Abstract: The current disclosure shows how to make a fast switching array of mirrors for projection displays. Because the mirror does not have a via in the middle connecting to the underlying spring support, there is an improved contrast ratio that results from not having light scatter off the legs or vias like existing technologies. Because there are no supporting contacts, the mirror can be made smaller making smaller pixels that can be used to make higher density displays. In addition, because there is not restoring force from any supporting spring support, the mirror stays in place facing one or other direction due to adhesion. This means there is no need to use a voltage to hold the mirror in position. This means that less power is required to run the display.

Abstract: A display apparatus includes an array of light modulators. Each light modulator has a first actuator configured to drive the light modulator into a first state and a second actuator configured to drive the light modulator into a second state. The display apparatus also includes a control matrix including, for each light modulator in the array, a single actuation voltage interconnect. The actuation voltage interconnect is configured to apply a first drive voltage to the first actuator of the light modulator and apply a second drive voltage to the second actuator of the light modulator. In addition, the actuation voltage interconnect is configured to control application of a data voltage to a latch circuit to control the application of the first and second drive voltages to the first and second actuators.

Abstract: Direct view color displays and design structures of direct view color displays. The direct view displays include micromirrors having un-tilted and tilted states and multiple color filters or color reflectors.

Abstract: An apparatus comprises a first photonic crystal structure having a first photonic band gap distribution and configured to support a first electromagnetic signal, wherein the first photonic band gap distribution may vary according to a second electromagnetic signal.

Abstract: In a pixilated spatial light modulator having a mesh-based modulator element per pixel, a real location-dependent amplitude and a location-dependent phase can be adjusted independently of each other for modulating a coherent wavefront using complex values. A complex-valued spatial light modulator includes a regularly constructed pixel array, wherein each pixel comprises a controllable reflective line mesh. The modulation of the amplitude and phase take place independently of each other in each modulator element, by relative motions of the self-supporting line mesh relative to a base plate. The line meshes are suspended and supported such that both the distance between the base plate and the line mesh (normal adjustment for amplitude modulation) and the lateral displacement of the line mesh in the mesh plane itself (phase modulation) are modified by a system controller. The reflected light is thus modulated independently of each other.

Abstract: The present invention is directed to a method of utilizing a digital micromirror device (DMD) to spectrally matching a standard or device-independent color. DMD can be fitted on an integrated chip and can provide more than one thousand (1,000) color primary channels for low metameric color matching producing a spectrally matched batch color. This represents a two orders of magnitude improvement in color matching.

Abstract: A device for inserting information into the finder beam path of a motion picture camera comprising an imaging optics and a DMD chip are arranged with a multiplicity of micromirrors that are arranged in the form of a grid and can be swiveled under electronic control. One portion of the micromirrors reflects the finder beam path toward the imaging optics, and the other portion of the micromirrors is swiveled at least temporarily out of the finder beam path, and respectively reflects toward the imaging optics a section of an information surface arranged laterally offset from the finder beam path.

Abstract: A micromechanical component includes: a mirror element with a reflective surface on a first outer side of the mirror element, which is designed in such a way that a first potential is applied to a first electrode surface on a second outer side of the mirror element opposite from the first outer side; a counterelectrode situated adjacent to the second outer side of the mirror element and which is designed in such a way that a second potential is applied to a second electrode surface of the counterelectrode; and a voltage control unit configured to apply a temporally varying voltage signal between the first electrode surface and the second electrode surface.

Abstract: An optical scanning projector includes: a raster scanning unit that draws an image in a drawing area on a display surface by scanning beams in a first direction on the display surface while scanning beams in a second direction on the display surface that is orthogonal to the first direction; and a vector scanning unit that draws an image by irradiating beams so as to sequentially form segments each connecting two different points positioned on the display surface.

