Embodiments described herein utilize Non-Destructive Inspection (NDI) scan data obtained during a process performed on a surface of a structure to update a location of an NDI scanner on the surface. A subsurface feature within the structure is detected based on the NDI scan data, which are correlated with pre-defined position data for the subsurface feature. A measured location of the NDI scanner on the surface is corrected based on the pre-defined position data for the subsurface feature.

A method for determining a running parameter of a vehicle travelling on a road, based on a measurement of a sound signal produced by a tire of the vehicle, and on measurements and estimations of running conditions effected in real time.

In order to detect a road surface condition, a road surface condition estimation device extracts a detection signal of a portion that detects vibration in a tire tangential direction in a vibration detection and power generation unit which is in a ground contact section, for example, a vibration power generation element. In this case, it is identified that the vibration detection and power generation unit is in the ground contact section, based on whether a centrifugal force acting on the vibration detection and power generation unit is generated, or not, and it is identified that a time when no centrifugal force is generated is in the ground contact section. As a result, even if a pulse level of an output voltage of the vibration detection generation unit changes according to a traveling speed of the vehicle, the ground contact section can be accurately identified.

A characterization device for non-destructively characterizing a material includes emitter/receiver cells, each cell being able, in an emit mode, to emit ultrasound waves towards the material for characterizing, and, in a receive mode, to receive ultrasound waves that have been transmitted through the material. The non-destructive characterization device includes a ring made up of a plurality of adjacent angular sectors, each angular sector including ultrasound cells stacked in a radial direction of the ring.

A system for determining the excitation frequency of vibratory stress relief is disclosed, comprising a host computer system, an arbitrary waveform generation card, a driver, a vibration exciter, an acceleration sensor, a charge amplifier, a data acquisition card, and a support device. The vibration exciter is mounted on the surface of a component, and the component is supported by the elastic support device; the host computer system comprises a finite element numerical simulation module, a preferred excitation frequency determination module, a reference voltage peak setting module, an excitation signal synthesis module, a voltage signal acquisition module, a Fourier transform module, an actual voltage peak acquisition module, and a voltage peak difference storage module. The method for determining the vibratory stress relief frequency comprises the following steps: numerical simulating; determining the preferred excitation frequency; synthesizing the excitation signal; Fourier transforming; determining the excitation frequency for the vibratory stress relief treatment from the preferred excitation frequency. The present invention is advantageous in that it is capable of determining the vibratory stress relief excitation frequency based on the surface residual stress distribution state of the component.

Disclosed is an ultrasonic inspection probe assembly comprising a water wedge and a flexible probe array assembly having a flexible acoustic module. The wedge is machined to match a test surface to be inspected and is configured to shape the acoustic module so that the active surface of the acoustic module is parallel to the test surface. Different wedges may be machined to match different test surfaces, but the same flexible probe array assembly may be used for all such surfaces.

A system for detecting damage to a glass surface particularly vehicle glazing panels such as vehicle windscreens. The system uses a sensor unit disposed proximate the surface and a processor in communication with the sensor unit. The processor is configured to analyse data received from the sensor unit in order to determine the integrity of the surface and a communication unit is configured to output a signal in response to the processor determining that the surface has been damaged. For vehicle glass the system is preferably integrated into the vehicle management and control systems such that the system is active when the vehicle is active or moving. The management and or control system may monitor for instances or situations when changes, such as above threshold changes, occur in order to produce an output warning signal.

The present document relates to a anatomic force microscope comprising a probe comprising a probe tip configured to sense a sample disposed proximate to the probe tip, a detector to detect a deflection of the probe tip, an actuator coupled to the probe and configured to move the probe in a sense state with the sample at a predetermined force set point and a vibrator in communication with the sample to provide a vibration to the sample, the vibration comprising a modulation frequency, wherein the acoustic vibrator is configured to provide the vibration in a modulation period after an initial sense period without modulation and wherein the probe is moved during or after said modulation period to a successive sample position over said sample while moving the probe in a non-contact state.

According to one embodiment, a structure evaluation system according to an embodiment includes a plurality of sensors, a position locator, a corrector, and an evaluator. The plurality of sensors detect elastic waves generated from a structure. The position locator is configured to locate positions of sources of a plurality of elastic waves detected by the plurality of sensors on the basis of the plurality of elastic waves. The corrector is configured to correct information based on the position location in the position locator using a correction value which is determined according to a temperature of the structure. The evaluator is configured to evaluate a deterioration state of the structure on the basis of the corrected information.

Embodiments described herein utilize Non-Destructive Inspection (NDI) scan data obtained during a process performed on a surface of a structure to update a location of an NDI scanner on the surface. A subsurface feature within the structure is detected based on the NDI scan data, which are correlated with pre-defined position data for the subsurface feature. A measured location of the NDI scanner on the surface is corrected based on the pre-defined position data for the subsurface feature.