US3204240A - Passive communication system - Google Patents

Passive communication system Download PDF

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US3204240A
US3204240A US216422A US21642262A US3204240A US 3204240 A US3204240 A US 3204240A US 216422 A US216422 A US 216422A US 21642262 A US21642262 A US 21642262A US 3204240 A US3204240 A US 3204240A
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microwave
radiometer
antenna
modulator
energy
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Michael W Mckay
Thomas W Odell
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General Precision Inc
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/14Relay systems
    • H04B7/145Passive relay systems

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  • microwave radiometers All objects emit electromagnetic radiation at temperatures above absolute zero, and in the case of solids and liquids the radiation spectra are continuous and cover all frequencies, including microwave frequencies. Although the amounts of radiation energy are generally small in the microwave region, this radiation can be detected and measured by sensitive microwave receivers which, when designed for this use, are commonly termed microwave radiometers.
  • the amount of microwave radiant energy emitted by an object is dependent on its temperature and on its coefficient of emissivity.
  • the microwave energy emanated from an object also includes reflected microwave energy. This energy is generated elsewhere, intercepted by the object and reflected thereby to the radiometer. The amount of this reflected energy depends on the coeflic-ient of reflectivity of the object and the temperature of the generator of the energy.
  • the magnitude of the electromagnetic energy received by a radiometer is dependent on both of these factors and is commonly described as a temperature on the Kelvin scale.
  • a temperature on the Kelvin scale When the antenna of a microwave radiometer is pointed at the sky it registers a very small amount of microwave emission, generally of the order of 30 K. at 1 cm. wavelengths. Objects on the earth, such as the terrain of a hillside, will register a larger amount of microwave radiation, usually about 300 K.
  • the present invention employs a microwave radiometer, including a narrow-beam antenna, as the receiver of a one-way microwave communication link.
  • the transmitter consists of two microwave antennas joined through a microwave waveguide in which is inserted a modulator.
  • the modulator may be of any suitable type.
  • the system is completely passive in the sense that no artific ally generated microwave energy is required at any time although in those instances in which telephonic modulation is utilized a direct current or low frequency power source may be required at the transmitter location.
  • the modulating signal may be telegraphic, telephonic, or of any other character provided that the system time constants are suitable for the frequencies to be transmitted.
  • the radiometer antenna In preparing to operate over a distance of several hundred yards, the radiometer antenna is pointed in the direction of the transmitter, and at the transmitter one of its antennas is aimed at the radiometer antenna. The other transmitter antenna is pointed at the sky.
  • the waveguide and modulator connects two transmitter antennas together, the 30 K. microwave energy amplitude picked up by the antenna pointed to the sky is transmitted through the waveguide to the other antenna pointed at the radiometer.
  • the modulator is caused to interrupt this waveguide transmission, the antenna pointed at the radiometer is provided with some other amount of microwave energization, for example, an intensity characterized as 300 K.
  • the narrow radiometer receiving beam is pointed at an area and, in the absence of the transmitter, registers a microwave radiation intensity of about 300 K.
  • the transmitting .sky antenna transfersits 30 K. intensity to the other transmitting antenna, the radiometer perceives a 3,2 4,240 Patented Aug. 31, 1965 lowered average intensity in the area intercepted by the receiving beam, and registers this intensity.
  • the transmitting antenna signal is then modulated by a suitable intelligence and this modulated signal is received at the radiometer.
  • Two-way communication can be efiected by providing two links, each similar to that described, with some parts in common, as for example, the temperature reference 17 might be the same as the sky directed antenna 34, etc.
  • An object of this invention is to provide electrical communication between two points by utilizing the sensitivity of a microwave radiometer to the spontaneous generation of microwave energy by any object within its field.
  • Another object of this invention is to provide a system for secret communication between two points employing no transmitter carrier power beyond the electromagnetic radiation spontaneously generated by all solid and liquid objects.
  • Still another object of this invention is to provide oneway telegraphic or telephonic communication with the only electrical power supplies located at the receiver and without the radiation of artificially generated radiation at either receiver or transmitter.
