Disclosed are a substrate inspection method and a method of fabricating a semiconductor device using the same. The inspection method may include measuring a target area of a substrate using a pulsed beam to obtain a first peak, measuring a near field ultrasound, which is produced by the pulsed beam in a near field region including the target area, using a first continuous wave beam different from the pulsed beam to obtain a second peak, and measuring a far field ultrasound, which is produced by the near field ultrasound in a far field region outside the near field region, using a second continuous wave beam to examine material characteristics of the substrate.

This optical fiber distribution measurement system of distributed optical fiber sensing type includes: a tunable wavelength distributed feedback LD (1) for obtaining a DTSS signal through frequency shift analysis; an external resonance laser (2) for obtaining a DAS signal through phase shift analysis; a pulse compression coding circuit (4) including an intensity modulator (4a) and an phase modulator (4b); an acousto-optic switch (5); an erbium doped optical fiber amplifier (6); a circulator (7); a diversity device (8); a digitizer (11); a CPU (12); and a serial transfer interface (13). Through calculation on discrete signals sent from the digitizer (11), the CPU (12) converts an analyzed Rayleigh frequency shift signal obtained as the DTSS signal, to phase error, and corrects an analyzed phase signal obtained as the DAS signal, by the phase error.

A device and method for weld root hardening determination compensated for variations in distance between sensor and sample are disclosed. A sensor is used to determine hardness of a weld for weld fabrication quality control. Because of irregular weld protrusion geometry, there may be variations in the tip of the sensor and the surface, resulting in inconsistent measurements. To compensate, one or both of a positional compensation or a software compensation are performed. Positional compensation mechanically moves the tip of the sensor to within a predetermined range of the surface. Software compensation may at least partly compensate for the variation by using one part of the generated sensor data (such as the 1.sup.st harmonic signal) in order to modify another part of the generated sensor data (such as the 3.sup.rd harmonic signal). In this way, the sensor determination of hardness of the weld may be less dependent on the variations.

An ultrasonic-resilience value testing apparatus for an inorganic non-metal plate, including: a fixing mechanism, a testing mechanism and a control mechanism. The fixing mechanism is for carrying and fixing an inorganic non-metal plate to be tested; the testing mechanism is for performing ultrasonic-resilience value testing on the inorganic non-metal plate fixed on the fixing mechanism; and the control mechanism is in communication connection to the fixing mechanism and the testing mechanism, and is for controlling the fixing mechanism and the testing mechanism to run. By setting the fixing mechanism, problems such as slipping, angle deviation, vibration or movement and damage to the test sample are avoided. By setting the testing mechanism for the resilience value testing, the phenomenon that the relevant mechanical properties of the test sample cannot be accurately reflected since a resilience angle, a velocity and the like are affected by human factors, is improved.

A non-destructive testing method for flexural strength of fine ceramic, an apparatus, and a storage medium, including adjusting an uncut intact fine ceramic test sample to an ultrasonic testing position, and fixing the test sample; adjusting an ultrasonic testing instrument, controlling and adjusting the positions of ultrasonic testing probes of the ultrasonic testing instrument until the ultrasonic testing probes, the fine ceramic test sample and the resiling direction are located on the same plane, performing ultrasonic testing on the test sample, and collecting ultrasonic testing data of the test sample; adjusting the position of the fine ceramic test sample until a resilience testing rod and the test sample are located on the same plane and fixed, performing resilience testing on the test sample, and collecting resilience testing data of the test sample; and building a data model, or substituting testing data into the pre-built data model.

The disclosure discloses a stress gradient high-efficiency non-destructive detection system based on frequency domain calculation of broadband swept frequency signals, and a detection method thereof. The detection method includes: step 1: calibrating an LCR wave velocity of an object to be measured; step 2: calculating a starting frequency and a cut-off frequency of broadband swept frequency signals based on the LCR wave velocity of the object to be measured in the step 1 and a stress gradient measuring range in a depth direction of the object to be measured; step 3: converting phase delay to time delay information based on the phase delay of the starting frequency and the cut-off frequency in the step 2; and step 4: determining stresses of depths corresponding to different frequency components based on the time delay information in the step 3 to finally realize layer-by-layer scanning of stresses at different depths of the measured object. The disclosure is used to solve the problem of low stress gradient measuring accuracy, and realize the high-efficiency characterization of the stress gradient in the depth direction.

This application relates to a method of analyzing dynamic characteristics of a carbon composite material. This application also relates to a method of calculating sensitivity indices for structural stiffness and a viscous damping coefficient of a carbon composite material and a method of analyzing dynamic characteristics of a carbon composite material by using the same. Respective sensitivity indices for structural stiffness and a viscous damping coefficient according to a direction (angle) of carbon fiber for a carbon composite material are calculated. A change in the dynamic characteristics of the carbon composite material is evaluated through a proportional relationship between the sensitivity indices, thereby conducting a more accurate and efficient analysis.

System and method for shear wave elasticity imaging perform a) acquiring B-mode ultrasound images of a target region; b) selecting a region of interest; c) transmitting a shear wave excitation pulse; d) measuring displacements of tracking focal points or depth ranges at different depths positions along each of laterally staggered tracking lines within the selected region of interest; e) determining a curve representing displacement of tissue as a function of time at different spatial locations within the region of interest; f) determining for spatial locations candidate time(s) of arrival of the shear wave at the spatial location as a function of the curve; g) finding linear functional relation between the time of arrival and the spatial coordinate in the lateral direction using Random Sample Consensus (RANSAC) algorithm; and h) determining the inverse of velocity of the shear wave in a spatial location as the angular coefficient of the linear function.

Ultrasonic pulse velocity (UPV) is an extremely important parameter for the assessment of strength of concrete structures and study of elastic properties. ASTM international standard: (ASTM: C597-09) covers the determination of the propagation velocity of longitudinal stress wave pulses through concrete. The suggested method involves transmission of longitudinal ultrasound by transmitting transducer and receiving by a suitable similar transducer. The transit time-measurement and the associated triggering pulses must provide the overall time-measurement resolution of at least 1 μs. The present invention relates to the design of ultrasonic pulse velocity measuring device capable to generate ultrasound preferably in the solid materials including concrete or material supporting the propagation of ultrasound and precisely measure the ultrasonic propagation delay time commonly known as the transit time. The present invention relates to an improved design of an ultrasonic transit time measurement device having provision for automatic pulse threshold error correction. The invention also discloses the method to realize fast counting for the generation of high resolution with relatively slower microcontrollers. The accuracy in the transit time measurement is relatively improved by subtracting the threshold corrected zero offset (without material under test) from the threshold corrected transit time (with sample).

A method for performing shear wave elastography imaging of an observation field in a medium, the method comprising a plurality of shear wave imaging steps (30) to acquire a plurality of sets of shear wave propagation parameters, the method further comprising a reliability indicator determining step (40) during which a reliability indicator of the shear wave elastography imaging of the observation field is determined.