초록 ▼

A method for measuring the resistivity of geologic formations is described. An electromagnetic field may be generated using at least one stationary long-range transmitter. The frequency of the electromagnetic field may be between and/or including the ULF/ELF range. At least one component of the elec

A method for measuring the resistivity of geologic formations is described. An electromagnetic field may be generated using at least one stationary long-range transmitter. The frequency of the electromagnetic field may be between and/or including the ULF/ELF range. At least one component of the electromagnetic field may be measured by land, marine, and/or airborne receiver. A conductivity distribution may be determined based on the at least one measured component. The determined conductivity distribution may be correlated with geological formations and/or hydrocarbon deposits.

대표청구항 ▼

1. A method for measuring the resistivity of geologic formations comprising: generating an electromagnetic field using at least one stationary long-range or short-range transmitter, wherein the electromagnetic field is generated by a transmitter formed by a system of grounded electric bipoles of at

1. A method for measuring the resistivity of geologic formations comprising: generating an electromagnetic field using at least one stationary long-range or short-range transmitter, wherein the electromagnetic field is generated by a transmitter formed by a system of grounded electric bipoles of at least 500 meters in length or formed by a loop of wire with the radius of at least 500 meters, wherein the frequency of the electromagnetic field is between or including the ULF/ELF range;measuring at least one component of the electromagnetic field using at least one airborne receiver that is remotely located from the at least one long-range or short-range transmitter;determining a conductivity distribution based on the at least one measured component; andcorrelating the determined conductivity distribution with geological formations or hydrocarbon deposits. 2. The method of claim 1, wherein generating an electromagnetic field further comprises generating the electromagnetic field over a plurality of frequencies or in the time domain. 3. The method of claim 2, wherein generating the electromagnetic field in the time domain further comprises using a magnetohydrodynamic (MHD) generator. 4. The method of claim 2, wherein measuring at least one component of the electromagnetic field further comprises using a receiver that measures the electromagnetic field over a plurality of frequencies or in the time domain. 5. The method of claim 1, wherein generating an electromagnetic field further comprises locating a transmitter on land or in the sea. 6. The method of claim 1, wherein the electromagnetic field is generated by a transmitter formed by the system of grounded electric bipoles of more than three kilometers in length or formed by a loop of wire with the radius of at least three kilometers. 7. The method of claim 1, wherein measuring at least one component of the electromagnetic field further comprises using at least one galvanic receiver or at least one induction receiver. 8. The method of claim 7, further comprising recording the voltage detected in at least one of the receivers. 9. The method of claim 1, wherein measuring at least one component of the electromagnetic field further comprises measuring the amplitude or phase of electromagnetic field. 10. The method of claim 1, wherein using at least one airborne receiver includes using an airborne survey. 11. The method of claim 10, wherein the airborne survey includes using an airborne survey craft selected from the group consisting of a fixed wing airplane, a propeller airplane, a jet propelled airplane, and an unmanned aerial vehicle. 12. The method of claim 1, wherein measuring at least one component of the electromagnetic field further comprises using a receiver that measures a magnetic component or electric component of the electromagnetic field. 13. The method of claim 1, wherein determining a conductivity distribution is based on a plurality of measured components of the electromagnetic field and wherein the conductivity distribution is determined by determining at least one transfer function using the plurality of measured components of the electromagnetic field. 14. The method of claim 13, wherein determining at least one transfer function further comprises determining at least one of the following transfer functions selected from the group consisting of: an electric transfer function, a magnetic transfer function, an impedance transfer function, and an admittance transfer function. 15. The method of claim 13, wherein determining at least one transfer function further comprises using a linear relationship between a first component of the electromagnetic field and a second component of the electromagnetic field. 16. The method of claim 13, wherein determining at least one transfer function further comprises using a least-squares method. 17. The method of claim 1, wherein correlating the determined conductivity distribution with geological formations or hydrocarbon deposits further comprises characterizing geologic material, remotely detecting hydrocarbon deposits, or imaging the hydrocarbon deposits. 18. The method of claim 1, wherein correlating the determined conductivity distribution with geological formations or hydrocarbon deposits further comprises determining a three-dimensional conductivity distribution. 19. The method of claim 18, wherein determining a three-dimensional conductivity distribution further comprises using a three-dimensional inversion technique. 20. The method of claim 19, wherein the three-dimensional inversion technique is based on a regularized three-dimensional focusing nonlinear inversion of the at least one measured component of the electromagnetic field. 