Rotational angle sensor systems and methods are provided for detecting an angular position of a movable structure. The movable structure may be configured to rotate about an axis of rotation between a first rotational position and a second rotational position. A magnet may have a magnetic field pattern with a magnetic field orientation and an angle sensor may be configured to detect the magnetic field pattern and generate one or more signals, based on the magnetic field orientation, corresponding to a rotational position of the movable structure. Additionally, a first one of the magnet and the angle sensor is configured to rotate about the axis of rotation relative to a second one of the magnet and the angle sensor that is rotationally fixed such that the magnetic field orientation changes relative to the angle sensor as the movable structure rotates about the axis of rotation.

A measuring unit for simultaneous measurement of two current values and two voltage values of a power line with three high-voltage conductors includes: three two-pole electrical interconnections, each interconnection being configured to be connected between two separated ends a high-voltage conductors; a first and second current sensor, configured and arranged to measure a current through the first interconnection and through the third interconnection respectively; and a first and second voltage sensor, configured and arranged to measure a voltage between the first and second interconnection and between the second and third interconnection. The measurement of the two current values and the two voltage values is at a floating potential. This measuring unit may be installed directly on all three phases, of a substation for example, with its own internal power source and with no ground connection. Such features are important for power systems with high penetration of variable renewable energy resources such as solar PV or wind.

A measuring unit for simultaneous measurement of two current values and two voltage values of a power line with three high-voltage conductors includes: three two-pole electrical interconnections, each interconnection being configured to be connected between two separated ends a high-voltage conductors; a first and second current sensor, configured and arranged to measure a current through the first interconnection and through the third interconnection respectively; and a first and second voltage sensor, configured and arranged to measure a voltage between the first and second interconnection and between the second and third interconnection. The measurement of the two current values and the two voltage values is at a floating potential. This measuring unit may be installed directly on all three phases, of a substation for example, with its own internal power source and with no ground connection. Such features are important for power systems with high penetration of variable renewable energy resources such as solar PV or wind.

A full bridge circuit comprises first to fourth magnetic resistance elements. The first and fourth magnetic resistance elements have a first polarity, while the second and third magnetic resistance elements have a second polarity. A comparison circuit compares a first value indicating a difference between a potential of a first connecting node and a first potential and a second value indicating a difference between a potential of a second connecting node and a second potential to determine presence/absence of an external magnetic field. An initial magnetization vector of a magnetization free layer of the first magnetic resistance element is the reverse of that of a magnetization free layer of the second magnetic resistance element. An initial magnetization vector of a magnetization free layer of the third magnetic resistance element is the reverse of that of a magnetization free layer of the fourth magnetic resistance element.

A full bridge circuit comprises first to fourth magnetic resistance elements. The first and fourth magnetic resistance elements have a first polarity, while the second and third magnetic resistance elements have a second polarity. A comparison circuit compares a first value indicating a difference between a potential of a first connecting node and a first potential and a second value indicating a difference between a potential of a second connecting node and a second potential to determine presence/absence of an external magnetic field. An initial magnetization vector of a magnetization free layer of the first magnetic resistance element is the reverse of that of a magnetization free layer of the second magnetic resistance element. An initial magnetization vector of a magnetization free layer of the third magnetic resistance element is the reverse of that of a magnetization free layer of the fourth magnetic resistance element.

A power detection device for a facility monitoring system provides non-contact power detection in a power supply line for determining a powered up or energized state of equipment connected to the power supply line. The power detection device is adapted to be disposed in communication with a live power supply line without disconnecting or interrupting the power supply to the powered equipment. A hinged casing including a sensor circuit for detecting electrical current is frictionally engaged to the power supply line by closing the hinge and drawing opposed sides of the casing together. Sensor signals are aggregated and amplified such that an amplified signal above a threshold is indicative of a current flow sufficient to power the equipment and render a determination of an energized, or equipment on state. Conversely, the lack of a threshold signal indicates inactive equipment such that remedial measures may be commenced.

A power detection device for a facility monitoring system provides non-contact power detection in a power supply line for determining a powered up or energized state of equipment connected to the power supply line. The power detection device is adapted to be disposed in communication with a live power supply line without disconnecting or interrupting the power supply to the powered equipment. A hinged casing including a sensor circuit for detecting electrical current is frictionally engaged to the power supply line by closing the hinge and drawing opposed sides of the casing together. Sensor signals are aggregated and amplified such that an amplified signal above a threshold is indicative of a current flow sufficient to power the equipment and render a determination of an energized, or equipment on state. Conversely, the lack of a threshold signal indicates inactive equipment such that remedial measures may be commenced.

A non-contact voltage detector module pluggable to a mobile communication device. The non-contact voltage comprises an antenna, a connector configured for connecting to a connector of a mobile communication device, and an assembly coupled to the antenna and the connector. The assembly converts an electromagnetic field received by the antenna to an indication of a strength of the electromagnetic field and transmits the indication of the strength of the electromagnetic field via the connector.

A non-contact voltage detector module pluggable to a mobile communication device. The non-contact voltage comprises an antenna, a connector configured for connecting to a connector of a mobile communication device, and an assembly coupled to the antenna and the connector. The assembly converts an electromagnetic field received by the antenna to an indication of a strength of the electromagnetic field and transmits the indication of the strength of the electromagnetic field via the connector.

Systems, devices, and methods for an monitoring power consumption of a known electronic device including: monitoring, by a monitoring device, a received input electrical power from the known electronic devices; determining a maximum measured power value of the monitored input electrical power; converting the determined maximum power value to a current value; determining if the converted current value is greater than the determined maximum measured power value; connecting to a remote computing device and obtaining access to communicate with the remote computing device via an authentication process; and transmitting data to the connected remote computing device if the determined converted current value is greater than zero.