US2653220A - Electromagnetic wave transmission system - Google Patents

Electromagnetic wave transmission system Download PDF

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US2653220A
US2653220A US122803A US12280349A US2653220A US 2653220 A US2653220 A US 2653220A US 122803 A US122803 A US 122803A US 12280349 A US12280349 A US 12280349A US 2653220 A US2653220 A US 2653220A
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transmitter
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Carl A Bays
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B13/00Transmission systems characterised by the medium used for transmission, not provided for in groups H04B3/00 - H04B11/00
    • H04B13/02Transmission systems in which the medium consists of the earth or a large mass of water thereon, e.g. earth telegraphy

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  • This invention relates generally to the transmission of electromagnetic and radio waves, and particularly to the transmission of such waves from point to point by utilizing solids of high electrical resistivity, as compared with the resistivity of metals.
  • One object of this invention is to provide means for transmitting and receiving electromagnetic waves without reliance upon the ether or upon metallic conductors connecting the loci of transmission and reception.
  • Another object is to provide cheap and simple means for transmitting electromagnetic waves.
  • This invention is predicated upon the discovery that certain lithologic formations which have a high order of electrical resistivity and are bounded, above and below, by formations of lower electrical resistivity, may be made to transmit electromagnetic waves laterally over great distances.
  • Such formations as limestone and quartzite, bounded by shales, sandstones containing saline water, and the like, are particularly suitable.
  • Such electromagnetic waves are guided through the formation of high electrical resistivity by the boundary formations of lower electrical resistivity, acting as imperfect conductors.
  • lithologic formations of high resistivity and strata of high resistivity refer to formations whose electrical resistivity is sufficiently higher, relative to the formations which oppositely bound it, that the selected formation or stratum acts as a guided wave transmitting medium.
  • the limestone bed known variously as the Galena Platteville formation (in the Chicago area), the Trenton (in the neighborhood of Cincinnati), and the Kimmswick (in the vicinity of St. Louis), for example, extends from the Mohawk Valley to Montana, and from Canada to Texas. Faults, folds, and stratigraphic facies changes in such formations which might make them discontinuous may be bridged by means of electrodes or by means of an intermediate receiver-transmitter system, as is later explained.
  • Figure 1 is a diagrammatic view of a transmitter-receiver system
  • Figure 2 is a diagrammatic view showing the use of an exterior antenna for introducing the waves into an exposed stratum of high resistivity
  • Figure 3 is a diagrammatic view of a transmitter-receiver system showing one method of bridging separated lithologic formations, by means of an electrode;
  • electromagnetic waves generated by a transmitter are introduced into a selected lithologic formation, and are transmitted laterally through said formation to a receiver.
  • the waves may be introduced into the formation in a number of ways. At outcrops of the particular formation through which transmission is to be accomplished, the waves may be directed from an antenna, above or at the surface of the ground, or may be directly coupled to the formation at the ground surface.
  • the propagator may take the form of a plug or plugs of a suitable material such as salt water, lead wool, copper or other metal either dispersed in concrete or plastic or in solid form, and the like, embedded in the formation and connected to the transmitter by a suitable conductor such as coaxial cable, a. single conductor or a twisted pair.
  • a suitable conductor such as coaxial cable, a. single conductor or a twisted pair.
  • the composition and dimensions of a conductor and propagating plug depend upon the frequencies to be transmitted, the impedance of the transmitter, and primarily on the impedance characteristics of the lithologic formation, which depend upon the physical characteristics such as shape, minimum cross-section and fluid content of the formation itself, and also on its boundary conditions and the characteristics of the overlying and underlying formations.
  • the impedance of the transmitters propagating plug and the receivers terminating plug are matched as nearly as possible to the impedance characteristics of the formation between the loci of transmission and reception.
  • the output impedance of the transmitter and the input impedance of the receiver and their respective conductors are matched to their respective plugs. t is apparent that impedance matching may also be utilized as a means of determining the impedance of a particular formation between two points in the formation.
  • Discontinuities in a formation may be bridged in any of several ways.
  • a receiver-transmitter system is especially desirable where the characteristics of the formations to be joined differ.
  • electromagnetic waves from the original transmitter, transmitted in the first formation are picked up by a receiving system the impedance of which is matched as well as can be to the impedance of the formation to which the receiver is connected, and are fed to a transmitter connected with the second formation, to which the impedance of the second transmitter, its conductor and plug, are matched.
  • the impedance of a receiver from the second formation is, of course, matched to the second formation.
