The invention relates to a device for determining at least one physical parameter of pharmaceutical products such as, for example, tablets (T), pills, oblongs or similar, the device having at least one examining station (1). The device has, in addition, at least one automatic system for transporting the products to and/or between and/or inside and/or from the or each examining station (1). The transport system has at least one robotic arm (2) having at least one controllable holding mechanism (3) for the pharmaceutical products. The travel paths and the spatial orientation of the holding mechanism (3) can be freely programmed.

An apparatus to detect the topology of a workpiece including surface variations and flaws according to images from several viewpoints includes a frame, a loading member, a robot, an image capturing mechanism, and a controller. The loading member is positioned on the frame and loads a workpiece. The controller controls the robot to drive the image capturing mechanism to move or rotate to different preset positions from each of which the image capturing mechanism can capture images of the workpiece and transmit the images to the controller. The controller further processes the images to obtain an assessment of the components and surface of the workpiece for further processing.

An imaging system for a smartphone includes a housing configured to rigidly attach to a handheld smartphone device. The system further includes an arm extending from the housing, wherein the arm is configured to be adjustable such that the arm is movable toward and away from the housing. Additionally, the system includes a sample mounting portion attached to the arm, the mounting portion having a retaining device, wherein the retaining device is configured to secure a target sample, the mounting portion configured to direct an image of the target sample to a first camera in the handheld smartphone device.

A Laser Induced Breakdown Spectrocopy (LIBS) system for the analysis of a sample pellet of a consolidated granular material retained in a tubular container may include a laser source configured to emit a pulsed laser beam towards an exposed surface of the sample pellet; and a sample station configured to hold the cylindrical tubular container in one or more orientations to present an exposed surface of the sample pellet towards the pulsed laser beam. The sample station may induce linear movement of the sample pellet along an axis and to expose a portion of the outer side surface of the sample pellet previously constrained through contact with an inner surface of the cylindrical tubular container. The sample station may induce rotational motion of the outer side surface of the sample pellet around the movement axis to present the portion of the outer side surface as the exposed surface.

Cryogenic analysis assemblies and methods are provided. The assemblies and/or methods can be configured for optical sample analysis. The assemblies and/or methods can include: an objective assembly operatively aligned with a sample support assembly, both the objective assembly and sample support assembly residing within a vacuum housing; wherein the objective assembly defines an objective mount housing an objective coupled to a mounting ring within a chamber below a heater assembly; and an insulative member between the objective mount and the mounting ring, the insulative member supporting the objective mount and thermally isolating the objective mount from the mounting ring.

A sampling tool for use with an infrared spectrophotometer, and method of use. The sampling tool comprises a bottom plate; and a mesh attached to the bottom plate, the mesh having a plurality of interstitial spaces, and the mesh having a mesh width and a mesh thickness, wherein the mesh is configured to receive a sample material and retain a portion of the sample material within the interstitial spaces of the mesh to form a sample having a sample thickness which is substantially the same as the mesh thickness. The mesh width may be sized to be in a range of about 1 to 3 times the width of an infrared beam directed toward the sampling tool from the spectrophotometer.

An imaging system for a smartphone includes a housing configured to rigidly attach to a handheld smartphone device. The system further includes an arm extending from the housing, wherein the arm is configured to be adjustable such that the arm is movable toward and away from the housing. Additionally, the system includes a sample mounting portion attached to the arm, the mounting portion having a retaining device, wherein the retaining device is configured to secure a target sample, the mounting portion configured to direct an image of the target sample to a first camera in the handheld smartphone device.

Systems, devices, and methods for combined wafer and photomask inspection are provided. In some embodiments, chucks are provided, the chucks comprising: a removable insert, wherein the removable insert is configured to support a wafer so that an examination surface of the wafer lies within a focal range when the chuck is in a first configuration, wherein the removable insert is inserted into the chuck in the first configuration; and a first structure forming a recess that has a depth sufficient to support a photomask so that an examination surface of the photomask lies within the focal range when the chuck is in a second configuration, wherein the removable insert is not inserted into the chuck in the second configuration.

According to an example aspect of the present invention, there is provided a sample container for use inside an optically integrating cavity, comprising an enclosing member comprised of fluorocarbon plastic, the enclosing member having diffuse transmittance of at least 80% and the sample container being adapted to contain a solid or liquid sample.

Described herein are methods and apparatus for spectroscopic analysis of samples. In many embodiments, an apparatus for providing spectroscopic analysis of a sample comprises a sample holder. For example, the sample holder may comprise a consumable single use sample holder that can be readily coupled to and removed from a measurement apparatus such as a spectrometer. The sample holder may comprise a measurement surface configured to receive the sample during measurement, wherein the measurement surface may comprise a porous mesh. The porous mesh can receive the sample to optimally configure the sample for spectroscopic measurement, as described in further detail herein.