Abstract: Methods for driving a plurality of MEMS devices in an apparatus are described. A voltage pulse is applied to an electrode or a structure portion of a MEMS device. The electrode is on the substrate underneath the structure portion. At least two MEMS devices of the plurality of MEMS devices have different threshold voltages, and the threshold voltage is the minimum voltage required to move the structure portion. A bias voltage is applied to whichever of the electrode or the structure portion of the MEMS device does not have the voltage pulse applied thereto. The bias voltage and the voltage pulse are capable of moving the structure portion of the MEMS device that has the higher threshold voltage of the different threshold voltages.

Abstract: In various embodiments of the invention, an interferometric display device is provided having an external film with a plurality of structures that reduce the field-of-view of the display. These structures may comprise, for example, baffles or non-imaging optical elements such as compound parabolic collectors. The baffles may comprise a plurality of vertically aligned surfaces arranged, e.g., in a grid. In certain preferred embodiments these baffles are opaque or reflective. These vertical surfaces, therefore, can substantially block light from exiting the interferometric display device in a substantially non-perpendicular direction. These vertical surfaces may, however, permit light directed in a substantially vertical direction to exit the display. The non-imaging optical elements, e.g., compound parabolic collectors, redirect light from large incident angles into more normal angles towards the display. As a result, the light reflected by the display to the user is also at a more normal angle.

Abstract: A spatial light modulator may be adapted to receive bi-directional drive signals. The spatial light modulator may include a plurality of pixel elements having individual first electrodes and a common electrode providing a second electrode for each of the pixel elements. The pixel elements may be adapted to change between a first state and a second state in accordance with signals applied thereto, and the bi-directional drive signals may include at least a first drive signal and a second drive signal. Both drive signals are applied to change the pixel elements from the first state to the second state and from the second state to the first state.

Abstract: An apparatus is provided that includes a light source, an array of light-reflecting devices, and a processor for positioning the light-reflecting devices so as to display an image on the display screen. Each of the light-reflecting devices selectively reflects the light from the light source onto a corresponding pixel of a display screen. The processor positions a first of the light-reflecting devices such that light from the light source is reflected by the first light-reflecting device onto a first pixel of the display screen, which is different than the pixel of the display screen that corresponds to the first light-reflecting device.

Abstract: A light control device according to the present invention comprises a plurality of optical elements between two transparent plates in each of which a pair of transparent substrates having taper-shaped side faces with transparent electrodes are located so as to face each other, and a light control layer capable of changing the light transmitting state by electrically controlling the pair of transparent electrodes is disposed between the pair of transparent electrodes, and further, a transparent solid layer is filled in a space formed in the gap between the two transparent plates.

Abstract: Provided is an optical element including: a substrate; and at least one at least partially aligned thermally reversible photochromic-dichroic compound connected to at least a portion of the substrate and having an average absorption ratio greater than 2.3 in an activated state.

Abstract: One embodiment relates to a method of independently controlling amplitude and phase modulation by a spatial light modulator. Light is illuminated onto upper layer deflectable planar areas and lower layer deflectable planar areas over a substrate of the spatial light modulator. First active circuitry on the substrate is used to provide amplitude modulation by controlling a relative displacement between upper layer deflectable planar areas and adjacent lower layer deflectable planar areas. Second active circuitry on the substrate is used to provide phase modulation by controlling a displacement between the (upper and lower layer) deflectable planar areas and the substrate. Other embodiments and features are also disclosed.

Abstract: An assembly is provided for simulating the dilating and constricting of a pupil of an eye. The assembly includes a shell that is at least translucent to light and a dilation mechanism with a deformable member positionable to contact an inner surface of the shell. An actuator is provided in the dilation mechanism to move the deformable member toward and away from the inner surface, which causes the size of a contact area between the inner surface and a lip of the deformable member to vary over a preset range. The assembly includes a light source directing light onto the inner surface of the shell. The deformable member dynamically blocks light from reaching the inner surface, creating a pupil or dark hole. The light may be an ultraviolet light and the deformable member contacts a pattern or artwork on the inner surface including portions that glow in ultraviolet light.

Abstract: A lens-free ophthalmoscope (21, 41) comprising means (22, 42) defining a first light path (a), reflective means (23, 43) arranged to divert light from the first light path (a) along a second light path (b) extending through a first window (24, 44) and into a subject eye (29, 49), a second window (25, 45) through which a user can view a subject generally parallel to the second light path (b), and a baffle (23, 26; 43, 46) arranged between the first light path (a) and second window (25, 45) to prevent, or at least substantially reduce, any light exiting the ophthalmoscope through the second window (25, 45). Hence, any light which might otherwise pass through the second window (25) int the eye (30, 50) of an user, is eliminated or at least substantially reduced, thereby substantially reducing glace and enhancing the user's view of the subject eye (29, 49).

Abstract: A micromirror array 110 fabricated on a semiconductor substrate 11. The array 110 is comprised of four operating layers 12, 13, 14, 15. An addressing layer 12 is fabricated on the substrate. A raised electrode layer 13 is spaced above the addressing layer by an air gap. A hinge layer 14 is spaced above the raised electrode layer 13 by another air gap. A mirror layer 15 is spaced over the hinge layer 14 by a third air gap.