  • FIGURE 1 is a functional schematic diagram of an embodiment of the invention.
  • FIGURE 2 is a view of a form of waveguide modulator suitable for use in the invention.
  • a microwave radiometer includes a dish antenna 11 and the components. connected to it.
  • the diameter of antenna 11 is such as to provide a receiving beam of about one degree diameter.
  • the signal received by antenna 11 is applied through a wave guide 12 to a modulator 13 to which the output of an oscillator 14 is also applied.
  • the frequency of this oscillator may be, for example, 100 c.p.s., which is high enough to permit use of an information signal frequency of 40 c.p.s.
  • telegraphic signals are to be transmitted at a speed not higher than about 100 words per minute.
  • the modulator 13 performs the function of a singlepole double-throw switch, switching the output waveguide 16 either to the antenna waveguide 12 or to a noise reference 17.
  • This reference may consist of a resistor maintained at a suitable temperature or may consist of an active noise source, such as an electronicdischarge tube, together with a suitable attenuator.
  • the waveguide 16 is connected to a balanced mixer 18 also receiving the output of a local microwave oscillator 19 having a frequency in the microwave band in which it is desired to operate.
  • the mixer output is applied to a wideband intermediate frequency amplifier 21.
  • This amplifier may have, for example, a center frequency of 600 m.c.p.s. and a bandwidth of 300 m.c.p.s.
  • the output is applied to an amplitude detector 22 having such time constant as to permit the 100 c.p.s. modulating frequency to appear in the output.
  • This output is filtered in a band filter 23 centered at 100 c.p.s. and having a bandwidth of approximately cycles per second.
  • phase detector 26 Referenced to the oscillator 14.
  • the output is connected to an adding circuit 29 for the purpose of adding direct current bias from conductor 31 having for its purpose the maintenance of a selected range of output potential values and also to prevent overloading of the output indicator 32.
  • This indicator may be a galvanometer, a telegraph printer, an ink recorder, a sounder, or any other form of telegraphic code receiving instrument.
  • this radiometer is obvious and is well known. Its design and operation are based on the work of R. H. Dicke as described in The Measurement of Thermal Radiation at Microwave Frequencies, published in The Review of Scientific Instruments for July 1946, on pages 268-275. Other radiometer configurations may also be used as will be apparent to one skilled in the art.
  • the antenna 11 and all which are transmittable by the Waveguide 12 are applied to the modulator 13.
  • the signal is of the nature of very wideband noise.
  • This signal is alternated with that from another source 17, having a different noise temperature, at the 100 c.p.s. rate in modulator 13.
  • the alternated noise signal is heterodyned by the local oscillator 19, and the sidebands accepted by the amplifier 21 consist of the sum of two bands, originating at two frequency locations above and below the local oscillator frequency and separated from it by the amount of the intermediate amplifier center frequency. At each of these locations a 300-mc.-wide section of the input noise signal is utilized.
  • the amplified intermediate frequency signal is rectified in the detector 22 and the resulting 100 c.p.s. signal is filtered by the filter 23.
  • the output is phase shifted to secure maximum efficiency of synchronous detection in the phase detector 26, resulting in a direct current signal in conductor 27 containing the information signal. Noise variations are further removed in the integrator 28, bias is added in the sum circuit 29, and the signal is indicated by the indicator 32.
  • the transmitting end of the communications link includes two microwave antennas 33 and 34.
  • the antenna 34 is joined by a waveguide 36 to one terminal of a modulator 37.
  • Another microwave terminal of the modulator is joined by a waveguide 38 to the antenna 33.
  • a microphone or other type of intelligence signal generator 39 is connected to operate the modulator 37.
  • the modulator 37 may be of any type which can be inserted in a waveguide and which is capable of modulating microwave energy.
  • some form of on-otf switch is suitable such as, for examle, that described in Patent Number 2,960,539.
  • any of the common forms of ferrite modulators may be suitable such as, for example, the type described in Patent Number 2,983,883.
