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A material constituent sensor includes one or more metamaterial assisted antennas located to probe a material that is a multiphase composition. A signal source excites at least one metamaterial assisted antenna in a desired range of radio frequency (RF) signals, a desired range of microwave signals,

A material constituent sensor includes one or more metamaterial assisted antennas located to probe a material that is a multiphase composition. A signal source excites at least one metamaterial assisted antenna in a desired range of radio frequency (RF) signals, a desired range of microwave signals, or a combination RF signals and microwave signals. A data processing device is programmed to estimate material constituent fractions associated with the probed material based on amplitude data, phase data, frequency shift data, or a combination of amplitude data, phase data and frequency shift data in response to transmitted energy from at least one excited metamaterial assisted antenna, reflected energy received by at least one metamaterial assisted antenna, frequency shift data, or a combination of the transmitted energy, the reflected energy and the frequency shift.

대표청구항 ▼

1. A method of material constituent measurement, the method comprising: providing at least one metamaterial assisted sensor, each sensor comprising at least one antenna configured as a transmitter of electromagnetic (EM) energy, a receiver of EM energy, or a combination thereof, wherein a metamateri

1. A method of material constituent measurement, the method comprising: providing at least one metamaterial assisted sensor, each sensor comprising at least one antenna configured as a transmitter of electromagnetic (EM) energy, a receiver of EM energy, or a combination thereof, wherein a metamaterial of the at least one metamaterial assisted sensor comprises a negative refractive index;placing at least one metamaterial assisted sensor inside a conduit to probe a material;exciting at least one metamaterial assisted sensor via a signal source at one or more frequencies;measuring a transmitted energy level, a reflected energy level, a frequency shift, or a combination thereof in response to the sensor excitation; andapplying transfer functions to estimate via a programmable computing device, one or more material fractions associated with the probed material based on amplitude data, phase data, frequency shift data or a combination thereof in response to the transmitted energy level, reflected energy level, a measured frequency shift, or combination thereof to determine a gas fraction and a liquid fraction. 2. The method according to claim 1, further comprising estimating via the programmable device, probed material salinity. 3. The method according to claim 1, wherein the one or more material fractions comprise a water fraction. 4. The method according to claim 1, wherein the probed material is flowing within a conduit. 5. The method according to claim 4, wherein placing at least one metamaterial assisted sensor to probe a material, comprises placing a liner configured with metamaterial inside a desired portion of the conduit through which the probed material is flowing. 6. The method according to claim 1, wherein the probed material comprises a multi-constituent material. 7. The method according to claim 6, further comprising applying transfer functions via the programmable computing device to estimate constituent fractions of the probed multi-constituent material. 8. The method according to claim 1, wherein providing at least one metamaterial assisted sensor further comprises placing a liner configured with metamaterial inside a desired portion of a conduit through which the probed material can flow, placing a radome configured with metamaterial around at least a portion of one or more antennas, or a combination thereof. 9. The method according to claim 1, wherein measuring a transmitted energy level, a reflected energy level, a frequency shift, or a combination thereof in response to the sensor excitation comprises measuring signal characteristics in a radio frequency range, a microwave range, or a combination thereof. 10. The method according to claim 1, wherein providing at least one metamaterial assisted sensor comprises providing at least one metamaterial assisted antenna and at least one non-metamaterial assisted antenna when the metamaterial assisted sensor comprises a plurality of antennas. 11. A material constituent sensor, comprising: one or more metamaterial assisted sensors placed inside a conduit to probe a material, wherein each metamaterial assisted sensor comprises at least one antenna configured as a transmitter of electromagnetic (EM) energy, a receiver of EM energy, or a combination thereof, and wherein a metamaterial of the at least one metamaterial assisted sensor comprises a negative refractive index;a signal source configured to excite at least one metamaterial assisted sensor in a desired range of radio frequency signals, a desired range of microwave signals, or a combination thereof; anda programmable computing device configured to estimate one or more material fractions associated with the probed material based on amplitude data, phase data, frequency shift data, or a combination thereof in response to transmitted energy from at least one sensor antenna, reflected energy received by at least one sensor antenna, or a combination thereof to determine a gas fraction and a liquid fraction. 12. The material constituent sensor according to claim 11, wherein at least one antenna is configured with metamaterial. 13. The material constituent sensor according to claim 12, wherein at least one antenna is a non-metamaterial antenna when the material property sensor comprises a plurality of antennas. 14. The material constituent sensor according to claim 11, wherein at least one antenna comprises at least a portion thereof sealed by a radome configured with metamaterial. 15. The material constituent sensor according to claim 11, wherein at least one antenna comprises a fractal geometry. 16. The material constituent sensor according to claim 11, wherein the programmable computing device is further configured to estimate probed material salinity. 17. A material constituent sensor comprising: one or more metamaterial assisted sensors placed inside a conduit to probe a material, wherein each metamaterial assisted sensor comprises: at least one antenna configured as a transmitter of electromagnetic (EM) energy, a receiver of EM energy, or a combination thereof,wherein a metamaterial of the at least one metamaterial assisted sensor comprises a negative refractive index, andwherein the sensor is configured to determine a gas fraction and a liquid fraction. 18. The material constituent sensor according to claim 17, wherein at least one antenna is configured with a fractal geometry. 19. The material constituent sensor according to claim 17, further comprising a liner configured with metamaterial disposed inside a desired portion of a conduit through which the material to be probed is flowing. 20. The material constituent sensor according to claim 17, further comprising a programmable computing device configured to estimate one or more constituent fractions associated with the probed material based on amplitude data, phase data, frequency shift data, or a combination thereof in response to transmitted energy from at least one sensor antenna, reflected energy received by at least one sensor antenna, or a combination thereof.