Abstract: An optical module includes a variable wavelength interference filter provided with a pair of reflecting films, and an electrostatic actuator configured to change a gap dimension between the pair of reflecting films, a driver configured to apply a periodic drive voltage to the electrostatic actuator, a gap detector configured to detect a gap dimension between the pair of reflecting films, and a light receiver configured to receive light from the variable wavelength interference filter. The light reception signal from the light receiver is detected at a predetermined timing from a detection timing of one of a maximum value and a minimum value of the gap dimension detected by the gap detector.

Abstract: A MEMS device and a method to manufacture a MEMS device are disclosed. An embodiment includes forming trenches in a first main surface of a substrate, forming conductive fingers by forming a conductive material in the trenches and forming an opening from a second main surface of the substrate thereby exposing the conductive fingers, the second main surface opposite the first main surface.

Abstract: A miniature camera module that achieves autofocus (AF) by applying actuation to the image sensor using MEMS (Micro Electro Mechanical System) actuators comprising of a piston-tube electrostatic actuators. The camera comprises of a MEMS piston-tube actuator, an image sensor die, an IC package, a housing, and a lens barrel. The image sensor die is attached and is electrically bonded to the moving rotor of the MEMS electrostatic piston-tube actuator, which is, in turn, attached and electrically bonded to a semiconductor device package. The packaged piston-tube actuator with the image sensor attached to it is covered with a transparent protection lid which could be an IR filter.

Abstract: An optical component comprising a mirror array having a multiplicity of mirror elements, which each have at least one degree of freedom of displacement, and which are each connected to at least one actuator for displacement, has a multiplicity of local regulating devices for damping oscillations of the mirror elements, wherein each of the regulating devices in each case has at least one capacitive sensor having at least one moveable electrode and at least one electrode arranged rigidly relative to the carrying structure.

Abstract: The invention relates to an arrangement for actuating an element in an optical system, in particular an optical system of a projection exposure apparatus, wherein the optical element is tiltable about at least one tilting axis via at least one joint having a joint stiffness, comprising at least one actuator for exerting a force on the optical element, wherein the actuator has an actuator stiffness which at least partly compensates for the joint stiffness.

Abstract: At the first etching step of etching an SOI substrate from a first silicon layer side, a portion of a first structure formed of the first silicon layer is formed as a pre-structure having a larger shape than a final shape. At the mask formation step of forming a final mask on a second silicon layer side of the SOI substrate, a first mask corresponding to the final shape of the first structure is formed in the pre-structure. At the second etching step of etching the SOI substrate from the second silicon layer side, the second silicon layer and the pre-structure are, using the first mask, etched to form the final shape of the first structure.

Abstract: A MEMS chip (100) includes a silicon substrate layer (110), a first oxidation layer (120) and a first thin film layer (130). The silicon substrate layer includes a front surface (112) for a MEMS process and a rear surface (114), both the front surface and the rear surface being polished surfaces. The first oxidation layer is mainly made of silicon dioxide and is formed on the rear surface of the silicon substrate layer. The first thin film layer is mainly made of silicon nitride and is formed on the surface of the first oxidation layer. In the above MEMS chip, by sequentially laminating a first oxidation layer and a first thin film layer on the rear surface of a silicon substrate layer, the rear surface is effectively protected to prevent the scratch damage in the course of a MEMS process. A manufacturing method for the MEMS chip is also provided.

Abstract: A touch-sensitive interface module that is able to provide 3-dimensional information about a touch by a user is disclosed. The touch-sensitive interface can detect the x-y position and the amount of the force applied on the interface. It comprises of a flexible display panel, an array of MEMS capacitive force sensors, each of which is electrically addressable and/or a circuit board of electrical connections. The force sensors comprise of a piston-tube electrode configuration that allows for easy to detect capacitive changes even when a small force is applied.

Abstract: A MEMS arrangement is provided that has a top plane containing a rotatable element such as a mirror. There is a middle support frame plane, and a lower electrical substrate plane. The rotatable element is supported by a support frame formed in the middle support frame plane so as to be rotatable with respect to the frame in a first axis of rotation. The frame is mounted so as to be rotatable with respect to a second axis of rotation. Rotation in the first axis of rotation is substantially independent of rotation in the second axis of rotation.

Abstract: On/off digital drive signals are used to create arbitrary spatial and temporal ribbon movement patterns in MEMS ribbon arrays.

