A method of improving agricultural treatment includes collecting a machine data set, analyzing the machine data set to identify a mineralogical feature, generating a clay characterization by analyzing the mineralogical feature, and generating an agricultural prescription. A system includes a processor and a memory storing instructions that, when executed by the processor, cause the system to collect a machine data set, analyze the machine data set to identify a mineralogical feature, generate a clay characterization by analyzing the mineralogical feature, and generate an agricultural prescription. A non-transitory computer readable medium containing program instructions that when executed, cause a computer to collect a machine data set, analyze the machine data set to identify a mineralogical feature, generate a clay characterization by analyzing the mineralogical feature, and generate an agricultural prescription.

A detection system including a detection device and an assay device. The detection device includes a space for receiving an assay device, a drive arrangement engaging the assay device to rotate the assay device, a light source arranged to direct light towards the assay device, and a diffuser arranged to diffuse light from the light source. The diffuser is arranged between the light source and the space. The detection device includes a light receiver arranged to receive light from the light source that has passed through the assay device.

The equipment for the traceability of biological samples placed in cassettes provided with encoded identification data and intended to be stored within baskets, the general shape of which may vary from one basket to another includes at least one container to accommodate at least one basket, at least one apparatus for reading encoded data affixed on cassettes arranged in at least one basket placed in the container, a device for computerized processing of the data read by the apparatus for reading, and a device for identifying the shape of the basket placed in the container.

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 an analytical laboratory is presented. The method comprises recording time at which samples are first identified; retrieving an order list comprising test orders for the samples; retrieving a degradation limit to each test order; determining workflows for each sample; instructing the laboratory instruments to carry out the test orders according to the workflows. Determining the workflows comprises i) determining target instruments capable of carrying out the test orders; ii) determining a sequence/timing of the test orders; iii) calculating an estimated completion time for each test order; iv) determining a lead time for each sample and test order; v) prioritizing test orders if the lead time exceeds the degradation limit. Steps ii) to v) are repeated until the lead time doesn't exceed the degradation limit for any of the test orders; or until steps ii) to v) have been repeated for a number N of iterations.

Pre-registration information representing a correspondence relationship between analysis information representing a condition in regards to analysis or preparation of a sample, and a tray ID or a container type ID of a sample container is acquired by a pre-registration information acquirer. The tray ID or the container type ID is acquired by a tray ID acquirer or a container type ID acquirer from an automatic sample injector. The analysis information corresponding to the tray ID or the container type ID is specified by an analysis information specifier based on pre-registration information. Holding information representing whether a sample is held in a tray is acquired by a holding information acquirer from the automatic sample injector. A batch file is created by a batch file creator based on the holding information and the analysis information.

In an example, an apparatus includes a biological analysis component and a control component. The biological analysis component is configured to obtain an expected biological sample value. The expected biological sample value indicates an expected concentration of a material biologically processed by a courier. The biological analysis component is further configured to determine whether a measured biological sample value is associated with the courier based on a comparison of the expected biological sample value to the measured biological sample value. The control component is configured to perform a first set of operations based on the result of the comparison indicating that the measured biological sample value is associated with the courier. The control component is configured to perform a second set of operations based on the result of the comparison indicating that the measured biological sample value is outside an acceptable range of the biological sample value.

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 high throughput system and method for analyzing the effects of a plurality of agents on planaria is disclosed. Multiple test zones are provided, where each test zone contains at least a portion of one planarian. The planaria in each test zone are then exposed to at least one agent, the test zones are sealed, and at various times, the test zones are moved automatically between a storage location and at least one assay station. At each assay station, the test zones are exposed to a set of conditions, and an image or video of the planaria in the test zones are captured. Automated image or video analysis is used to are evaluate and determine whether the agent has an effect.

A sample identification system for an automated sampling and dispensing device is described. In an example implementation, the sample identification system includes a sample probe configured to contact a sample positioned within a sample vessel. Further, the sample identification system includes an identifier capture device configured to measure a sample identifier associated with the sample vessel and generate a data signal in response thereto, where the data signal corresponds to an identity of the at least one sample. During operation, the identifier capture device scans a sample holder, a sample vessel, or a table top of the automated sampling and dispensing device to measure the sample identifier and to generate the data signal in response thereto.