  • two formations may be connected by a conducting electrode bridge.
  • Boreholes may be drilled, or trenches dug, connecting the two formations, which boreholes or trenches may be filled with materials of the character suggested for propagating and terminating plugs, the dimensions of which and characteristics of which will be determined by the impedance of the formations sought to be connected.
  • i represents a transmitter connected to lithologic formation 2 by means of a conductor 3 and propagating plug 4.
  • Transmitter l and receiver 1 are of the types generally used for the transmission and reception of ordinary broadcast, frequency modulated, or television waves.
  • Formation 2 is bounded by lithologically distinct formations 8.
  • the selected formation 2 outcrops at a face 9. Electromagnetic waves are directed into the face 9 from antenna In. It is understood that waves introduced into a formation by means of a propagating plug may be received by means of an external antenna, or that waves introduced by an external antenna may be received by means of an external antenna, the external antennae being directed toward the selected formation.
  • a discontinuity in formation 2 is bridged by means of electrode I I
  • the electrode l I may be made of copper or other conducting metal, either dispersed in concrete or in plastic, or in solid form, lead wool, salt water, or, when made of comparable dimensions with the two formations being bridged, of concrete or other rocklike material.
  • the discontinuity of Figure 3 is bridged by means of intermediate receiver l2, connected with intermediate transmitter [3, by a conventional conductor or aerial transmission-reception system,
  • the present invention provides means for transmitting electromagnetic waves without the use of towering aerials, without the use of coaxial cable or other metallic conductors joining the transmitter and ultimate receiver, unlimited as to distance by the curvature of the earths surface, with comparatively cheap, simple, sturdy, propagating equipment and an almost indestructible transmitting medium.
  • a wave transmission-reception system comprising transmitter means, receiver means, conductors connecting each of said means to a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity, the impedance of the said lithogolic stratum of high resistivity between the loci of connection with said means being matched by the impedance of said conductors.
  • a wave transmission-reception system comprising transmitter means, a propagating plug embedded in a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity and connected to said transmitter means by a conductor, receiver means, a terminating plug imbedded in said lithologic stratum of high resistivity at a distance from said propagating plug and connected to said receiving means by a conductor, the impedance of said propagating plug and said terminating plug matching the impedance of said lithologic stratum of high resistivity intermediate the said plugs.
  • a wave transmission-reception system comprising transmitter means, an antenna above the earth connected to said transmitter means and directed toward an exposed lithologic stratum of high resistivity bounded by lithologic strata of greater conductivity, receiver means, a terminating plug the impedance of which matches that of the said lithologic stratum of high resistivity between the loci of transmission and reception, and a conductor connecting said terminating plug with said receiving means.
  • a wave transmission-reception system comprising transmitter means, a propagating plug embedded in a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity and connected to said transmitter means by a conductor, receiver means, a terminating plug embedded in said lithologic stratum of high resistivity at a distance from said propagating plug and connected to said receiving means by a conductor, the impedance of said terminating plug matching the impedance of said lithologic stratum of high resistivity intermediate said terminating and said propagating plugs.
  • a wave transmission-reception system comprising transmitter means, a propagating plug embedded in a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity and connected to said transmitter means by a conductor, receiver means, and an antenna above the earth directed toward said lithologic stratum of high resistivity and connected to said receiver means.
  • a wave transmission-reception system comprising transmitter means, a conductor directly coupled to an outcrop of a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity and connected to said transmitter means, receiver means, a terminating plug embedded in said lithologic stratum of high resistivity at a distance from said direct coupling and connected to said receiving means by a conductor, the impedance of said terminating plug matching the impedance of said lithologic stratum of high resistivity intermediate said terminating plug and said direct coupling.
  • a wave transmission-reception system comprising transmitter means, means for introducing electro-magnetic waves from said transmitter inma single uniform lithologic stratum bounded on either side by formations of such greater conductivity as to form with said lithologic stratum a guided wave transmitting medium, and means for receiving said waves from said lithologic stratum.
  • a wave transmission-reception system comprising first transmitter means, first receiver means, conductors connecting each of said first means to a first single lithologic stratum bounded on either side by formations of such greater conductivity as to form, in eifect, a wave guide, a second transmitter means, a second receiver means, conductors connecting each of said second means to a second single lithologic stratum bounded on either side by formations of such greater conductivity as to form, in effect, a wave guide, and conductors connecting said first receiv- 1' means with said second transmitter means.
