US2414488A - Heat responsive communication signal repeater - Google Patents

Description

Jali. 21, 1947. R. B. SHANCK HEAT RESPONSIVE COMMUNICATION SIGNAL; REPEATER Filed July 22, 1942 y F T /0/ 20.9) 2/0 206 207 I I p I hm if lNl/E/VTOR y R B. SHA/VCK A TTORNEV Patented Jan. 21, 1947 HEAT RESPONSIVE COMMUNICATION SIGNAL REPEATER Roy B. Shanck, Douglas Manor, N. Y., assignor to Bell Telephone Laboratories, Incorporated, New York, N. Y., a corporation of New York Application July 22, 1942, Serial No. 451,906

13 Claims.

This invention is a communication signal repeater responsive to changes in heat.

An object of the invention is the improvement of repeaters in communication circuits.

A feature of the invention is the employment of a resistance the magnitude of which is varied in response to changes in heat as a repeater for communication signals.

One specific form of resistance which varies in magnitude in response to changes in heat suitable for use in practicing this invention comprises an element commonly classed as a semiconductor possessing the characteristic of substantial change in resistance with change in temperature. Such materials may be employed to form circuit elements by fusing or otherwise binding platinum or other conductor leads into electrical contact with a suitable quantity of semiconductor compound. These elements are ordinarily of comparatively high resistance but as the temperature is raised, either because of an external heater or because of the heating efiect of such current as is flowing through the element, the resistance falls very greatly. The device therefore takes on the nature of a switch or, as employed in this invention, as a valve, in which the control is exercised through change in temperature. Devices of this kind have been called thermistors.

Incorporated herein by reference are the following patents disclosing thermally sensitive resistors with which the invention herein may be practiced: G. L. Pearson 2,184,847, December 26, 1939; G. L. Pearson et al, 2,253,577, August 26, 1941; G. L. Pearson 2,280,257, April 21, 1942; and G. L. Pearson 2,276,864, March 17, 1942.

In the invention herein communication signal current pulses are translated into variations in heat. The heat changes are impressed on a resistance, the magnitude of which varies in response to heat changes. The heat responsive resistance controlled by communication signals is arranged to act as a valve to regulate the flow of current in a second circuit in response to communication signals in a first circuit. The two circuits may be coupled solely by means of a heat transfer element in which case the circuit in which the communication signals originate and the circuit into which they are repeated may be otherwise independent. Or the communication signal current may flow directly through the heat responsive reactance so that the two cir cuits are electrically as well as heat coupled.

Heat responsive resistors or thermistors as they are known in the art are presently available which respond satisfactorily to current changes of a frequency even beyond 10,000 cycles per second. Such thermistors are described in Patent 2,276,864 mentioned above. Various applications of these thermistors are described in my copending application Serial No. 451,905, filed July 22, 1942. Their use is feasible, therefore, as communication signal repeaters, not only in telegraph systems, both of the direct and alternating current types, including carrier current telegraph systems, but also in telephone systems including both those operated at speech current and carrier current frequencies up to the upper frequency limit of the response of the thermistor.

The thermistors intended to be used in this invention are all types in which the resistance change in response to heat change is satisfactory for the signaling speed employed in whatever communication system and includes all types of thermistors from those of relatively slow response to the modern ultra fast response of 10,000 cycles per second and upward.

It is to be understood that the heat responsive thermistor type repeaters, whether used in telegraph or telephone systems or in other systems may be connected in tandem throu h as many repeating stations without limit as may be required for any case either with or without other intervening repeaters.

Further, this invention specifically comprehends the employment of the heat responsive thermistor type communication signal repeaters in radio transmitters and receivers of all types, both in broadcasting and receiving speech and music and in television broadcasting and receiving. In general it may be substituted widely for vacuum tubes for many purposes to effect a saving in first cost and operating expense.

The invention is embodied in telegraph circuits but it is to be understood that the invention is not limited to telegraph circuits and may be applied in the repeating of speech signals in telephone communication, in the repeating of signals in picture transmission, in the repeating of signals in telemetering circuits, remote control circuits and in many other circuits.

The invention may be understood from the following description when read with reference to the associated drawing, in which:

Fig. 1 discloses the heat-responsive repeater applied in a direct current telegraph circuit arranged for the transmission of polar signals;

Fig. 2 discloses a heat-responsive repeater in a direct .current telegraph circuit arranged for the full commutation of a direct current telegraph battery in a one-Way, two-wire circuit; and

Fig, 3 discloses the embodiment of a heatresponsive repeater of a form different from Fig. 2 but arranged also to provide full commutation.

