In an embodiment, a computer-implemented method of tracking soil sampling in a field is disclosed. The method comprises receiving, by a processor, digitally stored field map data and digitally stored sampling data. The method further comprises displaying, by the processor, a field map depicting the first set of sampling points in a computer-generated graphical user interface. In addition, the method comprises receiving a selection of a first sampling point and displaying first sampling data associated with the first sampling point. The method also comprises receiving an update indicating that a soil sample has been collected at the first sampling point. Finally, the method comprises determining a second sampling point at which a next soil sample is to be collected and displaying the second sampling point in the field map.

A system for tracking one or more subjects for collecting airborne contaminants. The system includes one or more subjects configured to collect air contaminants. Each of the one or more subjects includes an identification tag encoded with identification information identifying the each subject. The system further includes an identification reader configured to decode the identification information encoded within the identification tag of a scanned one of the one or more identification tags. A computer receives and stores the decoded identification information in a record in a database. The computer may also receive and stored an identification code for a user who scanned the scanned identification tag in the record in the database. Additional records in the database are created each time the identification tag of one of the one or more subjects is scanned. The one or more subjects are thereby tracked as they collect airborne contaminants and are incubated.

A method and corresponding apparatus for monitoring air quality while allowing the real tracking of both gaseous and powder pollutants and the identification of the sources of pollution, includes the use of a network of monitoring stations mutually arranged at a maximum distance between one and three kilometers in a straight line, wherein each station is positioned at a vertex of a plurality of adjacent triangles or meshes into the geographic zone to be mapped, wherein each monitoring station is configured to pre-process the air data quality together with the weather data and to send it with its GPS coordinates to a central collection and processing computer, and wherein the data received by the single stations are classified, recorded and processed in real time using an algorithm configured to directly provide the positions of the pollution sources.

In various embodiments, the invention is a versatile, automated system to allow researchers to continuously measure gas flux rates from multiple chambers over time without (or with reduced) need for personnel in the field. The invention is compatible with any high-frequency analyzer or vial filler and most chamber designs.

A method of monitoring hygiene or cleanliness, the method comprising a robot collecting at least one sample from a location, performing at least one test on the at least one sample to generate at least one data point, wherein said at least one data point is an indicator of hygiene or cleanliness of the location from where the sample was collected and recording the data point in a data file.

The present disclosure provides an integrated collection, filtration, and analysis system which is configured to automatically collect fluid samples from a surrounding open water environment, isolate floating particles of a target size range, and perform analysis on the collected particles in-situ. The particles may also be filtered by one or more parameters other than size, and also provided herein is a two-stage vortex filter specially adapted to isolate floating particles of a desired density range from a fluid.

In accordance with the invention, there is provided a method of obtaining samples from a body of water by a marine vessel in a body of water the marine vessel comprising an electronic device, the method comprising: obtaining a predefined model data of a first water sample device, generating a first primary control signal for the first water sample device and performing a first movement of a first testing part in a first position in the body of water, receiving a first sensor data from the first water sample device, generating first comparison data where the first sensor data is compared with the predefined model data of the first water sample device, generating a second primary control signal to the first water sample device based on the first comparison, performing a second movement of the first water testing part relative to the body of water.

Disclosed is a sampling device, a sampling system and a method of collecting samples of particulates. Also disclosed a sampling device, a sampling system and a method of generating data associated with the collection of the samples of particulates. Also disclosed is a system and method for analysing the sample data to identify the particulates in the collected samples and their one or more characteristics which may be correlated with the surrounding environment.

Provided herein are systems and methods allowing for automated sampling and/or analysis of controlled environments, for example, to determine the presence, quantity, size, concentration, viability, species or characteristics of particles within the environment. The described systems and methods may utilize robotics or automation or remove some or all of the collection or analysis steps that are traditionally performed by human operators. The methods and systems described herein are versatile and may be used with known particle sampling and analysis techniques and particle detection devices including, for example, optical particle counters, impingers and impactors.

A system and method are provided for warning of an exposure of a second individual to an allergen by transfer from a first individual. Movements of the individuals are tracked so that allergen types and levels to which the individuals have been exposed can be obtained. Using knowledge of user sensitivity information to different allergens, it is determined if the first individual has been exposed to allergen types and levels which pose a risk to the second individual by GPS transfer from the first individual to the second individual. Thus, action can be taken when there is a determined risk of allergen transfer between individuals.