Abstract: A multilayered integrated optical and circuit device. The device has a first substrate comprising at least one integrated circuit chip thereon, which has a cell region and a peripheral region. Preferably, the peripheral region has a bonding pad region, which has one or more bonding pads and an antistiction region surrounding each of the one or more bonding pads. The device has a second substrate with at least one or more deflection devices thereon coupled to the first substrate. At least one or more bonding pads are exposed on the first substrate. The device has a transparent member overlying the second substrate while forming a cavity region to allow the one or more deflection devices to move within a portion of the cavity region to form a sandwich structure including at least a portion of the first substrate, a portion of the second substrate, and a portion of the transparent member.

Abstract: A MEMS mirror for a laser printing application includes providing a CMOS substrate including a pair of electrodes, and providing a reflecting mirror moveable over the substrate and the electrodes. Voltages applied to the electrodes create an electrostatic force causing an end of the mirror to be attracted to the substrate. A precise position of the mirror can be detected and controlled by sensing a change in capacitance between the mirror ends and the underlying electrodes.

Abstract: A method of forming a package for a MEMS structure coupled to a substrate includes depositing an encapsulant material on the substrate and patterning the encapsulant material to form a plurality of encapsulated structures. The method also includes depositing a first capping layer on the substrate and forming one or more release hole patterns in the first capping layer. The method further includes removing the encapsulant material and depositing a second capping layer.

Abstract: A resonator includes a CMOS substrate having a first electrode and a second electrode. The CMOS substrate is configured to provide one or more control signals to the first electrode. The resonator also includes a resonator structure including a silicon material layer. The resonator structure is coupled to the CMOS substrate and configured to resonate in response to the one or more control signals.

Abstract: A method for aligning multiple substrates. The method includes providing a handle substrate, providing a spacer substrate, and forming a plurality of first alignment marks on a first surface of the handle substrate. The method also includes forming a plurality of self-limiting alignment marks on a first surface of the spacer substrate and forming a plurality of openings in the spacer substrate, each of the plurality of openings surrounded by standoff regions. The method further includes aligning the first surface of the handle substrate and the first surface of the spacer substrate using the first alignment marks and the self-limiting alignment marks and bonding the handle substrate to the spacer substrate to form a composite substrate structure. In a specific embodiment, the plurality of self-limiting alignment marks and the plurality of openings are formed using an anisotropic wet etching process that preferentially etches the spacer substrate.

Abstract: A method of fabricating a spatial light modulator. The method includes providing a first substrate having a mirror layer, the mirror layer having an upper surface and a lower surface. The method also includes forming a standoff structure from the first substrate, the standoff structure having an integrated surface coupled to the lower surface of the mirror layer and a bonding surface opposite the integrated surface. The standoff structure includes a centrally located base section extending from the integrated surface to the bonding surface along a first axis and a plurality of lateral extension arms extending from the base section along a second axis orthogonal to the first axis. The method further includes providing a second substrate having a bonding surface and a support surface, joining the bonding surface of the standoff structure to the bonding surface of the second substrate, and releasing a portion of the first substrate to form a torsion spring hinge coplanar with the mirror layer.

Abstract: A method of fabricating a spatial light modulator. The method includes providing a first substrate including a first bonding surface, forming a first layer coupled to the bonding surface, wherein the first layer is characterized by a first set of material parameters, and forming a second layer coupled to the first layer, wherein the second layer is characterized by a second set of material parameters. The method also includes patterning the first layer and the second layer to form a plurality of landing structures extending to a first distance from the bonding surface of the first substrate. The method further includes providing a second substrate including a second bonding surface, joining the first bonding surface of the first substrate to the second bonding surface of the second substrate, and forming a plurality of moveable mirrors from the second substrate. During operation, the moveable mirrors make contact with the second layer.

Abstract: The contrast offered by a spatial light modulator device may be enhanced by positioning nonreflective elements such as supporting posts and moveable hinges, behind the reflecting surface of the pixel. In accordance with one embodiment, the reflecting surface is suspended over and underlying hinge-containing layer by integral ribs of the reflecting material defined by gaps in a sacrificial layer. In accordance with an alternative embodiment, the reflecting surface is separated from the underlying hinge by a gap formed in an intervening layer, such as oxide. In either embodiment, walls separating adjacent pixel regions may be recessed beneath the reflecting surface to further reduce unwanted scattering of incident light and thereby enhance contrast.

Abstract: One embodiment of an micromechanical device includes a first contact surface, a moveable component having a second contact surface, where the second contact surface interacts with the first contact surface during device operation, and a gas-phase lubricant disposed between the first contact surface and the second contact surface, where the gas-phase lubricant is adapted to reduce stiction-related forces between the first contact surface and the second contact surface. One advantage of the disclosed device is that a gas-phase lubricant has a high diffusion rate and, therefore, is self-replenishing, meaning that it can quickly move back into a contact region after being physically displaced from the region by the contacting surfaces of the device during operation. Consequently, the gas-phase lubricant is more reliable than conventional solid or liquid lubricants in preventing stiction-related device failures.

Abstract: Hydrogen cleave silicon process for light modulating mirror structure using single crystal silicon as the base cross-member. Existing processes use two critical alignment steps that can contribute to higher actuation voltages and result in lower manufacturing yields. The hydrogen cleave process simplifies the manufacturing process to one step: transferring a thin film of single crystal silicon to the CMOS substrate, resulting in minimal alignment error and providing large bonding area.

