A beehive system includes a processing system for monitoring and controlling a beehive. The beehive can include a bottom board, one or more boxes, and an outer cover. The one or more boxes can contain bees and bee materials, as well as various components and sensors for monitoring and controlling conditions in the beehive. The beehive can include one or more sensors for monitoring a corresponding one or more conditions inside the beehive, and one or more control elements for manipulating the one or more conditions inside the beehive.

Devices and meters comprising: a housing configured to mount to a pole supporting an existing meter, the housing defining an interior; a sensor within the interior of the housing, the sensor configured to collect environmental information pertaining to the local external environment of the existing meter; a wireless radio within the interior of the housing, the wireless radio configured to transmit the environmental information to the existing meter or to a remote server in communication with the existing meter; a power unit within the interior of the housing, the power unit supplying power to the sensor and the wireless radio.

A multi-function acquisition device comprising a connector having two connection terminals, and an electronic circuit that comprises an acquisition circuit configured for enabling the digital conversion of analogic signals from a sensor, and the memorization of the digitized signals in a memory; a harvesting circuit configured for enabling the transmission of data stored in the memory to a harvesting device; a charging circuit configured for enabling the charging of a battery with the power provided by a powering device. A control unit controls the activation of the acquisition circuit, the activation of the harvesting circuit, and the activation of the charging circuit.

A healthcare device and a vehicle system are capable of charging a sensor device that measures a biosignal. The healthcare device includes the sensor device that includes a biosignal measuring sensor that measures the biosignal and uses the biosignal measuring sensor as a charging electrode during charging, a healthcare controller that collects and calculates the biosignal measured through the biosignal measuring sensor, a sensor device battery that receives power from an external pogo pin through an electrode of the biosignal measuring sensor during charging by the charging electrode to charge a power supply of the sensor device battery, and a selecting device that connects the biosignal measuring sensor to any one of the healthcare controller and the sensor device battery.

In one example, a method for optimizing operational parameters of a hardware implemented telemetry system is provided. The operational parameters can include a performance characteristic, an energy use, data creation, and a cost. The operation parameters are monitored. The method further includes adjusting a balance between the operational parameters in accordance with a predetermined operational guideline.

A power control system with a power management apparatus and a power monitoring control apparatus for each control segment. The power monitoring control apparatus is provided with: a contribution degree setting unit setting the degree of contribution of each control segment; a device control unit controlling the power consumption of each power using device connected; a priority control unit setting a priority for reducing the power of the power using device; and a device monitoring unit obtaining the priority of each power using device and transmitting the obtained priority to the power management apparatus. The power management apparatus is provided with an optimum control calculation unit determining a control command for controlling each power using device connected. The control command is determined based on: a target value of the total power consumption of all the control segments; the degree of contribution; and the priority of each power using device.

A submarine gas-leakage monitoring system for long-term detection of gas and a method of operating the same are disclosed. The submarine gas-leakage monitoring system includes: a buoy equipped with a satellite communication unit to transmit acquired data to a satellite or to receive a command for activation or inactivation of a first submarine sensor from the satellite when the buoy is raised to float on the seawater surface; a seabed observation unit located close to a seabed, the seabed observation unit acquiring and storing information about gas leakage from the seabed and controlling the buoy such that the buoy is raised or lowered; and a signal cable equipped with the first submarine sensor that detects migration or diffusion of leaked gas and connected between the buoy and the seabed observation unit to allow a signal transmission between the buoy and the seabed observation unit.

Embodiments of the present invention relate to an industrial wireless sensor system and aim to provide an industrial wireless sensor system in which three types of sensors (e.g., magnetic field detection sensor, limit sensor, proximity sensor), which are conventionally provided only as wired sensors, are replaced with wireless sensors. To that end, according to the present invention, there is disclosed an industrial wireless sensor system, comprising a sensor sensing an external physical state and outputting a sensing signal, a sensor controller converting the sensing signal from the sensor, converting the sensing signal into a digital signal, and outputting the digital signal, a wireless communication unit receiving the digital signal from the sensor controller, converting the digital signal into a wireless signal, and outputting the wireless signal to a factory controller, a power source supplying power to each of the sensor and the sensor controller, and a battery connected to the power source.

An ultra-low pressure, vapor analyte, and vapor pathway parameter monitoring system can include an embedded server comprising a base radio and memory. In some embodiments, the embedded server is communicatively coupled to a third-party database. The system can include a first monitoring device comprising a first ultra-low pressure sensor and a first radio communicatively coupled to the base radio. The embedded server can be remotely located with respect to the first monitoring device whereby the embedded server receives first pressure data from the first monitoring device.

An apparatus for connecting a wireless sensor may include a charging battery which is self-powered, a measurement sensor configured for performing wireless communication and receive power from the charging battery, and a vehicle controller configured to be connected to the measurement sensor through wireless communication and receive measured data.