Abstract: An electro-wetting display device includes a light guide plate having a light incident surface and a light output surface, a light source, a transparent electrode, a dielectric layer, a transparent non-polar solution layer, a counter substrate, a light emitting material layer, a counter electrode layer and a transparent polar solution layer. The light source is disposed near the light incident surface. The transparent electrode layer is disposed on the light output surface. The dielectric layer covers the transparent electrode layer and has refractive index n1. The transparent non-polar solution layer is disposed on the dielectric layer and has refractive index n2, and n2?n1. The counter substrate is disposed above the transparent non-polar solution layer. The light emitting material layer and the counter electrode are disposed on the counter substrate. The transparent polar solution layer is disposed between the counter substrate and the light guide plate.

Abstract: This disclosure provides systems, methods and apparatus for encapsulating electromechanical systems devices. In one aspect, large arrays of electromechanical systems devices can be encapsulated. In one aspect the encapsulation includes an encapsulation layer supported over the electromechanical systems devices by encapsulation layer supports. The encapsulation layer can also include a plurality of orifices. The orifices can be sealed such that the electromechanical systems devices below are not damaged.

Abstract: This disclosure provides systems, methods and apparatus for dissipating charge buildup within a display element with a conductive layer. The conductive layer is maintained in electrical contact with a fluid within the display element. The fluid, in turn, remains in contact with light modulators within the display elements. Any charge buildup that may be caused by the filling of the fluid during fabrication of the display device, or during operation of the light modulators can be dissipated by the conductive layer. Thus, by dissipating the charge buildup, the conductive layer reduces or eliminates electrostatic forces due to the charge buildup that may affect the operability of the light modulators. The display can include conductive spacers in an active display region of the display and a spacer-free region that allows the substrates to deform while retaining an electrical connection between the conductive layer and the spacers in the active display region.

Abstract: Systems and methods for generating a position reference grid and relative positioning of an object are presented. Radiation is emitted towards a digital micro-mirror device including a plurality of micro-mirrors. Additionally, one or more of a plurality of micro-mirrors are modulated such that at least a portion of the radiation reflected from the plurality of micro-mirrors is projected on to a designated location in a designated pattern representative of a position reference grid. The radiation reflected from the plurality of micro-mirrors is detected. Further, the detected radiation is interpreted as location coordinates in the position reference grid. Additionally, the location coordinates are communicated to the object moving in relation to the digital micro-mirror device for positioning the object at a designated position in the position reference grid.

Abstract: A method of forming a tunable Fabry-Perot filter includes forming a first reflective layer on a surface of a substrate, forming a sacrificial layer over the first reflective layer, forming a second reflective layer over the sacrificial layer, defining vias through the sacrificial layer, forming a support body over the sacrificial layer which extends into the vias and removing the sacrificial layer to define a gap intermediate the first and second reflective layers.

Abstract: Methods of estimating the size of an ocular lens capsule.

Abstract: An optical element array includes a first substrate and a second substrate facing each other, a plurality of first walls which is provided upright on an inner surface facing the second substrate of the first substrate, a first electrode and a second electrode which are respectively provided on facing wall surfaces of the adjacent first walls, a third electrode which is provided on an inner surface facing the first substrate of the second substrate, a second wall which partially covers the inner surface of the first substrate and the first walls to partially or entirely surround at least a part of a space which is interposed between the first substrate and the second substrate; and a polar liquid and a nonpolar liquid which are sealed in the space surrounded by the first substrate, the second substrate and the second wall and have different refractive indices.

Abstract: A laser absorption layer is first selectively formed in a seal pattern region surrounding an array of electromechanical systems elements, followed by depositing an antistiction layer as a blanket layer over the substrate and the laser absorption layer. The antistiction layer is then selectively removed from the seal pattern using a laser. An epoxy sealing material is provided in the seal pattern where the antistiction layer was removed and a backplate is sealed to the substrate using epoxy.

Abstract: This disclosure provides systems, methods and apparatus for storage capacitors. In one aspect, a device includes an array having at least a first display element and a second display element, at least one switch configured to control a flow of charge between a source and the first display element, and at least one interferometric optical mask structure disposed in a non-active area of the array between the first display element and the second display element. The optical mask structure includes a storage capacitor formed by a first conductive layer and a second conductive layer. The storage capacitor is electrically coupled to the at least one switch and the first display element.

