A wireless terminal includes a memory that stores a parameter, a microcomputer that operates in an operation mode, which is predetermined, on the basis of the parameter, and a wireless communication device that wirelessly receives a change command of the parameter. When the change command is wirelessly received, the microcomputer suspends the operation and changes the parameter on the basis of the change command.

A trailer monitoring system for monitoring a trailer having at least one trailer sensor has a bridge integrator unit, configured to couple with the trailer, including a wireless data transceiver electrically coupled with a microcontroller and capable of wirelessly communicating data over a short-range wireless protocol; the bridge integrator unit receives data existing in a first messaging format that is compatible with and used by one or more trailer sensors via a short-range wireless protocol, extracts the data, encodes the data into a second messaging format that is compatible with a master control unit having a telematic data transceiver capable of cellular data communications, and transmits the data in the second messaging format from the bridge integrator unit to the master control unit via a short-range wireless protocol.

A compact surveillance system (CSS) comprising: a power input configured to provide power to the system; one or more sensors configured to measure a measurand; a receiver configured to receive an external signal; and a processor configured to generate information, the processor being in electrical communication with: the one or more sensors; an information storage device configured to store the information; a transmitter unit configured to transfer the information; wherein the information is generated based on the measurand so as to reduce a transfer energy.

Disclosed is a reader device, system, and method for communicating with a wireless sensor. The reader device may be configured to communicate wirelessly with an implant device associated with a proprietary system provided by a first entity. An external device, that may not be associated with said first entity, is provided and is configured to be calibrated to communicate with the implant device that is located within a patient. The external device may be used in place of an existing reader device that was initially calibrated to communicate with the implant device prior to the implant device being placed within the patient. The external device may be particularly useful for implant devices that communicate wirelessly with external devices where said implant devices are intended to be located within the human body on a permanent or indefinite duration of time.

A wireless sensor assembly incudes a housing, a wireless power source, a wireless communication component, and firmware. The housing defines a first aperture for receiving an external sensor and a second aperture defining a communication port configured to receive a wire harness. The wireless communications component and the firmware are powered by the wireless power source. The wireless communications component is configured to be in electrical communication with the external sensor and transmit data from the external sensor to an external device. The firmware is configured to manage a rate of data transmittal from the wireless communications component to the external device. The wireless power source, the wireless communications component, and the firmware are mounted within the same housing. The data from the external sensor is transmitted from the external sensor wirelessly through the wireless communications component or through the wire harness to the external device for processing.

Provided is an energy harvester and an engine monitoring system. An engine monitoring system using an energy harvester includes at least one or more self-power generation wireless sensor nodes for generating electric energy using the energy harvester and monitoring an engine; and a management server that receives and manages sensing information received from the self-power generation wireless sensor nodes. The self-power generation wireless sensor nodes includes sensor modules monitoring the engine; a data processing unit identifying and packaging sensing information; a wireless communication unit wirelessly transmitting the packaged sensing information to the management server; the energy harvester generating electric energy to be supplied to the sensor modules, the data processing unit, and the wireless communication unit by converting vibration energy of the engine into the electric energy; and a power management unit controlling the electric energy to supply the electric energy to the sensor modules, the data processing unit.

A detector includes a housing having a window. A detection engine is configured to detect an event external to the housing. A battery is connected to the detection engine and configured to supply power thereto. A solar cell is configured to generate electricity when exposed to a light received through the window. The solar cell is arranged in the housing and electrically connected to the battery.

A sensing system including: a sensor located in an external environment, including: an electrically powered sensor element sensing an environment variable and converting the sensing to a corresponding analog electrical value measure; an electrically powered sensor value conversion system connected to the electrically powered sensor and converting the analog electrical value measure to a digital measure, in addition to encoding the digital measure with sensor identification information; a transducer element for sending the sensed data information over an optical conduit for inputting an optical power signal and outputting optical sensed data information; a coupler splitting a first portion of the optical power signal to an energy storage system; and an energy storage system converting the first portion of the optical power signal into corresponding electrical energy and storing it for on demand usage; said electrically powered sensor value conversion system being supplied with electrical power from said energy storage system.

A sensor device is provided. The sensor device includes an energy harvester configured to generate electric energy, a monitoring circuit, a sensor, a communication circuit, and at least one processor configured to obtain information indicating a magnitude of the generated electric energy via the monitoring circuit, obtain a sensing value via the sensor, and transmit the sensing value and the information indicating the magnitude of the generated electric energy via the communication circuit to the other electronic device.

A sensor system for determining a condition associated with a piston rod of a reciprocating system includes an interrogator system having a first antenna. The sensor system further includes a second antenna separated from the first antenna by an air gap distance. The second antenna is configured to be coupled to the piston rod of the reciprocating system. The second antenna is a patch antenna and is configured to communicate with the first antenna through a range of translational movement relative to the first antenna. The sensor system further includes a radio frequency sensor coupled to the second antenna. The radio frequency sensor is configured to be coupled to the piston rod of the reciprocating system, measure a characteristic associated with the piston rod of the reciprocating system, and transmit data associated with the characteristic to the first antenna of the interrogator system through the second antenna.