Some aspects of the present disclosure feature a sensing device comprising a magnetic bias layer, a resonator, a spacer, and a housing. The spacer includes an environmental change receptor. The thickness of the environmental change receptor rapidly increases in response to a change to an environment variable.

A method and system for a sensor system of a device is disclosed. The sensor system includes a first MEMS sensor (FMEMS), a second MEMS sensor (SMEMS) and a signal processor (SP). An excitation is imparted to the device along a first axis (FA). The FMEMS has a first primary sense axis (FPSA), moves in response to a component of the excitation along the FA aligned with the FPSA and outputs a first signal proportional to an excitation along the FPSA. The SMEMS has a second primary sense axis (SPSA), moves in response to a component of the excitation along the FA aligned with the SPSA and outputs a second signal proportional to an excitation along the SPSA. The SP combines the first signal and the second signal to output a third signal proportional to the excitation along the FA. The FA, the FPSA and the SPSA have different orientations.

Systems and methods for a door or window contact sensor are provided. Some systems can include a three-dimensional (3D) microelectromechanical system (MEMS) magnetic sensor, a programmable processor, and executable control software stored on a non-transitory computer readable medium, wherein the 3D MEMS magnetic sensor can measure magnetic parameters of a magnetic field along three axes, and wherein the programmable processor and the executable control software can compare the magnetic parameters to reference values to determine whether the magnetic parameters indicate that a door or a window associated with the 3D MEMS magnetic sensor is open or closed.

A MEMS triaxial magnetic sensor device includes a sensing structure having: a substrate; an outer frame, which internally defines a window and is elastically coupled to first anchorages fixed with respect to the substrate by first elastic elements; a mobile structure arranged in the window, suspended above the substrate, which is elastically coupled to the outer frame by second elastic elements and carries a conductive path for flow of an electric current; and an elastic arrangement operatively coupled to the mobile structure. The mobile structure performs, due to the first and second elastic elements and the arrangement of elastic elements, first, second, and third sensing movements in response to Lorentz forces from first, second, and third magnetic-field components, respectively. The first, second, and third sensing movements are distinct and decoupled from one another.

The present invention relates to a magnetic field sensor for detecting a magnetic field, comprising: a magnetoelectric sensor element which can mechanically oscillate, the sensor element having at least one first layer made of a magneto-restrictive material, a second layer made of a piezoelectric material, and at least one electrode made of an electrically conductive material, more particularly metal; and electronics. The magnetic field sensor, more particularly the electronics, is designed to induce mechanical oscillations of the sensor element by means of an excitation signal, to receive the mechanical oscillations of the sensor element and to convert said mechanical oscillations into a reception signal, to produce the excitation signal from the reception signal, and to determine a variable related to the magnetic field on the basis of the reception signal.

Nano-electromechanical systems (NEMS) devices that utilize thin electrically conductive membranes, which can be, for example, graphene membranes. The membrane-based NEMS devices can be used as sensors, electrical relays, adjustable angle mirror devices, variable impedance devices, and devices performing other functions. The NEMS devices have a serpentine shape arrangement of the electrically conductive membrane. The electrically conductive membrane can be controllably wicked down on the edge of the oxide cavity to increase sensitivity of the NEMS device.

A magnetic field measuring device having a cantilevered, mechanically vibratable, rectangular substrate strip, at least one flat side of the substrate strip being coated with a magnetostrictive material system, further having drive means designed for the temporally periodic exertion of a force component directed perpendicular to the flat sides of the substrate strip on at least one part of a flat side of the substrate strip with a predetermined excitation frequency and having a detection device for detecting an electrical signal generated by the vibration of the substrate strip, wherein a. the substrate strip is formed from a material with a modulus of elasticity greater than 5 GPa and b. the excitation frequency is set up as a function of the dimensions of the substrate strip in such a way that the substrate strip oscillates in mechanical resonance and forms a U-mode, and c. the detection device has an induction coil which surrounds the substrate strip in a contactless manner and has a coil axis aligned along the substrate strip.

A communicator for autonomous monitoring, detecting, and tracking of movement and orientation of a portion of a body of a wearer is disclosed. The communicator includes a sensor configured to detect a translational and/or rotational movement of the portion of the body of the wearer; an altimeter to measure changes in altitude of the portion of the body of the wearer; and a processor configured to determine an orientation and/or position of the portion of the body of the wearer. The processor further configured to compensate for the measured changes in altitude. The sensor is implemented at least by one of the following: accelerometer(s), gyroscope(s), and/or magnetometer(s).

The present invention relates in general to a novel microelectromechanical sensor device for detecting and measuring electric field and magnetic field. In particular, the sensor device of the present invention is useful for measuring low and high strength electric fields and magnetic fields without reference ground connection, the device comprising a first electrode and a second electrode rigidly connected together via a joining segment so that the first electrode and second electrode are mutually and dependently pivotal about an axis passing through a joining segment to form a tiltable unit, and the first electrode and the second electrode are electrically isolated from each other. The present invention further provides novel methods of using through specific arrangement of such novel sensor device.

A door lock detection system is disclosed. The system includes a magnet flexibly attached to a strike plate. The strike plate includes an opening. The magnet extends across the opening of the strike plate in a first orientation when a bolt does not extend into the opening of the strike plate. The magnet is configured to be deflected from the first orientation to a second orientation, distinct from the first orientation, in response to the bolt being extended into the opening of the strike plate. The system includes a magnetometer configured to detect one or more magnetic fields of the magnet that is flexibly attached to the strike plate in the first orientation and in the second orientation.