US1904618A - Telegraph system - Google Patents

Telegraph system Download PDF

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Publication number
US1904618A
US1904618A US582696A US58269631A US1904618A US 1904618 A US1904618 A US 1904618A US 582696 A US582696 A US 582696A US 58269631 A US58269631 A US 58269631A US 1904618 A US1904618 A US 1904618A
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Prior art keywords
circuit
station
relay
receiving
signals
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Expired - Lifetime
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US582696A
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English (en)
Inventor
Everett T Burton
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AT&T Corp
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Bell Telephone Laboratories Inc
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Priority to US582696A priority Critical patent/US1904618A/en
Priority to GB29969/32A priority patent/GB409026A/en
Priority to DEE43480D priority patent/DE599232C/de
Application granted granted Critical
Publication of US1904618A publication Critical patent/US1904618A/en
Anticipated expiration legal-status Critical
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/14Two-way operation using the same type of signal, i.e. duplex
    • H04L5/18Automatic changing of the traffic direction
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/14Two-way operation using the same type of signal, i.e. duplex
    • H04L5/16Half-duplex systems; Simplex/duplex switching; Transmission of break signals non-automatically inverting the direction of transmission

Definitions

  • This invention relates to telegraph systems and more particularly to the type of telegraph system known as single Morse circuit in which signals are transmitted over the line in only one direction at one time and in which the direction of transmission may be reversed, whenever desired, by means of aspecial reversing condition or signal impressed upon the line.
  • the invention though not limited thereto, is especially adapted for use in telegraph systems operating over lines, such as long submarine cables, having a large attenuation factor; an example of such a. system, to which the invention is applicable, is disclosed in Patent No. 1,632,27 5, issued on June 14, 1927, to A. M. Curtis.
  • an object of the invention is to avoid the use of mechanical timing devices responsive to the reversing signal for the control of the reversing operations.
  • a further object of the invention is the prevention of interference with the reversing signal by variations in earth potentials at the cable ends.
  • Another object is to insure'that the reversing equipment responds but once to each reversing signal, thereby preventing the possibility of two stations becoming opposed to each other.
  • Another object is the reduction of disturbing effects and of delays at the time of reversal of the system due to charges in the cable and to earth currents.
  • Another object is the protection against overloading of the receiving equipment during reversal operations.
  • the invention in its preferred form provides for a system in which there is connected to the line circuit at each station, a leak circuit arranged to differentiate between two line conditions, one characterized by cond tinued signaling and the other by a prolonged absence of signals.
  • This leak circuit includes an electron discharge device or thermionic tube, the input circuit of which is subjected to potential variations from the line.
  • the leak circuit also includes a network capable of condition and storing potentials applied at the frequencies of the ordinary signals, thereby maintaining the electron discharge device in'unoperated or paralyzed condition; however, "during a prolonged steady condition o'nthe line, the network after a predetermined interval loses its potential, 'thereby vitalizing the device, which then operates to cause the local reversing switch, associated with its output circuit, i
  • the coupling of the leak circuit'to the linecircuit is such as to prevent the entrance of very low frequency lmpulses into the input circuit of the electron discharge device, thereby preventing that the slowly varying earth currents interfere during-the absence 'ofsignals with the operation ofthe' electron discharge device and thus insuringdefinite control by the transmitting station of the switching of remote stations.
  • the switching control is thus independent of the line potential and depends only upon the frequency of the line current.
  • the special reversing signal in accordance with the invention' is transmitted from that terminal station which at the'time is sending and constitutes an'interruption ofgtheoutgoing signals and a temporary impression'of a steady potential, preferablya ground or zero potential, on the cable; forthispu-rpose; a manual or automatic switch is. preferably provided at each terminal station for conditioning the local. electron discharge device to operate its associated reversing'switch from its sending to its receiving position.- The v transmitting circuit of this operation being disconnected from the line and the grounded receiving circuit being substituted therefor, the electron discharge devices at the-distant terminal station and at any. intermediate station respond to the consequent cessation of signals and operate their associated reversing switches.
  • the reversing switch at a station may, according to the requirements, be arranged to respond to theline conditions either by taking one position forv signaling the other position for no-signaling condition, or by reversing in either direction under no-signal condition and maintaining its new position under signal conditions. In the latter instance it is necessary to prevent false operation of the switch, which, in a preferred arrangementin accordance with the invention, is accomplished by inserting, in the operating circuit for the switch magnet, a blocking network which prevents the magnet from operating more than once in response to a reversing signal.
