases into individual symbol representations and to save them exist.

Individual description With the resistance values specified in the description and capacitance values, the receiving device responds precisely to impulses that are mutually exclusive in one -tripping, with intervals of approximately rooiNicrosecond between the Trips follow with about 50 kilohertz. The pulse trains are thus like this in short, that an unauthorized interruption of the transmitted information is extremely difficult is.

Those generated by a transmitting device according to the information to be transmitted positive voltage impulses are released from the signal input pole 33o of the receiving device recorded.

The receiving device shown in Fig. I to 8 takes these pulse releases one after the other and distributes them to various conversion and symbol storage means. each conversion and symbol storage means consists of a tube group or bank. The impulses are able to make one tube of the group optionally conductive, making this the symbol that is represented by the number of those present in the trip Impulse: is displayed, displayed and saved.

For the purpose of displaying the received symbols, the receiving device on: a means of distinction that picks up all the transmitted impulses and the impulses with a small amplitude differs from the pulses with a large amplitude, several Conversion and symbol storage means consisting of `groups or banks of symbolic and storage tubes exist, which are used for the purpose of converting the impulse releases into Symbol displays can be put into operation, as well as a means of instruction, every time a pulse with a large amplitude or an identification pulse is recorded is set in motion and the successive trips in different Conversion and symbol storage means conducts. The medium of distinction The medium of distinction is shown in FIG. All delivered to the input terminal of the receiving device Signals are effective to control the differentiating means that respond to impulses with small amplitude responds differently than to those with large amplitude.

Part of the means of distinction speaks to both received Pulses with small as well as those with large amplitude and is able to the same number of pulses on a common pulse conductor in the receiving device transfer.

Another part of the means of discrimination speaks only to impulses with a large amplitude or on identification pulses and can send a pulse to a training control device and this in operation every time an identification pulse is received to put. This part of the means of distinction secretes the identification pulse (with a large Amplitude), which indicates the end of a trip and causes the instruction means routes the next trip to another group of symbol storage tubes.

The portion tds discriminating means responsive to all received pulses consists of a pair of vacuum tubes 300 and 301 (Fig. 8), of which tube 300 is responsive to all positive voltage pulses received from the transmitter. The tube 301 is controlled by the tube 300 and is used to change the phase of a series of voltage pulses produced in the tube 300 during the operation, to amplify them and to deliver the amplified pulses to: a common pulse conductor in the receiving device.

The tube 300 remains due to the bias of its control grid 302 normally not ;, will be high every; time, when a positive voltage pulse on, that the front grille is released, made conductive.

The voltage supply circuit for the cathode 303 of the tube 3oo begins at pole 304, which is supplied with a positive voltage of 150 V, and continues via Leiber 305, points 3o6 and 3o7, the adjustable io ooo-O'hm resistor @ d @ 3o8, 5ooo-ohm Wi: clerstan: d 3o9, point 310 as well as via the iooo-ohm resistor 3-11 and the parallel i-microfara-d conidenizer 3! I2 to earth. The cathode 3o3 is connected to point 31o and can receive a voltage of 3 to 25 V , depending on the setting of the resistor 308. The screen grid 3i3 also draws its voltage from pole 304, namely via a circuit which corresponds to the one that leads to point 307 and via conductor 314, 100,000 ohms Wi, which rstand 315, points 3 "16 and 3i7 and 25 ooo-O'hm-Wi. & rstand 318. The screen grid 3i3 is connected to this circuit at point 317 and receives a voltage of 43 V. , Point 32o and i-microfarad capacitor 321 to earth, which absorbs the shock resulting from a sudden voltage application or change in the circuit.

The control grid 302 is connected to a circuit which, starting from signal input po133o, is grounded via point 331, 25o; -micro-microfarad capacitor 332, 10000 ohms Wi, de, rstand 333, point 334 and conductor 323. A voltage take-off member 335 works with; resistor 333 and thereby enables grid 302 to be connected to this circuit.

The control grid 302 is normally under tension and prevents conduction in the tube 300 until the positive pulse is delivered to the signal input port and causes a voltage increase in the grid so that the tube becomes conductive.

The anode 336 of the tube 30o provides a normal positive voltage of 150 volts which is supplied via a circuit running from pole 304 via conductor 305, point 337, 15,000 ohm resistor 338, conductor 339 and point 340. As soon as the tube 300 becomes conductive, the voltage of the anode 336 drops as a result of this; Resistor 338. This voltage drop is transmitted to the control grid 341 of the tube 301 for the purpose of controlling the conduction in this tube.

The voltage of the K @ athod @ e 303 and the effect of the input signal pulses on the support frame 3o2 can be regulated by the adjustable resistor 3o8 or by the voltage pick-up element 335, which enables the tube 300; to respond correctly to the positive pulses delivered to the signal input terminal with both large and small amplitudes.

