US1976120A - Light control device - Google Patents
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- 239000003086 colorant Substances 0.000 description 5
- 230000010349 pulsation Effects 0.000 description 2
- 208000027418 Wounds and injury Diseases 0.000 description 1
- 239000012141 concentrate Substances 0.000 description 1
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- 230000006378 damage Effects 0.000 description 1
- 230000001419 dependent effect Effects 0.000 description 1
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- 230000003287 optical effect Effects 0.000 description 1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N5/00—Details of television systems
- H04N5/30—Transforming light or analogous information into electric information
Definitions
- This invention relates to light control devices and more particularly to a means for signalling by high frequency light pulsations.
- Such systems all have decided disadvantages, such as low optical efficiency, high polarizing voltages, carrier frequencies of considerable magnitude and do not permit of the use of extremely high frequency carrier currents.
- the light produced by such devices normally covers a wide band of frequencies of the visible spectrum thereby making possible only limited color selectivity by color filters at the receiving station.
- Another 0 J c 18 to produce variations in intensity of a light emitting source by varying the space charge around said source and utilizing said variations for signalling purposes.
- Another object is to produce variations in the predominate frequencies given off by a light emitting source by varying the space charge around said source.
- Another object is to produce large variations in amount of light emitted over a predetermined band of color frequencies only.
- Another object is to illustrate a means of obtaining higher light frequencies from an incandescent body by placing a negative charge around said body to keep these frequencies from being dissipated in emitting electrons, with consequent injury to said incandescent body.
- Another object is to produce carrier frequency variations in light by varying the number of electrons emitted by a source of light, the energy absorbed by the emission of said electrons varying the intensity of said source and consequently the light emitted by said source.
- Another object is to illustrate means whereby weak variations in light may be amplified.
- Fig. l is a diagramatic illustration of one form of the invention.
- Fig. 2 is a further illustration thereof in which a relay or intermediate station is illustrated.
- transmitting station TS is composed of three electrode vacuum tube V1 containing plate P1, filament F1, and grid G1.
- An A battery A1 heats filament F1.
- Resistance R1 prevents any substantial increase in filament current when the space current of the tube increases, since it is common to the negative A lead and 3" battery circuit.
- Battery Bl impresses a high positive potential on plate Pl.
- C" battery CB1 impresses a negative potential on grid G1. sufficient to block the space current thru tube VI when no signal is being impressed between G1 and F1 by oscillator OSC controlled by modulator MOD in response to microphone M1 thru transformer TR.
- Reflector D1 directs the light from filament F1 on to lens D2 which in turn concentrates the rays on photo-electric cell PEI thru color filter CF at receiving station RS. Since the light from filament F1 varies in accordance with the modulated carrier frequency of oscillator 050, the electrical current variations in the circuit B PEI primary of transformer PR2, are similar in form to the modulated carrier frequency.
- This energy is transferred to a tuned circuit comprising secondary of transformer 'IR2 and C2, which in turn is detected by C bias vacuum tube detector V2. the modulation frequency thereof appearing in translating device T.
- m is the mass of an electron.
- v is the velocity of its emission.
- h is the Planks constant.
- P is the energy lost by the electron in freeing itself from the surrounding atoms.
- e is the charge of the electron.
- V is the voltage thru which it falls.
- Color filter CF has been selected controlling the space charge in the vicinity of so as to pass only the band of frequencies, over said second source in accordance with said genwhich the variation in amplitude of frequencies erated electrical current, and means for gengiven off by filament F1 is most pronounced.
- erating asecond electrical current in accord- Fig. 2 is a further embodiment in which a ance with said variations in intensity of said as relay or intermediate station IS-is placed besecond light source.
- the functioning and designating light radiating Source Of light, eans for recharacters at the transmitting and receiving dueing frequencies given O by Said l t bove station are the same as illustrated in Fig. 1.
- the varying light from filament F1 has been me means for varying the spac h e i he i t t d relay t ti 15 m l r vicinity of said source of light, an electron emisfllter CF22 onto a photo-electric cell PE21.
- the SiVe v ce illum ated by said li d me variations in the photo-electric cell circuit PE21, generating an electrical cur ent in Said de- B21 primary of transf rmer T321 are passed vice corresponding to reductions in said freonto a tuned circuit comprising secondary of queneies given fi by d Source.