  • At least part Of the receiving equipment at a repeater station, including the receiving transformer is duplicated and one-set is switched into the line circuit for transmission in one direction and the other set for transmission in the other direction, therebyj permitting each: transformer to-remain in connection with its associated cable, no matter what the direction of transmission may be, so that it will be in condition for immediate use upon being switched into the line circuit.
  • the line circuit may be bridged and grounded temporarily to divert excessive impulses due to the switching operations and thus prevent overloading, particularly of the later stages of the amplifiers as described in the patent to Curtis, referred to above.
  • this pro? tection is controlled from theleak circuit referred to above and its proper timing is attained by suitable networks.
  • Station W may, for example, be located at New York and is connected through a submarinecable C tothe intermediate repeaterstation IR, which may be located at the Azores and in turn is connected through thesubmarine cable C to the terminal station E, which may be located in some European city, such as Rome.
  • the equipment in this system for sending and reception of commercial messages may correspond in all details to the system disclosed in the patent to Curtis 1,632,275, referred to above, and is shown in the drawing in a schematic form, and the equipment for synchronization of the two terminal stations may be similar to that disclosed in Patent 1,670,461 issued on - May 22, 1928, to G. A. Locke or to that disclosed in application Serial No. 354,954 filed on April 13, 1929, by IV. A. Knoop, and issued as Patent No. 1,848,180, on March 8, 1932, according to which disclosures the synchronization is under the control of the terminal station which is transmitting at the moment.
  • the transmitting device T is of any well known typefo-r sending ofthe ordinary signals; with this device'is associated the necessary amplification equipment A for impressing signals of sufiicient strength onto the cable C the signals usually being made up of plus and minus impulses in various combinations.
  • Signals incoming fromthe cable C to station W will be impressed upon the receiving equipment which comprises a shaping network N, amplifiers A and A and the receiving translating device R.
  • Terminal station E may be'identically equipped.
  • incoming signals from either one'of the cables are switched into a receiving amplifier A and then passed through the sending amplifier A and thus will be repeated into the other cable.
  • each station is provided with an electromagnetically operated multiacone tact switching device or gang switch; thus at station W the switchingdevice S comprises an operating magnet 10 having an armature for operation ofthe contact springs 13 and 14 against the return action of spring 11.
  • the switch S comprises the magnet 20 withiits armature for operation of contact springs 23, 24, 25, 26 against the return spring 21; and at station E the switch S comprises the magnet 30 with its armature for operation of contact springs 33 and 34 against the return spring 31.
  • the contact springs of switches S and S are deenergized, the contact springs engage corresponding contacts toward the right to condition the main signaling equipment for reception of signals, at the same time disconnecting the transmitting circuit from the cable; whereas when the magnets are energized their respective contact springs will engage contacts toward the left, thereby connecting the transmitting circuit to the cable and disabling the receiving circuit.
  • the contact springs of the switch S when its magnet 20 is deenergized, will engage contacts toward the right for reception and retransmission of signals from W to E, whereas when the magnet 20 is energized, the contact springs engage contacts toward the left for the reception and retransmission of signals from E to 7.
  • the switch S for transmission from W to E is held operated, whereas the witches S and S are inreleased position.
  • the switch S at station E will be energized, thereby connecting the transmitting equipment to the cable C and disabling the receiving equipment;
  • the switch S at station IE will be energized, thereby connecting the receiving condenser C shaping network N and receiving transformer T between the cable C and the amplifiers A and A which in turn will be connected to the cable G at the same time disabling the receiving condenser C with its associated network N and transformer T and the switch S at the station W will be deenergized, thereby disconnecting the transmitting equipment from the cable C and connectingthe receiving equipment, including transformer T receiving amplifiers A and A and the receiving translating device R, to the cable.
  • the circuit for transmission of messages under these conditions may readily be traced similar to the circuit traced above for transmission from W to E.
  • the input circuit of the tube includes a high resistance 108,the secondary winding of transformer '110 and the condenser 102 with its leak resistance 103, which, when no signals are being received through the transformerllO applies a zero potential to the grid of the tube with respect to the filament;
  • the output circuit of the tube 101 includes the plate battery 1-O5and winding of relay 104. Under the assumed conditions the zero grid potential causes a plate current to flow, sufiicient for the energization of relay 104, which by its front contact applies battery to' a circuit through the winding of magnet 10 of the switch S and the wind ing of shorting relay 120 to ground.
  • the magnet 10 consequently hold sthe switch S operated, therebyconnecting the transmitting equipment to the cable and groundin over contacts 14 the receiving condenser thus disabling the receiving equipment and in turn maintaining a zero potential on the grid of vacuum tube 101.
  • the relay 120 in its operated condition places a grounded short circuit across the input circuit of receiving amplifier A thereby eiiectively preventing excessive impulses, due to switching, from overloading the receiving equipment.