Refer now to Fig, 1. Relay I! is assumed to be located at a first telegraph station. It is connected by means of two conductors I02 and H33 to the heat-responsive repeater located at a second telegraph station. The heat-responsive repeater is connected by means of conductor we to a third telegraph station, not shown. As the winding of relay [0! is energized and deenergized, its armature W is actuated between its contacts I 06 and I01. When armature [05 is in engagement with contact I06, a circuit may be traced from ground, through battery I08, resistance I 09, armature I95, contact I 06, conductor I02 and the resistance heating element I It of thermistor III to ground. When current flows in this path the temperature of resistance unit H6 is raised. This, in turn, raises the temperature of the heat-responsive resistance element I [2. The resistance of heat-responsive resistance element H2 is reduced and a voltage pulse from grounded positive battery H3 is impressed through the upper winding of polar relay He and conductor IM to the distant station. Simultaneously current flows through the bottom winding of relay l I 4 and through the artificial line H5 to ground. The net effect of the current flowing in the two windings of relay H 5 maintains the armature of relay H4 in engagement with its marking contact. When the armature of relay I05 is operated so as to engage with contact IN, a circuit is established from ground through battery I08, resistance I89, armature 105, Contact H31, conductor I 03, and resistance heating element H6 of thermistor I 88 to ground. Resistance heating element I I6 is raised in temperature. The heat-responsive repeating element II! of thermistor I I8 is also raised in temperature lowering its resistance. A negative pulse from grounded negative battery H9 is impressed through repeater ill, the top and bottom windings of relay I I4 and conductor I04 to the distant station. The net effect of the current in the two windings of relay H4 again maintains the armature of relay I M in engagement with its marking contact in a well-known manner.

Refer now to Fig. 2. Relay is located at a first telegraph station. It is connected to the heat-responsive repeater by conductors 2G2 and I 203. The heat-responsive repeater is located at a second telegraph station and it is connected to a third telegraph station by means of conductors 284 and 205. As the winding of relay 2i is energized and deenergized, armature 206 is operated between its contacts 201 and 208. When armature 2% is in engagement with its contact 2G? a circuit is established from battery 299, through resistance 2H1, armature 206, contact 2&7, conductor 2B2, resistance heating element 2i i of thermistor 2 I2, and resistance heating element 2E3 of thermistor 2M to ground. The temperatures of resistance heating elements 2H and 253 are raised, in turn, raising the temperatures of the heat-responsive repeating elements it? and 2H5 of thermistors M2 and 253, respectively. The resistancesof repeating elements 2I5 and ZIG are lowered. A circuit may then be traced from the positive terminal of battery 2H,

through repeating element 2E6, over conductor 265 to the distant station and returning over conductor 264, through repeating element 2I5 to the negative terminal of battery 2H. When armature 2&5 of relay 26% engages contact 2938, a circuit is established from ground, through battery 2S9, resistance ZIG, armature 2%, contact 268, conductor 2%, resistance heating element N8 of the heat-responsive repeater ift, and heating element 22!] of heat-responsive repeater 22! to ground. The temperatures oi resistances 2H! and 223 are increased, in turn, increasing the temperatures of the repeating elements 222 and 223. The resistances of the elements are decreased. A circuit may then be traced from the positive terminal of battery 2H, through repeating element 223 and over conductor 2% returning over conductor 205, through repeating element 222 to the negative terminal of battery 2H. As a result or" this the connections of the terminals of battery 2!? to conductors Add and 265 are alternately reversed.

In the embodiment shown in Fig. 3, relay SM is located at a, first telegraph station. It is connected to the heat-responsive repeater at a second telegraph station by means of conductors 302 and 363, The heat-responsive repeater is connected to a third telegraph station by means of conductors 3M and 385. The heat-responsive repeater elements are connected in a bridge, the resistances of the arms of which are equal when the heat responsive elements are cold. When relay SM is energized and deenergized, armature 306 is actuated between its contacts 397 and 363. When armature 3% is in engagement with contact 3B1 a circuit is established which may be traced from battery 3%, through resistance 3), armature $65, contact 301', conductor 3G2, and resistance heating element 3| I of heat-responsive repeater M2 to ground. The temperature of the resistance heating element 3!! is increased, in turn, increasing the temperature of the heatresponsive repeating element SIB of thermistor 3I2. The resistance of the heat-responsive element 3I3 is decreased. Current will thereupon flow from ground, through negative battery am, repeating element 3I3, over conductor 3594, re turning over conductor 30%, through resistance 3I5, and positive battery sue to ground. When armature 3% of relay 39! engages with contact 308, a circuit is established from battery 309, through resistance 3H3, armature 366, contact 308, conductor 393, and resistance heating element 3H of thermistor 3l8 to ground. The temperature of resistance 311 is increased, in turn, increasing the temperature of repeating element 3i 9. The resistance of repeating element 3|9 is decreased. Thereupon current flows from ground through negative battery 3M, repeating element SIS, over conductor 395, to the distant station, returning over conductor 3%, through resistance 32c and positive battery Bit to ground.

