Abstract: A package for moving a platform in six degrees of freedom, is provided. The platform may include an optoelectronic device mounted thereon. The package includes an in-plane actuator which may be a MEMS actuator and an out-of-plane actuator which may be formed of a piezoelectric element. The in-plane MEMS actuator may be mounted on the out-of-plane actuator mounted on a recess in a PCB. The in-plane MEMS actuator includes a plurality comb structures in which fingers of opposed combs overlap one another, i.e. extend past each other's ends. The out-of-plane actuator includes a central portion and a plurality of surrounding stages that are connected to the central portion. The in-plane MEMS actuator is coupled to the out-of-plane Z actuator to provide three degrees of freedom to the payload which may be an optoelectronic device included in the package.

Abstract: A simplified MEMS fabrication process and MEMS device is provided that allows for cheaper and lighter-weight MEMS devices to be fabricated. The process comprises etching a plurality of holes or other feature patterns into a MEMS device, and then etching away the underlying wafer such that, after the etching process, the MEMS device is the required thickness and the individual die are separated, avoiding the extra steps of wafer thinning and die dicing. By etching trenches into the substrate wafer and filling them with a MEMS base material, sophisticated taller MEMS devices with larger force may be made.

Abstract: A system and method for manipulating the structural characteristics of a MEMS device include etching a plurality of holes into the surface of a MEMS device, wherein the plurality of holes comprise one or more geometric shapes determined to provide specific structural characteristics desired in the MEMS device.

Abstract: A device can have an outer frame and an actuator. The actuator can have a movable frame and a fixed frame. At least one torsional flexure and at least one hinge flexure can cooperate to provide comparatively high lateral stiffness between the outer frame and the movable frame and can cooperate to provide comparatively low rotational stiffness between the outer frame and the movable frame.

Abstract: A system and method for manipulating the structural characteristics of a MEMS device include etching a plurality of holes into the surface of a MEMS device, wherein the plurality of holes comprise one or more geometric shapes determined to provide specific structural characteristics desired in the MEMS device.

Abstract: A simplified MEMS fabrication process and MEMS device is provided that allows for cheaper and lighter-weight MEMS devices to be fabricated. The process comprises etching a plurality of holes or other feature patterns into a MEMS device, and then etching away the underlying wafer such that, after the etching process, the MEMS device is the required thickness and the individual die are separated, avoiding the extra steps of wafer thinning and die dicing. By etching trenches into the substrate wafer and filling them with a MEMS base material, sophisticated taller MEMS devices with larger force may be made.

Abstract: A moving image sensor package is provided that may be used to provide optical image stabilization (OIS) in the same form factor as non-OIS enabled image sensors utilized in portable/mobile devices. The moving image sensor package includes an image sensor attached to a MEMS actuator mounted within a cutout in a circuit board, wherein the MEMS actuator has substantially the same thickness as the circuit board.

Abstract: An apparatus is provided. The apparatus includes a bidirectional comb drive actuator. The apparatus may also include a cantilever. The cantilever includes a first end connected to the bidirectional comb drive actuator and a second end connected to an inner frame. In addition, the cantilever may include first and second conductive layers for routing electrical signals. Embodiments of the disclosed apparatuses, which may include multi-dimensional actuators, allow for an increased number of electrical signals to be routed to the actuators. Moreover, the disclosed apparatuses allow for actuation multiple directions, which may provide for increased control, precision, and flexibility of movement. Accordingly, the disclosed embodiments provide significant benefits with regard to optical image stabilization and auto-focus capabilities, for example in size- and power-constrained environments.

Abstract: The present disclosure provides a detection device for lithium-ion battery, which comprises an insulative housing having a receiving chamber; an insulative separator positioned between the positive electrode sheet and the negative electrode sheet when the positive electrode sheet and the negative electrode sheet are received in the receiving chamber; a positive electrode sheet conductive fastener passing through the insulative housing and fixedly connected to a positive electrode current collector at a positive electrode current collector non-film-coating region; a negative electrode sheet conductive fastener passing through the insulative housing and fixedly connected to a negative electrode current collector at a negative electrode current collector non-film-coating region; an insulative cover engaged with the insulative housing and the insulative separator; a positive electrode region detection hole communicated to the positive electrode sheet gas region; and a negative electrode region detection hole comm

Abstract: A device may comprise a substrate formed of a first semiconductor material and a trench formed in the substrate. A second semiconductor material may be formed in the trench. The second semiconductor material may have first and second portions that are isolated with respect to one another and that are isolated with respect to the first semiconductor material.