Abstract: A method for aligning multiple substrates. The method includes providing a handle substrate, providing a spacer substrate, and forming a plurality of first alignment marks on a first surface of the handle substrate. The method also includes forming a plurality of self-limiting alignment marks on a first surface of the spacer substrate and forming a plurality of openings in the spacer substrate, each of the plurality of openings surrounded by standoff regions. The method further includes aligning the first surface of the handle substrate and the first surface of the spacer substrate using the first alignment marks and the self-limiting alignment marks and bonding the handle substrate to the spacer substrate to form a composite substrate structure. In a specific embodiment, the plurality of self-limiting alignment marks and the plurality of openings are formed using an anisotropic wet etching process that preferentially etches the spacer substrate.

Abstract: A multilayered integrated optical and circuit device. The device has a first substrate comprising at least one integrated circuit chip thereon, which has a cell region and a peripheral region. Preferably, the peripheral region has a bonding pad region, which has one or more bonding pads and an antistiction region surrounding each of the one or more bonding pads. The device has a second substrate with at least one or more deflection devices thereon coupled to the first substrate. At least one or more bonding pads are exposed on the first substrate. The device has a transparent member overlying the second substrate while forming a cavity region to allow the one or more deflection devices to move within a portion of the cavity region to form a sandwich structure including at least a portion of the first substrate, a portion of the second substrate, and a portion of the transparent member.

Abstract: A method of fabricating a spatial light modulator. The method includes forming cavities in a first substrate and fabricating electrodes on a second substrate. The method also includes bonding the first substrate to the second substrate and forming a mirror plate from a portion of the first substrate. The mirror plate has an upper surface and a lower surface. The method further includes forming a hinge coupled to the mirror plate and forming a reflective surface coupled to the upper surface of the mirror plate.

Abstract: An electromechanical system comprising a substrate including a surface region and a flexible member coupled at a first end to the surface region. The system further comprises a base region and a tip region. The system also comprises a reflective member coupled to the flexible member, including a reflective surface and a backside region, the backside region being coupled to the second end of the flexible member, the reflective surface being substantially parallel to the surface region while the reflective member is in a first state and being substantially non-parallel to the surface region while the reflective member is in a second state. The flexible member moves from a first position characterized by the first state to a second position characterized by the second state and the angle between the first state and the second state is greater than 12°.

Abstract: A system for wafer-level packaging of a plurality of MEMS devices includes a substrate having a plurality of individual chips. Each of the plurality of individual chips includes a plurality of MEMS devices and each of the plurality of individual chips is arranged in a spatial manner as a first array configuration. The system also includes a transparent member of a predetermined thickness. The transparent member includes a transparent substrate of a first thickness having a bonding surface joined to a bonding surface of a standoff substrate of a second thickness. The standoff substrate defines a plurality of recessed regions arranged in a spatial manner as a second array configuration. The system further includes a sealed interface between the standoff substrate and the substrate. The sealed interface is adapted to enclose each of the plurality of individual chips within one of the plurality of recessed regions.

Abstract: The contrast offered by a spatial light modulator device may be enhanced by positioning nonreflective elements such as supporting posts and moveable hinges, behind the reflecting surface of the pixel. In accordance with one embodiment, the reflecting surface is suspended over and underlying hinge-containing layer by integral ribs of the reflecting material defined by gaps in a sacrificial layer. In accordance with an alternative embodiment, the reflecting surface is separated from the underlying hinge by a gap formed in an intervening layer, such as oxide. In either embodiment, walls separating adjacent pixel regions may be recessed beneath the reflecting surface to further reduce unwanted scattering of incident light and thereby enhance contrast.

Abstract: A method for hermetically sealing devices. The method includes providing a substrate which includes a plurality of individual chips. Each of the chips includes a plurality of devices and each of the chips are arranged in a spatial manner as a first array. The method also provides a transparent member of a predetermined thickness which includes a plurality of recessed regions arranged in a spatial manner as a second array and a standoff region. The method also includes aligning the transparent member in a manner to couple each of the plurality of recessed regions to a respective one of said plurality of chips. The method further includes hermetically sealing each of the chips within one of the respective recessed regions by using at least a bonding process to isolate each of the chips within one of the recessed regions.

Abstract: A spatial light modulator is provided. The spatial light modulator includes a first substrate comprising a plurality of electrically activated electrodes and a bias grid and a standoff structure coupled to the first substrate. The standoff structure includes a central portion projecting to a first height above the first substrate and an extension portion projecting to a second height above the first substrate, the second height being less than the first height. The spatial light modulator also includes a mirror plate comprising a central contact structure integrally formed with the central portion of the standoff structure, a torsion beam coplanar with the central contact structure and free from contact with the standoff structure, and a reflective surface coupled to the plurality of torsion arms and free from contact with the standoff structure.

Abstract: A spatial light modulator for use in display applications. The spatial light modulator includes a support substrate and a flexible member coupled to the support substrate. The spatial light modulator also includes a mirror plate coupled to the flexible member and characterized by an activated position. The mirror plate is adapted to rotate in relation to the flexible member from the activated position to a second activated position in a time less than 6.0 ?s.

Abstract: A method of activating a micro-mirror includes applying a first electrode voltage to one or more electrodes associated with the micro-mirror. The micro-mirror is positioned at a first positive deflection angle during a portion of the application of the first electrode voltage. The method also includes maintaining the first electrode voltage for a first predetermined time and applying a second electrode voltage to the one or more electrodes. The micro-mirror rotates to a first negative deflection angle during a portion of the application of the second electrode voltage. The method further includes maintaining the second electrode voltage for a second predetermined time and applying a third electrode voltage to the one or more electrodes. The micro-mirror is positioned at a second positive deflection angle greater than the first positive deflection angle during a portion of the application of the third electrode voltage.