- a se o d electransformer TR21 21 amplified by vaguum tron emitting light radiating source, means for tube amplifier V21 the filament of which is reducing frequencies given Ofi by said second heated by A21 and the plate of which receives Source above predetermined q y.
- d current from B21 thru primary of transformer last means comprising means for Varying the 21 Th variations in plate current of v21 space charge in the vicinity of said second source are impressed by t secondary of transformer in accordance with said generated electrical cur- 2 between t grid and filament, of vacuum rent, a second electron emissive device illumit v22 similar in construction t v nated by said second source, and means for genbattery CB22 and B battery B22 furnish crating a second electrical current in said secproper potentials to the control electrode and find device correeponding to re uct ons in freanode of V22 respectively.
- a photo-emissive 1 In a signal ystem a generator of carrier surface by and means for current, a modulating device. controlled by a @mining 15mm said Variations in signal, for controlling said generator.
- light emit- Pncal current cm'respmdmg to sald variaticms ting controlling means including an electron in said light colors, a second incandescent body, emitting light source, means for controlling the means for Producing variations in light colors space charge around said source by said carrier Elven P?
- a second light emitting controlling Said electncal m means including a second electron emitting light 6.
- an electron emitting source means for controlling the space charge light radiating source of light of a plurality of around said second light source by said reprocolors" means for changmg the predominate duction of said carrier current, a photo-emissive 00101 of t e light given oil by Sa d Source.
- said surface illuminated by said second light source means comprising means v i h Sp ce and means for obtaining from said surface a ch in the v y of Said fl e. a l t reproduction of said signal. controlled device, and means for obtaining from 2.
- a second electron emitprising means for generating a variable voltage, ting light radiating source of a plurality of means for controlling the space charge in the colors, means for changing the predominate vicinity of said source in accordance with said color of light given off by said second source, variable voltage, and means for generating an said last means comprising means for varying 15p the energy absorbed in electron emission from said second source, said last mentioned means comprising means for varying the space charge around said second source in accordance with said electrical current, a second light controlled device, and means for obtaining from said second device a second electrical current. varying in accordance with changes in the color of light given off by said second source.
- said last means comprising means for varying the number of higher frequency light quanta absorbed in electron emission from said second source in accordance with said voltage variations, and means for translating said color variations of said second source into sound.
- means for producing a signal modulated carrier current means for producing variations in intensity of an electron emitting light radiating source of light in accordance with said current, said means comprising means for varying the space charge in the vicinity of said source of light in accordance with said current, means for impressing said light on a light sensitive surface, means for obtaining a second signal modulated carrier current from said surface corresponding to said first signal modulated carrier current, means for selecting said second carrier, means for amplifying said second carrier, means for producing variations in a second electron emitting light radiating source of light in accordance with said amplified current, said last mentioned means comprising means for varying the space charge in the vicinity of said second source of light in accordance with said amplified current, means for impressing said light from said second source on a second light sensitive surface, and means for obtaining from said second surface a reproduction of said signal.
- a generator of signal modulated carrier current, an electron emitting light radiating source of light means for producing variations in the colors given off by said source over a predetermined range, said means comprising means for varying the space charge in the vicinity of said source in accordance with said current, means for impressing said variations on a light sensitive surface, including a color filter to pass light only over said predetermined range, means for obtaining a second carrier current similar to said first carrier current from said surface, means for selecting said second carrier, means for amplifying said second carrier, a second electron emitting light radiating source of light, means for producing variations in the colors given off by said second source, said means comprising means for varying the space charge in the vicinity of said second source in accordance with said second current, means for impressing said second variations in color on a second light sensitive surface, and means for obtaining from said second surface a reproduction of said signal.
- a vacuum tube having a plate circuit, a grid circuit, and fila source of current connected in said filament circuit, a source of space current connected in said plate circuit.
- means for producing variations of light quanta absorbed by said space current from said filament said means comprising means for producing variations in magnitude of said space current
- said last mentioned means comprising a source of signal voltage connected in said grid circuit, means for preventing substantial increase in filament current as said space current increases
- said last mentioned means comprising a resistance common to said plate and said filament circuits, said resistance being of sufficient magnitude to prevent said increase, a photo-electric device, and means for obtaining from said device a reproduction of said signal.