Abstract: A micromirror and micromirror array may have a first stationary structure, and a mirror structure connected to a first pivoting structure that pivots the mirror structure relative to the first stationary structure about a first axis of rotation. A first comb drive pivots the mirror structure about the first axis of rotation. The first comb drive has a first portion attached to the stationary structure and a second portion attached to the mirror structure, the first portion being electrically isolated from the second portion. The micromirror or micromirror array may be mounted to a Through Silicon Via (TSV) wafer having electrical connections that extend between a first side and a second side of the TSV wafer such that the first and second portions of each comb drive are electrically connected to the electrical connections.

Abstract: A MEMS mirror device includes a semiconductor substrate, a mirror provided on the semiconductor substrate, a first cavity, a second cavity, and a frame portion to define the first cavity and the second cavity. The semiconductor substrate further includes a swing portion formed just above the first cavity to support the mirror, a straight beam provided just above the first cavity to extend between the frame portion and the swing portion, a comb-teeth-like fixed electrode, and a comb-teeth-like movable electrode, the movable electrode meshing with the fixed electrode with a gap left therebetween, the swing portion configured to swing about the beam as a swing axis in response to movement of the movable electrode.

Abstract: Disclosed herein is a dielectric microstructure with a substantially unit dielectric constant K for use in microelectromechanical systems.

Abstract: A Micro Electro Mechanical Systems (MEMS) device comprising: a rotor, comprising a first plurality of rotor teeth and a second plurality of rotor teeth, formed in at least two layers of silicon-on-insulator (SOI) substrate, wherein each rotor tooth belonging to the first plurality of rotor teeth is formed in a first layer and each rotor tooth of the second plurality of rotor teeth is formed in a second layer; and a stator comprising a first plurality of stator teeth and a second plurality of stator teeth, formed in at least two layers of SOI substrate, wherein each stator tooth belonging to the first plurality of stator teeth is formed in a first layer, and each stator tooth of the second plurality of stator teeth is formed in a second layer.

Abstract: A tunable tilting device is described. The device includes a tilting element and a suspension structure that has one or more flexures coupled to the tilting element. The suspension structure has a variable bending stiffness and configured to bend due to a tilting motion of the tilting element around a pivot axis. The suspension structure is responsive to a tuning force actuating a variation of an extension stress or a compression stress of the suspension structure, and thereby can vary the bending stiffness of the suspension structure.

Abstract: An electrostatically steerable actuator includes a gimbaled platform. A central portion of a rear side of the platform extends outward from the platform. A diameter of the central portion is substantially smaller than a corresponding diameter of the platform. An array of electrodes faces the rear side of the platform to provide an adjustable electrostatic field for tilting the platform.

Abstract: A micromechanical actuator includes a shaft and at least a first driving mechanism. The shaft and the first driving mechanism are connected by a first joint.

Abstract: An optical scanner includes: a light reflecting section having light reflectivity; a movable section which includes the light reflecting section and can be displaced; two link sections connected to positions of ends of the movable section, the positions facing each other; a supporting section supporting the link sections; and a displacement providing section turning the two link sections, wherein each link section includes a turnable drive section, and a shaft section connecting the movable section and the drive section and bending in a thickness direction of the movable section by turning of the drive section.

Abstract: A micro-mirror includes stiffer end sections for limiting curvature, and thin middle sections forming ground electrodes and a hinge. Spacers arc provided beneath the thin middle sections of the micro-mirror for supporting hot electrodes, which attract the ground electrodes for rotating the micro-mirror about a tilt axis. The spacers enable the gap between the hot electrode and the micro-mirror to be designed separately from the thickness of the micro-mirror, and the gap between the ends of the micro-mirror and the substrate.

Abstract: A MEMS arrangement is provided that has a top plane containing a rotatable element such as a mirror. There is a middle support frame plane, and a lower electrical substrate plane. The rotatable element is supported by a support frame formed in the middle support frame plane so as to be rotatable with respect to the frame in a first axis of rotation. The frame is mounted so as to be rotatable with respect to a second axis of rotation. Rotation in the first axis of rotation is substantially independent of rotation in the second axis of rotation.

Abstract: The present invention provides a light field display device (300) comprising an array of light field display elements (310) populating a display surface, each display element (310) comprising: a beam generator (522) for generating an output beam of light; a radiance modulator (524) for modulating the radiance of the beam over time; a focus modulator (530) for modulating the focus of the beam over time; and a scanner (504, 506) for scanning the beam across a two-dimensional angular field.