  • a wave transmission-reception system c prising transmitter means means, means for introducing electro-magnetic waves from said transmitter into a first lithologic stratum of high resistivity bounded on either side by formations of such greater conductivity as to form, in efiect, a wave guide, and means for receiving said waves from a second lithologic stratum of high resistivity bounded on either side by formations of such greater conductivity as to form, in effect, a wave guide, said first and second lithologic stratums being connected by a conducting electrode bridge.

Description

- Filed Oct. 21, 1949 SEARCH ROUM Sept. 22, 1953 c. A. BAYS 1 2,653,220
ELECTROMAGNETIC WAVE TRANSMISSION SYSTEM v 2 Sheets-Sheet l ATTORNEYS- Sept. 22, 1953 c.'A. BAYS ELECTROMAGNETIC WAVE TRANSMISSION SYSTEM Filed 001;. 21, 1949 2 Sheets-Sheet 2 Patented Sept. 22, 1953 ELECTROMAGNETIC WAVE TRANSMISSION SYSTEM Carl A. Bays, Urbana, Ill.
Application October 21, 1949, Serial No. 122,803
This invention relates generally to the transmission of electromagnetic and radio waves, and particularly to the transmission of such waves from point to point by utilizing solids of high electrical resistivity, as compared with the resistivity of metals.
Systems heretofore employed for the transmission of electromagnetic waves, especially of radio waves of broadcast and lower (under 100 kc.) frequencies and electromagnetic waves of the high frequencies used in television and frequency modulation transmission, have either propagated those waves through the ether or transmitted them through some metallic conductor. When the ether is used, the aerial systems required are expensive and cumbersome, and particularly at the higher frequencies, their effective transmitting distance is limited. Metallic conductors have serious disadvantages, among which is their high cost. Television frequencies require coaxial cable or its equivalent, which is even more expensive and difficult to handle than ordinary wire.
One object of this invention is to provide means for transmitting and receiving electromagnetic waves without reliance upon the ether or upon metallic conductors connecting the loci of transmission and reception.
Another object is to provide cheap and simple means for transmitting electromagnetic waves.
Other objects will become apparent when the following description is read in connection with the drawings.
This invention is predicated upon the discovery that certain lithologic formations which have a high order of electrical resistivity and are bounded, above and below, by formations of lower electrical resistivity, may be made to transmit electromagnetic waves laterally over great distances. Such formations as limestone and quartzite, bounded by shales, sandstones containing saline water, and the like, are particularly suitable. Such electromagnetic waves are guided through the formation of high electrical resistivity by the boundary formations of lower electrical resistivity, acting as imperfect conductors. The phrases lithologic formations of high resistivity and strata of high resistivity, as used hereafter in the specification and claims, refer to formations whose electrical resistivity is sufficiently higher, relative to the formations which oppositely bound it, that the selected formation or stratum acts as a guided wave transmitting medium. The bounding lithologic for- 10 Claims. (Cl. 250--3) and power loss or attenuation. Formations of high resistivity are thus doubly valuable, being less subject to stray electrical currents, and having a high transmissive value. Suitable lithologic formations extend more or less continuously through great areas of this country. The limestone bed, known variously as the Galena Platteville formation (in the Chicago area), the Trenton (in the neighborhood of Cincinnati), and the Kimmswick (in the vicinity of St. Louis), for example, extends from the Mohawk Valley to Montana, and from Canada to Texas. Faults, folds, and stratigraphic facies changes in such formations which might make them discontinuous may be bridged by means of electrodes or by means of an intermediate receiver-transmitter system, as is later explained.
In the accompanying drawings:
Figure 1 is a diagrammatic view of a transmitter-receiver system;
Figure 2 is a diagrammatic view showing the use of an exterior antenna for introducing the waves into an exposed stratum of high resistivity;
Figure 3 is a diagrammatic view of a transmitter-receiver system showing one method of bridging separated lithologic formations, by means of an electrode; and
Figure 4 is a view showing another method of bridging the fault shown in Figure 3.
In accordance with this invention, electromagnetic waves generated by a transmitter are introduced into a selected lithologic formation, and are transmitted laterally through said formation to a receiver. The waves may be introduced into the formation in a number of ways. At outcrops of the particular formation through which transmission is to be accomplished, the waves may be directed from an antenna, above or at the surface of the ground, or may be directly coupled to the formation at the ground surface. In the more usual situation, where the formation to be used lies at some depth below the earth's surface, the propagator may take the form of a plug or plugs of a suitable material such as salt water, lead wool, copper or other metal either dispersed in concrete or plastic or in solid form, and the like, embedded in the formation and connected to the transmitter by a suitable conductor such as coaxial cable, a. single conductor or a twisted pair. The composition and dimensions of a conductor and propagating plug depend upon the frequencies to be transmitted, the impedance of the transmitter, and primarily on the impedance characteristics of the lithologic formation, which depend upon the physical characteristics such as shape, minimum cross-section and fluid content of the formation itself, and also on its boundary conditions and the characteristics of the overlying and underlying formations.
