A universal controller for integration of cryogenic equipment, requiring different control mechanisms, onto a single operating platform. The universal controller may include a power supply element that is configured to simultaneously drive a plurality of cryogenic devices that have different power supply requirements and a protocol translator element that is configured to enable communication between a plurality of cryogenic devices that use different, incompatible communication protocols, wherein the protocol translator element translates communications sent by a first type of cryogenic device from a first cryogenic device communication protocol into a second cryogenic device communication protocol and translates communications sent by a second type of cryogenic device from a second cryogenic device communication protocol into the first cryogenic device communication protocol, enabling the first type of cryogenic device and the second type of cryogenic device to communicate with each other.

An information processing device including a communication portion capable of receiving sensor data detected from a plurality of sensors arranged in predetermined regions and transmitting control signals to a plurality of actuators arranged around the sensors such that the actuators are, at least one by one, associated with each of the sensors. The information processing device further includes a control portion that performs control such that the sensor arranged in a specific region determined not to have an ideal situation is specified on the basis of the sensor data detected from the plurality of sensors, the actuator corresponding to the specified sensor is specified from the plurality of actuators, and the control signal for bringing the specific region into the ideal situation is generated and transmitted to the specified actuator through the communication portion.

A low-powered sensor, a method for a low-powered sensor, and an apparatus are provided for monitoring a condition of a machine. Responsive to receiving a trigger signal during a setup phase, the low-powered sensor collects sensor data for a predetermined extended period of time. The low-powered sensor receives a setting of a delay based on a determined amount of time of the predetermined extended period of time, since the receiving of the trigger signal, for the machine to reach a steady operating condition within predetermined limits. Upon receiving the trigger signal after the receiving of the setting of the delay, the low-powered sensor waits a period of time of the set delay before collecting the sensor data for a predetermined amount of time that is shorter than the predetermined extended period of time, and provides the collected sensor data to a computing device for analysis.

Each of wearable terminals includes a terminal time correction unit configured to correct terminal time of a terminal clock unit based on time data externally acquired, a terminal data generation unit configured to generate terminal data at a predetermined data generation time interval counted based on an output signal of an oscillation circuit, and a data transmission/reception unit configured to transmit the terminal data to an analysis apparatus. The analysis apparatus includes a terminal data correction unit configured to correct, for each of the wearable terminals, terminal time data of the plurality of pieces of terminal data received from each of the wearable terminals. The terminal data correction unit corrects the terminal time data of the plurality of pieces of terminal data in such a way that intervals between the terminal time data of the plurality of pieces of terminal data become even on the time axis.

The system comprises: a remote control station; a plurality of detection devices for the detection of noise which are located inside an area to be monitored; a master device adapted to receive noise level data from the detection devices and adapted to send the data to the remote control station, the master device being provided with a client communication module configured to communicate with the remote control station and with an access point communication module configured to communicate with one of the detection devices; wherein each of the detection devices is provided with a client communication module configured to communicate with the access point communication module of the master device, the detection devices and the master device being located in predetermined positions and in a substantially homogeneous manner inside said area for the detection of noise level data which are certifiable and homogeneous both in terms of spatial distribution and in terms of time distribution.

A system and a computer-implemented method for providing responder information are disclosed herein. The method includes receiving, via a computing device, a sensor data generated by one or more safety devices corresponding to one or more responders. The computer-implemented method further includes analyzing, via the computing device, the sensor data to generate an analyzed sensor data. The computer-implemented method further includes establishing, via an application programming interface (API), a direct communication link between the computing device and at least one server or establishing, via a local application, a direct communication link between the computing device and at least one third party server. The computer-implemented method further includes transmitting, via the computing device, the analyzed sensor data to the at least one server or transmitting, via the computing device, the analyzed sensor data to the at least one third party server.

Systems and methods for temperature monitoring and environmentally related calculations are disclosed herein. A system according to embodiments herein may include a memory, a network interface, and one or more processors. The system may receive one or more environmental readings from a sensor taking readings at an environmentally controlled area. The system may further determine a timestamp corresponding to each of the one or more readings and calculate, using the one or more readings and their corresponding timestamps, an exposure of a good stored within the temperature controlled area. The system may further determine that the calculated exposure of the good has surpassed a pre-determined exposure threshold for the good and send an electronic message configured to indicate such determination to a user. The system may use a neural network to predict future readings based on current readings and use the predicted future readings in methods described herein.

Methods and apparatus, including computer program products, are provided for remote monitoring. In some example implementations, there is provided a method. The method may include receiving, at a remote monitor, a notification message representative of an event detected, by a server, from analyte sensor data obtained from a receiver monitoring an analyte state of a host; presenting, at the remote monitor, the notification message to activate the remote monitor, wherein the remote monitor is configured by the server to receive the notification message to augment the receiver monitoring of the analyte state of the host; accessing, by the remote monitor, the server, in response to the presenting of the notification message; and receiving, in response to the accessing, information including at least the analyte sensor data. Related systems, methods, and articles of manufacture are also disclosed.

A data system for tracking use of a work tool attachment that may be interchangeably attached to a machine includes a data transmission device located on the work tool attachment and an electronic machine controller that may be located on the machine. When an event occurs with respect to the work tool attachment, the data system collects a first tool data set from the data transmission device and a first set of machine data associated with the machine. When another event occurs with respect to the work tool attachment, the data system collects a second tool data set from the data transmission device and a second set of machine data. The first and second tool data sets and the first and second sets of machine data may be entered in one or more data logs for analytics.

A device management system includes a device information transmitting apparatus that collects information about a device, and a management apparatus that communicates with the device information transmitting apparatus via a communication network. At least one of the management apparatus and the device information transmitting apparatus includes an anomaly state input unit that receives an anomaly state of the device, and a designating unit that designates, in accordance with the received anomaly state, first information to be used to identify a cause of the anomaly state of the device. The device information transmitting apparatus includes a first information transmitting unit that transmits the first information to the management apparatus.