Abstract: Methods and systems are disclosed for dynamically creating and annihilating subsurface electric dipoles having variable strength and variable alignment. The ability of various embodiments to create, annihilate, and control subsurface dipoles may be a useful technology for wide variety of applications including the nondestructive testing of materials and structures, for generating and receiving directed and omni-directional variable amplitude and frequency transmission waves without the need for conductive antennas, for phonon to electromagnetic power conversion, for materials and manufacturing process control, atomic and nanoparticle alignment, and for control and utilization as medical therapies.

Abstract: Various embodiments provide a multi-dimensional electric potential sensor array to remotely quantitatively measure static, quasi-static, and dynamic electric potential and electric field in free space, and emanating and propagating from objects. Various embodiments enable the evaluation of the integrity of electronic circuits and electronic components by quantitatively and dynamically imaging electric potential generated during electronic circuit activation, operation, and deactivation. In various embodiments, the electrical potential of active electronics and objects of interest in containers may be quantitatively measured by the electric potential and electric field methods and by using specified materials in a combined structural and electronic component design to construct a multi-dimensional sensor array.

Abstract: Methods and systems are disclosed for dynamically creating and annihilating subsurface electric dipoles having variable strength and variable alignment. The ability of various embodiments to create, annihilate, and control subsurface dipoles may be a useful technology for wide variety of applications including the nondestructive testing of materials and structures, for generating and receiving directed and omni-directional variable amplitude and frequency transmission waves without the need for conductive antennas, for phonon to electromagnetic power conversion, for materials and manufacturing process control, atomic and nanoparticle alignment, and for control and utilization as medical therapies.

Abstract: Methods and systems are disclosed for dynamically creating and annihilating subsurface electric dipoles having variable strength and variable alignment. The ability of various embodiments to create, annihilate, and control subsurface dipoles may be a useful technology for wide variety of applications including the nondestructive testing of materials and structures, for generating and receiving directed and omni-directional variable amplitude and frequency transmission waves without the need for conductive antennas, for phonon to electromagnetic power conversion, for materials and manufacturing process control, atomic and nanoparticle alignment, and for control and utilization as medical therapies.

Abstract: Various embodiments provide a multi-dimensional electric potential sensor array to remotely quantitatively measure static, quasi-static, and dynamic electric potential and electric field in free space, and emanating and propagating from objects. Various embodiments enable the evaluation of the integrity of electronic circuits and electronic components by quantitatively and dynamically imaging electric potential generated during electronic circuit activation, operation, and deactivation. In various embodiments, the electrical potential of active electronics and objects of interest in containers may be quantitatively measured by the electric potential and electric field methods and by using specified materials in a combined structural and electronic component design to construct a multi-dimensional sensor array.

Abstract: Various embodiments provide a multi-dimensional electric potential sensor array to remotely quantitatively measure static, quasi-static, and dynamic electric potential and electric field in free space, and emanating and propagating from objects. Various embodiments enable the evaluation of the integrity of electronic circuits and electronic components by quantitatively and dynamically imaging electric potential generated during electronic circuit activation, operation, and deactivation. In various embodiments, the electrical potential of active electronics and objects of interest in containers may be quantitatively measured by the electric potential and electric field methods and by using specified materials in a combined structural and electronic component design to construct a multi-dimensional sensor array.

Abstract: Various embodiments provide technology that may be used in harsh marine and harsh weather environments for the imaging of electric potentials and electric fields to characterize objects or regions. Various embodiments may enable a camera or eye type electric field imaging system that may be used in harsh weather or harsh environments (e.g., harsh marine environments, etc.) to image electrical potentials and electric fields.

Abstract: Various embodiments provide methods to identify and characterize remote objects by use of electric charge distributions generated by charge tunneling, charge injection, and charge induction. Various embodiments may use selective electrostatic charging to change the electrostatic potential throughout volumes for identification and characterization. In various embodiments, objects of interest may be selectively charged by tunneling, injection, and induction of electrical charges or free carriers. Tunneled, injected, and induced charges may migrate to sites or locations internal to volumes to yield electrostatic potential differences and electrostatic fields. In various embodiments, variations in the electrostatic potential created by the presence of the tunneled, injected, and induced charges may be quantitatively measured to identify and characterize remote objects.

Abstract: Various embodiments provide a multi-dimensional electric potential sensor array to remotely quantitatively measure static, quasi-static, and dynamic electric potential and electric field in free space, and emanating and propagating from objects. Various embodiments enable the evaluation of the integrity of electronic circuits and electronic components by quantitatively and dynamically imaging electric potential generated during electronic circuit activation, operation, and deactivation. In various embodiments, the electrical potential of active electronics and objects of interest in containers may be quantitatively measured by the electric potential and electric field methods and by using specified materials in a combined structural and electronic component design to construct a multi-dimensional sensor array.

Abstract: Various embodiments provide technology that may be used in harsh marine and harsh weather environments for the imaging of electric potentials and electric fields to characterize objects or regions. Various embodiments may enable a camera or eye type electric field imaging system that may be used in harsh weather or harsh environments (e.g., harsh marine environments, etc.) to image electrical potentials and electric fields.

