Abstract: A compact, high resolution, bright and long life modulator for projection displays, mates a field emission array (FEA) with a deformable light valve modulator (DLVM) of reflective operation in a thin vacuum package. The DLVM includes a continuous film mirror layer formed on or between one or more deformable layers on a transparent substrate. The field emitters (at least one per pixel) are driven to deliver primary electrons that strike and deposit a charge that produces electrostatic forces that locally deform the continuous film mirror layer. Because the mirror layer is a continuous film, i.e. not pixelated, the modulator resolution is limited only by the addressing resolution of the FEA. Mating the FEA and DLVM technologies also reduces the drive voltage requirements associated with typical FEA driven phosphor displays and scanned beam DLVMs thus improving their performance and extending the lifetime of each.

Abstract: A micromirror light valve target configuration that overcomes the problems of limited deflection range, electrostatic and resolution by forming the secondary electron collector grid of a fine conductive mesh and placing it in close proximity to the micromirror array. The source, preferably a fixed beam array, addresses the micromirror array such that it exhibits a secondary emission coefficient less than one to write a negative charge pattern onto the mirrors so that they are attracted to the collector grid. If the anode is also in close proximity to the array, the mirrors can be addressed so that they deflect up toward the grid and down toward the anode thereby increasing the deflection range.

Abstract: A thin low power, paper white, direct-view display includes an array of bistable micromirrors that are deflected between two stable states, a dark state in which the mirror covers a portion of the background and a white state in which the mirror uncovers the background. The drive electronics are similar to those used in multiplexed LCDs but are modified in order to drive the micromirrors to one of their two stable states. The micromirrors in the enabled row are attracted up or down with sufficient force to exceed the micromirrors' bistable threshold and deflect the micromirrors to their dark and white states, respectively. The attractive forces on the micromirrors in the remaining non-enabled rows are insufficient to exceed the micromirrors' bistable threshold so that the micromirrors remain in their current stable state.

Abstract: A bright, high contrast, compact, large area, high-resolution light modulator uses a field emitter array (FEA) to address a charge controlled mirror (CCM). The FEA deposits a charge pattern onto the CCM, which in turn produces electrostatic forces that deflect the micromirrors in accordance with the amount of accumulated charge. The CCM that is used in combination with the FEA can be configured in many different ways to implement different actuation modes, e.g. attractive, repulsive, grid-actuated or membrane-actuated and different charge control modes, e.g. RC decay, RC sustain and charge control.

Abstract: The present invention provides a Schlieren projection system with a large aperture reflective imager. The combination of a beam-addressed CCM design with flat-panel manufacturing techniques configuration produces a large aperture imager that overcomes the problems of limited deflection range, high beam current, electrostatic instability and limited resolution associated with known electrostatically-actuated micromirror targets. The CCM imager includes a thin insulating membrane that decouples the electron beam from the micromirror array. Decoupling also allows the mirror to be designed to optimize reflectivity, exhibit a higher resonant frequency for better video performance, and be fabricated simultaneously with the hinges. The CCM imager is fabricated using flat-panel manufacturing techniques that are ideally suited to producing large aperture devices at low cost.

Abstract: A flat-panel direct view display positions an array of electrostatically-actuated cantilevered micromirrors in front of a contrasting background and opposite a flat-panel electron beam source. Depending upon the display configuration, the electron beam source addresses either the array of micromirrors or a reference surface a row at a time while the other is held at a reference potential. The electron beams modulate the potential difference between each micromirror and the reference surface thereby adjusting the magnitude of the attractive electrostatic force between the two. This in turn modulates the deflection of the micromirrors between their quiescent and fully actuated states to selectively cover and uncover the background thereby producing a grey scale direct-view image.

Abstract: A beam addressed electrostatically-actuated charge controlled mirror (CCM) with frame time utilization approaching 100% is provided by partially coating the CCM's pixelized beam addressing surface with a material having the opposite electron affinity. Each pixel of the pixelized beam addressing surface has first and second portions that exhibit secondary emission coefficients that are respectively less than and greater than one for the same beam energy. A beam or beams that are capable of subpixel resolution selectively address each pixel's first and second portions to control the amount of charge on the pixelized beam addressing surface and its localized potentials.

Abstract: An electrostatically actuated micromirror light modulator that exhibits increased deflection range, better charge efficiency and improved electrostatic stability. A thin insulating membrane decouples the electron beam from the micromirror array inside the vacuum cell. The membrane is just thick enough to stop the incident electrons from penetrating through to the mirrors but is thin enough to maintain resolution of the deposited charge pattern. An equipotential layer beneath the mirror array prevents any attractive force from being developed due to the accumulation of static charge on the surface of the light modulator that may otherwise cause the mirror to snap-over and become stuck to the substrate.

Abstract: A high intensity light modulator includes a micro-mirror light valve target with electrostatically-repelled micro-mirror elements. Each micro-mirror of the target array comprises a base electrode and an overlying micro-mirror element. In operation, charge is deposited upon the micro-mirrors to produce repulsive electrostatic forces that outwardly deflect the micro-mirror elements by an amount proportional to the deposited charge. In one embodiment, an array of micro-mirror light valves is formed directly upon the face plate of a vidicon tube and is addressed using a scanning electron gun.