The phase changer and amplifier tube 301 has a: bias from zero and is therefore normally conductive. The cathode 342 of this tube is connected directly to the earth. The screen grid 343 of this tube becomes a positive A voltage of io5 V is supplied via a circuit that starts at pole 344 (dem a positive voltage of io5 V is supplied) one.:tzt and via conductor 345, Point 346 and ladder 347 runs.

The circuit from which the anode 348 draws its voltage begins at P-01 304 and runs via conductor 305, point 349, conductor 350, 500 ohm resistor 351, point 352 and 500 ohm resistor 353 to the anode 348, since the tube normally conducts, the voltage of its anode 348 is closer to 50 volts due to the resistors 35, 1 and 353 in the anode circuit. However, as soon as the conductivity of the tube is reduced by the control grid 341, this voltage rises towards i5o V.

The control grid 341 is normally under voltage to earth because it is earthed via, -, r point 354 and 10,000 ohm resistor 355. The point. 354 in -this St.romkreis is. Electrostatically coupled to the point 340 belonging to the anode circuit of the tube 300 via a 2oo-Milkro-Mikr: ofarad capacitor 356. This connection enables the negative voltage pulses produced by the conductive state of the tube 300 to be fed to the control grid 341. and decrease the conduction in tube 301.

A voltage take-off element 357 cooperates with the resistor 353 in the anode voltage supply circuit belonging to the tube 301 and enables the voltage increase resulting from the voltage increase in the anode 347 to be transmitted to the common pulse body 36o (FIG. 6) in the receiving device will. The connection leads from the Stiromabn, ahmegli, od 357 to pole 358, which is connected to learning POI 359 (Fig. 6). The common impulse conductor 360 is in turn connected to the pole 359.

It follows that this part is the means of distinguishing between impulses responds with both small and large amplitudes and every time a Impulse with a small or a pulse with a large amplitude at Edlen Signalingab01 33o is delivered, transmits a pulse on the common pulse conductor 36o.

The other part of the distinguishing means also contains two vacuum tubes 366 and 367 and is similar to the part described above. The tube 366 responds only to pulses with a large amplitude or identification pulses and controls the phase change and phase amplifier tube 367 so that each time a pulse is received with a large amplitude, a pulse is transmitted to a pulse conductor assigned to a training control device will. The tube 366 does not normally conduct, but is made conductive whenever a pulse with a large ampli.tu, d # z is output on: dien: input pole. The braking gate 370 is similar to the previously explained voltage supply circuits for the tube 300 and supplies these elements with positive voltages of 150 and 43 V or with earth voltage.

The Kat'hod! E 3711 b - draws positive voltage from pole 304, via a circuit that is connected via conductor 3o5, point 3o6, conductor 37z, i5 ooo-Ohin resistance: nd 373, adjustable io ooo-O ' hm resistance 374 "5ooo-Oh'm-Wi, derstan, d 375, point 376 and 5ooo-ohm resistor 377 as well as: the parallel .i-microfarad capacitor 378 is grounded. The cathode 371 is on at point 376 in connection with this circuit and receives a positive voltage, the value of which is between 2 1 and 30 V depending on the setting of the resistor 374.

The control grid 379 is connected to a circuit "which, starting from the Signaleingabepol 330 via point 331, 25o micro-microfarad capacitor 380, io, ooo-ohm resistor 38i point 382 and conductor 383 grounded the St-Iuergitter 379..: is connected to this circuit via: the 7 5 ooo @ -O'hm resistance 384 and the voltage take-off element 385 and is normally under earth voltage.

The voltage of the cathode 371 and: the influence of the input signals on the control grid 379 can be regulated by adjusting the resistor 374 or the voltage pick-up element 385 so that the tube is prevented from being influenced by pulses with a small amplitude and only making the tube 366 conductive is possible through the pulses with a large amplitude.

As often as the tube; 366 is made conductive, the voltage of its anode 368 falls as a result of the anode voltage supply circuit, which has 15,000 ohm resistors 386. One of point 387 outputs this anodeus.spannungsversorun@gsstromkreises and via a 2oo-Mikro-Microfara @ d-Kon @ densator 388 in addition point 389, with which the control grid 390 of the tube 367 is connected, enables a leading connection because: the anode voltage drop controls the conduction in the tube 367.