Abstract: Disclosed herein is a micromirror device having in-plane deformable hinge to which a deflectable and reflective mirror plate is attached. The mirror plate rotates to different angles in response to an electrostatic field established between the mirror plate and an addressing electrode associated with the mirror plate.

Abstract: An electric paper apparatus comprised of a single sheet of components, and a method of forming same, are provided. The single layer includes display elements, such as bi-stable pixel structures, and conductive particles, both preferably embedded in an insulating matrix of material (e.g. non-conductive particles). The display elements, or bi-stable pixel structures, take the exemplary form of microencapsulated bichromal spheres. The conductive particles serve as both conductive islands and as a ground plane. In this regard, the conductive particles form a discontinuous random pattern of conductive islands on one side of the sheet, and a continuous electrically conductive percolative network, or ground plane, on the other side of the sheet. This is accomplished by varying the effective percolation threshold across the thickness of the sheet. Doing so will provide particles on one side that are below the percolation threshold (e.g. the conductive islands) while the particles on the other side (e.g.

Abstract: A security element connected to at least a portion of a substrate, the security element including an at least partial coating having a first state and a second state connected to at least a portion of the substrate, the at least partial coating being adapted to switch from a first state to a second state in response to at least actinic radiation, to revert back to the first state in response to thermal energy, and to linearly polarize at least transmitted radiation in at least one of the first state and the second state.

Abstract: In some embodiments, a dynamic optical tag communication system is provided which includes high and low index CCR, both having a modulator, such as TCFP-MQWs on a first side of the CCR configured to modulate in a first temperature range, and a modulator on a second side of the CCR to modulate in a second temperature range. In some embodiments another high index CCR having corresponding first and second temperature range modulators is provided. In some embodiments, a CCR may have three modulators, such as MQWs, one configured to modulate in a first temperature range, another to modulate in a second temperature range, and yet another to modulate in a third temperature range. In some embodiments, a dynamic optical tag communication system has CCRs which include a high index CCR having a DDG modulator and a low index CCR having a DDG modulator.

Abstract: A method of fabricating a tiltable micro mirror plate includes forming a substrate comprising an upper surface and a hinge support post in connection with the upper surface, disposing over the substrate a first sacrificial material selected from the group of amorphous carbon, polyarylene, polyarylene ether, and hydrogen silsesquioxane, depositing one or more layers of structural materials over the first sacrificial material, forming an opening in the one or more layers of structural materials, wherein the opening can provide access from outside to the first sacrificial material below the one or more layers of structural materials, and removing the first sacrificial material to form the tiltable micro mirror plate in connection with the hinge support post.

Abstract: A portable ophthalmic apparatus (1) according to the present invention comprises a supporting part (7) to which a cellular phone (2) having a photographing camera (5) is mounted detachably and a main body (6) which is provided with the supporting part (7) integrally and has an illumination optical system (13) projecting an illumination beam toward photographing objective eyes (E) along an illumination optical axis (O2) intersected at a predetermined angle with a photographing optical axis (O1).

Abstract: A method of making an optical element including forming an at least partial coating of at least one at least partially aligned thermally reversible photochromic-dichroic compound on at least a portion of a substrate.

Abstract: Embodiments of the present invention generally relate to a device that has an improved usable lifetime due to the presence of a lubricant that reduces the likelihood of stiction occurring between the various moving parts in an electromechanical device. Embodiments of the present invention also generally include a device, and a method of forming a device, that has one or more surfaces or regions that have a volume of lubricant disposed thereon that acts as a ready supply of “fresh” lubricant to prevent stiction occurring between interacting components found within the device. In one aspect, components within the volume of lubricant form a gas or vapor phase that reduces the chances of stiction-related failure in the formed device. In one example, aspects of this invention may be especially useful for fabricating and using micromechanical devices, such as MEMS devices, NEMS devices, or other similar thermal or fluidic devices.

Abstract: The invention relates to an electro-optically active display device, comprising at least one individually addressable pixel, each pixel being provided with an obstructing element (3), such as a reservoir light shield, a black matrix or a mirror element. According to the invention, a portion of at least one component is positioned beneath the obstructing element in such a way that the portion is not visible for a viewer of the display device.

Abstract: Optically controlled micro-electromechanical systems (MEMS) is disclosed. In one embodiment, a MEMS device may include a rotatable mirror having an optical sensor that is in electrical communication with the rotatable mirror via an associated electrode. Electrical potential may be supplied to an appropriately configured optical sensor so that a variable range of voltages may be supplied to the rotatable mirror. In operation, an optical control beam may be directed onto the optical sensor where it may be sampled to determine its optical characteristics (e.g., optical wavelength, light intensity, position, polarization, duty cycle, etc.) The optical sensor may then supply voltage to the rotatable mirror based on the determined optical characteristics of the optical control beam, causing the rotatable mirror to rotate about one or more axes.