- an electron emitting light radiating surface means for producing light variations radiated by said surface, said means comprising means for varying the energy absorbed from said surface by electron emission, means for producing an electric current corresponding to said light variations, means for amplifying said electrical current, a second electron emitting light radiating surface, means for controlling the energy absorbed by electron emis- 120 sion from said second surface in accordance with said amplified current, and means for producing a second electric current in accordance with variations in light radiated by said second surface.
- a transmitting station an electron emitting light radiating source at said transmitting station, means for producing light intensity variations in said source, said means comprising means for generating a variable voltage, means for controlling the space charge in the vicinity of said source in accordance with said variable voltage, means for directing said light variations towards a relay station.
- a photo-electric cell at said relay station for producing voltage variations in accordance with said light variations
- a second electron emitting light radiating source at said relay station means for producing variations in said second source
- said last means comprising means for varying the light quanta absorbed from said second source in accordance with said voltage variations from said photo-electric cell, means for directing light variations from said relay 145 station towards a receiving station, and means at said receiving station for changing said light variations received from said relay station into signals.
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Description
455-617 AU 233 EX r PIP-8105 XR 1,9751120 Oct. 9, 1934. Q FRAN|$ 1,976,120
LIGHT CONTROL DEVICE Filed Jan. 31. 1933 IN VEN TOR.
Patented Oct. 9, 1934 LIGHT CONTROL DEVICE Oliver Thomas Francis, San Diego, Calif.
Application January 31,
13 Claims.
This invention relates to light control devices and more particularly to a means for signalling by high frequency light pulsations.
It has been proposed to use various forms of light chopping devices. One of the most promising systems is the one in which a Kerr cell is placed between two Nicol prisms, and a modulated carrier frequency impressed on the Kerr cell for the purpose of rotating a beam of polarized light.
Such systems all have decided disadvantages, such as low optical efficiency, high polarizing voltages, carrier frequencies of considerable magnitude and do not permit of the use of extremely high frequency carrier currents. The light produced by such devices normally covers a wide band of frequencies of the visible spectrum thereby making possible only limited color selectivity by color filters at the receiving station.
It is an object of this invention to provide a means of producing carrier frequency pulsations of light whereby the disadvantages above noted may not be present.
It is another object of this invention to provide a means of creating a carrier frequency rich in the infra-red end of the spectrum.
Another 0 J c 18 to produce variations in intensity of a light emitting source by varying the space charge around said source and utilizing said variations for signalling purposes.
Another object is to produce variations in the predominate frequencies given off by a light emitting source by varying the space charge around said source.
Another object is to produce large variations in amount of light emitted over a predetermined band of color frequencies only.
Another object is to illustrate a means of obtaining higher light frequencies from an incandescent body by placing a negative charge around said body to keep these frequencies from being dissipated in emitting electrons, with consequent injury to said incandescent body.
Another object is to produce carrier frequency variations in light by varying the number of electrons emitted by a source of light, the energy absorbed by the emission of said electrons varying the intensity of said source and consequently the light emitted by said source.
It is another object to illustrate means for utilizing variations in light given off by the filament of a vacuum tube having a plate. filament and grid. for light control purposes, the color of said light being controlled by the space current of said tube.
Another object is to illustrate means whereby weak variations in light may be amplified. and
passed onto another station.
1933, Serial No. 654,429
Other objects of this invention will become apparent from the following detailed description which is most readily understood by reference to the accompanying drawing in which:
Fig. l is a diagramatic illustration of one form of the invention.
Fig. 2 is a further illustration thereof in which a relay or intermediate station is illustrated.
Referring to Fig. 1, transmitting station TS is composed of three electrode vacuum tube V1 containing plate P1, filament F1, and grid G1. An A battery A1 heats filament F1. Resistance R1 prevents any substantial increase in filament current when the space current of the tube increases, since it is common to the negative A lead and 3" battery circuit.
Battery Bl impresses a high positive potential on plate Pl. C" battery CB1 impresses a negative potential on grid G1. sufficient to block the space current thru tube VI when no signal is being impressed between G1 and F1 by oscillator OSC controlled by modulator MOD in response to microphone M1 thru transformer TR.