The phase change and gain tube 367 of this portion of the distinguishing means has a zero bias and is normally conductive. The circuits that supply voltage t to the control grid 391, the cathode 391, the anode 392 and the screen grid 393 are the same as those previously explained for the corresponding elements of the tube 301. D: a tube 367 normally conducts, its anode is due to the resistances in the anode circuit normally under a voltage of approximately 50 V. Each time a pulse with a large amplitude is transmitted to the receiving device, the tube 366 becomes conductive and! i gives fish over the two: cle: n pointsi. 387 and 389 apply a negative pulse to grid 390 , thereby causing grid 39o of tube 367 to assume a negative voltage and. the conduction in this tube is decreased so that the voltage of the anode 392 increases to 150 V '. Eigin Spannu.ngsa, bna: hrneglied 394 works together with the 5000 obm resistor 395 located in the anode current circuit and enables the voltage rise resulting in this circuit when the conductor is retreated in this circuit to be avoided as a positive voltage pulse P01397 (Fig. 7) connected to: I # receiving member 394 is also connected to P01397 (Fig. 7), which is connected to an impulse conductor for the instruction control device, to which positive voltage impulses are also given .

This part: of the distinction: by means of every time leg Identification pulse is received, a pulse for the purpose of controlling the Einweisungsvorrichtunä to send.

The differentiating means therefore, as a whole, enables the amplitudes of the input pulses can be used to perform various controls. for the receptionist to be provided.

Conversion and symbol storage means The receiving device of the: shown From, for example: pieles contains five banks of conversion: ungsunid symbol storage means! N; however, the number of banks can be increased or decreased as required. The five banks are shown in FIGS. 11I, IV and V, which indicate the order in which the banks work and which symbols they save. Since the circuits provided for the individual banks are similar>, from the description of a bank, is the operation of all banks to see.

The Fig.; I, which: the first pulse triggering in a single representation a symbol transforming and: this symbol storing bank shows, shows, that a bank of conversion and symbol storage means several gas electron tubes that are of the same type as those used in the sending device .. Sub The bank’s gas-electric entrance is in front of the reception igniting, previously set tube »presetting«, a key pulse tube »Know, a distance symbol tube »distance« and one tube each for, dli: - letters A to Z, although in this figure the letters B to W for the purpose of simplifying the representation have been left out of the bank. The circuits belonging to the letters B to W. same as those of andwr: n tubes, and a clear picture of the working of the bank results from the circuits shown.

The bank's "Vorei.n: stell" tube is opened before reception begins ignited in the receiving device and is used to frank the bank of all beforehand saved Symbols and to ensure that daisi caused a trigger by the impulses successive ignition of the tubes in a banik always with the same tube begins, which in the embodiment is the Kenn.inl: pulse tube °. , The Ken pulse tube is not a symbolic tube. She is therefore turned into the bank, switched on, because a. Identifying impulse forms part of every trigger and is the indifference the identification pulse together with several pulses with a small amplitude on the banks transmits and because it is therefore necessary to switch this tube into the bank in such a way that let .the symbolic tubes at the end of each impulse release the corresponding- Character displays, the tubes of the bench ssi.nd for the purpose of successive ignition connected with each other, namely first the presetting tube, then the Kenni pulse tube, the tubes for the symbol and the letters A to Z. It follows that the tubes compared to. the order in which the symbol conversion control tubes in the sending device ignite, arranged in reverse order. The identification pulse tube and the Symbol storage tubes are opened in response to the common pulse conductor 36o from pulses transmitted to a conductor for ignition pulses, ignited one after the other. As soon as the tube in the row is ignited, the previously conducting side is extinguished Tube. The tube to be ignited last in a bank remains conductive and has d, ie Task for storing a single representation of the number of pulses which are present in a release, the symbol shown at the end a transfer process in the various banks of conductive tubes be monitored in such a way that they are in the various banks; sp @ eic'hert: n symbols show immediately; they can also be used to control a remote display or Registrienverkes and for direct transfer: the symbols to other storage means be used:..

The Stiromkkreis that connect the tubes of a bank with each other and to "apply" voltage to them are as follows: The cathodes of the tubes. d; kser Bank (Fig. 5) becomes negative by means of parallel circuits (one for each tube) Voltage supplied. They run from a negative voltage conductor 4oo, the at pole 4oi negative voltage of i5o V pulls; leads, becomes, to earth. The circuit for the tube Y (which can be dIene-n as a pattern) runs from point 402 of this supply conductor 400 from over the i5o ooo-O'hm-Wid @ erstand 403, point 4o4, ioo ooo.-Ohln-Wi, dierstand 405, points 4o6, 407 and 408 and over serving with the 25oo-O'hm-Wi, derstanid 4io and , the series-connected .ooi microfarad capacitor 41i in parallel with 15,000 o'clock 409 to earth. The cathode 412: the tube Y is at point 407 with this circuit connected and, when the tube is not conducting, has a negative voltage of approximately 8 V. If the tube conducts, then the voltage of the cathode 412 drops to about 5o -V positive.

