A method for controlling the mixing of a plurality of samples subject to a chemical process, the method comprising computer executed steps, the steps comprising: for each one of the samples, receiving respective data on a result obtained for the sample using the chemical process, and for each one of at least two of the samples, further receiving respective data on classification of the sample into one of at least two classes, for each one of the samples, calculating a respective rank based on the result obtained for the sample using the chemical process, finding among the samples, at least one pair of samples classified into different ones of the classes, such that for each respective one of the found pairs, none of the samples having a calculated rank in between the ranks calculated for the two samples of the found pair are classified into one of the classes.

A method of operating a laboratory sample distribution system is presented. The system comprises container carriers, a gateway having a network interface, and transport modules. Each module comprises a transport surface and are adjacent in a row-direction and column-direction to form a transport surface. The module comprises a driver arranged below the transport surface to move container carriers on the transport surface and left, right, upper and lower network interfaces. The left and right network interfaces connect modules in rows and the upper and lower network interfaces connect modules in columns. The network interface of the gateway is connected to a network interface of a first module. The method comprises sending an explore command from the gateway to the first module, propagating an initialization command from the first module to the remaining modules, storing addresses within the modules, and using the addresses by the gateway to address the modules.

An inspection result of a specimen inspection automation system can be reported within a prescribed time, even if a large number of urgent specimens have been input. An instruction reception unit receives turn around time (TAT) information and a discharge instruction. The necessity of discharging a specimen for which the instruction was issued with the discharge instruction is determined and a discharge instruction unit creates a discharge destination and a conveyance route to the discharge destination for the specimen. A discharge mechanism discharges the specimen for which the instruction was issued. Even for a specimen which is caused to wait for processing due to the occurrence of specimen congestion and for which there is a risk of an inspection result reporting delay, an inspection result can be reported within a prescribed time by switching from automatic processing by the system to manual processing by an operator.

A device and method for testing foodstuffs for the presence of microorganisms including an infeed unit for a package containing a foodstuff, a sample analysis device configured to take a sample of the foodstuff and test for the presence of microorganisms, a discharge unit for discharging the package, and a display for displaying the results of testing by the sample analysis device.

An input section of an incubator accepts, from a user, a first input selecting a specified incubation container which registers an observing schedule, and a second input specifying an imaging condition of the specified incubation container in an observing sequence. A calculating section calculates, according to the above-mentioned imaging condition, an observing duration of the specified incubation container from a first data relating to a carrying period of an incubation container and a second data with regard to an imaging duration. A schedule management section extracts, based on a schedule data, a registrable time zone in which an observing sequence of the specified incubation container can be executed without overlapping with previously registered observing schedules, and outputs to display the registrable time zone for presentation to the user.

A method is presented. The method includes receiving at least one order, generating one or more optimization problem instances using one or more resource descriptions of automated laboratory equipment, one or more protocol descriptions of the automated laboratory equipment, an objective function and the at least one order. The method further includes providing the one or more optimization problem instances as input to a constraint optimization solver and processing the one or more optimization problem instances by the constraint optimization solver to generate the schedule of operations to carry out the at least one order on the automated laboratory equipment.

In some embodiments of the invention, the central controller may comprise a processor and a computer readable medium coupled to the processor. The computer readable medium comprises code, executable by the processor to implement a method. The method comprises identifying, by the processor, a sample container or a sample container holder associated with the sample container, and then accessing, by the processor, a location database storing mapping data correlating sample containers or sample container holders with sample containers to test regions in the storage unit. The test regions store sample containers with samples that have been or are to be tested according to different tests. After accessing the database, the method continues by providing, by the processor, a proposal for storage of the sample container or the sample container holder associated with the sample container in the storage unit.

An automated laboratory system for processing biological samples in a batch type manner is disclosed. In one embodiment, the system may receive assay instructions for biological samples processing among a plurality of devices. The devices may include a pre-analytical instrument and one or more analysis systems. The system may include an orchestration core application for determining an order of performance for the assays ordered for the samples.

Disclosed are high-throughput vessel receiving systems and methods of receiving sample vessels, such as samples stored in test tubes. A system for receiving a plurality of individual vessels that each contains a sample, and systems and apparatus for guiding, reorienting, collecting, and transporting a plurality of articles, including vessels, are disclosed.

Disclosed are high-throughput vessel receiving systems and methods of receiving sample vessels, such as samples stored in test tubes. A system for receiving a plurality of individual vessels that each contains a sample, and systems and apparatus for guiding, reorienting, collecting, and transporting a plurality of articles, including vessels, are disclosed.