Examples include a fluid device. The fluid device includes a substrate, a sensor coupled on the substrate. A reservoir is formed in the substrate adjacent to the sensor. A deformable cover is disposed to seal the sensor and the reservoir on the substrate.

An optical detection device includes a base, a cartridge placing portion, a shield cover, a processor, and an optical sensor. The base includes an opening. The cartridge placing portion is located in the base, and is in communication with the opening. The shield cover is configured to open or close the opening. When the optical sensor is actuated, the shield cover closes the opening to prevent external ambient light from entering the opening to affect the optical sensor during sensing.

A method for installing at least one optical element in an interior space of a housing includes: clamping a sensor assembly in an interior of the housing in at least one radial clamping direction extending perpendicularly to a centering axis using at least one elastic body, wherein the sensor assembly comprises at least one optical elements, wherein each respective elastic body is inserted into a recess, which extends parallel to the centering axis and is open towards the interior space, and is clamped there such that each of the at least one elastic bodies exerts a clamping force acting in the respective radial clamping direction on an outer edge of each of the at least one optical elements of the assembly adjacent thereto in the interior space of the housing and to be clamped in the housing.

An inspection apparatus is provided that comprises an optical target including a solid host material and a fluorescing material embedded in the solid host material. The solid host material has a predetermined phonon energy HOST.sub.PE. The fluorescing material exhibits a select ground energy level and a target excitation (TE) energy level separated from the ground energy level by a first energy gap corresponding to a fluorescence emission wavelength of interest. The fluorescing material has a next lower lying (NLL) energy level relative to the TE energy level. The NLL energy level is spaced a second energy gap FM.sub.EG2 below the TE energy level, wherein a ratio of the FM.sub.EG2/HOST.sub.PE is three or more.

A device to measure the amount of light able to transmit through a liquid. The device uses a light detector and multiple light emitting diodes (LED's) along with an optical unit such that the light detector, LED's, and an optical unit define a path of light emitted by each individual LED or subgroup of LED's and detected by the detector. The device uses a structure designed to surround the LED's and light detector such that the structure allows the device to be immersed in the liquid and such that the structure is shaped to allow a volume of liquid to be between the LED's and detector, intersecting the light path.

The present disclosure describes an apparatus of measuring light scattering of a sample.

An inspection apparatus is provided that comprises an optical target including a solid host material and a fluorescing material embedded in the solid host material. The solid host material has a predetermined phonon energy HOST.sub.PE. The fluorescing material exhibits a select ground energy level and a target excitation (TE) energy level separated from the ground energy level by a first energy gap corresponding to a fluorescence emission wavelength of interest. The fluorescing material has a next lower lying (NLL) energy level relative to the TE energy level. The NLL energy level is spaced a second energy gap FM.sub.EG2 below the TE energy level, wherein a ratio of the FM.sub.EG2/HOST.sub.PE is three or more.

The present disclosure describes an apparatus of measuring light scattering of a sample. In an embodiment, the apparatus includes (1) at least one display logically coupled to an enclosure housing a light scattering measurement instrument, where the at least one display is configured to allow for operating the instrument to acquire light scattering data from the sample and for accessing the data, (2) an indicator connected to an outside surface of the enclosure, where the indicator is configured to indicate at least one status of the instrument, (3) a sample chamber configured to accommodate at least one sample cell, where each of the at least one sample cell has a unique size and a unique shape, and (4) and a sample door connected to the enclosure, where the sample door is configured to seal the sample chamber, thereby providing thermal insulation to the sample chamber.

Disclosed herein are seals for liquid-tight bonding of an optical window comprising a BiIn alloy. Also disclosed are optical cells comprising the BiIn alloy seals to provide a liquid-tight seal between a cell housing and a drilled optical window.

An inspection apparatus is provided that comprises an optical target including a solid host material and a fluorescing material embedded in the solid host material. The solid host material has a predetermined phonon energy HOST.sub.PE. The fluorescing material exhibits a select ground energy level and a target excitation (TE) energy level separated from the ground energy level by a first energy gap corresponding to a fluorescence emission wavelength of interest. The fluorescing material has a next lower lying (NLL) energy level relative to the TE energy level. The NLL energy level is spaced a second energy gap FM.sub.EG2 below the TE energy level, wherein a ratio of the FM.sub.EG2/HOST.sub.PE is three or more.