The 1i; The last tube Z has a power supply circuit that corresponds to the other circuits. This circuit runs from point 415, this voltage supply line, rs 400 via the 250 ooo-ohm-Wi, derstand! 416, points 417 and 418 and the 15,000-ohm resistor 419 to earth. Resistor 419 is connected in parallel to 25000-O'hm-W, i @ derstand 420, which is connected in series with an .ooi microfarad capacitor 42i.

The cathode voltage supply: power circuits for all tubes with the exception of the tube Z are used the control grids of the in the order apply negative bias to the next tubes. The connection runs from that Cathode circuit of a tube from to the control grid, he the one in the R "iihell-folige next tube. These connections enable successive ignition of the tubes, in which the voltage rise of the cathode of a tube for preparing which is first used to make the tube effective, so the next tube ignited: and can be made conductive when the next impulse hits the igniting one Pulse conductor 423 is delivered. The grid of the tube Z is z. B. over 50,000 ohm Wi, dL rstanid 426, point 427, 500 000-011,111-resistor 428, point 429 and conductor 430 connected to point 4o4 of the cathode voltage supply circuit of tube Y, from which it draws normal negative bias of 65 V, if tube Y does not directs. If the tube Y becomes conductive and its cathode voltage rises, this is the case As a result, the tension of the tube Z almost to its critical point is reduced, so there, ß this tube on the next given on the bank Ignition pulse, can respond .. A 25o micro-Mi'kro, farad capacitor 43r connects the point 429 of the grid circuit with point 4o6 of the Katho, denstrom'kreis, in order to apply the Spallnun gsanstieges. on the grid of the tube Z to b: Schleu, ni "-e-n, when the tube Y is conductive; will.

The control grid of the "Voreinst, ell" -Rö'hrie (the one in the beer row the first tube eats) is not connected to any cathode power supply circuit, but refers to a negative bias voltage of 64 V from a similar current circuit, di-r from point 432 of this conductor 40o out via the 120,000 ohm resistor: 433, the Points 434 and 435 and the 90,000-o'-o'-o'-o'-o'-o'clock o'clock position to earth. With this Circuit is connected to the control grid at point 435.

The grids of the tubes, starting from. of the Kenn.-Impulsrö'hre up to the tube Z, are electrostatically coupled with the Zülldim @ piulisleit "r, namely by means of io-Mikro-Mikro @ faraid-Kondiensat-onen, e.g. Kondiens @ ator 438, .durch which the point 427 in the grid circuit of the tube Z is connected to the ignition pulse conductor 423. The ignition pulse conductor 423 emanates from pole 424, which is connected to pole 425 (FIG. 6) of the relay, i.e. the pulses from the common pulse conductor 360 from transmitting on this bank. the normal negative bias @drz r grid!, these tubes normally prevents the ignition pulses cause Zündren of the tubes. However dignity through a tube, passing another tube core sequence vorbeneit-'t , the negative bias of the grid of the prepared tube has been reduced sufficiently so that the ignition pulse is able to ignite the tube and make it alive.

The anodes in this bank are connected to a common anode supply conductor 439, which in turn is connected to pole 441 via the 2oo ohm resistor, -4o, to which a positive voltage of 75 V is fed.

If none of the tubes conducts .this bank, the voltage is .der Anodes 75 V positive. But is hitting a tube of a bank; so becomes the anode voltage As a result of the drop in resistor 440 reduced to approximately 65 volts.

The moment one of the bank's tubes ignites, holds its cathode has a negative voltage of about 8 V, while the capacitor, z. B. 4111 in their cathode circuit, charges. As a result of the Wvd! @ Rs @ tarndts im Anode voltage, voltage supply circuits of this bank and the internal voltage wall of the tube, the anode voltage drops to about 15 V of the cathode voltage. This causes a corresponding voltage drop in the common anode voltage supply: conductor 439 Idie @ ser bank, used to erase a previously conductive tube of the bank will. This is possible because the voltage of all the anodes of the tubes & r bank together with the voltage of the anode voltage supply conductor 439 and thereby the voltage the anode of a previously conductive tube below the value of its cathode voltage, which rises as a result of the conduction tea of the tube, falls, so that the tube becomes conductive, the previously conducting tube stops conducting and its control grid regains control. records.

The presetting tube is ignited by a circuit, Ger closed by any suitable means prior to receipt of the information can. For the sake of simplicity, the circuit in the circuit diagram by a Key 442 closed. The circuit runs from pole. q.43 from which a positive Voltage of z 50 V is supplied! Via @d: n conductor 444, key 442, the conductor q, 45 and 167 o'äo-ohni-resistance q.46 to point 434 in the circuit of the control grid 437. If this circuit is closed by means of key 442, it leads to the grid positive voltage and causes its voltage to become more positive than that of the Cathode, which ignites the tube and makes it 'conductive'.