  • the intermediate repeater stationIR there is provided equipment similar to that described for station W and comprising the three electrode vacuum tube detector 201ineluding in its grid circuit the gridcondenser 202 and leak resistance 203, and in its output circuit plate battery 205 and relay 204.
  • the input circuit of the detector is shown connected directly across the output circuit of receiving amplifier A however, this connection may be in the nature of'an inductive coupling similar to the transformer 110 shown at station W.
  • impulses from amplifier A 'are being impressed upon the input circuit of the detector 201 a charge will be maintained on the grid condenser 202 which will apply a negative potential to the grid, therebyreducing the plate 'current'sufliciently to prevent the operation of relay 204.
  • relay 304 deenergized battery is disconnected from magnet 30 of the switch S and from shorting relay 320,.which consequently both remain deenergized.
  • the transmitter T is disconnected from the cable and signals-are received over condenser C. closed contacts 34, shaping network N, transformer T into the receiving equipment A A and R, the short circuit across the input of amplifier Ag being open at the contacts of relay 320.
  • the terminal stations W andE are provided with keys 100 and 306, respectively, connected in the input circuit of the detectors 101 and 301.
  • the key 106 is in the nature of a mechanical timing device, which may be manually operated, as for example, by the winding of a spring, to initiate the rotation of a cam adapted to close a set of contacts 107 for apredetermined length of time.
  • the key 106 may be operated, for example, at a time when station has completed the'tra-nsmission of a message or the key may be automatically operated at certa n definite intervals, for the reversal of transmission.
  • the closure of contacts 107 serves to insert'in the grid circuit of the tube 101, the battery 109 thereby applying negative potential to the grid; the plate current thus is reducedsufliciently to cause the relay 104: to release.
  • the release of relay 104i disconnects battery from magnet and relay 120, thereby first deenergizing the magnet 10 for the release of switch S and next releasing relay 120 for the removal of the short circuit across the input of receiving amplifiervA after the switching operation of switch S has been completed;
  • the sequential release of magnet 10 and relay 120 is secured by means of a network in multiple to relay 120 and consisting of condenser 121 and resistance 122, whereby the charge on the con denser 121, due to its previous inclusion in the operating circuit, is dissipated through the winding of relay 120 at a rate determined by resistance 122 to delay the release of relay 120; the condenser 123 bridged across the winding of magnet 10 is not of sufficient size to appreciably delay the release of magnet 10.
  • the release of relay 104 causes the
  • relay 204 places battery on the operating circuits of the two-position relay 225 and relay 220, the first circuit to be traced over condenser 223 and lower winding of doublerelay 225, closed-contact 22 to ground and the other circuit to be traced over condenser 221, winding of relay 220 to ground;
  • the relay 225 may be a polarized relay, for which purpose a simple rearrangement of its operating" circuit would be required.
  • the lower winding of relay 225 attracts the armature, thereby connecting battery to magnet which operates the contact springs of switch S to connect with their left-hand contacts.
  • the relay 220 Simultaneous with the operation of relay 225 and before the reversal of switch S the relay 220 operates to place a temporary short circuit across the input of receiving amplifier A; thereby protecting the amplifier against excessive impulses due to the subsequent opera tion of switch S
  • the condenser 221 after a predetermined length of time, adjustable by means of leak resistance 222, becomes sufficiently charged to cause the release'of relay 220 and the opening of the short circuit across the amplifier A.
  • the condenser 223 also assumes a charge which, by the time when the reversal of switch S has been completed, is sufliciently high to prevent the op eration of the upper winding of double relay 225 over the left-hand contact of spring 22: the armature of relay 225 is mechanically locked in both positions to stay put after the windings have become deenergized.
  • the armature of relay 225 is mechanically locked in both positions to stay put after the windings have become deenergized.
  • the station IR is now ready for retransmission from E to l/V.
  • a network consisting of con denser 321 and resistance 322 forming a bypath for relay 320, similar to that described for relay 120, and a condenser 323 forming a by-path for magnet similar to that de scribed for magnet 10 ,
  • the condenser 323 is not of sufiicient size to delay the release of the switch, as described in connection with the release of switch S the condenser is sufii'- ciently large to take an initial charge, when relay 304 operates, to delay the energization' of magnet 30, which delay may be timed by the adjustment of resistance 324; and whereas condenser 323, similar to condenser 121, in discharging serves to delay the release of relay 320, the by-path for relay 320, including also resistance 322, isvnot of sufficiently low impedance to delay the energization of relay 320.
  • relay 320 operates quickly to place a short circuit across the receiving amplifier A for protection of the amplifierduring the subsequent switching operation and magnet 30 operates after a short predetermined time to connect the transmitting equipment over contact 33 to the cable, and todisconnect at contacts '34 the receiving condenser C from receiving transformer T and ground the condenser.
  • the detector 301 will receive no impulses andconsequently will cause the relay 304 to remain energized, thereby maintaining the station in condition for transmission.