21. The method of claim 1, wherein correlating the determined conductivity distribution with geological formations or hydrocarbon deposits further comprises comparing observed data with predicted data. 22. The method of claim 21, wherein comparing observed data with predicted data further comprises minimizing a parametric functional. 23. The method of claim 22, wherein minimizing a parametric functional further comprises using gradient type methods or a misfit functional and a stabilizer. 24. The method of claim 1, wherein correlating the determined conductivity distribution with geological formations or hydrocarbon deposits further comprises stacking the measured at least one component of the electromagnetic field with a corresponding at least one component of the electromagnetic field measured at another period. 25. A method for locating mineral or hydrocarbon deposits, comprising: generating an electromagnetic field using at least one stationary long-range or short-range transmitter located on land or in the sea, wherein the frequency of the electromagnetic field is between or including the ULF/ELF range, the electromagnetic field propagating to an airborne receiver through an ionospheric waveguide or underground waveguide;measuring at least one component of the electromagnetic field using the airborne receiver, the airborne receiver being located remotely from the at least one stationary long-range or short-range transmitter;determining at least one transfer function based on the at least one measured component, wherein the at least one transfer function is independent of a location of the at least one stationary long-range or short-range transmitter; andcorrelating the determined transfer function with geological formations or hydrocarbon deposits. 26. A method for locating mineral or hydrocarbon deposits comprising: generating an electromagnetic field using at least one stationary long-range transmitter carrying a frequency domain current, wherein the frequency of the electromagnetic field is within the ELF range;measuring a plurality of components of the electromagnetic field using at least one magnetic or electric airborne movable receiver, wherein the at least one receiver measures the electromagnetic field over a plurality of frequencies, wherein the at least one magnetic or electric airborne movable receiver is located remotely from the at least one stationary long-range transmitter;determining at least one transfer function based on the plurality of measured components, wherein at least one of the following transfer functions is selected from the group consisting of: an electric transfer function, a magnetic transfer function, an impedance transfer function, and an admittance transfer function is determined;correlating the determined at least one transfer function with geological formations or hydrocarbon deposits by determining a three-dimensional conductivity distribution using a three-dimensional inversion technique based on a regularized three-dimensional focusing nonlinear inversion of the plurality of measured components of the electromagnetic field;comparing observed data with predicted data by minimizing a parametric functional using gradient type methods or a misfit functional and a stabilizer; andstacking the plurality of measured components of the electromagnetic field with a corresponding plurality of measured components of the electromagnetic field measured at another period. 27. A physical non-transitory computer readable medium having stored thereon computer executable instructions that when executed by a processor cause a computing system to perform method for measuring the resistivity of geologic formations, the method comprising: generating an electromagnetic field using at least one stationary long-range or short-range transmitter, wherein the electromagnetic field is generated by a transmitter formed by a system of grounded electric bipoles of at least 500 meters in length or formed by a loop of wire with the radius of at least 500 meters, wherein the frequency of the electromagnetic field is between or including the ULF/ELF range;measuring at least one component of the electromagnetic field using at least one airborne receiver that is remotely located from the at least one stationary long-range or short-range transmitter;determining a conductivity distribution based on the at least one measured component; andcorrelating the determined conductivity distribution with geological formations or hydrocarbon deposits. 28. A system for measuring the resistivity of geologic formations, the system comprising: at least one stationary long-range or short-range transmitter formed by a system of grounded electric bipoles of at least 500 meters in length or formed by a loop of wire with the radius of at least 500 meters,at least one airborne receiver that is remotely located from the at least one stationary long-range or short-range transmitter; anda computing system, the computing system comprising: a processor; andone or more physical non-transitory computer readable medium having computer executable instructions stored thereon that when executed by the processor, cause the computing system to perform the following:generate an electromagnetic field using the at least one stationary long-range or short-range transmitter, wherein the frequency of the electromagnetic field is between or including the ULF/ELF range;measure at least one component of the electromagnetic field using the least one airborne receiver;determine a conductivity distribution based on the at least one measured component; andcorrelate the determined conductivity distribution with geological formations or hydrocarbon deposits.