At the receiving end it is considered preferable, but not necessary, to duplicate as nearly as possible the antenna or propagator of the transmitter in the same formation. For optimum efliciency, the impedance of the transmitters propagating plug and the receivers terminating plug are matched as nearly as possible to the impedance characteristics of the formation between the loci of transmission and reception. The output impedance of the transmitter and the input impedance of the receiver and their respective conductors are matched to their respective plugs. t is apparent that impedance matching may also be utilized as a means of determining the impedance of a particular formation between two points in the formation.
Discontinuities in a formation may be bridged in any of several ways. A receiver-transmitter system is especially desirable where the characteristics of the formations to be joined differ. In such a case, electromagnetic waves from the original transmitter, transmitted in the first formation, are picked up by a receiving system the impedance of which is matched as well as can be to the impedance of the formation to which the receiver is connected, and are fed to a transmitter connected with the second formation, to which the impedance of the second transmitter, its conductor and plug, are matched. The impedance of a receiver from the second formation is, of course, matched to the second formation.
Alternatively, two formations may be connected by a conducting electrode bridge. Boreholes may be drilled, or trenches dug, connecting the two formations, which boreholes or trenches may be filled with materials of the character suggested for propagating and terminating plugs, the dimensions of which and characteristics of which will be determined by the impedance of the formations sought to be connected.
Referring now to the figures, i represents a transmitter connected to lithologic formation 2 by means of a conductor 3 and propagating plug 4. Connected to the same formation 2 by terminating plug 5 and conductor 6 is a receiver 1. Transmitter l and receiver 1 are of the types generally used for the transmission and reception of ordinary broadcast, frequency modulated, or television waves. Formation 2 is bounded by lithologically distinct formations 8. In Figure 2 the selected formation 2 outcrops at a face 9. Electromagnetic waves are directed into the face 9 from antenna In. It is understood that waves introduced into a formation by means of a propagating plug may be received by means of an external antenna, or that waves introduced by an external antenna may be received by means of an external antenna, the external antennae being directed toward the selected formation. In Figure 3 a discontinuity in formation 2 is bridged by means of electrode I I The electrode l I may be made of copper or other conducting metal, either dispersed in concrete or in plastic, or in solid form, lead wool, salt water, or, when made of comparable dimensions with the two formations being bridged, of concrete or other rocklike material. In Figure 4. the discontinuity of Figure 3 is bridged by means of intermediate receiver l2, connected with intermediate transmitter [3, by a conventional conductor or aerial transmission-reception system,
It is apparent that except for the comparatively short distances involved in bridging faults by means of the intermediate receiver-transmitter system, and the almost negligible distance between exterior antennae and outcrops in those situations in which outcrops of the selected formation are utilized as described, a system is provided which depends neither upon the ether nor upon continuous metallic conductors between transmitter and receiver. Thus, the present invention provides means for transmitting electromagnetic waves without the use of towering aerials, without the use of coaxial cable or other metallic conductors joining the transmitter and ultimate receiver, unlimited as to distance by the curvature of the earths surface, with comparatively cheap, simple, sturdy, propagating equipment and an almost indestructible transmitting medium.
Having thus described the invention, what is claimed and desired to be secured by Letters Patent is:
l. A wave transmission-reception system, comprising transmitter means, means for introducing waves from said transmitter into a uniform lithologic stratum of high resistivity bounded on either side by lithologic formations of greater conductivity so as to form, in effect, a wave guide, and means for receiving said waves from said lithologic stratum.
2. A wave transmission-reception system, comprising transmitter means, receiver means, conductors connecting each of said means to a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity, the impedance of the said lithogolic stratum of high resistivity between the loci of connection with said means being matched by the impedance of said conductors.
3. A wave transmission-reception system, comprising transmitter means, a propagating plug embedded in a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity and connected to said transmitter means by a conductor, receiver means, a terminating plug imbedded in said lithologic stratum of high resistivity at a distance from said propagating plug and connected to said receiving means by a conductor, the impedance of said propagating plug and said terminating plug matching the impedance of said lithologic stratum of high resistivity intermediate the said plugs.
