Abstract: Embodiments of methods and systems for monitoring stator winding vibration of a rotating electric machine are provided. According to one example embodiment, a system includes at least one sensor including at least one conductive sensor antenna deposited on a first side of at least one layer of a printed circuit board substrate and positioned to substantially face a stator winding, and a non-conductive shield mounted to an opposing side of the printed circuit board substrate and positioned to substantially face away from the stator winding. The system further includes an alternating current power source in communication with the sensor and operable to deliver current to the conductive sensor antenna. A signal processing unit may be in communication with the sensor, operable to measure a load on the sensor antenna and to transmit vibration data to a controller responsive to the load on the sensor antenna.

Abstract: This disclosure describes examples of condition monitoring systems with node devices that can adjust the power level of a radio. Embodiments of the node device can dynamically vary the power level for the radio in response to communication with other node devices. In one example, the node devices measure the strength of a signal received from the other node devices. The node devices can, in response to this value, vary the power level of the radio to optimize power consumption and extend the battery life for the node device.

Abstract: This disclosure describes examples of condition monitoring systems with node devices that can adjust the power level of a radio. Embodiments of the node device can dynamically vary the power level for the radio in response to communication with other node devices. In one example, the node devices measure the strength of a signal received from the other node devices. The node devices can, in response to this value, vary the power level of the radio to optimize power consumption and extend the battery life for the node device.

Abstract: A method for measuring a proximity of a component with respect to a microwave emitter is provided. The method comprises transmitting at least one microwave signal to the microwave emitter. At least one electromagnetic field is generated by the microwave emitter from the microwave signal. Moreover, the method comprises inducing a loading to the microwave emitter by an interaction between the component and the electromagnetic field, wherein at least one detuned loading signal representative of the loading is reflected within a data conduit from the microwave emitter. The detuned loading signal is received by at least one signal processing device. The signal processing device then measures the proximity of the component with respect to the microwave emitter based on the loading signal. An electrical output is generated by the signal processing device.

Abstract: A proximity probe, for use in determining a distance to a probe target, includes a first antenna configured to wirelessly receive a radio-frequency signal at a first predetermined frequency and a converter configured to convert the received signal to a driving signal and to an electrical signal. The proximity probe also includes a second antenna configured to receive power via the driving signal and to generate a signal indicative of a distance from the proximity probe to the probe target, and a third antenna configured to transmit the generated signal.

Abstract: A proximity probe, for use in determining a distance to a probe target, includes a first antenna configured to wirelessly receive a radio-frequency signal at a first predetermined frequency and a converter configured to convert the received signal to a driving signal and to an electrical signal. The proximity probe also includes a second antenna configured to receive power via the driving signal and to generate a signal indicative of a distance from the proximity probe to the probe target, and a third antenna configured to transmit the generated signal.

Abstract: Embodiments of methods and systems for monitoring stator winding vibration of a rotating electric machine are provided. According to one example embodiment, a system includes at least one sensor including at least one conductive sensor antenna deposited on a first side of at least one layer of a printed circuit board substrate and positioned to substantially face a stator winding, and a non-conductive shield mounted to an opposing side of the printed circuit board substrate and positioned to substantially face away from the stator winding. The system further includes an alternating current power source in communication with the sensor and operable to deliver current to the conductive sensor antenna. A signal processing unit may be in communication with the sensor, operable to measure a load on the sensor antenna and to transmit vibration data to a controller responsive to the load on the sensor antenna.