The arrangement shown in Fig. 3 could be used for reversing the phase of an alternating current if batteries 3M and 3H: were replaced by an alternating current generator.

It has been found that the heat-responsive repeater greatly reduces noise and it is to be understood that, if it is preferred, the apparatus described as being located atstations I and 2 may all be located at the same station to take greater advantage of this characteristic. As thus arranged the heat-responsive repeater would be controlled by a local circuit at the same station instead of being controlled from a remote station. The reduction in noise is so substantial that in some cases the noise filters ordinarily required may be eliminated. In other cases they may be simplified.

It is to be understood that when the heatresponsive repeater is used for repeating speech signals, the telegraph equipment shown will be replaced by equipment responsive to speech. Relays IM, 20!, 3M at office l, for instance, would be replaced by a telephone transmitter. The heat-responsive repeater at offioe 2 would connect directly to a telephone line extending to oflice 3. Telephone receiving equipment would be installed at ofiice 3 instead of telegraph receiving equipment. Corresponding changes, well understood, would be required when the heat-responsive repeater was used to repeat picture signals or to operate in remote control circuits, etc.

What is claimed is:

1. In a direct current telegraph circuit, a heatresponsive telegraph signal repeater for minimizing noise, means for varying the heat supplied to said repeater directly by the variations in received telegraph signal current and means for effectively reversing the terminals of a battery connected to a two conductor telegraph transmitting circuit in response to said received signal current. I

2. In a direct current telegraph circuit a heatresponsive telegraph signal repeater for 1minimizing noise, a plurality of resistances in said repeater, a plurality of heating elements individually associated with said resistances and means for simultaneously controlling the heating of said elements to vary the magnitude of said resistances to transmit telegraph signals in response to received telegraph signal current directly.

3. In a direct current telegraph circuit, a telegraph channel interconnecting two telegraph stations, a heat-responsive thermistor repeater in said channel, said repeater comprisin a resistance through which attenuated, electrical telegraph signals are conducted to generate in said resistance corresponding variations in heat energy and means directly responsive to said heat energy variations for regenerating amplified signals corresponding to said telegraph signals, to reduce repeater noise by rounding the beginnings and the ends of the waves of said regenerated signals, through the heating and cooling time lag of said resistance.

4. In a direct current telegraph system, a polar telegraph thermistor repeater circuit for minimizing noise, by rounding the beginnings and ends of regenerated telegraph signals through thermal lag, said circuit having a first output branch extending from grounded negative battery through a first thermistor variable resistance element to the line winding of a telegraph receiving relay and a second output branch extending from grounded positive battery through a second thermistor variable resistance element to said winding, a thermistor heating resistance element in each of two input branches, thermally connected individually with each of said variable resistance elements, and means for varying the heat supplied to said heating resistance elements alternately in response to received telegraph signal currents directly.

5. In a direct current telegraph system, a polar telegraph thermistor repeater comprising two heat controlled variable resistance elements, means for alternately varying the amount of heat supplied to said elements in response directly to received telegraph signal current of the same polarlty, and means in said repeater for generating polar signals having wave forms with rounded beginnings and ends, due to thermal lag, to minimize noise, in response to said variations in heat.

6. In a telegraph system, a bridge type direct current, thermistor telegraph repeater for minimizing repeater noise comprising four conjugate arms, each of two of said arms having a variable resistance thermistor element therein, each of said elements having associated therewith a heating resistance element responsive to changes in heat generated by telegraph signal currents directly for regenerating telegraph signals.