Abstract: Single-chip, multiple-linear-array MEMS form the basis for high-resolution, high-frame-rate video displays.

Abstract: Static IMOD structures may be formed in a border area of a substrate. In some implementations, conductive layers such as an absorber or a reflector of a static IMOD may be used to make electrical connections from the electrodes of a touch sensor to the flex cable or controller of the touch sensor. In some implementations, static IMODs may be configured to provide a border with a single, uniform color, whereas in other implementations static IMODs may be configured to provide artwork for the substrate. A variety of images and/or patterns of colors may be formed using the static IMODs. Some such static IMODs may be configured as numerous individual pixels or subpixels, such as red, blue and green subpixels.

Abstract: A method and apparatus are provided for attenuating an optical beam. The method includes selecting a level of attenuation to be applied to the optical beam. A pattern of on-state and off-state pixels in a two dimensional spatial light modulator (SLM) is selected such that the pattern will modulate the optical beam to provide the selected level of attenuation. Finally, the optical beam is directed onto the SLM while tile pixels are arranged in the selected pattern. The pattern is periodic along a first axis and symmetric along a second axis along which an intensity distribution of die optical beam extends.

Abstract: An addressable nano-scale mechanical actuator is formed at the intersection of two nanowires. The actuator has an active region disposed between the two nanowires, which form the electrodes of the actuator. The active region contains an electrolytically decomposable material. When an activation voltage is applied to the electrodes, the material releases a gas that forms a bubble at one electrode, causing a bulging of a top surface of the actuator. The bulging may be used, via mechanical coupling, to provide mechanical actuation on a nanometer scale. The nanowires may be arranged in a two-dimensional array to provide an array of individually addressable actuators.

Abstract: According to one embodiment of the present invention a digital micro-mirror device is taught that includes a pixel occupying an area of the device and a hinge coupled to the pixel and positioned such that at least a portion of the hinge falls outside the area of the pixel.

Abstract: A series bias voltage increases the sensitivity of a MEMS ribbon to control signal voltages. This effect is obtained because of the nonlinear dependence of ribbon deflection on applied voltage. The resulting low-voltage operation of MEMS ribbons makes them more compatible with high speed electronics.

Abstract: The present invention relates to a light modulating device, comprising a SLM and a pixelated optical element, in which a group of at least two adjacent pixels of the SLM in combination with a corresponding group of pixels in the pixelated optical element form a macropixel, the pixelated optical element being of a type such that its pixels comprise a fixed content, each macropixel being used to represent a numerical value which is manifested physically by the states of the pixels of the SLM and the content of the pixels of the pixelated optical element which form the macropixel.

Abstract: A display device is provided. The display device includes: a substrate including a unit display area, a fixing member that is formed on the substrate and that is electrically isolated, an insulating layer that is formed on the fixing member, a fixing electrode that is formed on the insulating layer and that is electrically connected to a power source, and a plurality of moving members with one end fixed to the insulating layer and positioned apart by a distance from the fixing electrode. The plurality of moving members and the fixing electrode are positioned within the unit display area.

Abstract: A method and apparatus of producing a three-dimensional image of at least a part of the retina of an eye is provided. The method including obtaining a two-dimensional wide-field image of said part of said retina, determining a three-dimensional shape for said part of said retina and using the three-dimensional shape for said part of said retina to modify said two-dimensional image to produce a three-dimensional image of said part of said retina. The apparatus including an imaging system adapted to provide a two-dimensional wide-field image of said part of said retina, a three-dimensional shape determination module adapted to determine a three-dimensional shape for said part of said retina, and a two-dimensional image modification module adapted to modify said two-dimensional wide-field image of said part of said retina using said three-dimensional shape to produce a three-dimensional image of said part of said retina.