  • connection at station E of the transmitter T and amplifier A to the line circuit will, in a commercial system, immediately cause the transmitter T to send and the effect of signals arriving at station IR upon the detector 201 is, that the condenser 202 will again be charged, thereby applying a negative paralyzing potential to the detector and'thus reducing the plate current sufliciently for the release of relay 204.
  • the signals arriving from station E are received over re-' DCving condenser C, closed contacts 14, shaping network N and recelving transformer T and are impressed upon the amplifiers A and A and recorder R.
  • the signals in the output circuit of amplifier A are impressed, through the transformer 110,u-pon the input circuit of detector 101 thereby charging the condenser 102 to impress a negative potential onthe grid circuit, temporarily aiding the negative potential of battery 109, which still isincluded in the grid circuit by the continued operation of key 106.
  • Relay 104 remains deenergized, and after a short time the contacts 107 are restored to their open condition, thereby removing the battery 109 from the grid circuit which now is maintainednegative under the influence of incoming signals, thus insuring that the switch Si remains released'as long as signals are being received. The reversal of all three stations for'transmission from E to W is thus completed.
  • the timing device 306 at station E is operatedto close contacts 307, thereby releasing relay 304 and operating switch S in the manner de-- scribed for the correspondingequipment of station IV.
  • the cessation of signals at the repeater station IR again causes the opera-v tion ofrelay 204 which extends'battery over the circuit through upper winding of relay 225, prepared at contact 22 at the time of the last reversal.
  • Relay 225 operates to disconnect battery from magnet 20 of switch S which nowreverses and at contact 22 again prepares an operating circuit for the lower winding of relay 225 which, however,:is prevented from energizing-due to a charge builtup 1n the meantime on condenser 223.
  • Shorting relay 220 is operatech as described above,
  • the coupling of the input circuitsof the detectors 101, 201-and 301to the respective receiving circuits is such as not to'pass impulses of low frequency into the input circuits.
  • the transmitting equipment at each terminal station may be arranged to in- V clud'e a plurality of transmitters, and at such time, when no messages are being transmitted, the transmitters automatically continue to send synchronizing impulses over the line as long as they are connected to the line circuit for the purpose of keeping the distant receiving equipmentin synchronism with the local transmitting equipment, and at the same time serving the purpose of maintaining the direction of transmission until either key 106 or 306 is operated.
  • thescope of the invention is not limited to the arrangement described above and shown in the draw ing, but that the invention may be applied to systems of different kinds and may be modified in different manners well known to those skilled in the art without a departure from the principles or objects of the invention;
  • a long'signaling line a simplex telegraph station connected to said line and comprising sending and receiving equipments, relay means for alternately conditioning said equipments for operative relation with the line, frequency discriminating means for said relay means to differentiate between impulses of high and low frequencies to change the operative relation of said e ui ments at the cessation of impulses of one of said frequencies in the line.
  • a signa-ling station which comprises a long line circuit, a signaling station connected to said circuit, sending and receiving equipments at said station, relay means for alternately switching one and the other of said equipments into operative relation with said line circuit, connecting means betweensaid relay means and 'saidline circuit, and a biasing network included in said connecting means for preventing switching operation by said relay means during signaling, andfor causing said relay means to switch during a cessation of signaling.
  • a simplex telegraph station comprisin sending equipment, receiving equipment, switching means for alternately switching said sending and receiving equipments into service, thermionic control means for said switching means, and biasing means for said control means to di'flere'ntiate between signal and no-signal conditions on the line thereby rendering said control means responsive for the operation of said switching means.
  • a simplex telegraph station comprising sending equipment, receiving equipment, switching means for alternately conditioning said sending and receiving equipments for service, thermionic control means for said switching means, biasing means for rendering said control means unresponsive to line impulses including a high impedance for reducing the biasing effect of said biasing means upon sald control means to render said con trol means responsive in the absence of line impulses thereby operating said switching means.
  • a simplex telegraph station for transmission of impulses alternately in opposite directions comprising switching means for reversing the direction of transmission of said station, thermionic control means for said switching means and a slow discharge circuit for paralyzing said control means dur-.
  • a simplex telegraph system for transmission of signal impulses alternately inopposi-te directions comprising a long line :c-iricuit, signaling stations connected at remotely separated points to said line circuit, a
  • switching means. for converting said stations from receiving to send ing condition, relay means at each-station for operation of said switch means, biasing means for said relay means to di-ilerent-iate between signal and no-signa-l conditions on the line thereby rendering said relay means responsive for operation of said switching means and connecting means including inductive coupling meansbetweensaid line circuit and *said biasing means, said inductiv'e coupling having low eificiency at fre,
