According to one embodiment, an automatic analyzing apparatus includes: a holder including a plurality of placement portions for a reaction tube to be placed thereon; a photometry unit for performing photometry on a solution inside the reaction tube, the photometry unit including a plurality of light emitters and a plurality of first light receivers respectively disposed in the plurality of placement portions; and processing circuitry configured to adjust quantities of light of the plurality of light emitters based on a light quantity signal from a second light receiver that receives light generated by the light emitters and guided by jig inserted into the placement portions.

This automatic analysis apparatus is provided with: an analysis port comprising a reaction container holding part that holds a reaction container storing the liquid mixture of a sample and a reagent, a light source that emits light to the liquid mixture stored in the reaction container held by the reaction container holding part, and a detector that detects light generated when the light from the light source is emitted to the liquid mixture; and a control unit that controls the analysis port, and analyzes the sample on the basis of information about the detected light. The automatic analysis apparatus is characterized in that: the surface of an inner wall of the reaction container holding part is configured to reflect at least a portion of the light emitted from the light source; and the control unit executes control so as to emit the light from the light source in a state where the reaction container is not held by the reaction container holding part, to detect the light reflected on the surface of the inner wall of the reaction container holding part by the detector, and to not use the analysis port for analysis when the result of the detection shows that the detected light is less than a first value determined in advance.

A detecting device for light-emitting property of a light source is provided and the detecting device for light-emitting property of a light source includes: a positioning device configured for fixing the light source; and a detection apparatus configured for acquiring a parameter of an emergent light from the light source. The detecting device for light-emitting property of a light source can detect the light-emitting property of the light source, thus help to select the chrominance and brightness degree, of a light source, required by a display module, and shorten the researching and manufacturing period for a liquid crystal display.

Various embodiments of a light detection device and a method of using the device are disclosed. In one or more embodiments, the light detection device can include a housing that extends along a housing axis between top and bottom surfaces. The device can also include a port that is adapted to receive a sample, and a door connected to the housing. The door can include an actuator portion adapted to selectively move the door between a closed position and an open position, and a cover portion connected to the actuator portion and adapted to close the port when the door is in the closed position and open the port when the door is in the open position to allow external access to the port.

Disclosed is a data acquisition device for optical compensation including a platform for carrying a display panel; and a linear image acquisition module located above the platform. The linear image acquisition module is movable relative to the platform.

A method and associated apparatus are disclosed for measuring illumination characteristics of a luminaire having unknown characteristics. The method includes steps of providing an array of calibrated photodetectors in known locations in proximity to a mounting location, and then illuminating the array with a luminaire having unknown illumination properties. The resulting data is used to calculate the luminous intensity vs. angle from the luminaire and the luminous flux of the luminaire. Methods of calibrating the measurement with a known luminaire are presented along with methods of determining the angular position of the detectors in the array. Color-sensitive detectors can be used to determine the angular distribution and average value of the luminaire's correlated color temperature.

A test fixture used to calibrate an electronic device is disclosed. The test fixture includes several modules positioned on a rack. The modules may include either a stimulus member or light-absorbing material. An actuator connected to an end unit is configured to engage any one of the several modules and transport the module from the rack to a location over the electronic device. At least one module can calibrate a touch sensor of the electronic device, while at least another module can calibrate a proximity sensor of the electronic device. In some cases, an additional module is configured to calibrate a touch sensor of a second electronic device, such as a previous generation of an electronic device or an electronic device having a different dimension. The electronic device can lie on a cradle that may be identified by a feature on the cradle, such as a magnet.

Disclosed are methods and devices for photometric measurements of a liquid sample. The methods and devices use one or more diffractive reflective surfaces to enable a light beam incident on a measurement chamber to be steered so as to be reflected inside the measurement chamber to achieve relatively long optical paths in the measurement chamber. The liquid sample may be blood or blood serum. The measurement chamber may be provided in a microfluidic device, for example a centrifugal microfluidic device. Some embodiments enable multiplexing of different wavelengths or path lengths. Some embodiments make use of multiple returned beams to determine the position and/or orientation of the measurement chamber.

The invention relates to an ion surface trap (10) with (a) an electrode pair (12) that comprises a first trap electrode (14.1) and a second trap electrode (14.2) and is configured to form a trap volume for at least one ion (22) when an electrical AC voltage is applied, (b) at least two AC voltage electrodes (16) arranged to close the trap volume and/or generate an electrical field, by means of which an ion position of an ion (22) trapped in the ion surface trap can be modified relative to the ion surface trap (10), and (c) a sensor for detecting photons (20) emitted by at least one ion (22), wherein (d) the sensor is an energy-sensitive measuring superconductor sensor (18) that has a superconductor layer/separating layer/superconductor layer structure and (e) at least the first superconductor layer (24, 28) forms the first trap electrode (14).

A gauge that is configured to detect a time at which radiation enters the gauge. The gauge may include a member that is configured to transition from a first state to a second state upon receipt of the incoming radiation, and may include a light probe that is configured to detect when the member transitions to the second state. The gauge may provide for determining a time of arrival of the radiation at another gauge. For example, the gauge may correlate the time of arrival at the gauge with the another gauge, thereby providing for correlating a response time of a test specimen with actual exposure time of the test specimen to radiation (e.g., an ion beam).