4. A wave transmission-reception system, comprising transmitter means, an antenna above the earth connected to said transmitter means and directed toward an exposed lithologic stratum of high resistivity bounded by lithologic strata of greater conductivity, receiver means, a terminating plug the impedance of which matches that of the said lithologic stratum of high resistivity between the loci of transmission and reception, and a conductor connecting said terminating plug with said receiving means.
5. A wave transmission-reception system, comprising transmitter means, a propagating plug embedded in a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity and connected to said transmitter means by a conductor, receiver means, a terminating plug embedded in said lithologic stratum of high resistivity at a distance from said propagating plug and connected to said receiving means by a conductor, the impedance of said terminating plug matching the impedance of said lithologic stratum of high resistivity intermediate said terminating and said propagating plugs.
6. A wave transmission-reception system, comprising transmitter means, a propagating plug embedded in a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity and connected to said transmitter means by a conductor, receiver means, and an antenna above the earth directed toward said lithologic stratum of high resistivity and connected to said receiver means.
'7. A wave transmission-reception system, comprising transmitter means, a conductor directly coupled to an outcrop of a lithologic stratum of high resistivity bounded on either side by lithologic strata of greater conductivity and connected to said transmitter means, receiver means, a terminating plug embedded in said lithologic stratum of high resistivity at a distance from said direct coupling and connected to said receiving means by a conductor, the impedance of said terminating plug matching the impedance of said lithologic stratum of high resistivity intermediate said terminating plug and said direct coupling.
8. A wave transmission-reception system comprising transmitter means, means for introducing electro-magnetic waves from said transmitter inma single uniform lithologic stratum bounded on either side by formations of such greater conductivity as to form with said lithologic stratum a guided wave transmitting medium, and means for receiving said waves from said lithologic stratum.
9. A wave transmission-reception system, comprising first transmitter means, first receiver means, conductors connecting each of said first means to a first single lithologic stratum bounded on either side by formations of such greater conductivity as to form, in eifect, a wave guide, a second transmitter means, a second receiver means, conductors connecting each of said second means to a second single lithologic stratum bounded on either side by formations of such greater conductivity as to form, in effect, a wave guide, and conductors connecting said first receiv- 1' means with said second transmitter means.
10. A wave transmission-reception system c prising transmitter means, means for introducing electro-magnetic waves from said transmitter into a first lithologic stratum of high resistivity bounded on either side by formations of such greater conductivity as to form, in efiect, a wave guide, and means for receiving said waves from a second lithologic stratum of high resistivity bounded on either side by formations of such greater conductivity as to form, in effect, a wave guide, said first and second lithologic stratums being connected by a conducting electrode bridge.
CARL A. BAYS.
References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 777,216 Musits Dec. 13, 1904 996,092 Johnson June 27, 1911 1,175,082 Reincke Mar. 14, 1916 1,333,095 Roe Mar. 9, 1920 2,389,432 Hansell Nov. 20, 1945 2,424,274 Hansell July 22, 1947 2,499,195 McNiven Feb. 28, 1950 2,517,951 Wheeler Aug. 8, 1950
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Cited By (24)

* Cited by examiner, † Cited by third party
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US3195131A (en) * 1963-01-10 1965-07-13 Norman R Ortwein Distance measuring system utilizing oceanic inversion duct
US3273112A (en) * 1962-12-03 1966-09-13 Leland S Hobson Tuned seismic wave communication system
US3283250A (en) * 1962-04-19 1966-11-01 Geophysique Cie Gle Electromagnetic transmission systems operating below ground surface
US3328753A (en) * 1964-07-06 1967-06-27 Stanford Research Inst Sound communication system
US3350634A (en) * 1964-12-22 1967-10-31 Mobil Oil Corp Electromagnetic investigation for salt webs interconnecting spaced salt domes
US3440523A (en) * 1965-04-02 1969-04-22 Inst Francais Du Petrole Method and apparatus for electromagnetic determination of the position of boundaries of and discontinuities in a geological formation