Abstract: An interferometric modulator (Imod) cavity has a reflector and an induced absorber. A direct view reflective flat panel display may include an array of the modulators. Adjacent spacers of different thicknesses are fabricated on a substrate by a lift-off technique used to pattern the spacers which are deposited separately, each deposition providing a different thickness of spacer. Or a patterned photoresist may be used to allow for an etching process to selectively etch back the thickness of a spacer which was deposited in a single deposition. A full-color static graphical image may be formed of combined patterns of interferometric modulator cavities. Each cavity includes a reflector, and an induced absorber, the induced absorber including a spacer having a thickness that defines a color associated with the cavity.

Abstract: A method for controlling a characteristic of a variable optical filter including a frequency selecting element includes changing a driving voltage for a specific pixel of the frequency selecting element continuously to produce an amount of change in a frequency that is passed through that pixel, changing a driving voltage value for a specific pixel of the frequency selecting element continuously to produce an attenuation value for a beam that is passed through that pixel, calculating, from a relationship between the driving voltage and a frequency characteristic and between the driving voltage and amount of attenuation, a function that indicates an approximated curve of no less than a second order and no more than a sixth order for expressing a relationship between a transmissivity and a frequency, and controlling the characteristic through driving a controlled pixel of the frequency selecting element based on the function.

Abstract: An apparatus and method for reducing perceived color shift as a function of viewing angle is disclosed. One embodiment is a display device that includes a color light modulator and a color filter. The filter is configured to filter wavelengths of light that would be perceived as color shifted light when reflected by the modulator at an off-axis viewing angle. Another embodiment includes a color light modulator and a color light source configured to provide light having a spectral content that lacks the wavelengths that would be perceived as color shifted light by a view of the display at an off-axis viewing angle. Another embodiment are methods of making such display devices.

Abstract: Operating methods of an array of electromechanical pixels resulting in efficient and reliable operation of light modulating elements. The invention simplifies the design of electromechanical light modulators and permits the construction of large size displays with greater mechanical tolerances on glass substrates.

Abstract: An optical probe includes a laser light source that emits laser light, a collimator lens that converts the laser light into parallel light, a light shape changing section that converts the parallel light into linear laser light, an irradiating section to irradiate an object with a selected part of the linear laser light, an image pickup section that picks up an image of the object based on the laser light reflected from the object, and a controller that controls irradiation of the linear laser light. The linear laser light is composed of a plurality of parts including one end part and the other end part; and the irradiating section irradiates the object with the parts of the linear laser light sequentially from the one end part to the other end part.

Abstract: An optical system is disclosed that includes a housing that has an interior, a reflective interior surface, and a first opening. The optical system further includes a spatial light modulator that is disposed proximate the first opening and a light source that is disposed within the interior of the housing. The spatial light modulator modulates the light that is emitted by the light source to form image rays. The optical system further includes a first light redirecting film that is disposed proximate the first opening between the spatial light modulator and the light source. The first light redirecting film recycles at least a portion of the light that is emitted by the light source. The optical system further includes an optically absorptive film that is disposed proximate the first opening between the spatial light modulator and the viewing position. The optically absorptive film receives the image rays from the spatial light modulator and displays the received image rays to the viewing position.

Abstract: An optical device includes a non-transparent substrate. The optical device further includes a first optical layer which is at least partially transmissive and at least partially reflective to incident light. The optical device further includes a second optical layer which is at least partially reflective to incident light. The second optical layer is spaced from the first optical layer. At least one of the first optical layer and the second optical layer is movable between a first position at a first distance from the first optical layer and a second position at a second distance from the first optical layer. Movement of the at least one of the first optical layer and the second optical layer between the first and second positions modulates the reflectivity of the device.

Abstract: A method and apparatus is provided for processing an optical beam. The method includes spatially dispersing an optical beam received from an optical port into a plurality of wavelength components. The wavelength components are focused and at least one of the components is selectively directed to one of the optical ports by reflecting the focused wavelength component at least twice from a DMD before being directed to a selected one of the optical ports. A resolution of the focused wavelength component is optimized when it is reflected from the DMD a first or second time at the expense of the other time when it is reflected.