  • FIGURE 2 depicts a simple modulator which may be employed as the modulator 37, FIGURE 1. It is a flap attenuator which has an absorbing graphite card, 41, pivoted to enter a slot 42 in one broad face of a waveguide 43. The card 41 is held out of the slot by a ten sion spring 44. Pressure of the finger on the rod 46, depressing the card, causes substantially complete attenuation of microwave energy passing through the Waveguide and movement of the card can modulate the microwave energy in the telegraph code.
  • the signal generator 39, FIGURE 1 is replaced by operator manipulation and the transmitter is not only passive in the sense of not transmitting any artificially generated microwave energy but also in the sense of not requiring the use of any electrical sources.
  • the radiometer In the operation of the passive communication system the radiometer is trained on a hillside, forest, or other terrain feature at a range of, say, 300 yards. Its onedegree beam spans an area at that range having a diameter of about 15 feet and an area of about 177 square feet. The microwave energy received by the radiometer from this terrain area results in an indication of the indicator 32 representing a microwave energy of about 300 K.
  • the transmitting antenna 33 having, for example, an effective area of one square foot, is positioned in the beam and aimed at the radiometer antenna 11.
  • the antenna 34 is aimed at the sky and the modulator 37 is adjusted to transmit microwave energy between the antennas 33 and 34.
  • the radiometer now perceives less than 300 K.
  • the temperature change, AT being Such a temperature change is readily perceptible by even a moderately sensitive radiometer.
  • the modulator 37 is now changed to interrupt the connection between the antennas 33 and 34, and the temperature of the antenna 33 now perceived is that of the resistive card 41, about 300' K. and indistinguishable from that of the terrain perceived by the rest of the beam.
  • the radiometer perceives two different average temperatures, depending on which of the two positions which the card 41 has, in or out of the waveguide, and the radiometer indicator 32 exhibits two different corresponding indications.
  • code communication can be effected from the transmitter to the radiometer.
  • a passive communication system comprising,
  • a first radiant electromagnetic energy sensing member connected to said input terminal, said member sensing radiation from a selected delimited terrestrial area
  • a second radiant electromagnetic energy sensing member therein, said second member being directed toward a selected celestial area emitting a low level of electromagnetic radiation
  • a passive communication system comprising,
  • a radiometer having input and output terminals and constituting a receiving member
  • a first electromagnetic radiant energy sensing element connected to said input terminal, said element having a narrow beam sensing radiation from a selected delimited area on the surface of this earth,
  • a passive communication system comprising,
  • a radiometer for operating in a selected frequency range having input and output terminals and constituting a communication receiving member
  • a first electromagnetic radiant energy sensing element connected to said input terminal, said element having a narrow beam sensing radiation in said selected frequency range from a selected delimited area on the surface of this earth,
  • a second electromagnetic radiant energy sensing element incorporated in said transmitting member, said second element being pointed toward a selected celestial area emitting a low level of electromagnetic radiation in said selected frequency range
  • an electromagnetic energy radiating element incorporated in said transmitting member, said radiating element being pointed to radiate toward said first sensing element and the latter being directed to sense the radiations produced by said radiating element
  • a passive communication system comprising,
  • a radiometer for operating in the microwave frequency range and having input and output terminals
  • a first microwave narrow-beam antenna connected to said input terminal, said antenna being aimed to sense microwave radiation from a selected, delimited area of the surface of the earth, said radiometer, indicator and first antenna constituting a communication signal receiving member,
  • a second microwave antenna incorporated therein, said second antenna being directed toward a selected celestial area emitting a low level of microwave radiation
  • a third microwave antenna included in said transmitting member said third antenna being positioned in the beam of said first antenna and aimed thereat,

Description

Aug. 31, 1965 M. w. MGKAY ETAL 3,204,240
PASSIVE COMMUNICATION SYSTEM Filed Aug. 15, 1962 33 MOD SIGNAL GEN 38 C [7 REF I6 '8 2| yzz 23 24 C:
, r Y x n BAL AMPLITUDE k NB 8 MOD U MIX DET FILTER IFT 27 29 32 r S INTEGRATOR DET |4 L26 2s: 3|
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INVENTOR. MICHAEL w. McKAY THOMAS w. ODELL ATTORNEY.
