The present application provides a sample rack conveying apparatus, a sample rack conveying pipeline, and a sample rack conveying method. The sample rack conveying apparatus includes a track, a detector and dual-channel track switching areas. The detector provided at an outside of the analysis areas to detect whether there is a test tube or not. The dual-channel track switching areas are defined at two ends of the track and positions between every two analysis areas. The track includes an outer track and a parallel inner track. The inner track defines at least two analysis areas. The dual-channel track switching areas include two parallel connecting channels. The connecting channels are moved along a direction perpendicular to the track to transfer the tracks between the inner track and the outer track.

To minimize cross talk in systems and methods for detecting two or more different optical signals emitted from each of a plurality of reaction receptacles, an excitation signal associated with each of the optical signals has a known excitation frequency, and any detected signal having a frequency that is inconsistent with the excitation frequency is discarded. The receptacles are moved relative to optical sensors configured to detect each unique optical signal from an associated receptacle, and to further minimize cross talk, the optical sensors are arranged so that only one reaction receptacle at a time is in a signal detecting position with respect to one of its associated optical sensors, and the optical sensors are grouped by the optical signal they are configured to detect so that a first optical signal is detected from each of the reaction receptacles before a second optical signal is detected from the reaction receptacles.

The present invention lies in the field of automated analyzers and relates to an automated warning system for potentially erroneous measurement results, which may be caused by the loss of a liquid container during a transport process.

In an example, a method for preparing a nucleotide solution includes flowing an aqueous solution from an initial solution storage of a sequencing instrument continuously through a container fluidically coupled to the sequencing instrument, the container comprising a nucleotide concentrate; and collecting the aqueous solution with nucleotide in a storage container.

Provided is a test system operable with a simplified structure. A test system includes a first test device and a second test device each of which transports and tests a sample. The test device includes a master control unit, which performs assignment of samples to the first test device and the second test device, and control of a transport operation of the sample assigned to the test device. The test device includes a slave control unit, which controls a transport operation of the sample assigned to the test device by the master control unit.

A laboratory sample distribution system with a number of sample container carriers, each comprising at least one magnetically active device and adapted to carry a sample container; a transport plane adapted to support the carriers; a number of electro-magnetic actuators stationary arranged below the transport plane and adapted to move a corresponding carrier located on top of the transport plane by applying a magnetic force to the carrier; a touch panel arranged below the transport plane adapted to generate position signals (PS) depending on positions of the carriers located on top of the transport plane; a position determination unit adapted to determine the positions of the carriers located on top of the transport plane in response to the position signals (PS); and a control unit adapted to control the operation of the laboratory sample distribution system in response to the determined positions of the carriers.

Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

Provided is a connection module with a high degree of freedom for an automatic analyzer which does not depend on a device as a discharge destination. For this purpose, a module to be connected to an automatic analyzer with a rack rotor mechanism includes: a rack discharge mechanism for moving a rack from the rack rotor mechanism to a rotation holder; a rack rotating mechanism for rotating the rack moved to the rotation holder; a conveyor mechanism for transporting the rack from the rack rotating mechanism to a discharge port; and a feeder mechanism for pushing the rack out of the rotation holder to the conveyor mechanism, in which the rack rotating mechanism rotates the rotation holder from a direction parallel to the rack discharge mechanism to a direction parallel to the feeder mechanism and the conveyor mechanism in the selected rotation direction.

A device includes sample tray units, a sample tray transporting unit, a sample tray handling unit, and a sample tray radiation stage unit. The sample tray units are configured to load samples. The sample tray transporting unit is configured to carry a sample tray unit to a radiation room. The sample tray handling unit is between the sample tray transporting unit and the sample tray radiation stage unit, and is configured to transfer the sample tray unit on the sample tray transporting unit to the sample tray radiation stage unit or return the sample tray unit on the sample tray radiation stage unit to the sample tray transporting unit. The sample tray radiation stage unit is configured to carry the sample tray unit and move the samples to be irradiated in the sample tray unit to a particle beam radiation area to receive radiation.

Provided are methods and apparatuses for controlling a position of a target point on a processing result relative to a focus point of a focusing sensor system for determining properties of the processing result. The method includes the steps of determining an initial focus point of the focusing sensor system, controlling rotation of the cartridge and disc, checking whether the initial focus point of the focusing sensor system corresponds to the target point on the processing result, comparing (x, y) target positions in captured images with the initial focus point of the focusing sensor system, adjusting rotation of the cartridge and disc such that the focus point of the focusing sensor system corresponds to the target point on the processing result, and detecting and examining signals received from the focusing sensor system for determining properties of the processing result.