Abstract: A comb drive includes an inactive comb finger array and an opposing active comb finger array positioned to oppose the inactive comb finger array and configured to move in a non-linear path relative to the inactive comb finger array, wherein each comb finger array includes a comb spine and a plurality of comb fingers extending from its comb spine, and each comb finger on the active comb finger array is shaped to match a non-parallel profile. The non-parallel profile may be tapered, curved, or selected to linearize the capacitance in a gap between adjacent comb fingers from the inactive comb finger array when a comb finger from the active comb finger array moves through the gap.

Abstract: Techniques are disclosed for systems and methods to provide shock impact mitigation for MEMS structures. A MEMS structure may include one or more actuators. An actuator may include a first frame having a spine, where the spine includes a body and a tip. The actuator may include a second frame connected to the first frame and including a shock stop, where the shock stop includes a surface in proximity to the spine tip. An actuator may include a shock cushion spring fixed relative to the spine tip and situated substantially between the spine tip and the shock stop surface, where the shock cushion spring is adapted to protect the spine tip from contact with the shock stop surface.

Abstract: A device may comprise a substrate formed of a first semiconductor material and a trench formed in the substrate. A second semiconductor material may be formed in the trench. The second semiconductor material may have first and second portions that are isolated with respect to one another and that are isolated with respect to the first semiconductor material.

Abstract: In one embodiment, an electrostatic actuator includes a generally planar fixed frame, a generally planar moving frame coupled to the fixed frame by a flexure for substantially coplanar, perpendicular movement relative to the fixed frame, a plurality of interdigitated teeth, a fixed portion of which is attached to the fixed frame and a moving portion of which is attached to the moving frame, and an elongated output shaft having opposite input and output ends, the input end being coupled to the moving frame.

Abstract: A moving image sensor package is provided that may be used to provide optical image stabilization (OIS) in the same form factor as non-OIS enabled image sensors utilized in portable/mobile devices. The moving image sensor package includes an image sensor attached to a MEMS actuator mounted within a cutout in a circuit board, wherein the MEMS actuator has substantially the same thickness as the circuit board.

Abstract: Systems and methods provide dust removal on an image sensor surface of a digital camera. Dust removal can be achieved by either imparting vibrational movement on a stage upon which the image sensor is mounted and/or by moving the stage towards one or more impact stops. The vibrational movement may shake loose any contaminants present on the image sensor. The impact of the stage at the one or more impact stops also may shake loose any contaminants present on the image sensor.

Abstract: A flexure includes a support first end connected to a first frame; a support second end connected to a second frame; and a buckled section connecting the first support end to the second support end. The length of the flexure is substantially greater than its width, and the width of the flexure is substantially greater than its thickness. During operation, the flexure is maintained in a buckled state where the flexure's stiffness is significantly less than in the unbuckled state. In one implementation, a stage includes a flexure array joining a first frame and a second frame, where: the first frame and the second frame are substantially on a plane; the flexure array is substantially on the plane prior to buckling by the flexures of the flexure array; and the flexure array is bent substantially out of the plane after buckling by the flexures.

Abstract: In one embodiment, an electrostatic actuator includes a generally planar fixed frame, a generally planar moving frame coupled to the fixed frame by a flexure for substantially coplanar, perpendicular movement relative to the fixed frame, a plurality of interdigitated teeth, a fixed portion of which is attached to the fixed frame and a moving portion of which is attached to the moving frame, and an elongated output shaft having opposite input and output ends, the input end being coupled to the moving frame.

Abstract: A method for making a motion control feature for an actuator device of a type that has a moveable component coupled to an opposing fixed component for out-of-plane rotational movement relative thereto includes forming first and second flaps respectively extending from the moveable and fixed components and toward the opposing component and operable to effect one or more of damping movement of the moveable component relative to the fixed component and/or restraining movement of the moveable component relative to the fixed component in a direction substantially perpendicular to the actuator device.

Abstract: A method for making an actuator includes forming a substantially planar actuator device of an electrically conductive material, the device incorporating an outer frame, a fixed frame attached to the outer frame, a moveable frame disposed parallel to the fixed frame, a motion control flexure coupling the moveable frame to the outer frame for coplanar, rectilinear movement relative to the outer frame and the fixed frame, an actuator incorporating a plurality of interdigitated teeth, a fixed portion of which is attached to the fixed frame and a moving portion of which is attached to the moveable frame, moving the moveable frame to a deployed position that is coplanar with, parallel to and spaced a selected distance apart from the fixed frame, and fixing the moveable frame at the deployed position for substantially rectilinear, perpendicular movement relative to the fixed frame.