Reflector D1 directs the light from filament F1 on to lens D2 which in turn concentrates the rays on photo-electric cell PEI thru color filter CF at receiving station RS. Since the light from filament F1 varies in accordance with the modulated carrier frequency of oscillator 050, the electrical current variations in the circuit B PEI primary of transformer PR2, are similar in form to the modulated carrier frequency.
This energy is transferred to a tuned circuit comprising secondary of transformer 'IR2 and C2, which in turn is detected by C bias vacuum tube detector V2. the modulation frequency thereof appearing in translating device T.
The principles involved in varying an electron emitting light source by varying the space charge around said light source may be analyzed by the well known Einstein equation:
/2 mo equals (hf-P) equals Ve. wherein;
m is the mass of an electron.
v is the velocity of its emission.
h is the Planks constant.
1 is the frequency of radiant energy, and
P is the energy lost by the electron in freeing itself from the surrounding atoms.
e is the charge of the electron.
V is the voltage thru which it falls.
Each time an electron is emitted a quantum of energy (hf) is absorbed. This absorbed energy is of the higher radiant frequencies present at filament F1. It is evident that the frequencies of radiant energy I present at filament F1 is dependent upon the space charge V (which in turn is governed by oscillator 080), and that for greatest variation of light emitted a high electrical current in accordance with said variafllament temperature is necessary, since the tions in intensity of said light source, a second radiant frequencies present at filament F1 canelectron emitting light source, means for pronot be cut off by varying the space charge at a ducing variations in intensity of said second point lower than where hf equals P of the Einsource, said last means comprising means for stein equation. Color filter CF has been selected controlling the space charge in the vicinity of so as to pass only the band of frequencies, over said second source in accordance with said genwhich the variation in amplitude of frequencies erated electrical current, and means for gengiven off by filament F1 is most pronounced. erating asecond electrical current in accord- Fig. 2 is a further embodiment in which a ance with said variations in intensity of said as relay or intermediate station IS-is placed besecond light source. tween transmitting station TS and receiving 3. The combination with an electron emitting station RS. The functioning and designating light radiating Source Of light, eans for recharacters at the transmitting and receiving dueing frequencies given O by Said l t bove station are the same as illustrated in Fig. 1. 8 p r ed f equency. said means comp The varying light from filament F1 has been me means for varying the spac h e i he i t t d relay t ti 15 m l r vicinity of said source of light, an electron emisfllter CF22 onto a photo-electric cell PE21. The SiVe v ce illum ated by said li d me variations in the photo-electric cell circuit PE21, generating an electrical cur ent in Said de- B21 primary of transf rmer T321 are passed vice corresponding to reductions in said freonto a tuned circuit comprising secondary of queneies given fi by d Source. a se o d electransformer TR21 21; amplified by vaguum tron emitting light radiating source, means for tube amplifier V21 the filament of which is reducing frequencies given Ofi by said second heated by A21 and the plate of which receives Source above predetermined q y. d current from B21 thru primary of transformer last means comprising means for Varying the 21 Th variations in plate current of v21 space charge in the vicinity of said second source are impressed by t secondary of transformer in accordance with said generated electrical cur- 2 between t grid and filament, of vacuum rent, a second electron emissive device illumit v22 similar in construction t v nated by said second source, and means for genbattery CB22 and B battery B22 furnish crating a second electrical current in said secproper potentials to the control electrode and find device correeponding to re uct ons in freanode of V22 respectively. The amplified variquencies from d Second Sourceations in light of cathode V22 corresponding to In i Signalling S t m, a S u ce f the weak variations received by PE2l are religh.t comprising t e c t e O a v cu tu e flected by D21 thru lens n22 onto color filter havms an anode, and a control electrode. a 11 CF and {yarn that point t fun tioning of the source of anode current for said anode, means receiving tation Rs 15 the same as described for Varyi g the amount Of energy absorbed from for Fig. 1 above It 111 be understood that the said cathode in the emission of the electrons of system is not nmited to a single intermediate said anode current, said means comprising a or relay station IS but that such additional ones Source Of Signals f0r said control electrode, 115 may be utilized as may be necessary and means for maintaining said cathode current virsimb1e tually constant as said anode current increases, The forms of the invention described are said 135? 