An energy harvesting device for powering electronic devices such as wireless sensors and IoT devices is described. The device relies on nature's fundamental forces to convert kinetic energy to electrical energy, acting as power source; while accounting for the Casimir force. Nanotechnology and MEMS are used to fabricate the device embedding a mechanical oscillator, electronic circuitry, energy harvester, and transducer integrated in the same packaging. The device supports mechanism to excite and ignite the oscillatory behavior via RF signal from a remote signal source that synthesizes the RF signal on a fix or mobile platform. Additionally, solar and RF signals may be added constructively to boost the output power of the device. The device scales from micron size to blades and racks formed from arrays of the connected devices to increase the output power of the aggregate system to any desired level for powering home appliances or computer networks.

A vibrator device includes an intermediate substrate that includes a frame having a first surface and a second surface opposite to the first surface and a vibration element and is formed of quartz crystal, a first substrate that is bonded to the first surface of the frame and is formed of the quartz crystal or glass, a second substrate that is bonded to the second surface of the frame and is formed of the quartz crystal or the glass, and a functional element that is disposed on the first substrate and includes a functional layer, in which the functional element includes a portion overlapping the vibration element in plan view.

The present disclosure provides a biomimetic mobile legged robot, which includes a body formed to extend in one direction and having a piezoelectric element, and a leg connected to intersect the body and having a piezoelectric element. Here, a power is supplied to the body and the leg, respectively, and the piezoelectric elements of the body and the leg are operated with the supplied power to cause a full body motion so that the legged robot moves.

A method for manufacturing an imaging module, including: providing a first substrate and bonding a first dielectric layer on the first substrate; patterning the first dielectric layer to form at least one first bump and at least one second bump which are mutually independent, wherein a region surrounded by the at least one second bump defines a location region of the moved element; providing a piezoelectric element, adhering one end of the piezoelectric element to the first bump through a first adhesion material and making the other end of the piezoelectric element at least partially located above the second bump; adhering the moved element to the second bump through a second adhesion material; and debonding to remove the first substrate.

A piezoelectric device includes a base portion and an upper layer on an upper side of and supported by the base portion. The upper layer includes a membrane portion that does not overlap with the base portion in plan view. The membrane portion includes at least one piezoelectric layer sandwiched by electrode layers from a top and a bottom thereof. An intermediate layer is between a lower electrode and the base portion. The intermediate layer includes one or more individual layers, and an individual layer exposed as a lower surface of the membrane portion among the one or more individual layers includes a bent portion, which extends from the lower surface of the membrane portion to a lateral wall, on a boundary between a portion defining and functioning as the lower surface of the membrane portion and a portion overlapping with the base portion.

An electroactive material actuator is clamped along one edge (12) and has a pre-bend about a first axis (21) which is parallel to said edge and/or about a second axis which is perpendicular to said edge. The actuator expands with expansion coefficients along the first and second axes which differ by less than 20%. This combination of isotropic (or near isotropic) expansion with a pre-bend across at least one of main axes of the device (i.e. the axes which form the general plane of the actuator) gives rise to various additional operating characteristics.

A vibration device includes a first vibration plate having a length direction, the first vibration plate including a first end portion at one end in the length direction and a second end portion at another end in the length direction, a first piezoelectric element provided on the first vibration plate, a first conductive wiring line joined to the first piezoelectric element at a position closer to the first end portion in the length direction than a center of the first vibration plate, a first fixed component connected to the first conductive wiring line, and a case component to which the first fixed component is fixed. The second end portion is a free end, and the first conductive wiring line includes a bent portion.

An electrostatic protection device includes: a first conductive layer, a second conductive layer and a polarization film layer, in which the polarization film layer is disposed between the first conductive layer and the second conductive layer and formed of a piezoelectric material which is capable of deforming when applied with electricity; a conductive cantilever, disposed on the second conductive layer and including a free end; and a charge diffusion layer, disposed at a side of the conductive cantilever away from the polarization film layer, electrically connected with the first conductive layer and spaced apart from the conductive cantilever, in which upon a voltage difference between the first conductive layer and the second conductive layer reaching a predetermined value, the polarization film layer deforms to allow the conductive cantilever to connect with the charge diffusion layer.

A piezo actuator for carrying out an actuating movement is disclosed, with a piezo bending transducer made of a carrier layer which is at least partially covered on one or two sides with a piezo lamella, with a movable end and with a housing, with a reference stop connected to the housing for determining a reference position for the actuating movement, with a first bearing region which comprises regions of the piezo actuator and the housing and which allows for twists ϕ1 of the piezo bending transducer, with a second bearing region having a surface on the side of the bending transducer and a surface on the side of the housing, and an intermediate layer between the surfaces, which connects them and which can be liquefied, and with a pressure element for generating a bias torque on the piezo bending transducer around the first bearing region against the reference stop.

Disclosed herein are structures, devices, methods and systems for providing haptic output on an electronic device. In some embodiments, the electronic device includes a display portion, a housing pivotally coupled with the display portion and comprising a glass sheet that defines an input surface of the electronic device. The input surface can define a keyboard having a set of key regions arranged along the glass sheet. The electronic device may also include a haptic mechanism positioned beneath a key region of the set of key regions that includes a substrate defining a beam structure having first and second fixed ends, a spacer positioned along a first side of the beam structure and a piezoelectric element positioned along a second side of the beam structure. The piezoelectric element can be configured to deflect the beam structure to provide haptic output along the input surface.