United States Patent 3,204,240 PASSIVE COMMUNICATION SYSTEM Michael McKay, Tarrytown, and Thomas W. Odell, Pearl River, N .Y., assignors to General Precision, Inc., a corporation of Delaware Filed Aug. 1'3, 1962, Ser. No. 216,422 4 Claims. (Cl. 343'100) This invention relates to microwave systems for pointto-point communication.
All objects emit electromagnetic radiation at temperatures above absolute zero, and in the case of solids and liquids the radiation spectra are continuous and cover all frequencies, including microwave frequencies. Although the amounts of radiation energy are generally small in the microwave region, this radiation can be detected and measured by sensitive microwave receivers which, when designed for this use, are commonly termed microwave radiometers.
The amount of microwave radiant energy emitted by an object is dependent on its temperature and on its coefficient of emissivity. The microwave energy emanated from an object also includes reflected microwave energy. This energy is generated elsewhere, intercepted by the object and reflected thereby to the radiometer. The amount of this reflected energy depends on the coeflic-ient of reflectivity of the object and the temperature of the generator of the energy.
The magnitude of the electromagnetic energy received by a radiometer is dependent on both of these factors and is commonly described as a temperature on the Kelvin scale. When the antenna of a microwave radiometer is pointed at the sky it registers a very small amount of microwave emission, generally of the order of 30 K. at 1 cm. wavelengths. Objects on the earth, such as the terrain of a hillside, will register a larger amount of microwave radiation, usually about 300 K.
The present invention employs a microwave radiometer, including a narrow-beam antenna, as the receiver of a one-way microwave communication link. The transmitter consists of two microwave antennas joined through a microwave waveguide in which is inserted a modulator. The modulator may be of any suitable type. The system is completely passive in the sense that no artific ally generated microwave energy is required at any time although in those instances in which telephonic modulation is utilized a direct current or low frequency power source may be required at the transmitter location. The modulating signal may be telegraphic, telephonic, or of any other character provided that the system time constants are suitable for the frequencies to be transmitted.
In preparing to operate over a distance of several hundred yards, the radiometer antenna is pointed in the direction of the transmitter, and at the transmitter one of its antennas is aimed at the radiometer antenna. The other transmitter antenna is pointed at the sky. Thus, when the waveguide and modulator connects two transmitter antennas together, the 30 K. microwave energy amplitude picked up by the antenna pointed to the sky is transmitted through the waveguide to the other antenna pointed at the radiometer. When, however, the modulator is caused to interrupt this waveguide transmission, the antenna pointed at the radiometer is provided with some other amount of microwave energization, for example, an intensity characterized as 300 K.
In operation, the narrow radiometer receiving beam is pointed at an area and, in the absence of the transmitter, registers a microwave radiation intensity of about 300 K. However, when the transmitter is located at the are encompassed by the receiving beam and the transmitting .sky antenna transfersits 30 K. intensity to the other transmitting antenna, the radiometer perceives a 3,2 4,240 Patented Aug. 31, 1965 lowered average intensity in the area intercepted by the receiving beam, and registers this intensity. The transmitting antenna signal is then modulated by a suitable intelligence and this modulated signal is received at the radiometer.
Two-way communication can be efiected by providing two links, each similar to that described, with some parts in common, as for example, the temperature reference 17 might be the same as the sky directed antenna 34, etc.
An object of this invention is to provide electrical communication between two points by utilizing the sensitivity of a microwave radiometer to the spontaneous generation of microwave energy by any object within its field.
Another object of this invention is to provide a system for secret communication between two points employing no transmitter carrier power beyond the electromagnetic radiation spontaneously generated by all solid and liquid objects.
Still another object of this invention is to provide oneway telegraphic or telephonic communication with the only electrical power supplies located at the receiver and without the radiation of artificially generated radiation at either receiver or transmitter.
A further understanding of this invention will be secured from the detailed description and drawings in which:
FIGURE 1 is a functional schematic diagram of an embodiment of the invention.
FIGURE 2 is a view of a form of waveguide modulator suitable for use in the invention.