1988115 D iE 811 e- Q illustrative of the principles involved, wherein mon to Sam #P and fi 9 clrcmts, fluctuations of are produced varying electron emissive surface by Said the space charge around an electron Source Of light, and means for obtaining from su f ce and the invention may take wideiy said surface a reproduction of said signals. diflerent forms without departing from the 5. The combination withanincandescent body, spirit thereof and the scope of the invention means Producing Variations m the light is to be limited only by prior art and as degiven of! by d body, Said means scribed in the following 013mm prislng means for varying the electrical charge w is claimed in the vicinity of said body, a photo-emissive 1 In a signal ystem a generator of carrier surface by and means for current, a modulating device. controlled by a @mining 15mm said Variations in signal, for controlling said generator. light emit- Pncal current cm'respmdmg to sald variaticms ting controlling means, including an electron in said light colors, a second incandescent body, emitting light source, means for controlling the means for Producing variations in light colors space charge around said source by said carrier Elven P? by 594d said last #1691115 current a light sensitive device, means for ob- R 9 rymg the charge in the taining from said device a reproduction of said f Seccmd In accordance with carrier, a second light emitting controlling Said electncal m means including a second electron emitting light 6. In an electrical circuit, an electron emitting source means for controlling the space charge light radiating source of light of a plurality of around said second light source by said reprocolors" means for changmg the predominate duction of said carrier current, a photo-emissive 00101 of t e light given oil by Sa d Source. said surface illuminated by said second light source, means comprising means v i h Sp ce and means for obtaining from said surface a ch in the v y of Said fl e. a l t reproduction of said signal. controlled device, and means for obtaining from 2. The combination with an electron emitting said device an electrical current varying in aclight source, means for producing variations in cordance with changes in the color of the light the intensity of said source, said means comgiven of! by said source, a second electron emitprising means for generating a variable voltage, ting light radiating source of a plurality of means for controlling the space charge in the colors, means for changing the predominate vicinity of said source in accordance with said color of light given off by said second source, variable voltage, and means for generating an said last means comprising means for varying 15p the energy absorbed in electron emission from said second source, said last mentioned means comprising means for varying the space charge around said second source in accordance with said electrical current, a second light controlled device, and means for obtaining from said second device a second electrical current. varying in accordance with changes in the color of light given off by said second source.
7, The combination with a source of sound modulated carrier current, an electron emitting light radiating source of light, means for producing variations in the color of said light, said means comprising means for varying the space charge around said source in accordance with ment circuit, a source of electrical energy connected in said filament circuit, a source of space current in said plate circuit, means for varying the amount of energy absorbed from said filament by said space current, said means comprising a source of signal current connected in said grid circuit, means for preventing substantial increase of filament current as said space current increases, said last means comprising a resistance common to said plate and said filament circuits, said resistance being of suflicient magnitude to prevent said increase, a photoemissive surface illuminated by energy radiated by said filament, and means for obtaining from said surface an electrical current, corresponding to said current means for translating said coloi signal current. variations into voltage variations, a second elec- 11. In a light signalling system, a vacuum ron mi in li r in source, means for 1' tube, having plate. grid, and filament circuits. a
producing variations in the color of light of said second source, said last means comprising means for varying the number of higher frequency light quanta absorbed in electron emission from said second source in accordance with said voltage variations, and means for translating said color variations of said second source into sound.
8. In a light signalling system, means for producing a signal modulated carrier current, means for producing variations in intensity of an electron emitting light radiating source of light in accordance with said current, said means comprising means for varying the space charge in the vicinity of said source of light in accordance with said current, means for impressing said light on a light sensitive surface, means for obtaining a second signal modulated carrier current from said surface corresponding to said first signal modulated carrier current, means for selecting said second carrier, means for amplifying said second carrier, means for producing variations in a second electron emitting light radiating source of light in accordance with said amplified current, said last mentioned means comprising means for varying the space charge in the vicinity of said second source of light in accordance with said amplified current, means for impressing said light from said second source on a second light sensitive surface, and means for obtaining from said second surface a reproduction of said signal.
