Introduced here is a system for optically tracking displacement with high precision across one or more axes. To track displacement of an object, images that are generated by a plurality of optical sensors can be compared against one another. For example, images that are generated by a first optical sensor can be compared against images that are generated by a second optical sensor. Because the first and second optical sensors are in a fixed spatial relationship with one another, displacement of the object can be established based on the degree to which a given image generated by the first optical sensor matches another image generated by the second optical sensor.

The present disclosure provides a position detection device. The position detection device includes a movable unit, a light source unit and a color sensor. The movable unit can move along a moving direction and include one or more colored portions. The light source unit irradiates the colored portions with a light. The color sensor receives a reflected light reflected by the colored portions and detecting a color component.

A correction value measurement method includes, measuring a position of a reference sphere, calculating a relative position of the reference sphere with respect to a sensing position from the position of the reference sphere, a length of the position measurement sensor, and a length of the reference tool. The method further includes acquiring a reference tool position as a distal end position of the reference tool using, calculating a length direction correction value of the position measurement sensor from the reference tool position, the position of the reference sphere, the relative position, and a length of the reference tool, and measuring the position of the reference sphere to calculate a radial direction correction value of the position measurement sensor.

Optical assembly comprising a variable focal length lens assembly comprising a variable focal length lens and an actuating unit, wherein an energy absorption rate of energy absorbed by the variable focal length lens assembly depends on the applied controlling signal. The optical assembly comprises a controlling unit configured to control focal length settings of the variable focal length lens by providing respective controlling signals and to apply a default controlling signal for providing a default focal length and default energy absorption rate. The controlling unit provides a thermal stabilisation functionality, the thermal stabilisation functionality is defined by applying a varying controlling signal related to a varying focal length and applying a compensation controlling signal related to a compensating focal length.

A system for inspecting each workpiece of a plurality of non-identical workpieces, each workpiece having a distinct workholding specification. The system includes a workholder configured to autonomously execute a plurality of workholding operations pursuant to parameters of a specified pre-defined workholding mode specified from a plurality of distinct, pre-defined workholding modes. Each pre-defined workholding mode specifies a plurality of holding parameters corresponding to the holding specification of a corresponding workpiece.

Systems and methods described for embossing micro-scale features are provided. On various substrates. Micro-scaled features can contain nanometer to micrometer structural features. Various embodiments may relate to methods and systems that may allow substrates, non-limiting examples of which may include metals such as silver, copper, tin, gold, or the like, to be embossed to diffract light into various colors that can be refracted at various perspective angles. High-quality grooves can be machined down to the sub-micron or nanometer regime to generate embossment moulds for fast, single-step, repeated (e.g. in the order of tens to thousands) replication of gratings on bulk metallic substrates using a same embossing die without significant loss of embossing quality.

A method provides distance calibration data for a chromatic range sensor system with a chromatic range sensor optical pen configured to focus different wavelengths at different distances along a distance measurement axis. The chromatic range sensor optical pen is arranged in a relationship relative to a spherical calibration object that has a nominally spherical calibration surface. Relative movement of the chromatic range sensor optical pen in relation to the nominally spherical calibration surface is controlled so as to perform a spiral scan of a portion of the nominally spherical calibration surface. Distance indicating data is determined as corresponding to the distances between the chromatic range sensor optical pen and surface points on the nominally spherical calibration surface as the spiral scan is performed. Distance calibration data for the chromatic range sensor system is determined based on the distance indicating data.

A three-dimensional measuring device, comprising an arm having a free end provided with an interface body carrying a measuring member and a grip member enabling an operator to point the measuring member at a zone of the object that is to be measured. The measuring member includes a connector to be electrically connected to a corresponding connector of the interface body by a fastener mechanism that is controllable by a lever and that is arranged in such a manner that the lever controls the fastener mechanism to occupy selectively a snap-fastening state in which the measuring member is held on the interface body while the connectors are disengaged from each other, a locking state in which the measuring member is fastened to the interface body and the connectors are engaged with each other, or a release state in which the measuring member can be separated from the interface body.

An image capturing apparatus includes: a coordinate value acquisition unit acquiring first coordinate values serving as position information of a moving target; an image capturing unit capturing an image of the target; a direction and distance calculation unit calculating a direction of an optical axis that connects the target and the image capturing unit and a distance between the target and the image capturing unit on the optical axis based on the first coordinate values and second coordinate values serving as position information of the image capturing unit; an attitude control unit controlling an attitude of the image capturing unit based on the calculated direction of the optical axis; and an imaging magnification setting unit setting an imaging magnification of the target in the image capturing unit based on the calculated distance, wherein the image of the target is captured while changing the imaging magnification and the attitude.

An exemplary computing system for locating an object in an operational area is disclosed. The computing system having a server and plurality of edge devices. The edge devices having an image sensor configured to capture video data of the operational area from a specified location. The edge devices can process the video data to identify an object and generate a two-dimensional shape representative of the object, generate a vector from a lens of the image sensor through a center point of the two-dimensional shape; and determine relative position of the two-dimensional shape based on geospatial information of the edge device and the vector. The server and one or more of the edge devices receiving video data from a plurality of edge devices and generating a graphic, which defines a position of the object within the operational area based on the vector and location information of each edge device.