  • a simplex telegraph system for transmission of signal impulses alternately in opposite directions comprising a long line circuit, signaling stations connected at remotely separated points to said line circuit, a ground connection for said line circuit at each of said stations, receiving and sending circuits and switching means at each station for reversing the direction of transmission, one of said stations including a thermionic amplifying device in said receiving circuit, a
  • inductive coupling means be tween said leak circuit and said device, a signal detecting thermionic tube circuit in said leak circuit for operation of said switching means in the absence of impulses impressed on said leak circuit by said device, said inductive coupling having low efficiency at frequencies considerably below the signaling frequency to prevent earth current variations from entering said leak circuit.
  • a simplex telegraph station comprising sending equipment, receiving equipment, switching means for alternately switching said sending and receiving equipments into operative relation with the line, a thermionic electron discharge tube having an input circuit for reception of signal impulses from said receiving equipment and having an output circuit for control of said switching means, a condenser and a slow discharge circuit therefor in said input circuit for storing of a paralyzing potential for said tube supplied by impulses of signaling frequencies to prevent operation of said switching means and for discharging said paralyzing potential during a prolonged absence of signaling impulses in said receiving circuit to cause the operation of said switching means.
  • a simplex telegraph station compris-' ing sending and receiving equipments, switching means for alternately switching said equipments into service relation with the line, thermionic control means for said switching means, biasing means connected to said control means for differentiating between signal and no-signal conditions on the line to render said control means responsive for the operation of said switching means, relay means interposed between said control means and said switching means for accomplishing the operation of said switching means during the responsive condition of said control means, and energy storing and dissipating means associated with said relay means to prevent operation of said switching means more than once for each responsive condition of said control means.
  • a signal communication system for alternating transmission in opposite directions, two long cable sections, a repeater station intermediate said sections comprising signal repeating equipments having input and output circuits, automatic means for reversing the connections from said input and output circuits with respect to said cable sections for changing the direction of transmission of said station in response to a change in line conditions, and two setsof receiving circuit means, each continuously connected to its associated cable section, and each including a receiving condenser and a grounded input transformer, said switching means being adapted to render either one of said ets non-responsive to outgoing signals in accordance with the direction of transmission.
  • a cable for the transmission of signals alternately in'opposite directions, a receiving amplifier having an input circuit, switching means for connecting together and disconnecting said amplifier and said cable, control means for operating said switching means in response to a special signal repeated by said amplifier, a normally open shunt path for said input circuit for protection thereof during switching operations, means for temporarily closing said shunt path once in response to each special signal comprisin a series circuit including a relay and a con enser and a slow discharge path for said condenser independent of said relay.
  • a communication system for transmission of signals alternately in opposite directions comprising two terminal signaling stations, a long line circuit interconnecting said stations, receiving and sending equipments at each station, switching means at each station for opcratively associating said equipments alternately with said line circuit, thermionic control means and frequency discriminating means therefor at each station responsive to diflerentiate between impulses of signaling frequencies and impulses of longer duration to control said switching means for changing the station from receiving condition to sending condition at the termination of a message, and a source of potential and contact means therefor at each of said stations for temporarily biasing said control means to control the switching means for changing the station from sending to receiving condition.
  • a communication system for transmis sion of signals alternately in opposite directions comprising terminal and intermediate stations, a line circuit having a high attenuation factor interconnecting said stations, sending and receiving equipments at each station, switching means at each station for alternately connecting said equipments in operative relation to said line circuit for transmission in opposite directions, thermionic control means at each station for said switching means having an input circuit for reception of impulses from said receiving equipment, energy storing and dissipating circuit means included at each station in said input circuit for differentiation between current variations of the signaling frequencies and current variations of longer duration to apply a biasing potential to said control means during a signaling period to prevent operation of said switching means and to discharge said biasing potential upon completion of a signaling period to operate said switching means, a source of continuous biasing potential at each terminal station and contact instrumentalitiesfor temporarily connecting said source into said input circuit to apply said continuous biasing potential to the control means at said terminal stations for operation of said switching means from sending to receiving condition, and energy storing and dissipating circuit means at an intermediate station to prevent the operation