Referring now to FIGURE 1, a microwave radiometer includes a dish antenna 11 and the components. connected to it. The diameter of antenna 11 is such as to provide a receiving beam of about one degree diameter. The signal received by antenna 11 is applied through a wave guide 12 to a modulator 13 to which the output of an oscillator 14 is also applied. The frequency of this oscillator may be, for example, 100 c.p.s., which is high enough to permit use of an information signal frequency of 40 c.p.s. As an example of use, telegraphic signals are to be transmitted at a speed not higher than about 100 words per minute.
The modulator 13 performs the function of a singlepole double-throw switch, switching the output waveguide 16 either to the antenna waveguide 12 or to a noise reference 17. This reference may consist of a resistor maintained at a suitable temperature or may consist of an active noise source, such as an electronicdischarge tube, together with a suitable attenuator.
The waveguide 16 is connected to a balanced mixer 18 also receiving the output of a local microwave oscillator 19 having a frequency in the microwave band in which it is desired to operate. The mixer output is applied to a wideband intermediate frequency amplifier 21. This amplifier may have, for example, a center frequency of 600 m.c.p.s. and a bandwidth of 300 m.c.p.s. The output is applied to an amplitude detector 22 having such time constant as to permit the 100 c.p.s. modulating frequency to appear in the output. This output is filtered in a band filter 23 centered at 100 c.p.s. and having a bandwidth of approximately cycles per second. Its output is applied to a manually adjustable phase shifter 24 and its output is in turn applied to a phase detector 26 referenced to the oscillator 14. The direct-current output in conductor 27 of the phase detector 26, upon which is superimposed the communication signal, is applied to a smoothing filter 28. The output is connected to an adding circuit 29 for the purpose of adding direct current bias from conductor 31 having for its purpose the maintenance of a selected range of output potential values and also to prevent overloading of the output indicator 32. This indicator may be a galvanometer, a telegraph printer, an ink recorder, a sounder, or any other form of telegraphic code receiving instrument.
The operation of this radiometer is obvious and is well known. Its design and operation are based on the work of R. H. Dicke as described in The Measurement of Thermal Radiation at Microwave Frequencies, published in The Review of Scientific Instruments for July 1946, on pages 268-275. Other radiometer configurations may also be used as will be apparent to one skilled in the art.
Briefly, a very wide range of electromagnetic frequencies is picked up by the antenna 11 and all which are transmittable by the Waveguide 12 are applied to the modulator 13. The signal is of the nature of very wideband noise. This signal is alternated with that from another source 17, having a different noise temperature, at the 100 c.p.s. rate in modulator 13. In the mixer 18 the alternated noise signal is heterodyned by the local oscillator 19, and the sidebands accepted by the amplifier 21 consist of the sum of two bands, originating at two frequency locations above and below the local oscillator frequency and separated from it by the amount of the intermediate amplifier center frequency. At each of these locations a 300-mc.-wide section of the input noise signal is utilized. The amplified intermediate frequency signal is rectified in the detector 22 and the resulting 100 c.p.s. signal is filtered by the filter 23. The output is phase shifted to secure maximum efficiency of synchronous detection in the phase detector 26, resulting in a direct current signal in conductor 27 containing the information signal. Noise variations are further removed in the integrator 28, bias is added in the sum circuit 29, and the signal is indicated by the indicator 32.
The transmitting end of the communications link includes two microwave antennas 33 and 34. The antenna 34 is joined by a waveguide 36 to one terminal of a modulator 37. Another microwave terminal of the modulator is joined by a waveguide 38 to the antenna 33. A microphone or other type of intelligence signal generator 39 is connected to operate the modulator 37.
The modulator 37 may be of any type which can be inserted in a waveguide and which is capable of modulating microwave energy. For telegraph dot frequencies some form of on-otf switch is suitable such as, for examle, that described in Patent Number 2,960,539. For voice frequencies any of the common forms of ferrite modulators may be suitable such as, for example, the type described in Patent Number 2,983,883.