Abstract: A DND device is disclosed. In one aspect, the device includes a nano-mirror (21), and an actuating module configured to move the nano-mirror in an upward and/or downward position. The actuating module has a cantilever mounted to a fixed structure, and at least one first electrode for moving the cantilever in an upward and/or downward position. Such DND devices may be arranged in a 2D array.

Abstract: A mirror device includes a mirror (153) which is supported to be pivotable with respect to a mirror substrate (151), a driving electrode (103-1-103-4) which is formed on an electrode substrate (101) facing the mirror substrate, and an antistatic structure (106) which is arranged in a space between the mirror and the electrode substrate. This structure can fix the potential of the lower surface of the mirror and suppress drift of the mirror by applying a second potential to the antistatic structure.

Abstract: A layered micro-electronic and/or micro-mechanic structure comprises at least three alternating electrically conductive layers with insulating layers between the conductive layers. There is also provided a via in a first outer layer, said via comprising an insulated conductive connection made of wafer native material through the layer, an electrically conductive plug extending through the other layers and into said via in the first outer layer in order to provide conductivity through the layers, and an insulating enclosure surrounding said conductive plug in at least one selected layer of said other layers for insulating said plug from the material in said selected layer. It also relates to micro-electronic and/or micro-mechanic device comprising a movable member provided above a cavity such that it is movable in at least one direction. The device has a layered structure according to the invention. Methods of making such a layered MEMS structure is also provided.

Abstract: An optical imaging system having two micromirrors is disclosed. Each of the two micromirrors can be rotated by a first set of combdrive actuators along a first axis and a second set of combdrive actuators along a second axis. Each of the first and second set of combdrive actuators includes multiple stator comb fingers and multiple rotor comb fingers capable of rotating about a torsion bar. One of the micromirrors can be tuned by applying a current to the torsion bar to change the Young's modulus of the torsion bar via thermoelectrical heating of the torsion bar.

Abstract: A mirror device includes a mirror (153) which is supported to be pivotable with respect to a mirror substrate (151), a driving electrode (103-1-103-4) which is formed on an electrode substrate (101) facing the mirror substrate, and an antistatic structure (106) which is arranged in a space between the mirror and the electrode substrate. This structure can fix the potential of the lower surface of the mirror and suppress drift of the mirror by applying a second potential to the antistatic structure.

Abstract: A micro scanning mirror is disclosed in the present invention. The micro scanning mirror includes a substrate, an annular structure and a mirror structure. The substrate includes a hollow area and a first shaft. The annular structure is disposed inside the hollow area on the substrate and encircles the mirror structure. The mirror structure includes a second shaft connected to the annular structure. The annular structure includes at least one first edge, at least one second edge and a first comb electrode. The first edge is connected to the first shaft, and an end of the second edge is connected to the first edge. The second edge includes a first side adjacent to the mirror structure, and a second side adjacent to the substrate. The first comb electrode is disposed on the second edge.

Abstract: A light scanning mirror device is provided, which can be improved low power consumption, low voltage, small size, and a large scanning angle. The light scanning mirror device comprises a reflective mirror; and a torsion beam connecting the reflective mirror with a frame structure so as to enable the reflective mirror to rotate around an axis; a pair of cantilevers arranged perpendicular to the axis of rotation of the reflective mirror, and in axial symmetry centering on the axis of rotation; and a fixed electrode arranged oppositely to the cantilever in parallel at rest. The fixed electrode comprises an adsorptive fixed electrode on the free end side of the cantilever, and a rotation controlling fixed electrode on the fixed end side of the cantilever. The cantilever, the adsorptive fixed electrode, and the rotation controlling fixed electrode are configured to be separated electrically with each other.

Abstract: A micro movable device includes a movable member, a stationary portion, and connecting portions each connected to the movable member and the stationary portion. The movable member includes a pair of electrodes. The stationary portion includes a pair of electrodes cooperating with the electrodes of the movable member to generate a driving force for translating the movable member in its thickness direction. The connection points at which the respective connecting portions are connected to the movable member are spaced from each other. The electrodes of the movable member are positioned between two mutually spaced connection points, as viewed along the spacing direction of the two connection points.

Abstract: A Micro-Electro-Mechanical Systems (MEMS) device for actuating a gimbaled element, the device comprising a symmetric electromagnetic actuator for actuating one degree of freedom (DOF) and a symmetric electrostatic actuator for actuating the second DOF.

Abstract: A device for deflecting light beams is provided, which includes a swing-mounted light exit segment of an optical waveguide and a swing-mounted mirror. The device features a first rotation device that is set up to rotate the light exit segment of the optical waveguide, from which light is able to strike the mirror, in a rotational plane, and a second rotation device that is set up to rotate the mirror around a rotational axis situated in the mirror plane, which deviates from the vertical to the rotational plane.