The bank's operation is as follows: The presetting tube is fired by closing button 442 prior to receipt of the indications. By igniting of this tube, every tube that was previously conductive in the bank is deleted and the signaling pulse tube prepared so that the first pulse fed to the ignition pulse conductor, 423 of the bank, the triggering ignites the identification tube and makes it conductive. By igniting of the identification pulse tube, the preset tube is cleared and by passing the Identification pulse tube prepared the distance symbol tube. The subsequent impulses of the Triggering ignite depending on: depending on the number of pulses of triggering the tubes »distance«, A, B, C etc. After the last pulse of the trip ignites a tube, stays .this tube conductive; thereby saves the symbol, displays it and thus represents immediately represents the symbol represented by the trip. This conductive tube is the only one in the bank to have a positive cathode voltage. From the cathodes the symbol display tubes outgoing lines, z. B. 450, can by a suitable Means to be scanned for this state and a closed display or Registration mechanism or direct transfer of the setting of the bank control another storage medium.

Dk! other banks for converting and storing the. second, third, fourth, and fifth symbols, work exactly like this bank. These benches will be by the keys 451, 452, 453 and 454 (Figs. 2, 3, 4 and 5) prepared. For the purpose of. Simplification of the representation of the Circuits are the ignition of the 'presetting tubes causing circuits in the Drawing closed by individual keys. It: it goes without saying, however, that all these circuits through contacts of a single preset relay or through any one other, similar device could be closed.

The anodes of the tubes of each bank are connected to each other and over one Resistance connected to a separate voltage source, so that the mutual Extinguishing effect is caused by the fact that the tubes are limited to the tubes of a bank. At the end of a reception process, the last one remains effective in each bank tube to be made conductive until the banks are zeroed for a new receive operation will.

Those assigned to banks II, III, IV and V (Figs. 2, 3, 4 and 5) Ignition filters 455, 456, 457 and 458 are with the poles 45g, 46 ', 461 and 462 and these again with the poles 463, 464, 465 and 466 (Fig. 6) of the relays of the various Benches connected.

As soon as the relays assigned to the individual banks: for the purpose of. transmission of pulses on the ignition conductor 'are made effective one after the other, the The tubes in the individual banks were ignited in succession. At the end of the reception process The impulse releases have been converted into individual symbols and in the individual; Benches those. Conducting tubes, you can feel them through them correspond to the symbols entered on the transmitter. Instruction, means in the receiving device . Instructional means are provided, which include a relay and a! Initiation control device have and the successive Pulse releases in the One-way different banks of environmental and symbol storage media.

For the optional transmission of impulses from the common conductor 36o to the ignition impulse conductors of the individual conversion and symbol banks several relays (one for each bank of conversion, - and: symbol @ lspeichermiit4tlni) used. The individual relays speak - usually to the impulses in common. Impulse conductor 36o not on, but can: but under the control of the instruction control device prepared one after the other or for such! Impulses are made receptive so that different relays respond to successive pulse releases and will cause, i.e. the successive pulse releases. the setting the symbols in the different banks.

The instruction controller (Fig. 7) instructs for each relay open a control tube. These control tubes are gas electron tubes of the same type, as used in the transmitter! will:; they are connected and work, every time an identification pulse is received, gradually and in, sequential order. As soon as a control tube ignites and becomes conductive, it extinguishes any previously conductive Control tube of the device, also prepares .Ihr associated relay for transmission of pulses from the pulse conductor 36o as well as the next: control tube in sequence so that it ignites and becomes conductive when the next identification pulse is received.

If the identification impulses a triggering your impulses with smaller Amplitude must be followed by the control tube for the first bank before receiving the first Trigger to be ignited. If the first control tube ignites, each one before it becomes conductive Control tube that is still from; a previous operation of the device like to do, cleared and ensured that the first impulse trigger the serious Conversion and. Symbolspeichermi.ttelbank is supplied.

The instruction control device is shown in Fig. 7, in which the Control tubes, with the reference numerals I, 1I, 11I, IV and V are provided, whereby displayed: oll, with which: releases they work. Because the circuits for the individual control tubes. are similar, only one circuit is used for the purpose Explanation of the operation of the device described.

The cathode 47o of the control tubes I draws its voltage from a circuit "which has two branches, namely one which also supplies the relay, negative voltage assigned to the control tube I, and one which also supplies the control tube 47 i with a negative bias voltage The first branch runs from the negative voltage supply line 472, which receives a negative voltage of 150 V at pole 473, via point 474, 390,000 ohm resistor 475, point 476 and 150,000 ohm resistor 477 to the points 47 $, 479 and 480, while the other branch from point 482 of the voltage supply conductor, 472 leads out via the 300,000 ohm resistor and 483, point 484 and zoo ooo ohm resistance 485 to points 479 and 480. From the points 479 and 480 of the two branches extend through the parallel with the 25oo-ohm resistor 487 and the oo2 microfarad Kondernsator 488 connected in series 1 5 ooo ohm resistor 486 lashing earth ,. the cathode. 470 is energized at point 479 in that circuit and receives a negative voltage of approximately 9 volts each time the tube does not conduct. When the tube conducts, the electron discharge enables one to be supplied to the anode; Voltage is transferred to the cathode and d, ate thereby the cathode voltage rises to about 5o V positive.

