A sensor head is provided and achieves improved measurement accuracy while reducing measurement time. The sensor head includes: a case including a first case section having a lens therein, a second case section having an objective lens therein, and a third case section providing connection between the first case section and the second case section. Inside the third case section, a mirror member for folding light incident thereon from the lens toward the objective lens is disposed, and a hollow tube providing communication between through holes respectively formed in the mirror member and the objective lens is provided.

A stylus is arranged on a coordinate measuring machine. A method for aligning a component in relation to the coordinate measuring machine includes positioning the stylus and the component in relation to one another according to a defined arrangement. The method includes acquiring at least one coordinate of the component. The method includes changing at least one of a position and an orientation of the component in relation to the coordinate measuring machine while maintaining the defined arrangement.

A calibration configuration for a chromatic range sensor (CRS) optical probe of a coordinate measurement machine (CMM) includes a calibration object. The calibration object includes at least a first nominally cylindrical calibration surface having a central axis that extends along a Z direction that is intended to be aligned approximately parallel to a rotation axis of the CRS optical probe. The first nominally cylindrical calibration surface is arranged at a known first radius R1 from the central axis that extends along the Z direction. A first set of angular reference features is formed on or in the first nominally cylindrical calibration surface. The angular reference features are configured to be sensed by the radial distance sensing beam and are located at known angles or known angular spacings around the central axis from one another on or in the first nominally cylindrical calibration surface.

A method of putting a feature of interest on an object and an optical inspection system of a non-contact probe mounted on a positioning apparatus in a desired relationship. The method includes: a) identifying a target point of interest on the object to be inspected by arranging the non-contact probe and object at a first relative configuration at which a marker feature, projected by the non-contact probe along a projector axis that is not coaxial with the optical inspection system's optical axis, identifies the target point of interest; and b) subsequently moving the non-contact probe and/or object so as to put them at a second relative configuration at which the target point of interest and optical inspection system are at the desired relationship, in which the positioning apparatus is configured to guide such motion in accordance with the control path.

Various arrangements for handling a potential security situation using a home automation system are presented. A biometric measurement of a user may be received. An alert from a home automation device in wireless communication with the home automation host system may be received. If the biometric measurement is associated with the alert, a security response action may be performed.

An optical system comprising an optical coherence tomography (OCT) measuring device and a beam deflection unit for laterally deflecting the position or angle of a beam path of the OCT measuring device. There is an optical component in the beam path, said optical component being embodied in such a way that a back-reflection of the optical component has a different configuration in terms of its longitudinal location along the beam path depending on the lateral position of the deflected beam path on the optical component. The optical system comprises an evaluation unit which is embodied in such a way that a value of the lateral position or angle deflection of the beam deflection unit is determinable on the basis of a longitudinal location of the back-reflection at the optical component determined by the OCT measuring device.

Provided is a shape measurement system in order to perform three-dimensional measurement corresponding to a measurement object having various shapes, which includes a measurement probe, a probe tip, and a processor. The probe tip includes an optical element that is configured to irradiate an object with measurement light and a cylindrical unit that is configured to lock the optical element. The processor is configured to calculate an optical path length from the optical element to an object based on reflected light of the measurement light with which the object is irradiated; and calculate a three-dimensional shape of the object based on the input information and the optical path length.

A configuration for coupling a chromatic range sensor optical probe to a coordinate measurement machine (CMM) includes an electric auto connection and a free-space fiber optic coupling with first and second coupling elements. The first coupling element has a first fiber optic connector configured to couple to wavelength detector and light source elements of a CMM through a first optical fiber, and is configured to mount to a probe head of the CMM. The second coupling element has a second fiber optic connector configured to couple to an optical pen of a chromatic range sensor (CRS) optical probe through a second optical fiber, and is configured to mount to the CRS optical probe. One of the first or second coupling elements includes a pair of optical lenses configured to collimate light received via the first optical fiber and focus the collimated light into the second optical fiber.

A coordinate measurement device comprises an articulated arm having a first end, a second end, and a plurality of jointed arm segments therebetween. Each arm segment defines at least one axis of rotation. A laser scanner assembly is coupled to the second end of the arm and is rotatable about a last axis of rotation of the articulated arm. The laser scanner assembly comprises a laser and an image sensor. The laser is positioned on an opposite side of the last axis of rotation from the image sensor.

Various arrangements for handling a potential security situation using a home automation system are presented. A biometric measurement of a user may be received. The biometric measurement of the user may exceed a defined threshold value for the biometric measurement. A security alert from a home automation device in wireless communication with the home automation host system may be received. If the biometric measurement is associated with the security alert, a security response action may be performed.