The present disclosure provides implants, sensor modules, networks, and methods configured to establish transcutaneous power and transcutaneous bidirectional data communication using ultrasound signals between two or more medical devices located on and within a body of a patient.

Sensor intended to be positioned on a mobile portion of a deployable structure, and to emit an information signal to a transmission unit intended to be positioned on a fixed portion of the deployable structure, such that the sensor comprises a wireless emitter/receiver configured to receive an incident signal originating from the transmitting unit when the deployable structure is in a folded position; a processing logic unit adapted to decide on the emission of the information signal to the transmission unit by the wireless emitter/receiver; a standalone energy source configured to power the processing logic unit.

A system for cabling infrastructure that includes at least one port, at least one shutter, at least one sensor and a gateway is provided. The port is configured to be selectively coupled to a connector. Each shutter is configured to have an open state that allows access to an associated port and a closed state that covers the port. Each sensor is configured to sense the open state and the closed state of an associated shutter and generate shutter state signals that include information relating to a current sensed state of the associated shutter and an identification of a port that is associated with the associated shutter. The gateway is in wireless communication with each sensor to receive the shutter state signals. The gateway is configured to communicate the shutter state signals that indicate a change in a state of an associated shutter to a remote location.

Embodiments of the present technology may include a system for tracking and monitoring, including a fastener, a triggering mechanism coupled to the fastener for reacting to physical movement of the fastener resulting from tampering, destruction, or uncoupling; a generator; a tracker coupled to the fastener, wherein the tracker determines a triggered event, and wherein the tracker switches to a low power mode based on an event.

Sensor having a control unit, configured to analyze data available to the sensor, in particular measurement data of the sensor, for generating power management data, the power management data being configured to for select a power saving mode from a plurality of available power saving modes of a wireless module (103) of the sensor and/or for controlling the times of measurement intervals of the sensor and/or for power management of the sensor.

A measuring assembly with at least two measuring devices and a higher-level unit, characterized in that the measuring assembly further has a network distributor, wherein the measuring devices are connected to the network distributor via a two-wire Ethernet connection, the measuring devices are fully supplied with power via the two-wire Ethernet connection, and the network distributor is connected to the higher-level unit with an Ethernet connection.

There are provided a sensor data collection device, a sensor data collection system, and a method of collecting sensor data capable of reducing a drain of a battery due to standby power. The sensor data collection device includes a power supply, a power supply control circuit configured to control the power supply, a sensor configured to perform sensing to thereby obtain data, a memory configured to store the data obtained by the sensor, and a control circuit configured to control the power supply control circuit, the sensor, and the memory. The power supply control circuit supplies the sensor, the memory, and the control circuit with electrical power supplied by the power supply, and the control circuit makes the transition to any one of a plurality of operating states, and makes the power supply control circuit shut off the electrical power supplied by the power supply after a first operating state is completed and before the transition to a second operating state is made wherein the first operating state and the second operating state are included in the plurality of operating states.

A drag pointer configured for calculating a process measurement variable including calculation circuitry for approximately calculating a past temporal development of the value of the process measurement variable from process measurement data of a measuring device, and for calculating the current value of the process measurement variable from the past temporal development.

An aerological sonde for measuring meteorological conditions in a cyclonic storm, the aerological sonde including a sonde casing having an outer casing surface and measurement unit arranged inside the sonde casing. The outer casing surface is arranged to form a sole drag surface of the aerological sonde such that a self-sustaining aerological sonde is formed. The measurement unit of the self-sustaining aerological sonde includes a turbulence sensor arranged to measure change of movement of the self-sustaining aerological sonde.

The embodiments disclose an apparatus including a test cartridge configured for inserting into a reader, a sample insertion component coupled to the test cartridge a test sample, a heater device coupled to the test cartridge configured to heat to a predetermined temperature the test sample, a sensor array coupled to the test cartridge consisting of at least one electrochemical sensor for sensing analytes in a sample, a reader configured to gather test related data from the sensor array coupled to the test cartridge, an analyzer coupled to the reader configured for determining test results of each sensor in the sensor array and comparing all the test results for confirmation of a valid test and coherent results, a MCU (Microcontroller Unit) to perform main control and processing functions, and orchestrates all the functionality for the Reader, and a BLE Radio RF link between the MCU and an external processing system.