A circuit runs from point 476 of the aforementioned one junction from via Leiber 489, point 490, conductor 49i and pole 492, the one with pole 493 (Fig. 6) and the relay for the first conversion and symbol storage center bank supplies a negative voltage of about 50 V. This circuit also enables as a result the conductive state of the control tube, that the increase in voltage of the cathode 47o, used to step down the negative voltage or bypassing the relay will.

Between points, 478 and 490 there is a 5o-micro, -microfarad condensato, r 494 switched on so that the resulting voltage change is applied quickly, when the relay is prepared as a result of the increase in voltage in the cathode.

From point 484 of the second junction of this cathode spa, nnungsversorgungslstromkreises a circuit runs through 500,000 ohm resistor 495, point 496 and 50,000 ohm resistor 497 to grid 471 of control tube II and this grid normal negative voltage of about 65 V leads to. This circuit enables tube II to be primed by reducing this negative voltage to 30 volts by increasing the voltage of cathode 470 when tube I is conducting.

The grid 471 of the tube, II is via point 496 and, io-micro-microfarad capacitor 5oi with an impulse lead 5o2 and this in turn connected to pole 397, to the every time an identification pulse is received by the discriminating means po-s: itive impulse. is transmitted. These positive, impulses are not in there Able to ignite one of the tubes: unless the tube to be ignited is prepared been.

Tube I is the first tube in the sequence and its grid 503 therefore cannot get its negative voltage from the cathode power supply circuit, a previous tube. A circuit which runs from point 5o4 in conductor 472 via 150,000 ohm resistor 5o5, point 5o6 and foo, oooohm resistor 507 to earth, supplies grid 503 via point 5o6 and 500,000 ohm resistor 5o8 with a negative voltage of 60 V. Since the instruction site glows in response to the identification impulses that follow the impulses with a small amplitude, the instruction control tube I must before receiving the first tripping be ignited by eiirrer other source, so that the relay is prepared for icheirbank düie first conversion and Symbolspe and responsive to all pulses of the first. off solution. This is accomplished, for. example, by so-called by a Voreiwistelltaste ( Fig. 7) A circuit is closed, which is closed from pole 5io, to which a positive voltage of iioV is supplied, via the suction button and the 167,000 ohm resistor 511 to point 5o6 of the circuit of the grid, 503 This is thus fed to the grid 503 e poisiiltive voltage reduces the negative grid voltage, which ignites the tube and becomes conductive. This activates the relay for the first conversion and symbol storage center and prepares the initiation control tube to fire in response to the identification pulse of the first trip. The circuit closed by the test facility suction can also be closed by means of a pre-setting relay together with the presetting circuits of the conversion and symbol memory banks (as explained above).

The anode 515 of the tube, I draws its voltage from a circuit which is fed from pole 516, which is supplied with a positive voltage of 75 V, via the 25o-ohm resistor 517, point 518, 2ooo-ohm resistor 51g and conductor 52o, with which the anode 51.-5 is connected, runs. The anodes of the other tubes are also connected to conductor 520 , and if so. ke: Before the tubes conduct, the voltage of the anodes is 75 V. However, if a tube conducts, this voltage is reduced to 65 V as a result of the resistors 517 and 51g. The point 51 8 dieises @ circuit, cs, is grounded via an 8 M; microfarad capacitor in order to absorb the vibrations occurring in this circuit in the event of a sudden application or change of voltage. The common resistance in the anode voltage supply circuit enables the ignition of a tube to the instruction control device to extinguish any previously operated tube of this device, as already explained above.

It follows that the control tubes in the instruction control device, as soon as. diiei = follow one another. the releases are received one after the other are ignited and the relays of the individual banks one after the other in succession prepare.

The in F, ig. 6, relails, consist of a pair of vacuum tubes for every conversion and symbol storage bank. These relays were given the reference numbers I, 1I, III, IV and V to indicate which bank of conversion and symbol storage means they are assigned and the order in which they work, to be marked. It just becomes that! at I (Fig. 6) shown relay described, there the! The relays of the other banks are identical and their mode of operation is derived from the Description of a relay is to be understood clearly.