Abstract: Systems, methods, and devices of the various embodiments provide a field effect transistor (FET) that controls equilibrium by reversing the effects of leakage currents affecting the gate response of the FET by using an equilibrium pump electrode. The equilibrium reversing gate FETs (ergFETs) of the various embodiments, may include an equilibrium pump electrode located within a non-conducting gap. The ergFETs of the various embodiments may provide solid state ephemeral electric potential and electric field sensor systems and methods for measuring ephemeral electric potentials and electric fields.

Abstract: Various embodiments provide methods to identify and characterize remote objects by use of electric charge distributions generated by charge tunneling, charge injection, and charge induction. Various embodiments may use selective electrostatic charging to change the electrostatic potential throughout volumes for identification and characterization. In various embodiments, objects of interest may be selectively charged by tunneling, injection, and induction of electrical charges or free carriers. Tunneled, injected, and induced charges may migrate to sites or locations internal to volumes to yield electrostatic potential differences and electrostatic fields. In various embodiments, variations in the electrostatic potential created by the presence of the tunneled, injected, and induced charges may be quantitatively measured to identify and characterize remote objects.

Abstract: Methods and systems are disclosed for dynamically creating and annihilating subsurface electric dipoles having variable strength and variable alignment. The ability of various embodiments to create, annihilate, and control subsurface dipoles may be a useful technology for wide variety of applications including the nondestructive testing of materials and structures, for generating and receiving directed and omni-directional variable amplitude and frequency transmission waves without the need for conductive antennas, for phonon to electromagnetic power conversion, for materials and manufacturing process control, atomic and nanoparticle alignment, and for control and utilization as medical therapies.

Abstract: Systems, methods, and devices of the various embodiments provide a field effect transistor (FET) that controls equilibrium by reversing the effects of leakage currents affecting the gate response of the FET by using an equilibrium pump electrode. The equilibrium reversing gate FETs (ergFETs) of the various embodiments, may include an equilibrium pump electrode located within a non-conducting gap. The ergFETs of the various embodiments may provide solid state ephemeral electric potential and electric field sensor systems and methods for measuring ephemeral electric potentials and electric fields.

Abstract: Systems, methods, and devices of the various embodiments provide for the minimization of the effects of intrinsic and extrinsic leakage electrical currents enabling true measurements of electric potentials and electric fields. In an embodiment, an ephemeral electric potential and electric field sensor system may have at least one electric field sensor and a rotator coupled to the electric field sensor and be configured to rotate the electric field sensor at a quasi-static frequency. In an embodiment, ephemeral electric potential and electric field measurements may be taken by rotating at least one electric field sensor at a quasi-static frequency, receiving electrical potential measurements from the electric field sensor when the electric field sensor is rotating at the quasi-static frequency, and generating and outputting images based at least in part on the received electrical potential measurements.

Abstract: A generator for producing an electric field for with an inspection technology system is provided. The generator provides the required variable magnitude quasi-static electric fields for the “illumination” of objects, areas and volumes to be inspected by the system, and produces human-safe electric fields that are only visible to the system. The generator includes a casing, a driven, non-conducting and triboelectrically neutral rotation shaft mounted therein, an ungrounded electrostatic dipole element which works in the quasi-static range, and a non-conducting support for mounting the dipole element to the shaft. The dipole element has a wireless motor system and a charging system which are wholly contained within the dipole element and the support that uses an electrostatic approach to charge the dipole element.

Abstract: A method and system are provided for making a quantitative measurement of an electric field. A plurality of antennas separated from one another by known distances are arrayed in a region that extends in at least one dimension. A voltage difference between at least one selected pair of antennas is measured. Each voltage difference is divided by the known distance associated with the selected pair of antennas corresponding thereto to generate a resulting quantity. The plurality of resulting quantities defined over the region quantitatively describe an electric field therein.

Abstract: Systems, methods, and devices of the various embodiments provide for the minimization of the effects of intrinsic and extrinsic leakage electrical currents enabling true measurements of electric. potentials and electric fields. In an embodiment, an ephemeral electric potential and electric field sensor system may have at least one electric field sensor and a rotator coupled to the electric field sensor and be configured to rotate the electric field sensor at a quasi-static frequency. In an embodiment, ephemeral electric potential and electric field measurements may be taken by rotating at least one electric field sensor at a quasi-static frequency, receiving electrical potential measurements from the electric field sensor when the electric field sensor is rotating at the quasi-static frequency, and generating and outputting images based at least in part on the received electrical potential measurements.

Abstract: A method and system are provided for making a quantitative measurement of an electric field. A plurality of antennas separated from one another by known distances are arrayed in a region that extends in at least one dimension. A voltage difference between at least one selected pair of antennas is measured. Each voltage difference is divided by the known distance associated with the selected pair of antennas corresponding thereto to generate a resulting quantity. The plurality of resulting quantities defined over the region quantitatively describe an electric field therein.

Abstract: A method of validating a probability of detection (POD) testing system using directed design of experiments (DOE) includes recording an input data set of observed hit and miss or analog data for sample components as a function of size of a flaw in the components. The method also includes processing the input data set to generate an output data set having an optimal class width, assigning a case number to the output data set, and generating validation instructions based on the assigned case number. An apparatus includes a host machine for receiving the input data set from the testing system and an algorithm for executing DOE to validate the test system. The algorithm applies DOE to the input data set to determine a data set having an optimal class width, assigns a case number to that data set, and generates validation instructions based on the case number.