Abstract: Enhanced measurement of thickness in bulk dielectric materials is disclosed. Microwave radiation is partially reflected at interfaces where the dielectric constant changes (e.g., the back wall of a part). The reflected microwaves are combined with a portion of the outgoing beam at each of at least two separate detectors. A pair of sinusoidal or quasi-sinusoidal waves results. Thickness or depth measurement is enhanced by exploiting the phase and amplitude relationships between multiple sinusoidal or quasi-sinusoidal standing waves at detectors sharing a common microwave source. These relationships are used to determine an unambiguous relationship between the signal and the thickness or depth.

Abstract: Enhanced measurement of thickness in bulk dielectric materials is disclosed. Microwave radiation is partially reflected at interfaces where the dielectric constant changes (e.g., the back wall of a part). The reflected microwaves are combined with a portion of the outgoing beam at each of at least two separate detectors. A pair of sinusoidal or quasi-sinusoidal waves results. Thickness or depth measurement is enhanced by exploiting the phase and amplitude relationships between multiple sinusoidal or quasi-sinusoidal standing waves at detectors sharing a common microwave source. These relationships are used to determine an unambiguous relationship between the signal and the thickness or depth.

Abstract: The enhanced detection of defects and features in bulk dielectric materials is disclosed. Microwave radiation partly reflected at interfaces where the dielectric constant changes (e.g., where there are defects or structures). A sinusoidal or quasi-sinusoidal wave results. Localization or imaging of features is enhanced by exploiting the variation in distance resolution in a sinusoidal or quasi-sinusoidal standing wave. At characteristic distances, the wave has a high slope, and the amplitude of the wave varies strongly with small changes in distance. By inspecting at these characteristic distances, the resolution is enhanced. By systematically varying the position of the transducer or specimen, detailed images may be formed of the internal structure of the specimen across a range of depths. Defects and structures may be detected at smaller sizes than has previously been possible. The resolution of the imaging may be substantially smaller than the wavelength of the interrogating radiation.

Abstract: The enhanced detection of defects and features in bulk dielectric materials is disclosed. Microwave radiation partly reflected at interfaces where the dielectric constant changes (e.g., where there are defects or structures). A sinusoidal or quasi-sinusoidal wave results. Localization or imaging of features is enhanced by exploiting the variation in distance resolution in a sinusoidal or quasi-sinusoidal standing wave. At characteristic distances, the wave has a high slope, and the amplitude of the wave varies strongly with small changes in distance. By inspecting at these characteristic distances, the resolution is enhanced. By systematically varying the position of the transducer or specimen, detailed images may be formed of the internal structure of the specimen across a range of depths. Defects and structures may be detected at smaller sizes than has previously been possible. The resolution of the imaging may be substantially smaller than the wavelength of the interrogating radiation.

Abstract: The enhanced detection of defects in the bulk dielectric material (Specimen) having radiation partly reflected at interfaces where the dielectric constant changes (e.g., where there are defects or structures). A sinusoidal or quasisinusoidal wave (Microwave Source) results. Localization or imaging of features is enhanced by exploiting the variation in distance resolution (Standoff+/?) in a sinusoidal or quasi-sinusoidal standing wave. At characteristic distances, the wave has a high slope and the amplitude of the wave varies strongly with small changes in distance (Standoff+/?). By inspecting at these characteristic distances (Standoff+/?), the resolution is enhanced. By systematically varying the position of the transducer or specimen, detailed images may be formed of the internal structure of the specimen across a range of depths. Defects and structures may be detected at smaller sizes than has previously been possible.

Abstract: The enhanced detection of defects in the bulk dielectric material (Specimen) having radiation partly reflected at interfaces where the dielectric constant changes (e.g., where there are defects or structures). A sinusoidal or quasisinusoidal wave (Microwave Source) results. Localization or imaging of features is enhanced by exploiting the variation in distance resolution (Standoff+/?) in a sinusoidal or quasi-sinusoidal standing wave. At characteristic distances, the wave has a high slope and the amplitude of the wave varies strongly with small changes in distance (Standoff+/?). By inspecting at these characteristic distances (Standoff+/?), the resolution is enhanced. By systematically varying the position of the transducer or specimen, detailed images may be formed of the internal structure of the specimen across a range of depths. Defects and structures may be detected at smaller sizes than has previously been possible.

Abstract: An apparatus and method for the nondestructive inspection of dielectric materials are disclosed. Monochromatic, phase coherent electromagnetic radiation, preferably in the 5-50 gigahertz frequency range (i.e., microwaves) impinges on the sample. In accordance with Snell's law, the microwaves are partly transmitted and partly reflected at each interface where the dielectric constant changes (e.g., where there are delaminations, cracks, holes, impurities, or other defects.) A portion of the reflected beam is combined with the signal reflected by the specimen being inspected. These two signals have the same frequency, but may differ in amplitude and phase. The signals combine to produce an interference pattern, a pattern that changes as the specimen changes, or as the position of the specimen changes relative to that of the detector.

Abstract: A turbine controls testing device is disclosed that can be adapted to test the control systems of most turbine rotors without the use of steam. The turbine controls testing device comprises an operator control system, a drive motive power assembly and a purge gas assembly. The novel device controllably spins, accelerates, and decelerates a turbine with a relatively high level of precision, minimizing the likelihood that, in the event an overspeed mechanism malfunction occurs, the turbine will be damaged as a result of sonic velocity or any other mechanical failure.

Abstract: An apparatus and method for the nondestructive inspection of dielectric materials are disclosed. Monochromatic, phase coherent electromagnetic radiation, preferably in the 5-50 gigahertz frequency range (i.e., microwaves) impinges on the sample. In accordance with Snell's law, the microwaves are partly transmitted and partly reflected at each interface where the dielectric constant changes (e.g., where there are delaminations, cracks, holes, impurities, or other defects.) A portion of the reflected beam is combined with the signal reflected by the specimen being inspected. These two signals have the same frequency, but may differ in amplitude and phase. The signals combine to produce an interference pattern, a pattern that changes as the specimen changes, or as the position of the specimen changes relative to that of the detector. Appropriate processing of the interference signal can greatly improve the signal-to-noise ratio.