Compositions and methods related to multiaxially straining defect doped materials as well as their use in electrical circuits are generally described.

Methods for training statistical models for modeling phononic energy and/or frequency dispersion, as well as phononic stability of materials as a function of an applied strain, as well as uses of these trained statistical models for elastic strain engineering of materials, are described.

A display device and a display method thereof, and a display equipment are disclosed. The display device includes a display panel and a light transmittance adjusting layer, the display panel includes a plurality of pixel regions, the light transmittance adjusting layer is stacked with the display panel, and the light transmittance adjusting layer is configured to adjust display brightness of the plurality of pixel regions.

A resonant structure comprising at least two coaxial rings, wherein adjacent coaxial rings have adjacent peripheries and are attached together by a plurality of connection structures regularly arranged along said adjacent peripheries; and wherein a first ring has a first ring portion with a first radial thickness and a second ring, portion, in a vicinity of a first connection structure, with a second radial thickness smaller than said first radial thickness.

A micromechanical component having a mount, an adjustable element, which is connected via at least one spring to the mount, and an actuator device, a first oscillatory motion of the adjustable element about a first axis of rotation and simultaneously a second oscillatory motion of the adjustable element, which is set into the first oscillatory motion, being excitable about a second axis of rotation in response to the actuator device; and the adjustable element being configured by the at least one spring to be adjustable on the mount in such a way that the adjustable element is adjustable by a resulting angular momentum about a rotational axis, which is oriented orthogonally to the first axis of rotation and orthogonally to second axis of rotation. Also, a method for manufacturing a micromechanical component. Moreover, a method for exciting a motion of an adjustable element about a rotational axis.

In a general aspect, a micromachined gyroscope can include a substrate and a static mass suspended in an x-y plane over the substrate by a plurality of anchors attached to the substrate. The static mass can be attached to the anchors by anchor suspension flexures. The micromachined gyroscope can include a dynamic mass surrounding the static mass and suspended from the static mass by one or more gyroscope suspension flexures.

A MEMS inertial sensor includes a supporting structure and an inertial structure. The inertial structure includes at least one inertial mass, an elastic structure, and a stopper structure. The elastic structure is mechanically coupled to the inertial mass and to the supporting structure so as to enable a movement of the inertial mass in a direction parallel to a first direction, when the supporting structure is subjected to an acceleration parallel to the first direction. The stopper structure is fixed with respect to the supporting structure and includes at least one primary stopper element and one secondary stopper element. If the acceleration exceeds a first threshold value, the inertial mass abuts against the primary stopper element and subsequently rotates about an axis of rotation defined by the primary stopper element. If the acceleration exceeds a second threshold value, rotation of the inertial mass terminates when the inertial mass abuts against the secondary stopper element.

Micro-Electro-Mechanical System (MEMS) devices may include at least one actuator. The actuator has a first end attachable to more than one side of a frame of the MEMS device, and has a second end attachable to a stage of the MEMS device, particularly via a joint. Further, the second end of the actuator is configured to bend upwards or downwards when the actuator is driven and the first end is attached.

To provide a physical quantity sensor having excellent reliability by reducing the influence of a force applied from the outside. Disclosed is a physical quantity sensor, which has a weight or a movable electrode formed on a device substrate, and an outer peripheral section that is disposed to surround the weight or the movable electrode, said weight or movable electrode being displaceable in the rotation direction in a plane. When the weight or the movable electrode is displaced in the rotation direction in the plane, the physical quantity sensor is provided with a rotation space at the outer peripheral section of an end portion of the weight or the movable electrode, said end portion being in the direction viewed from the center position of the weight or the movable electrode.

A button device includes a MEMS sensor having a MEMS strain detection structure and a deformable substrate configured to undergo deformation under the action of an external force. The MEMS strain detection structure includes a mobile element carried by the deformable substrate via at least a first and a second anchorage, the latter fixed with respect to the deformable substrate and configured to displace and generate a deformation force on the mobile element in the presence of the external force; and stator elements capacitively coupled to the mobile element. The deformation of the mobile element causes a capacitance variation between the mobile element and the stator elements. Furthermore, the MEMS sensor is configured to generate detection signals correlated to the capacitance variation.