Abstract: Embodiments of the invention are directed to a new type of phase screen, i.e., an opto-electronic device that can convert a distorted incoming optical wavefront into a plane wave or, conversely, transform a plane wave into a prescribed varying output wavefront. The basic concept involves novel binary all-digital MEMS interferometer configurations that can be used to create controlled and arbitrary optical wavefront using only 0,1 amplitude changes followed by differential propagation distances to convert these amplitude variations into controllable and/or continuous phase variations. Clustered pixel notions, such as Floyd-Steinberg, Stucki or other algorithms useful in digital half-tone printing, are simultaneously employed to create controllable grey-level variations as well as continuous phase variations. Desired grey-levels can be obtained wherein each pixel is formed by, e.g., a 3×3 or 5×5 cluster of mirrors.

Abstract: An optical modulator device (100), in particular for a spatio-temporally light modulated imaging system (200), comprises a light modulating micro-mirror device (110) comprising an array of mirror elements (111) arranged in a modulator plane (112), wherein each of the mirror elements (111) can be switched individually between first (111a) and second (111b) states with first and second tilting angles, resp., relative to a modulator optical axis (113) perpendicular to the modulator plane (112), and a first optical relaying device (120) being arranged for relaying light between the mirror elements (111) in the first (111a) state and a first optical axis (121) deviating from the modulator optical axis (113), wherein the first optical relaying device (120) includes a first group of imaging elements (122, 123, 124) being formed such that a planar light field (114) perpendicular to the modulator optical axis (113) is relayed to a first planar light field (125) perpendicular to the first optical axis (121).

Abstract: A releasing and post-releasing method for making a micromirror device and a micromirror array device are disclosed herein. The releasing method removes the sacrificial materials in the micromirror and micromirror array so as to enabling movements of the movable elements in the micromirror and micromirror array device. The post-releasing method is applied to improve the performance and quality of the released micromirrors and micromirror array devices.

Abstract: A micro-electro mechanical device includes a first structure, a second structure offset from the first structure by a gap. The first structure is configured to be electrostatically actuated to deflect relative to second structure. A pulse generator is configured to combine at least two different pulses to electrostatically drive at least one of the first structure and the second structure between an initial position and a final position.

Abstract: A system and method for determining humidity based on determination of an offset voltage shift are disclosed. In one embodiment, a system for determining humidity comprises an electromechanical device comprising a first layer, a second layer, and a dielectric between the two layers, wherein the dielectric is spaced apart from at least one of the first and second layers in an unactuated state of the electromechanical device, and wherein the dielectric contacts both the first and second layers in an actuated state of the electromechanical device, a voltage source configured to apply, between the first and second layers, one or more voltages, and a processor configured to control the voltage source, to determine an offset voltage shift based on the applied voltages, and to determine information regarding humidity about the device based on the offset voltage shift.

Abstract: This disclosure provides systems, methods and apparatus for an electromechanical systems (EMS) assembly. The EMS assembly includes a substrate, an anchor disposed on the substrate, and a suspended planar body supported over the substrate by the anchor. The suspended planar body includes at least one depression extending out of a plane of the suspended planar body and protruding towards the substrate. The suspended planar body also includes a substantially horizontal portion corresponding to a gap in the at least one depression. An extent of the gap is up to 20% of a length of the suspended planar body.

Abstract: A lighting device is described for receiving source light within a predetermined source wavelength range, converting the source light into a converted light, and reflecting the converted light to a desired output direction. The lighting device may use a micro electromechanical system (MEMS) device to receive and redirect the source light to the desired output direction. A conversion coating may be applied to the operative surface of the MEMS device to convert the source light into a converted light.

Abstract: An optical device comprises a transparent substrate having: an array of micromirrors on one surface of the substrate; and a corresponding array of microimage elements, the micromirrors presenting convex surfaces to the microimage elements whereby each convex surface causes ambient light to pass through the microimage element array from a virtual focus, the arrangement of the microimage elements and micromirrors being such that they cooperate to generate a lenticular type or a moiré magnification effect.