Abstract: The invention concerns a micromechanical element including a frame, a moving part rotating inside said frame, about an axis, two torsion beams connecting the moving part to said frame , aligned along the axis and provided with a portion of reinforced width, and stop members arranged on both sides of the reinforced portions, so as to limit the lateral movement of the moving part . According to the invention, the portions of reinforced width are integral with the frame , and the stop members are integral with the moving part.

Abstract: A mirror device includes a mirror (153) which is supported to be pivotable with respect to a mirror substrate (151), a driving electrode (103-1-103-4) which is formed on an electrode substrate (101) facing the mirror substrate, and an antistatic structure (106) which is arranged in a space between the mirror and the electrode substrate. This structure can fix the potential of the lower surface of the mirror and suppress drift of the mirror by applying a second potential to the antistatic structure.

Abstract: The present invention provides an improved electrostatic micro actuator array system comprising a plurality of electrostatic micro actuators, each of the micro actuators further comprising at least one hold-down electrode and at least two pull-down electrodes positioned to actuate the micro actuator. A hold-down signal line is then coupled to each of the hold-down electrodes of each of the plurality of micro actuators and a plurality of first pull-down signal lines coupled to one of the at least two pull-down electrodes of each micro actuator and a plurality of second pull-down signal lines coupled to another of the at least two pull-down electrodes of each micro actuator, the first pull-down signal lines and the second pull-down signal lines configured in a cross-point matrix such that a unique pair of first pull-down signal lines and second pull-down signal lines is associated with each of the plurality of micro actuators.

Abstract: An electromechanical tilting device including a first and a second electrode structures, shaped, positioned and oriented to define at least partially interdigitated electrodes, and a suspension defining a tilt-containing motion path for the second structure with respect to the first structure. The motion path is selected to cause changes in overlapping regions and overlapping regions' gaps of the interdigitated electrodes. The device is configured such that an increase in one or more voltage bias applied to interdigitated driving electrodes makes a decrease in a total area of overlapping regions of the driving electrodes electrically energetically favorable.

Abstract: A pseudo bipolar method for driving a MEMS ribbon device reduces charging effects in the device.

Abstract: A biaxial scanning mirror is disclosed in the present invention. The mirror includes: a first wafer having several cavities forming a first row and a second row, several permanent magnets each installed in one of the cavities, a spacer and a second wafer. The second wafer includes: a mirror unit, rotating around a first axis, for reflecting light beams; and a rotating unit, formed around the mirror unit, for rotating the mirror unit around a second axis which is perpendicular to the first axis. At least one coil substrate having a planar coil is assembled in the rotating unit.

Abstract: An optical scanning element is provided and includes: a substrate; a first movable section supported on the substrate so as to be capable of rocking displacement about a first axis parallel to a surface of the substrate; a second movable section arranged integrally on the first movable section and supported so as to be capable of rocking displacement about a second axis perpendicular to the first axis, the second movable section having a micro mirror on an upper surface thereof; and a driving section that applies a physical action force on the first movable section and the second movable section so as to cause the micro mirror to perform rocking displacement in two axial directions about the first axis and the second axis.

Abstract: A MEMS mirror device includes a semiconductor substrate, a mirror provided on the semiconductor substrate, a first cavity, a second cavity, and a frame portion to define the first cavity and the second cavity. The semiconductor substrate further includes a swing portion formed just above the first cavity to support the mirror, a straight beam provided just above the first cavity to extend between the frame portion and the swing portion, a comb-teeth-like fixed electrode, and a comb-teeth-like movable electrode, the movable electrode meshing with the fixed electrode with a gap left therebetween, the swing portion configured to swing about the beam as a swing axis in response to movement of the movable electrode.

Abstract: An MEMS-scanning mirror device includes an electrostatic comb actuator, in which a mirror surface is formed below a top surface (TOPS) of the mirror device. In a method for manufacturing the MEMS-scanning mirror device having the electrostatic comb actuator, a mirror surface (10BS) of a mirror plate (10B) is formed by removing an insulating layer (I) thereon.

Abstract: An MEMS-scanning mirror device includes an electrostatic comb actuator, in which a mirror surface is formed below a top surface (TOPS) of the mirror device. In a method for manufacturing the MEMS-scanning mirror device having the electrostatic comb actuator, a mirror surface (10BS) of a mirror plate (10B) is formed by removing an insulating layer (I) thereon.

