Abstract: An electronic device may have a MEMS device formed of a first conductive material. A trench may be formed in the MEMS device. A layer of non-conductive material may be formed in the trench. A second conductive material may be formed upon the non-conductive 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 device may comprise a substrate formed of a first semiconductor material, a first trench formed in the substrate, a second trench formed in the substrate proximate the first trench, an oxide layer formed in the first trench and the second trench, and a second semiconductor material formed upon the oxide layer. The oxide layer in the second trench may be adapted to mitigate undercut of the oxide layer in the first trench during an etching process.

Abstract: A device may comprise a flexure formed of a first semiconductor material. A first trench may be formed in the flexure. The first trench may separate the first semiconductor material into a first portion and a second portion thereof. An oxide layer may be formed in the first trench. The oxide layer may extend over a top portion of the first semiconductor material. A second semiconductor material may be formed on the oxide layer. The first trench and the oxide layer may cooperate to electrically isolate the first portion and the second portion from one another.

Abstract: A device can have an electrostatic MEMS actuator and a capacitive sensor in electrical communication with the electrostatic MEMS actuator. The capacitive sensor can be configured to determine a capacitance of the electrostatic MEMS actuator while a force is being applied to the electrostatic MEMS actuator as the electrostatic MEMS actuator is being actuated. The device can be used to construct a keyboard having tactile feedback, for example.

Abstract: In one embodiment, a device is provided that includes: a cascaded electrostatic actuator defining a stack in a substrate having a plurality of gaps between parallel plate electrodes; and a controller configured to drive the cascaded electrostatic actuator to open and close selected ones of the gaps.

Abstract: In one example, a camera is provided that includes: a plurality of MEMS electrostatic comb actuators, each actuator operable to exert a force on at least one lens; and an optical image stabilization (OIS) algorithm module operable to command the plurality of actuators to actuate the at least one lens responsive to motion of the camera.

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, and 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 at 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.

Abstract: Techniques are disclosed for systems and methods to provide concomitant mechanical motion inhibition and electrical distribution for actuator modules, such as microelectromechanical systems (MEMS) based optical actuators adapted to move and/or orient one or more lenses and/or optical devices of a camera module. A mechanical motion inhibition and electrical distribution system may include one or more flexible snubber structures disposed substantially adjacent a MEMS structure and between the MEMS structure and another component of a camera module. Each flexible snubber structure may be implemented with one or more electrical traces, flexible films, snubber films, and/or mechanical stabilizers adapted to route electrical signals to or from the MEMS structure and/or to inhibit mechanical motion of at least a portion of the MEMS structure.

Abstract: A method for focusing a miniature camera includes providing a current through a coil, moving a lens of a camera based on the current to adjust a focus of the camera, and limiting movement of the lens along an optical path of the camera.

Abstract: A multiple degree of freedom actuator can have at least one first MEMS actuator configured to move a platform in translation and at least one second MEMS actuator configured to move the platform in a different direction, e.g., tangentially. The first MEMS actuator(s) can facilitate autofocus and/or zoom, for example. The second MEMS actuator(s) can facilitate optical image stabilization (OIS), for example.

Abstract: A flexure assembly can have a stage that is deployed to a desired position by attachment of the flexure assembly to a housing. For example, a frame can be configured to be held in position by one portion of the housing and a deployment pad can be configured to be held in position by another portion of the housing. A deployment flexure can be configured to facilitate positioning of the frame and the deployment pad out-of-plane with respect to one another. The deployment flexure and a motion control flexure can facilitate movement of the stage with respect to the housing. In this manner, the position of the stage and the preload of the stage are determined by the housing.

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 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.

Abstract: A device may comprise an upper module cover, a lower module cover, an outer frame, and an actuator having a movable frame. The movable frame may be at least partially disposed intermediate the upper module cover and the lower module cover. A hinge flexure may interconnect the outer frame and the movable frame such that the movable frame is rotatable with respect to the outer frame. The upper module cover and/or the lower module cover may be adapted to limit a movement of the movable frame.

Abstract: A device may comprise a flexure formed of a first semiconductor material. A first trench may be formed in the flexure. The first trench may separate the first semiconductor material into a first portion and a second portion thereof. An oxide layer may be formed in the first trench. The oxide layer may extend over a top portion of the first semiconductor material. A second semiconductor material may be formed on the oxide layer. The first trench and the oxide layer may cooperate to electrically isolate the first portion and the second portion from one another.

Abstract: A method for focusing a miniature camera includes providing a current through a coil, moving a lens of a camera based on the current to adjust a focus of the camera, and limiting movement of the lens along an optical path of the camera.

Abstract: In accordance with the disclosure, a MEMS substrate is provided that includes: a central planar portion configured to support a MEMS device; and a first electrical pad coplanar with the central planar portion, the first pad being connected to the central planar portion through a first flexure, wherein the first flexure is configured to substantially mechanically isolate the first electrical pad from the central planar portion.

Abstract: A silicon MEMS device can have at least one solder contact formed thereupon. The silicon MEMS device can be configured to be mounted to a circuit board via the solder contact(s). The silicon MEMS device can be configured to be electrically connected to the circuit board via the solder contact(s).

Abstract: An electronic device may have a MEMS device formed of a first conductive material. A trench may be formed in the MEMS device. A layer of non-conductive material may be formed in the trench. A second conductive material may be formed upon the non-conductive material.