Abstract: A micromechanical component having a displaceable part connected to a residual substrate by at least one spring, and including first and second subunits, between which an insulating intermediate layer and at least one semiconductor boundary layer is formed; an inner region of the first subunit, which inner region is aligned with the second subunit, being patterned out of a substrate using at least one cavity etched in a first etching direction; an outer region of the first subunit of the displaceable part, which outer region faces away from the second subunit, being patterned out of the substrate using at least one hollowed-out section etched in a second etching direction; the second subunit being patterned out of a semiconductor layer deposited onto the insulating intermediate layer and/or on the at least one semiconductor boundary layer using at least one continuous separating trench. Also described is a related manufacturing method.

Abstract: A phase screen, i.e., an opto-electronic device that can convert a distorted incoming optical wavefront into a plane wave or, conversely, transform a plane wave into a prescribed varying output wavefront. Binary all-digital MEMS interferometer configurations that can be used to create controlled and arbitrary optical wavefront using only 0,1 amplitude changes followed by differential propagation distances to convert these amplitude variations into controllable and/or continuous phase variations. Clustered pixel notions, such as Floyd-Steinberg, Stucki or other algorithms useful in digital half-tone printing, are simultaneously employed to create controllable grey-level variations as well as continuous phase variations. Desired grey-levels can be obtained wherein each pixel is formed by, e.g., a 3×3 or 5×5 cluster of mirrors. Both the filling-in of the outputs of the binary mirror (0,1) and the grey-levels are accomplished simply by spatial averaging over a short propagation distance.

Abstract: The application of optical microstructures improve the quality of light available to the viewer of an optical display system, or any display which works on the concept of moving one surface into direct contact or close proximity of a light guide to extract light through frustrated total internal reflection. Certain ones of the microstructures can act to assist in overcoming stiction between the surface and the light guide.

Abstract: Systems and methods provide control of nanoparticle coverage of an interface between a first medium and a second medium through variation of an electric potential across such interface; the first medium and the second medium are immiscible media, and transparent or substantially transparent to visible light. The first medium can be a first electrolytic solution and the second medium can be a second electrolytic solution; thus, the interface can become an interface of two immiscible electrolytic solutions (ITIES). The nanoparticle coverage of the interface, e.g., the ITIES, can be regulated to vary between approximately zero and a full or nearly a full monolayer. The nanoparticle coverage of the interface can dictate at least one optical property of the interface, rendering the interface transparent or substantially transparent, or a mirror, or providing Faraday rotation of the optical polarization of light incident normal to the interface and propagating through the interface.

Abstract: According to one embodiment, a target system includes a display module comprising a plurality of pixel elements operable to display target patterns. Each pixel element includes a display segment, a plurality of first charged pigments housed within the display segment each having a first charge, a plurality of second charged pigments housed within the display segment each having a second charge, wherein the first charge is opposite the second charge, and an electrical contact coupled to the display segment and operable to receive signals which cause an electric field to be present in the display segment. The system also includes at least one computer-readable tangible storage medium comprising executable code that, when executed by at least one processor, is operable to transmit signals to the display module that cause an electric field to be present in at least one pixel element of the plurality of pixel elements.

Abstract: In certain embodiments, a microelectromechanical (MEMS) device includes a movable element over the substrate and an actuation electrode. The movable element includes an electrically conductive deformable layer and a reflective element mechanically coupled to the deformable layer. The reflective element includes a reflective surface. The actuation electrode is under at least a portion of the deformable layer and is disposed laterally from the reflective surface. The movable element is responsive to a voltage difference applied between the actuation electrode and the movable element by moving towards the actuation electrode.

Abstract: A tunable bandwidth selector is disclosed. The tunable bandwidth selector may include a plurality of spaced apart electron sheets which selectively separate a first bandwidth from an input spectrum.