FIGURE 2 depicts a simple modulator which may be employed as the modulator 37, FIGURE 1. It is a flap attenuator which has an absorbing graphite card, 41, pivoted to enter a slot 42 in one broad face of a waveguide 43. The card 41 is held out of the slot by a ten sion spring 44. Pressure of the finger on the rod 46, depressing the card, causes substantially complete attenuation of microwave energy passing through the Waveguide and movement of the card can modulate the microwave energy in the telegraph code. In this case the signal generator 39, FIGURE 1, is replaced by operator manipulation and the transmitter is not only passive in the sense of not transmitting any artificially generated microwave energy but also in the sense of not requiring the use of any electrical sources.
Such an attenuator, here used as a switch, is described in Patent Number 2,591,329.
In the operation of the passive communication system the radiometer is trained on a hillside, forest, or other terrain feature at a range of, say, 300 yards. Its onedegree beam spans an area at that range having a diameter of about 15 feet and an area of about 177 square feet. The microwave energy received by the radiometer from this terrain area results in an indication of the indicator 32 representing a microwave energy of about 300 K. The transmitting antenna 33 having, for example, an effective area of one square foot, is positioned in the beam and aimed at the radiometer antenna 11. The antenna 34 is aimed at the sky and the modulator 37 is adjusted to transmit microwave energy between the antennas 33 and 34. The radiometer now perceives less than 300 K. temperature because of the cooler antenna 33 area, the temperature change, AT, being Such a temperature change is readily perceptible by even a moderately sensitive radiometer. The modulator 37 is now changed to interrupt the connection between the antennas 33 and 34, and the temperature of the antenna 33 now perceived is that of the resistive card 41, about 300' K. and indistinguishable from that of the terrain perceived by the rest of the beam. Thus the radiometer perceives two different average temperatures, depending on which of the two positions which the card 41 has, in or out of the waveguide, and the radiometer indicator 32 exhibits two different corresponding indications. Thus code communication can be effected from the transmitter to the radiometer.
It i obvious that the several electrical components of the transmitter and of the radiometer which introduce delays, have modulating frequency limits or which possess time constants must be designed for the transmission of the desired upper limit of communication frequencies. These components include the modulator 37, modulator 13, oscillator 14 and the integrator 28.
What is claimed is:
1. A passive communication system comprising,
a radiometer having input and output terminals,
a first radiant electromagnetic energy sensing member connected to said input terminal, said member sensing radiation from a selected delimited terrestrial area,
transmitting means,
a second radiant electromagnetic energy sensing member therein, said second member being directed toward a selected celestial area emitting a low level of electromagnetic radiation,
an electromagnetic energy radiating member in said transmitting means,
an electromagnetic energy transfer path interconnecting said second sensing member and said radiating member and transmitting energy therebetween,
and modulating means inserted in said transfer path having an intelligence signal applied thereto.
2. A passive communication system comprising,
a radiometer having input and output terminals and constituting a receiving member,
a first electromagnetic radiant energy sensing element connected to said input terminal, said element having a narrow beam sensing radiation from a selected delimited area on the surface of this earth,
a transmitting member,
a second electromagnetic radiant energy sensing el ment therein, said second element being directed toward a selected celestial area emitting a lower level of electromagnetic radiation,
an electromagnetic energy radiating element in said transmitting member pointed toward said first sensing element and positioned in the beam thereof,
an electromagnetic energy transfer path interconnecting said second sensing element and said radiating element,
a modulator inserted in said electromagnetic energy transfer path,
and communication signal generating means connected to operate said modulator for modulating electromagnetic energy transferred from said second sensing element through said transfer path to said radiating element in accordance with the intelligence information contained in said communication signal whereby said communication signal modulation is sensed by said radiometer receiving member and appears on the output terminal thereof.
3. A passive communication system comprising,
a radiometer for operating in a selected frequency range having input and output terminals and constituting a communication receiving member,
a first electromagnetic radiant energy sensing element connected to said input terminal, said element having a narrow beam sensing radiation in said selected frequency range from a selected delimited area on the surface of this earth,
a communication transmitting member for operating in said selected frequency range,
a second electromagnetic radiant energy sensing element incorporated in said transmitting member, said second element being pointed toward a selected celestial area emitting a low level of electromagnetic radiation in said selected frequency range,
an electromagnetic energy radiating element incorporated in said transmitting member, said radiating element being pointed to radiate toward said first sensing element and the latter being directed to sense the radiations produced by said radiating element,
an electromagnetic energy transfer path interconnecting said second sensing element and said radiating element,
a modulator inserted in said transfer path,
an indicator connected to said output terminal,
and communication signal generating means connected to operate said modulator for modulating electromagnetic energy passed therethrough from said second sensing element to said radiating element whereby said communication signal is sensed by said radiometer receiving member and is indicated by said indicator.