9. In a signalling system, a generator of signal modulated carrier current, an electron emitting light radiating source of light means for producing variations in the colors given off by said source over a predetermined range, said means comprising means for varying the space charge in the vicinity of said source in accordance with said current, means for impressing said variations on a light sensitive surface, including a color filter to pass light only over said predetermined range, means for obtaining a second carrier current similar to said first carrier current from said surface, means for selecting said second carrier, means for amplifying said second carrier, a second electron emitting light radiating source of light, means for producing variations in the colors given off by said second source, said means comprising means for varying the space charge in the vicinity of said second source in accordance with said second current, means for impressing said second variations in color on a second light sensitive surface, and means for obtaining from said second surface a reproduction of said signal.
10. In a light signalling system, a vacuum tube having a plate circuit, a grid circuit, and fila source of current connected in said filament circuit, a source of space current connected in said plate circuit. means for producing variations of light quanta absorbed by said space current from said filament said means comprising means for producing variations in magnitude of said space current, said last mentioned means comprising a source of signal voltage connected in said grid circuit, means for preventing substantial increase in filament current as said space current increases, said last mentioned means comprising a resistance common to said plate and said filament circuits, said resistance being of sufficient magnitude to prevent said increase, a photo-electric device, and means for obtaining from said device a reproduction of said signal.
12. In an electric circuit, an electron emitting light radiating surface, means for producing light variations radiated by said surface, said means comprising means for varying the energy absorbed from said surface by electron emission, means for producing an electric current corresponding to said light variations, means for amplifying said electrical current, a second electron emitting light radiating surface, means for controlling the energy absorbed by electron emis- 120 sion from said second surface in accordance with said amplified current, and means for producing a second electric current in accordance with variations in light radiated by said second surface.
13. In a signalling system, a transmitting station, an electron emitting light radiating source at said transmitting station, means for producing light intensity variations in said source, said means comprising means for generating a variable voltage, means for controlling the space charge in the vicinity of said source in accordance with said variable voltage, means for directing said light variations towards a relay station. a photo-electric cell at said relay station for producing voltage variations in accordance with said light variations, a second electron emitting light radiating source at said relay station, means for producing variations in said second source, said last means comprising means for varying the light quanta absorbed from said second source in accordance with said voltage variations from said photo-electric cell, means for directing light variations from said relay 145 station towards a receiving station, and means at said receiving station for changing said light variations received from said relay station into signals.
OLIVER THOMAS FRANCIS.
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US654429A US1976120A (en) | 1933-01-31 | 1933-01-31 | Light control device |
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US654429A US1976120A (en) | 1933-01-31 | 1933-01-31 | Light control device |
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Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2515263A (en) * | 1944-02-24 | 1950-07-18 | Raibourn Paul | Communication system |
US2602886A (en) * | 1946-03-14 | 1952-07-08 | Morris H Fields | Light modulating device |
US2634366A (en) * | 1947-11-28 | 1953-04-07 | Bell Telephone Labor Inc | Light repeater for pulse communication systems |
US2892951A (en) * | 1956-07-11 | 1959-06-30 | Linderman Engineering Company | Detecting apparatus |
US2941084A (en) * | 1952-01-02 | 1960-06-14 | Fruengel Frank | Receiver for light-flash signaling system |
US3227882A (en) * | 1962-01-05 | 1966-01-04 | Bissett Berman Corp | Identification system using repetitively modulated infrared energy |
-
1933
- 1933-01-31 US US654429A patent/US1976120A/en not_active Expired - Lifetime
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2515263A (en) * | 1944-02-24 | 1950-07-18 | Raibourn Paul | Communication system |
US2602886A (en) * | 1946-03-14 | 1952-07-08 | Morris H Fields | Light modulating device |
US2634366A (en) * | 1947-11-28 | 1953-04-07 | Bell Telephone Labor Inc | Light repeater for pulse communication systems |
US2941084A (en) * | 1952-01-02 | 1960-06-14 | Fruengel Frank | Receiver for light-flash signaling system |
US2892951A (en) * | 1956-07-11 | 1959-06-30 | Linderman Engineering Company | Detecting apparatus |
US3227882A (en) * | 1962-01-05 | 1966-01-04 | Bissett Berman Corp | Identification system using repetitively modulated infrared energy |
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