Abstract: The invention relates to a micromechanical actuator, especially a micro-mirror scanner, comprising an actuator unit in an outer frame which unit is suspended in the outer frame via two torsion elements, and electrostatic tilt drives from intermeshing first and second comb-type electrodes which are off-set from each other vertically. The first electrodes are rigidly connected to the outer frame and the second electrodes to the outer frame via an outer connecting element and to the actuator unit via an inner connecting element. The inner connecting element has a spring which extends in parallel to the outer tilting axis, which is connected to the same in a section of the actuator unit close the outer tilting axis, and which is designed and arranged to be rigid in the vertical direction and flexible at a right angle to the vertical direction.

Abstract: The present invention provides an improved electrostatic micro actuator array system comprising a plurality of electrostatic micro actuators, each of the micro actuators further comprising at least one hold-down electrode and at least two pull-down electrodes positioned to actuate the micro actuator. A hold-down signal line is then coupled to each of the hold-down electrodes of each of the plurality of micro actuators and a plurality of first pull-down signal lines coupled to one of the at least two pull-down electrodes of each micro actuator and a plurality of second pull-down signal lines coupled to another of the at least two pull-down electrodes of each micro actuator, the first pull-down signal lines and the second pull-down signal lines configured in a cross-point matrix such that a unique pair of first pull-down signal lines and second pull-down signal lines is associated with each of the plurality of micro actuators.

Abstract: A mirror device includes a mirror (153) which is supported to be pivotable with respect to a mirror substrate (151), a driving electrode (103-1-103-4) which is formed on an electrode substrate (101) facing the mirror substrate, and an antistatic structure (106) which is arranged in a space between the mirror and the electrode substrate. This structure can fix the potential of the lower surface of the mirror and suppress drift of the mirror by applying a second potential to the antistatic structure.

Abstract: The invention relates to a micromechanical actuator, especially a micro-mirror scanner, comprising an actuator unit in an outer frame which unit is suspended in the outer frame via two torsion elements, and electrostatic tilt drives from intermeshing first and second comb-type electrodes which are off-set from each other vertically. The first electrodes are rigidly connected to the outer frame and the second electrodes to the outer frame via an outer connecting element and to the actuator unit via an inner connecting element. The inner connecting element has a spring which extends in parallel to the outer tilting axis, which is connected to the same in a section of the actuator unit close the outer tilting axis, and which is designed and arranged to be rigid in the vertical direction and flexible at a right angle to the vertical direction.

Abstract: Briefly, in accordance with one or more embodiments, an electric comb drive scanner comprises a scanning body comprising a mirror supported by one or more flexures along a first axis and one or more support structures coupled to the one or more flexures. One or more drive combs are disposed on the one or more support structures, wherein the drive combs cause the mirror to rotate about the first axis in response to a drive signal applied to the drive combs. The one or more support structures are tuned to reduce non-uniformity of warping of the support structures to reduce variation in disengagement of the drive combs along a length of the drive combs.

Abstract: A detection means (52) detects optimum driving voltages of a mirror device. A correction means (53) corrects driving voltage values in a table (54b) based on the optimum driving voltages. This makes it possible to drive the mirror to an optimum pivot angle even when the optimum pivot angle of the mirror changes due to, e.g., mirror drift or a change in the environment such as temperature.

Abstract: A method of controlling an element of an array of individually controllable elements. The method includes varying a frequency of a driving voltage with which the element is driven.

Abstract: A biaxial scanning minor is disclosed in the present invention. The minor includes: a first wafer having several cavities forming a first row and a second row, several permanent magnets each installed in one of the cavities, a spacer and a second wafer. The second wafer includes: a minor unit, rotating around a first axis, for reflecting light beams; and a rotating unit, formed around the minor unit, for rotating the minor unit around a second axis which is perpendicular to the first axis. At least one coil substrate having a planar coil is assembled in the rotating unit.

Abstract: An image projection system (100) has a laser (102, 104, 106) providing at least one beam (103, 105, 107) to a scan mirror apparatus (130) for scanning the at least one beam (103, 105, 107) in two orthogonal directions (404, 406). The scan mirror (130) includes an oscillating portion (204, 904) disposed contiguous to a frame (202) and includes a reflective portion (218, 918) capable of reflecting the beam (103, 105, 107). Circuitry (500) is provided for measuring the capacitance between interdigitated teeth (212, 214, 912, 914) on the frame (202) and the oscillating portion (204, 904).