A computerized component, designed to be used in a vehicle, is able to detect an ambient environmental variable; determine a memory profile corresponding to the ambient environmental variable; access memory parameters from the memory profile; and configure memory of the computerized component based on the accessed memory parameters. Another computerized component may be used to detect that the computerized component is initiating a shutdown procedure; obtain an ambient environmental variable, the ambient environmental variable indicating a state of an operating environment of the computerized component; identify memory parameters of random access memory integrated with the computerized component; and write the memory parameters to a memory profile stored in non-volatile storage in the computerized component, the memory profile keyed to the ambient environmental variable.

A system for monitoring the characteristics of a material by measuring electrical properties of a material uses a material monitoring device and a cloud database that relates electrical properties of a material to characteristics of that material. The aging and fermentation processes of wine and other alcohols can be monitored. The status and decomposition of foodstuffs can be monitored. The progress of chemical reactions in a vessel can be monitored. Water quality of water from a water conduit can be monitored. These characteristics can be indicated on a product monitoring device or can be communicated to an external computing device.

One variation of a method for tracking temperature exposure of foodstuffs within an automated sandwich assembly apparatus includes: at a topping module, receiving first topping sample and a second topping sample in a column of topping samples; at a first time, determining a first temperature of the first topping sample; in response to the first temperature of the first topping sample exceeding a threshold temperature, setting a first timer assigned to the first topping sample; cutting a slice from the second topping sample; following dispensation of the slice of the second topping sample from the topping module, tracking a position of the first topping sample within the topping module; and in response to expiration of the first timer prior to dispensation of a final portion of the first topping sample from the topping module, disqualifying the final portion of the first topping sample from dispensation onto a topping vehicle.

Systems and methods of the invention relate to methods and systems that collect data regarding a keg or container via a sensor, wherein such data collected is used to glean information regarding the container, the contents of the container, a location of the container, or an environment in which the container resides. The sensor can be affixed to a container which communicates wirelessly with a gateway device and the gateway device communicates such collected data to a track component. The track component can be configured to receive data from the sensor(s) and gateway device(s) and identify conditions to improve the quality of the contents of the container, track a location of the container, and among others.

A system may include a fiber optic cable buried under a surface and a smart sensor module coupled to the fiber optic cable. A controller may be coupled to the smart sensor module. The smart sensor module includes a light source coupled to an end of the fiber optic cable and a detector coupled to the end of the fiber optic cable. The controller may manage a transmission of a pulse of light from the light source to launch the pulse of light into the fiber optic cable. The detector may receive a backscatter generated from the pulse of light scattered off fiber molecules of the fiber optic cable. The smart sensor module may determine a temperature of the fiber optic cable based on an intensity of the generated backscatter. The controller may send an alert when the determined temperature is outside a predetermined threshold range from a base temperature.

A system may include a fiber optic cable buried under a surface and a smart sensor module coupled to the fiber optic cable. A controller may be coupled to the smart sensor module. The smart sensor module includes a light source coupled to an end of the fiber optic cable and a detector coupled to the end of the fiber optic cable. The controller may manage a transmission of a pulse of light from the light source to launch the pulse of light into the fiber optic cable. The detector may receive a backscatter generated from the pulse of light scattered off fiber molecules of the fiber optic cable. The smart sensor module may determine a temperature of the fiber optic cable based on an intensity of the generated backscatter. The controller may send an alert when the determined temperature is outside a predetermined threshold range from a base temperature.

An artificial produce includes a housing with at least one shell. At least one data logger for temperature measurement is placed in an area of a core of the housing and a pulp simulant is integrated at least partly in the housing of the artificial produce to show optimized simulation of thermal behavior of real produce. The form and outer surface of the at least one shell replicate the form and surface texture of the real produce simulated. The at least one shell forms at least one fluidtight chamber accessible from the outside by at least one opening which are closable with plugs. The at least one chamber is filled with the pulp simulant in the form of a gel-like filling composition comprising a water-carbohydrate mixture and a gelling agent showing similar thermal conductivity, density, heat capacity and freezing point as the pulp of the produce to be simulated.

The invention relates to a device (6) for communicating data with a data logger (28) that measures the temperature of ambient gas and logs the temperature data into a memory (55). The device (6) includes a body (73) for mounting a data logger (28) thereon, wherein the data logger (28) is disposed inside a capsule (12, 40). The data logger (28) includes: top and bottom covers (50, 51) that define an enclosed space and includes an electrical circuit (52) disposed in the enclosed space and having a memory (55) for storing data; a pair of electrodes (71, 72) for extending through two holes (18, 32) formed in the capsule (12, 40) and contacting the top and bottom covers (50, 51) of the data logger, respectively; a processor (1001) for retrieving data stored in the memory (55) through the pair of electrodes (71, 72); and a communication device (1015) for transmitting the data.

Memory gauge and method for processing recorded raw data acquired with a memory gauge in a well. The method includes selecting a first calibration table (C.sub.1), of the memory gauge, that has a highest calibration value for the measured parameter; performing a first analysis of the recorded raw data using the first calibration table (C.sub.1) to determine a highest measured value of the measured parameter; comparing the highest measured value of the measured parameter with highest calibration values of the plural calibration tables of the memory gauge; and when a highest calibration value of a second calibration table is closer to the highest measured value of the measured parameter than the highest calibration value of the first calibration table, selecting the second calibration table (C.sub.2); and performing a second analysis of the recorded raw data using the second calibration table (C.sub.2) to generate measured values of the measured parameter.

Embodiments for assessing energy usage efficiency in a fluid transfer pumping system in a cloud computing environment by a processor. A rate of temperature decay may be determined over a selected time period using a temperature signal collected by one or more non-intrusive Internet of Things (IoT) sensors located at one or more selected positions of a piping network in the fluid transfer pumping system so as to determine energy efficiency in the fluid transfer pumping system associated with a heating service, a cooling service, or combination thereof.