A chromatic range sensor (CRS) system is configured to provide an in-focus image of a workpiece surface including a measurement spot usable as a guide light. The system includes an optical pen having a chromatically dispersive lens configuration providing axial chromatic dispersion, and a reflected light dividing configuration (e.g., a beamsplitter) arranged to receive and divide reflected light from the workpiece surface into a measurement portion and an imaging portion. The optical pen includes a narrowband spectral filter and a camera. The CRS system includes a processing portion configured to measure a distance from the optical pen to the workpiece surface, and to make an adjustment so that the distance corresponds to a focus distance at which the workpiece surface is in focus when imaged by the light that passes through the narrowband spectral filter.

Systems and methods for determining the height of a subject include a fixed unit mounted to a surface in electronic communication with a mobile unit permitting user input to drive instructions for the system. A sensor in the fixed unit emits a signal upon activation which is received. Time difference between emitting and receiving the signal is used to calculate the height of the room for calibrating the system and the height of the subject when measuring. The mobile unit includes a measurement surface positioned proximate to a maximal point of the subject for measurement, which intercepts and preferably reflects a measurement signal emitted by the sensor of the fixed unit. A light source in the fixed unit may create a mark on the support substrate indicating the location for the subject for measurement. The height determination may be sent to a hub or subject's EMR.

The present invention provides a measurement device for grinding wheel. One or more thickness measurement device is disposed slidably on a platform. A spinning device is disposed on the platform. A grinding wheel is fixed on the spinning device. The spinning shaft spins the grinding wheel. The one or more thickness measurement device measures the flatness condition of the grinding wheel. Furthermore, according to the present invention, a diameter measurement device is disposed inside the platform and measures the roundness of the outer periphery of the grinding wheel. Since the structure can be disassembled easily, the whole measurement device for grinding wheel can be carried conveniently. In addition, measurements can be performed by users on the site where the grinding wheel is located for real-timely understanding the real size and wear condition of grinding wheel.

A spectral confocal measurement device includes a light source portion, configured to emit a broad-spectrum light beam with a certain wavelength range in a first predetermined path; an optical sampling portion, configured to converge the broad-spectrum light beam emitted from the light source portion on different measurement surfaces of an object to be measured, and output a reflected light in a second predetermined path that is different from a reverse direction of the first predetermined path; and a measurement portion, configured to receive and process the reflected light from the optical sampling portion to obtain a measurement result. The device can improve measurement accuracy and reduce production costs. In addition, a spectral confocal measurement method is also provided.

A vehicle wheel assembly position measurement apparatus measures, at each of at least three measurement positions in a circumferential direction, a distance in a vehicle width direction between each of plural measurement points located on a specified line that crosses a lateral surface of a tire section from an inner circumferential end to an outer circumferential end and a respective one of distance measuring instruments, calculates an approximate curve indicating a relationship between a position in an extending direction of the specified line and the distance of each of the measurement points at the respective measurement position, calculates a rotation center position of a wheel assembly from a specific position of the approximate curve at the measurement position, and calculates a height position of the wheel assembly relative to a vehicle body from the rotation center position and a height position of a specified portion of the vehicle body.

An information processing apparatus that executes processing of obtaining, from an interference fringe image that is a two-dimensional distribution of intensity of interference fringes of object light and reference light, a phase difference image that is a two-dimensional distribution of a phase difference between the object light and the reference light, and obtaining a shape of an object to be observed based on the phase difference image includes at least one processor configured to acquire object-related information regarding the object to be observed, read out, from a storage unit in which the object-related information and a shape profile indicating the shape of the object to be observed are stored in association with each other, the shape profile corresponding to the acquired object-related information, and perform phase connection with respect to the phase difference image with reference to the read-out shape profile.

The present disclosure also relates to systems and methods for quality control in histology systems. In some embodiments, a method is provided that includes receiving a tissue block comprising a tissue sample embedded in an embedding material, imaging the tissue block to create a first imaging data of the tissue sample in a tissue section on the tissue block, removing the tissue section from the tissue block, the tissue section comprising a part of the tissue sample, imaging the tissue section to create a second imaging data of the tissue sample in the tissue section, and comparing the first imaging data to the second imaging data to confirm correspondence in the tissue sample in the first imaging data and the second imaging data based on one or more quality control parameters.

A three-dimensional shape measuring method includes: projecting a first grid pattern based on a first light and a second grid pattern based on a second light onto a target object in such a way that the first grid pattern and the second grid pattern intersect each other, the first light and the second light being lights of two colors included in three primary colors of light; picking up, by a three-color camera, an image of the first grid pattern and the second grid pattern projected on the target object, and acquiring a first picked-up image based on the first light and a second picked-up image based on the second light; and performing a phase analysis of a grid image with respect to at least one of the first picked-up image and the second picked-up image and calculating height information of the target object.

A height measurement device images a target, extracts a contour of the target from a two-dimensional image, sets a circumscribed rectangular area of which each side is parallel to a corresponding side of the visual field of the camera and each side is circumscribed with the extracted contour of the target, and sets an extension area in which each of four sides of the set circumscribed rectangular area is extended outward by a predetermined amount. The height measurement device determines multiple imaging positions such that maximum parallax is obtained within a range where the extension area does not protrude from the visual field of the camera. Then, the height measurement device images the target at each of the determined multiple imaging positions, and estimates a height of the target from parallax of a two-dimensional image of the target imaged at each of the multiple imaging positions.

A measuring device includes a projector, a camera and a calculation device. The projector projects, on a target object, first stripe pattern light having a first period, second stripe pattern light having a second period, and third stripe pattern light having a third period. A relation of the periods is the first period<the second period<the third period. The camera captures an image of the first stripe pattern light, an image of the second stripe pattern light, and an image of the third stripe pattern light. The calculation device performs a phase analysis of luminance with a phase shifting method for the image of the first stripe pattern light, the image of the second stripe pattern light, and the image of the third stripe pattern light, and calculates a height of the target object based on obtained phase analysis results.