4. A passive communication system comprising,
a radiometer for operating in the microwave frequency range and having input and output terminals,
an indicator connected to said output terminal,
a first microwave narrow-beam antenna connected to said input terminal, said antenna being aimed to sense microwave radiation from a selected, delimited area of the surface of the earth, said radiometer, indicator and first antenna constituting a communication signal receiving member,
a communication signal transmitting member for operating at microwave frequencies,
a second microwave antenna incorporated therein, said second antenna being directed toward a selected celestial area emitting a low level of microwave radiation,
a third microwave antenna included in said transmitting member, said third antenna being positioned in the beam of said first antenna and aimed thereat,
a waveguide section interconnecting said second and third antennas,
a modulator of microwave energy inserted in said waveguide section,
and communication signal generating means connected to operate said modulator for modulating the microwave energy passing therethrough from said second antenna to the said third antenna.
References Cited by the Examiner UNITED STATES PATENTS Re. 23,295 11/50 Liston 25083.3 1,379,166 5/21 Case 250-833 2,428,713 10/47 Lindberg et al 25083.3 2,546,984 4/51 Deloraine et al. 343- 3,065,352 11/62 McFarlane 250-199 3,129,330 4/64 Seling 343100 OTHER REFERENCES Klass, P. 1.: Passive Radar Gives Infrared Technique at CHESTER L. JUSTUS, Primary Examiner.

Claims (1)

1. A PASSIVE COMMUNICATION SYSTEM COMPRISING, A RADIOMETER HAVING INPUT AND OUTPUT TERMINALS, A FIRST RADIANT ELECTROMAGNETIC ENERGY SENSING MEMBER CONNECTED TO SAID INPUT TERMINAL, SAID MEMBER SENSING RADIATION FROM A SELECTED DELIMITED TERRESTRIAL AREA, TRANSMITTING MEANS, A SECOND RADIANT ELECTROMAGNETIC ENERGY SENSING MEMBER THEREIN, SAID SECOND MEMBER BEING DIRECTED TOWARD A SELECTED CELESTIAL AREA EMITTING A LOW LEVEL OF ELECTROMAGNETIC RADIATION, AN ELECTROMAGNETIC ENERGY RADIATING MEMBER IN SAID TRANSMITTING MEANS, AN ELECTROMAGNETIC ENERGY TRANSFER PATH INTERCONNECTING SAID SECOND SENSING MEMBER AND SAID RADIATING MEMBER AND TRANSMITTING ENERGY THEREBETWEEN, AND MODULATING MEANS INSERTED IN SAID TRANSFER PATH HAVING AN INTELLIGENCE SIGNAL APPLIED THERETO.
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Cited By (4)

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US3470477A (en) * 1966-08-05 1969-09-30 Communications Satellite Corp Communication system having a multiple-access,man-made satellite
US3617898A (en) * 1969-04-09 1971-11-02 Eugene A Janning Jr Orthogonal passive frequency converter with control port and signal port
US3653045A (en) * 1970-06-03 1972-03-28 Sperry Rand Corp Radiometer modulator-demodulator system
GB2143035A (en) * 1983-07-11 1985-01-30 Marconi Avionic Limited Tyre temperature measurement apparatus

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US2428713A (en) * 1942-05-18 1947-10-07 Jr John E Lindberg Signalling system
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USRE23295E (en) * 1950-11-21 Tjxxted h heat
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US2428713A (en) * 1942-05-18 1947-10-07 Jr John E Lindberg Signalling system
US2546984A (en) * 1947-04-02 1951-04-03 Int Standard Electric Corp Communication system
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