7. In a telegraph system, a direct current telegraph repeater for minimizing repeater noise, a first and a second thermistor in said repeater, a heating element and a variable resistance element in each of said thermistors, an incoming circuit, an outgoing circuit, two incoming branches in said repeater connected to said incoming circuit, two outgoing branches in said repeater connected to said outgoing circuit, a telegraph battery connected through said outgoing branches to said outgoing circuit, one of said heating elements in each of said incoming branches, one of said variable resistances in each of said outgoing branches, means in said incoming circuit for impressing telegraph signal current impulses on each of said incoming branches to heat said heating elements, and means in said repeater responsive to the consequent variations in the resistances of said variable resistance elements, for efiectlvely reversing the polarity of said battery connected through said outgoing branches to said outgoing circuit, to regenerate said impulses, impressed by said incoming circuit, in said outgoing circuit.

8. In a telegraph system, a direct current telegraph communication signal repeater for reducing repeater noise, a thermistor in said repeater, a. heating element in said thermistor, a variable resistance element in said thermistor responsive to heat changes in said element, a receiving relay in said repeater, a telegraph transmitting and receiving circuit connected directly to said resistance, said relay in said repeater having an operating winding in series in said circuit, means connected to said repeater for transmitting telegraph communication signal current impulses through said heating element, means responsive to heat changes in said element effected by said signals for repeating said signals through said variable resistance and said relay winding in a first direction at a first time, and means responsive to other telegraph signal current impulses incoming through said winding and directly through said variable resistance in a second direction for receiving said other signals at a second time.

9. In a telegraph system, a direct current telegraph repeater for minimizing noise, a thermistor in said repeater, a heating element in said thermistor, a variable resistance element controlled by said heating element in said thermistor, a oneway telegraph circuit connected directly to said heating element, a two-way telegraph circuit connected directly to said variable resistance, means for impressing telegraph signal current impulses on said heating element, means responsive to heat changes effected by said impulses for repeating said signals directly through said variable resistance and said two-way circuit in a first direction at a first time, and means for receiving current impulses corresponding to other telegraph signals directly through said two-way circuit and saga-sass said-wariable Iresistance' in a second direction at a secondtime.

mistor; a variable resistance responsive to heat changes effected by saidelement in said thermistor,- a one-way telegraph circuit connected directly to saidl'heating element, a two-way telegraph circuit connected directly to said variable resistancameans connectedto said repeater for impressing telegraph signal current impulses through said heating element, means responsive thereto for repeating said impulses directly through said variable resistance and said -two-1 Way-circuit in a first direction ata first time,-and ,means connected to said repeater for receiving telegraph signals impressed through saidtwo- --way circuit and directly throughsaidvariable resistance in a second direction at a second'time.

v11. In a telegraph system, a direct currenttelegraph repeater for minimizing noise, a one-Way and a two-way telegraph circuit connected to said repeater, a'first and-a second thermistor in'said repeater, a heating element: and a variable 1' .isistance; responsive to heat changesin said element, in each'o'f said'thermistors,means'in said said variable resistances and said two-way circuit in a first direction at a first time, a telegraph signal receiving device in sad two-way circuit, and means for receiving telegraph signal impulses directly through said receiving device and either of said variable resistances in said two-Way circuit in a second direction at a second time.

12. In a telegraph system, a direct current teleraphrepeater for minimizing noise, a-two-conductor circuit incoming to said repeater, a-twoconductor circuit outgoing from said repeater, four thermistors in said repeater, a heatingelement and a variable :resistance responsive toheat changes in said element in each of said thermistors, a telegraph battery in said outgoing circuit, means connected to each of said 'conductorsein said incoming circuit 'for impressing telegraph signal current impulses on said heating elements of a first and a second pair of said thermistors alternately, and means responsive thereto"'for transmitting telegraph signal current impulses of opposite polarities-from said battery through said variable resistances of a corresponding-first and second pair of said thermistors tosaid twoconductor outgoing circuit.

13. In a telegraph system, a direct current telegraph repeater forminimizin noise; abridge having a first, second, third and fourth "arm in said repeatena two-conductor output circuit con-' nected to a first pair of diagonally opposite terminals between said arms of said bridge, a'telegraph battery connected to a second pair of diagonally opposite terminals between said armsof'said bridge, a first and a second thermistor 'in'said repeater, each of said thermistors comprisinga heating element and a variable resistance-element, said variable resistance elementresponsive to variations in heat of said heating element, one of said variable resistance elements in said first arm and another in said second arm, means for impressing telegraph signal current impulses on said heating elements alternately, and means comprisingsaid variable resistance elements, responsive to said impulses for effectively reversing the polarity of said battery to repeat said impulses in said output circuit.

ROY B. SHANCK.

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