The tubes: 52s and 526, which form the means for transmitting pulses from the common pulse conductor 36o to the first bank of conversion and symbol storage tubes, are normally not able to transmit the positive pulses from the common pulse conductor 3; 6o, because the Stle! Outer grid 527 of the tube .5-5 normally negative bias voltage is supplied, which the positive; Impulse does not overcome anything. The tube 525 is prepared by reducing the negative bias of its grid 527. In this state, the tube vornag- on the positive pulse in the common Spannungsimpulise: @ 36o to address conductors and to cause d: 1 - pulses to the Zündimpulsleiiter 423 deir first UMWA ndlungs-, and symbol storage tube bank are transferred.

The cathode 528 of tube 525 is grounded through point 529. The anode 53a of this tube 525 carries a positive voltage of: i So V =, over one; Circuit: is that from pole 531, which is supplied with a positive voltage of 15o V, via the voltage supply conductor 5.32, point 53.3, 500 ohm resistor 534, point 535. 5oo ohm resistance. 536 and point; 537 runs to anode 530. The screen grid 538 receives as it rruiit the point 535 of the aforementioned anode circuit. connected, a normal positive voltage of: 150 V.

The control grid 527 is connected to the terminal 493 via the point 539 and 10,000 ohm resistor 540, which, as previously explained, draws a negative voltage of about 50 V from a branch of the cathode voltage supply, the induction control tube . The control panel 527 is electrically connected from point 539 to the common pulse conductor 36o via an ioo-Mikro, -iMikrofarad-Kondiens.atOr 541. The voltage in gate 527 is normally sufficiently negative that tube S25 does not respond to the positive voltage impulses in pulse lead 36o. However, if the control tube 1 is directed by the instruction control device, the increase in voltage in its cathode 47o reduces the negative voltage of the grid 527 or prepares the tube 525 so that it is able to respond to the To address impulses in the line 36o and: to conduct each time an impulse occurs in this conductor.

Every time tube 525 becomes conductive, its voltage drops Anode Sao as a result of those present in its anode power supply circuit Resistors 534 and 536. This voltage drop is via an electrostatic Connection from point 537 via the i oo-M i @ kro-: VLikrofarad-Kon: capacitor 542 and point 556 as, a negative voltage pulse. on the. control grid of the phase change and amplifier tube 526.

Tube 526 is a normally leaning tube with a bias from zero. The cathode 544 this tube is directly earthed and your screen grid 545 over the 500 ohm W; iderstand @ 546, point 547 and conductor 548 is connected to pole 549, which is connected to a positive voltage of 105 V. The control grid 555 of the tube: 526 is from point 556 via the 10000 ohm resistor 557 grounded and further to the anode 53o of the tube 525, as previously described, eIektirosta.biiseh connected.

The anode 558 of phase change and amplification @ rrölire '526 is over the 5ooo-Ohm-Wid. °, rstand 559 with the point 56o of the voltage: supply conductor 532 and this in turn with pole 531, to which a positive voltage of i 50 V is supplied wied ', connected. Since, this tube, normally conducts, the anode normally has 558 One voltage of 50 V. However, whenever a negative voltage pulse is sent to the control grid 555 is delivered; is d'as Leiiiben: in the tube: decreased, and the tension of the Anode be: 'gt. A voltage tapping element 561 works with the resistance: 559 together and. made possible by the fact that this voltage rise as. a positive one Voltage pulse used on the Z.ünd: pulse conductor 423 of the first conversion and symbol storage ini: ttelbank is transferred and thereby the tubes in that bank be ignited. Düe, connection between the Spannuingsabgr-iffgl; iied 561 and the ignition pulse conductor runs from the voltage tap element! 561 over the ladder 562 To pole 425, which, as mentioned before, Miit pole 424 (Fig. I), with which in turn the Züudtiimpu @ lsleiter 423 is connected, stands in connection.

The other Reilais transmit, if they are effective, impulses from: the common pulse conductor 36o to the ignition pulse conductors of their respective banks.

The poles 563, 564, 565 and '566 (Fig. 7) connected to poles 567, 568, 569 and 570 (Fig. 6) supply the' single relay 'with negative voltage and possibly the control unit Ears: n 1I, 11I, IV and V of the instruction control: device to prepare the relay one after the other.

As already explained before, see the pole 463 (Fig. 6) mii, b the Poil 45.8 (Fig. 2), with which in turn the ignition pulse conductor 455 of the second bank connected, connected and allows you to relay as many pulses to this relay Head to transfer, as in the second "on your Leii, ter 36o given symbolic presentation Impulsiaus @ löis, ung are present.

Similarly, poles 464, 465 and 466 (Filg. 6) are connected to the Poland 46o, 4.61 and! 462 (Fig. 3, 4 or 5) connected so that the third, fourth and fifth pulse triggering on the ignition conductors d.56, 457 and 458 of their respective Umwa.udlungs- and @ symbol memory, mean banks can be transferred.

