The present disclosure relates to a spatio-temporal stimulus responsive foldable structure. The structure may have a substrate having at least a region formed to provide engineered weakness to help facilitate bending or folding of the substrate about the region of engineered weakness. The substrate is formed to have a first shape. A stimulus responsive polymer (SRP) flexure is disposed at the region of engineered weakness. The SRP flexure is responsive to a predetermined stimulus actuation signal to bend or fold in response to exposure to the stimulus actuation signal, to cause the substrate to assume a second shape different from the first shape.

An optical scanning device includes a reflector, a rotator, a first torsion beam and a second torsion beam, a first support part, a second support part, a first elastic layer, and a second elastic layer. The first elastic layer is superposed on the first torsion beam. The second elastic layer is superposed on the second torsion beam. A vertical dimension of an active layer is smaller than a horizontal dimension of the active layer in a cross section orthogonal to a direction in which the rotator is interposed between the first torsion beam and the second torsion beam. A material of the first elastic layer and the second elastic layer is higher in fatigue life than metal.

A manufacturing method of micro fluid actuator includes: providing a substrate; depositing a first protection layer on a first surface of the substrate; depositing an actuation region on the first protection layer; applying lithography dry etching to a portion of the first protection layer to produce at least one first protection layer flow channel; applying wet etching to a portion of a main structure of the substrate to produce a chamber body and a first polycrystalline silicon flow channel region, while a region of an oxidation layer middle section of the main structure is not etched; applying reactive-ion etching to a portion of a second surface of the substrate to produce at least one substrate silicon flow channel; and applying dry etching to a portion of a silicon dioxide layer to produce at least one silicon dioxide flow channel.

A MEMS transducer for interacting with a volume flow of a fluid includes a substrate which includes a layer stack having a plurality of layers which form a plurality of substrate planes, and which includes a cavity within the layer stack. The MEMS transducer includes an electromechanical transducer connected to the substrate within the cavity and including an element which is deformable within at least one plane of movement of the plurality of substrate planes, deformation of the deformable element within the plane of movement and the volume flow of the fluid being causally correlated. The MEMS transducer includes an electronic circuit arranged within a layer of the layer stack, the electronic circuit being connected to the electromechanical transducer and being configured to provide a conversion between a deformation of the deformable element and an electric signal.

A microfabricated fluid pump is formed in a multilayer substrate by etching a plurality of shallow and deep wells into the layers, and then joining these wells with voids formed by anisotropic etching. The voids define a flexible membrane over the substrate which deforms when a force is applied. The force may be provided by an embedded layer of piezoelectric material. Embedded strain gauges may allow self-sensing and convenient, precise operational control.

An apparatus comprising: a thermally-actuated microactuator configured to deflect a component in dependence on an applied stimulus; and an extender having a length configured to increase deflection of the component by the microactuator, wherein the extender comprises one or more voids.

Various embodiments of the present disclosure are directed towards a semiconductor device. The semiconductor device comprises a substrate. A cavity is disposed in the substrate. A microelectromechanical system (MEMS) layer is disposed over the substrate. The MEMS layer comprises a movable diaphragm disposed over the cavity. The movable diaphragm comprises a central region and a peripheral region. The movable diaphragm is flat in the central region of the movable diaphragm. The movable diaphragm is corrugated in the peripheral region of the movable diaphragm.

A platform includes first and second actuation layers. The first actuation layer includes first and second frames and a plurality of actuators connected between the first frame and the second frame, wherein the plurality of actuators are adapted to move the first and second frames with respect to each other in a first direction. The second actuation layer includes third and fourth frames and a plurality of actuators connected between the third frame and the fourth frame, wherein the plurality of actuators are adapted to move the third frame and the fourth frame with respect to each other in a second direction, different from the first direction. Thereby, the fourth frame of the second actuation layer and the second frame of the first actuation layer are mechanically connected to each other, such that the second actuation layer experiences the movement in the first direction induced by the first actuation layer.

An MEMS device includes a substrate with a substrate plane, a mass element having a rest position and configured to perform a deflection from the rest position parallel to the substrate plane and in a fluid surrounding the mass element. Further, the MEMS device includes a spring arrangement that is coupled between the substrate and the mass element and configured to deform based on the deflection. An actuator structure is provided that is coupled to the mass element by means of a coupling and configured to apply a force to the mass element by means of the coupling to cause the deflection and a movement of the fluid.

A MEMS device having a body with a first and a second surface, a first portion and a second portion. The MEMS device further has a cavity extending in the body from the second surface; a deformable portion between the first surface and the cavity; and a piezoelectric actuator arranged on the first surface, on the deformable portion. The deformable portion has a first region with a first thickness and a second region with a second thickness greater than the first thickness. The second region is adjacent to the first region and to the first portion of the body.