US3538431A (en) * 1968-09-26 1970-11-03 American Smelting Refining Geophysical prospecting with subsurface propagated electromagnetic waves
US3660760A (en) * 1969-07-23 1972-05-02 William J Foley Inductive communication system
US3967201A (en) * 1974-01-25 1976-06-29 Develco, Inc. Wireless subterranean signaling method
US4030032A (en) * 1960-04-05 1977-06-14 Westinghouse Electric Corporation Radio transmission system
US4088998A (en) * 1960-12-22 1978-05-09 Westinghouse Electric Corp. System for detecting nuclear explosions
US4183009A (en) * 1978-01-26 1980-01-08 The United States Of America As Represented By The Secretary Of The Navy Low frequency detection system
US4839644A (en) * 1987-06-10 1989-06-13 Schlumberger Technology Corp. System and method for communicating signals in a cased borehole having tubing
US20040048596A1 (en) * 2002-09-10 2004-03-11 Nortel Networks Limited Method and apparatus for extending high bandwidth communication services to the edge of the network
US9459371B1 (en) 2014-04-17 2016-10-04 Multi-Shot, Llc Retrievable downhole cable antenna for an electromagnetic system
US10385683B1 (en) 2018-02-02 2019-08-20 Nabors Drilling Technologies Usa, Inc. Deepset receiver for drilling application
US10984590B1 (en) 2019-12-06 2021-04-20 Chevron U.S.A. Inc. Generation of subsurface representations using layer-space
US11010969B1 (en) 2019-12-06 2021-05-18 Chevron U.S.A. Inc. Generation of subsurface representations using layer-space
US11187826B2 (en) 2019-12-06 2021-11-30 Chevron U.S.A. Inc. Characterization of subsurface regions using moving-window based analysis of unsegmented continuous data
US11249220B2 (en) 2019-08-14 2022-02-15 Chevron U.S.A. Inc. Correlation matrix for simultaneously correlating multiple wells
US11263362B2 (en) 2020-01-16 2022-03-01 Chevron U.S.A. Inc. Correlation of multiple wells using subsurface representation
US11320566B2 (en) 2020-01-16 2022-05-03 Chevron U.S.A. Inc. Multiple well matching within subsurface representation
US11397279B2 (en) 2020-03-27 2022-07-26 Chevron U.S.A. Inc. Comparison of wells using a dissimilarity matrix
US11604909B2 (en) 2019-05-28 2023-03-14 Chevron U.S.A. Inc. System and method for accelerated computation of subsurface representations

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US996092A (en) * 1910-10-06 1911-06-27 Maurice Bernays Johnson Box for carrying wireless signaling apparatus.
US1175082A (en) * 1912-07-16 1916-03-14 Studiengesellschaft Fuer Drahtlose Grubentelfeonie M B H Apparatus for the electric transmission of signs or speech in mines.
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Cited By (24)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4030032A (en) * 1960-04-05 1977-06-14 Westinghouse Electric Corporation Radio transmission system
US4088998A (en) * 1960-12-22 1978-05-09 Westinghouse Electric Corp. System for detecting nuclear explosions
US3283250A (en) * 1962-04-19 1966-11-01 Geophysique Cie Gle Electromagnetic transmission systems operating below ground surface
US3273112A (en) * 1962-12-03 1966-09-13 Leland S Hobson Tuned seismic wave communication system
US3195131A (en) * 1963-01-10 1965-07-13 Norman R Ortwein Distance measuring system utilizing oceanic inversion duct
US3328753A (en) * 1964-07-06 1967-06-27 Stanford Research Inst Sound communication system
US3350634A (en) * 1964-12-22 1967-10-31 Mobil Oil Corp Electromagnetic investigation for salt webs interconnecting spaced salt domes
US3440523A (en) * 1965-04-02 1969-04-22 Inst Francais Du Petrole Method and apparatus for electromagnetic determination of the position of boundaries of and discontinuities in a geological formation
US3538431A (en) * 1968-09-26 1970-11-03 American Smelting Refining Geophysical prospecting with subsurface propagated electromagnetic waves
US3660760A (en) * 1969-07-23 1972-05-02 William J Foley Inductive communication system
US3967201A (en) * 1974-01-25 1976-06-29 Develco, Inc. Wireless subterranean signaling method
US4183009A (en) * 1978-01-26 1980-01-08 The United States Of America As Represented By The Secretary Of The Navy Low frequency detection system
US4839644A (en) * 1987-06-10 1989-06-13 Schlumberger Technology Corp. System and method for communicating signals in a cased borehole having tubing
US20040048596A1 (en) * 2002-09-10 2004-03-11 Nortel Networks Limited Method and apparatus for extending high bandwidth communication services to the edge of the network
US9459371B1 (en) 2014-04-17 2016-10-04 Multi-Shot, Llc Retrievable downhole cable antenna for an electromagnetic system
US10385683B1 (en) 2018-02-02 2019-08-20 Nabors Drilling Technologies Usa, Inc. Deepset receiver for drilling application
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