In this way, the received: one after the other: consecutive: ndeni impulse releases by the fact that the instruction material automatically leads to the correct transformation: and symbol storage center banks, which they can be used in individual representations of the different symbols can be converted and saved.

The Ehuweisiungsmitfbel could ebe @ usog'ut be a follow-up switch, which can be activated in stages for the purpose of transferring the impulses to the various banks is..

Working method I The receiving device is used to receive information prepared; in that the Voineiinsiteilli tube j @ ade: r conversion and symbol storage tube bank and: the first tube of the initiation control device ignited and conductive. is made.

The ignition of the pre-position tube of each conversion and symbol storage tube bank emptied from: dia: n banks over the mutual extinguishing connections each before saved symbol, and! the ignition of the first tube of the egg: nweis.un: gssteu, cir device also causes every other tube of the device to extinguish and to ensure that wiwill that the first introduction always on d:; a first Umwanddilungs and. Symbol indicator tube slim briefed. will.

The le: itendi-, Vorein.ste: llr'öhre of each bank rushes the no-pulse-tube in her tube bank voir, so that it responds to signal, impulsie :. Dici presetting tube then remains conductive until the signal symbol pulses are transmitted to that bank and ignite the identification pulse tube of the same. and make it a leader.

The leading E: in @ w @ eiis.ungsste: u "eirrährei makes, the relay of the first bank effective and frees the. A: w.e; i, sungsstie, uerröhre the second Bank in front of you, so that you can respond to the, first: received pulse with a large Amplitude ignites.

The receiving device is now ready to receive signals. As soon as the first impulse trigger is received, the impulses will be klccin. @r 'and with a large amplitude passed on to your common impulse leader and. from this f to the first conversion and symbol storage tube bank überbragein. These tubes will. received in response to this. Impulses one after the other effective, the last effective tube being the one represented by the trip Symbol corresponding icon representing tube eats. The identification pulse (or pulse with large amplitude: e), which is the last pulse in; the triggering is, causes, likewise about d'asi differentiators that an impulse on the instruction control tubes is transmitted. The instruction control tube for the branched bank was through the Guide in the first; Prepare for the ignition, and when the pulse is in Response of the triggering signal to these tubes w, ifrd, wixd the initiation tube of the two: tein bank ignited and made conductive :.

If the instruction control tube of the second bank is ignited, it will be effected they that the instruction control tube. of the first bank is deleted and thereby there First bank relay normal inoperative state again records; furthermore, he prepares the instruction control tube for the third bank, so that this becomes effective in response to the next identification pulse, and does that Relay of the second conversion and symbol storage tube is effective.

The next pulse trigger causes the conversion and symbol storage tubes of the second bank are triggered, so that they can be triggered by the second pulse Determine and save the symbol shown ;. As mentioned earlier, causes the last impulse (identification impulse) of this release that the next instruction control tube will be heard ignited and, the next Umwaud '.- lungs and symbol storage bank for the admission d-the next impulse release is being prepared. In this way: become consecutive Pulse releases on the various symbol storage tube banks for the purpose of Strns the setting of the various symbols located therein or transferred.

After the sequence of trips has been received, the conducting, the symbols of the various banks of tubes for stoneing a display means, a, registry means or to stone the immediate, transmission of the symbols can be used on other storage media (for later use).

Claims (4)

PATENT CLAIMS: i. Electronic device for receiving and storing of symbols, each of which is caused by a release of [essentially similar, electrical impulses followed by a different core impulse is, with several banks of electron tubes to convert the pulse triggers into direct representations of the symbols, characterized in that each bank of electron tubes (e.g. A bssi Z, Fig. i) with normal, or otherwise ineffective relays (525, 526, Fig. 6) and a common input circuit via which the received Pulses are fed to a conductor (36o) that connects the relay and. one only on identification impulses responsive control device (366, 3.6T, I bis, V, Fig. 7) is common, where the control device, when actuated by the identification pulses, the relays makes effective one after the other. 2. Electronic. Apparatus according to claim i, characterized in that each relay comprises an electron tube (e.g. 525) normally biased to prevent conduction, the control device (366, 367, Fig. 8; I to. V, Fig. 7 ) the advance notice of the; Relays, electron tubes one after the other .in; Replying to successive identification pulses takes away. 3. Electronic Device according to claim i or 2, characterized in that the control device multiple electronic devices (I to 'V, Fig. 7) with a common input lead (5o2): which are so connected to one another in series, d: ate them in response successive identification pulses emitted via the input line one after the other be effective. 4. Electronic device according to claim 3, marked by a distinguishing unit (300, 301; 366, 367, Fig. 8) on which input pulses le are emitted and all of the pulses via a: first output circuits (357, 358) on each, the relay, as well as the different impulses over one. second output circuit (394, 396) to the [electronic devices (I to V, Fig. 7) of the control device.