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  • Engineering & Computer Science (AREA)
  • Signal Processing (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Radio Relay Systems (AREA)
  • Amplifiers (AREA)
  • Cable Transmission Systems, Equalization Of Radio And Reduction Of Echo (AREA)
US582696A 1931-12-23 1931-12-23 Telegraph system Expired - Lifetime US1904618A (en)

Priority Applications (3)

Application Number Priority Date Filing Date Title
US582696A US1904618A (en) 1931-12-23 1931-12-23 Telegraph system
GB29969/32A GB409026A (en) 1931-12-23 1932-10-26 Improved switching arrangements for electrical signalling systems
DEE43480D DE599232C (de) 1931-12-23 1932-11-05 Simplex-Telegraphiersystem, bei dem der Verkehrsrichtungswechsel selbsttaetig mittels einer Umschaltvorrichtung erfolgt, die bei einer laengeren Unterbrechung der ankommenden Signale ihre Stellung wechselt

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US582696A US1904618A (en) 1931-12-23 1931-12-23 Telegraph system

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US1904618A true US1904618A (en) 1933-04-18

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DE (1) DE599232C (de)
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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2439398A (en) * 1944-02-25 1948-04-13 Bell Telephone Labor Inc Telegraph system provided with channel assurance and transmission regulation
US2554793A (en) * 1947-06-11 1951-05-29 Teletype Corp Radio telegraph system with direction control

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2439398A (en) * 1944-02-25 1948-04-13 Bell Telephone Labor Inc Telegraph system provided with channel assurance and transmission regulation
US2554793A (en) * 1947-06-11 1951-05-29 Teletype Corp Radio telegraph system with direction control

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Publication number Publication date
GB409026A (en) 1934-04-26
DE599232C (de) 1934-06-27

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