The method of inspecting a degraded area of a metal structure covered by a composite repair generally comprises operating a Compton scattering inspection device onto the degraded area, including emitting a beam of radiation particles directed towards and across the composite repair, detecting at least some backscattered photons scattered back from the metal structure, and acquiring Compton scattering data from the detected backscattered photons, the Compton scattering data being indicative of remaining wall thickness of the degraded area.

A measurement processing device used for an x-ray inspection apparatus that detects an x-ray passing through a specimen with a detection unit to sequentially inspect a plurality of specimens on the basis of an acquired transmission image, includes a setting unit that sets a region to be inspected on a portion of the specimen; a determination unit that determines the non-defectiveness of the region to be inspected by using a transmission image of the x-ray that passed through the region to be inspected; a correction unit that performs a correction on the region to be inspected on the basis of a determination result by the determination unit; and a display control unit that displays the corrected region to be inspected corrected by the correction unit.

Imaging and processing techniques are employed to identify crystalline defects obtained by ECCI from surrounding topography and is combined with defect counting and automatic classification.

The present disclosure generally relates to methods for radiographic and computed tomography (CT) inspection of workpieces having increasingly complicated internal geometry. The disclosed methods are capable of distributing a contrast agent within the detailed internal geometry of, for example, an AM workpiece or precision cast turbine blade, followed by complete removal of the contrast agent and all residues thereof after inspection.

The present embodiments generally relate to methods of non-destructively imaging plant root damage by insect root herbivores and evaluating the efficacy of insecticidal materials associated with the roots of plants against the insect root herbivores, useful for automated high throughput bioassays.

An aperture array for a multi-beam array system and a method of selecting a subset of a beam from a multi-beam array system are provided. The aperture array comprises an array body arranged proximate to a beam source. The array body comprises a plurality of apertures, at least two of the apertures having different geometries. The array body is movable, via an actuator, relative to an optical axis of the beam source, such that a subset of a beam from the beam source is selected based on the geometry of the aperture that is intersected by the optical axis.

An X-ray apparatus includes: a mounting unit upon which an object to be measured is mounted; an X-ray generation unit that irradiates X-rays, from above the mounting unit or from below the mounting unit, to the object to be measured upon the mounting unit; an X-ray detector that acquires a transmission image of the object to be measured being irradiated by the X-rays; a first movement unit that moves at least one of the mounting unit, the X-ray generation unit, and the X-ray detector along a direction of irradiation of the X-rays; a position detection unit that detects a relative position of the mounting unit, the X-ray generation unit, and the X-ray detector; and a calculation unit that calculates a magnification of a transmission image of the object to be measured acquired by the X-ray detector, in a state in which deflection of the mounting unit has occurred while the object to be measured is mounted upon the mounting unit.

This invention utilizes two sensing technologies in combination with or in isolation of an automated inspection vehicle to conduct inspections of internal rail flaws in steel railroad track. A vehicle equipped with X-radiation sensing is used as a secondary method to assess the deviations in magnetic fields that are sensed by a primary sensor consisting of a single or multiple magnetometers. The magnetometers sense changes in magnetic field that are correlated to the flaws inside the steel rail. The combination of technologies improves the probability to detect railroad flaws and offers the ability to accurately track and monitor flaws.

A method including inspecting, using an X-ray transmission image, internal defects in a TSV formed in a semiconductor wafer, and detecting the X-rays, and processing an X-ray transmission image. Therein, the detection of X-rays is configured such that: the detection azimuth of the X-rays, and the detection elevation angle of the X-rays relative to the X-ray source are determined on the basis of information on the arrangement interval, depth, and planar shape of structures formed in the sample. The angle of rotation of a rotating stage on which the sample is mounted is adjusted in accordance with the detection azimuth which has been determined, and the X-rays that have been transmitted through the sample are detected with the position of the detector set to the detection elevation angle which has been determined.

The purpose of this invention is to estimate the occurrence of defects such as probability pattern defects, with a small number of inspection points. To achieve this purpose, the present invention proposes a system and a computer-readable medium. The system comprises: a step in which first data pertaining to the probability that the edge of a pattern determined on the basis of measurement data for a plurality of measurement points on a wafer is present at a first position is acquired or is generated; a step in which, if the edge is at the first position, second data pertaining to the probability that a film defect covers a region including the first position and a second position which is different to said first position is acquired or generated; and a step in which the probability of the defect occurring is predicted on the basis of the first data and the second data.