An example apparatus for produce magnetic fields includes a base plate comprising a plurality of grooves. The apparatus includes an MEMS device disposed on the base plate. The apparatus further includes a number of magnets to produce one or more magnetic fields disposed on the plurality of grooves and adjacent to the MEMS device.

A member for an optical scanner includes: a functional portion including a movable portion, a shaft portion oscillatably supporting the movable portion, and a support portion supporting the shaft portion; a wiring line provided on the movable portion; and a structure provided on the functional portion and thicker than the wiring line; the wiring line and the structure are provided on a first major surface of the functional portion.

The present disclosure may provide a MEMS scanner including a mirror configured to reflect light, a gimbal connected to the mirror to rotatably support the mirror, and a winding portion provided at the mirror or the gimbal to generate an electromagnetic force in interaction with a magnetic field formed in the vicinity when a current flows therethrough so as to adjust a rotational angle of the mirror, wherein the winding portion includes a silicon layer, a coil layer deposited on the silicon layer to generate physical deformation due to a current flowing therethrough, and a plurality of hollow holes formed on the coil layer to provide elasticity so as to reduce an amount of impact due to the physical deformation, and increase the dissipation area of heat generated.

A method for manufacturing a device having a three-dimensional magnetic structure includes applying or introducing magnetic particles onto or into a carrier element. A plurality of at least partly interconnected cavities are formed between the magnetic particles, which contact one another at points of contact, by coating the arrangement of magnetic particles and the carrier. The cavities are penetrated at least partly by the layer generated when coating, resulting in the three-dimensional magnetic structure. A conductor loop arrangement is provided on the carrier or a further carrier. When a current flows through the conductor loop, an inductance of the conductor loop is changed by the three-dimensional magnetic structure, or a force acts on the three-dimensional magnetic structure or the conductor loop by a magnetic field caused by the current flow, or when the position of the three-dimensional magnetic structure is changed, a current flow is induced through the conductor loop.

A pop-up laminate structure includes rigid layers, at least one flexible layer, at least one optical component, and an actuator. At least one of the rigid layers defines gaps extending there through to form a plurality of rigid segments separated by the gaps in the rigid layer. The flexible layer is bonded to the rigid segments to form joints for folding. The optical component is mounted to a rigid layer and configured to generate, capture or alter a light beam. The actuator is mounted to at least one of the rigid layers and configured to displace at least one rigid segment that, in turn, displaces the optical component. At least some of the layers are bonded to adjacent layers only at selected locations forming islands of inter-layer bonds to allow expansion of the laminate into an expanded three-dimensional structure.

A camera module, a camera assembly and an electronic device are provided. The camera module includes a casing, a mounting base, a light deflection element, an image sensor and a driving device. The casing has a light inlet. The mounting base is disposed in the casing. The light deflection element is fixed to the mounting base, and configured to deflect an incident light entering through the light inlet. The image sensor is arranged in the casing and configured to sense the defected incident light. The driving device has an arc rail, and is configured to drive the mounting base to rotate around a central axis of the arc rail along the arc rail.

An image projection apparatus includes a light source, an image generation unit configured to receive light from the light source and generate an image based on the received light, a projection optical system unit configured to project the image generated by the image generation unit, a heat dissipation unit configured to dissipate heat of the image generation unit, and a movable member configured such that a position of the movable member is movable relative to the projection optical system unit, wherein the image generation unit and the heat dissipation unit are mounted on the movable member.

A camera module (170) includes a miniature scanning mirror (120), lens elements (163a to 163d) corresponding to thin lateral lens slices, and a short, wide imaging sensor (165). As the scanning mirror (120) pivots to scan a scene, the imaging sensor (165) captures successive image segments. Multiple image segments are stitched together by software running on a digital processor to provide a complete image. The assembly of lens elements (163a to 163d) may include moveable elements to allow variable focus, variable magnification and image stabilization, and may utilize refraction, reflection, diffraction and/or planar optical elements. The camera module (170) may be less than 5 millimeters thick while allowing long focal length lenses and increased light collecting area. Other embodiments include a switchable scan mirror with two apertures and a dual-camera system that provides binocular images and video.

A micromechanical assembly having a holder, a drive frame which has at least one energizable coil device disposed at least one of on and in the drive frame and which is joined to the holder via at least one frame spring, a mirror element that is at least partially framed by the drive frame and is suspended from the drive frame by a first mirror spring and a second mirror spring, the mirror element being disposed between the two mirror springs and being adjustable about a mirror axis of rotation in relation to the drive frame, and the mirror element being suspended from the drive frame asymmetrically relative to the mirror axis of rotation. A method for manufacturing a micromechanical assembly is also described. A method for operating a micromechanical assembly is also described.

Examples are disclosed herein that relate to driving a resonant scanning mirror system using a linear LC resonant driving scheme. In one example, a resonant scanning mirror system includes a scanning mirror, first and second mirror drive elements, and a drive circuit to drive the scanning mirror at a resonant frequency. The drive circuit includes one or more signal sources configured to create a first source signal and a second source signal that is 180 degrees out of phase with the first source signal. The drive circuit further includes a buffer stage configured to receive the first and second source signals and output first and second drive signals, a first resonant LC stage configured to amplify the first drive signal for provision to the first mirror drive element, and a second resonant LC stage configured to amplify the second drive signal for provision to the second mirror drive element.