Abstract: An electroluminescent (EL) material is sandwiched between parallel strips of electrodes running at right angles to each other. Pixels are formed where the electrodes cross to provide a thin film, EL display. The display includes a layer of insulating material which has a hole at each pixel. The backside electrodes extend into the holes, thus providing a high electric field only at the pixel locations. These backside electrodes are broad to assure electrical continuity despite any open-circuit created by burned-out pixels. The insulating material overlaps the edges of the frontside electrodes, thus reducing the electric field which concentrates at the electrode edge. The insulating layer and the backside electrode can be made black, or a light-absorbing, semi-insulating layer used in order to reduce light scattering and reflection. Transparent electrodes can be used to allow light to emit from either the front, the back, or both sides of the display.

Abstract: A semiconductor light emitting device comprises a laminated semiconductive structure including a substrate, an active layer thereon and a second layer adjacent the active layer remote from the substrate, the second layer having an inner region of high carrier concentration and an outer region of lower carrier concentration. An insulative layer is on the second layer, the insulative layer having a window coaxial with and larger than the inner region. A first electrode deposited on the insulative layer establishes an ohmic contact with the inner region of the second layer and a Schottky-barrier contact with the outer region. A second electrode is provided on the substrate opposite to the first electrode, the second electrode having a window for allowing light to leave therethrough.

Abstract: The lumen output of a fluorescent lamp is improved by the triode radio frequency sputter coating of a continuous protective coating of vitreous alumina overlying the lamp phosphor layer.

Abstract: A gas discharge device is provided with a getter film by sputtering an electrode used normally for device operation.

Abstract: A transparent electrode for use in a dispersive type electroluminescent device or the like comprises a transparent substrate, a transparent electrode film on the substrate, and a number of closely spaced protective ridges continuous with each other on the electrode film.

Abstract: The present invention provides an improvement in color picture tubes having slit type apertured shadow masks wherein the aperture throats are arranged in columns, and the apertures within each column are separated by webs. The improvement comprises the aperture throat columns passing through a center portion of the mask being substantially straight, and the aperture throat columns on both sides of the center portion of the mask being convexly curved toward the center portion and increasing in curvature with distance from the center portion.

Abstract: An apparatus for maintaining constant pressure in gas discharge vessels, particularly for flat plasma picture screens with electron post-acceleration. The gas pressure is kept constant in the gas discharge vessel. For this purpose, a glass container preferably filled with helium is applied in the gas discharge vessel, this glass container being provided with a heater for temperature control and thus provides variable gas permeability. An apparatus of the invention is particularly employed for flat plasma picture screens.

Abstract: A slit light emitting type hot cathode fluorescent tube illumination system including at least one substrate, a plurality of strip anodes, a plurality of fluorescent substance layers each superposed on one of the anodes, and hot cathode filaments located above top surfaces of the fluorescent substance layers for emitting thermoelectrons exciting the fluorescent substance layers to emit light for illuminating an original by slit illumination. A cylindrical lens is located in a path of the light emitted by the fluorescent substance layers in such a manner that the generating line of the cylindrical lens is parallel to the length of the fluorescent substance layers. The substrate and cylindrical lens cooperate with each other to provide an illumination system in tubular form, with the aid of a side plate when necessary.

Abstract: Gas discharge display device having a vacuum-tight gas-filled envelope with a front plate and a back plate. A perforated control unit divides the interior of the envelope into a gas discharge space and a post-acceleration space and includes several electrode planes extending parallel to the plates. The gas discharge space has at least one plasma cathode and at least one plasma anode. The front layer carries on its back side a cathodoluminescent layer as well as an electrically conducting layer (post-acceleration anode). A spacer frame spaces the conductor as post-acceleration cathode in the foremost electrode plane of the control unit from the post-acceleration anode. In operation, a gas discharge burns at least temporarily between the plasmas electrodes. Electrons are pulled through selectively opened holes of the control unit into the post-acceleration space. The post-acceleration space which remains free of discharges is accelerated to several kV.

Abstract: A three electron gun color picture tube includes phosphorescent marks attached to the rear side fo the shadow mask. These marks can be used for checking the exact position of the electron beams during adjustment.

Abstract: To insure orientation of internal current leads (9, 10; 23, 24) extending om a press seal (14, 27) at the end of a bulb (3, 28) inwardly thereof, small metal elements (19, 20; 31, 32), preferably of the same material as the inwardly extending current leads, are connected, for example by welding, to the inwardly extending current leads, the small metal elements being oriented to extend transversely to the major direction of the current leads and positioned in a plane determined by the plane of the press seal.

Abstract: A short arc lamp includes a window assembly which can be fitted together and secured to a hollow cylindrical body member of the lamp in a single braze. The window assembly includes a transparent window, a tubular cowling member, a retaining ring and struts for supporting a cathode within the lamp. The lamp further includes a hollow concave reflecting shell which is held in place within the first body member by a second hollow cylindrical body member and a dielectric spacer ring.

Abstract: A cathode ray tube comprises an envelope, an electron gun having a beam limiting aperture, a first electrode, a second electrode, a third electrode and a mesh electrode, the first, second and third electrodes constituting electrostatic lens system to focus the electron beam, the second electrode being a deflection electrode of arrow or zig-zag patterns to deflect the electron beam, wherein if distance between the beam limiting aperture and the mesh electrode is l, length of the second electrode is made (1/3 l-1/10 l) and (1/3 l+1/10 l), and distance between the beam limiting aperture and the center of the second electrode is made (1/2 l-1/3 l) to (1/2 l).

Abstract: A novel color selection electrode assembly is utilized in screening a pattern of phosphor areas upon the faceplate of a color cathode ray tube. The faceplate, which is formed of a material having a predetermined temperature coefficient of expansion, has registration affording means. The aforesaid assembly comprises an auxiliary mount formed of a material having a temperature coefficient of expansion greater than that of the faceplate and has a central opening of such span as to enable the mount to surround the periphery of the faceplate. Index bosses, cooperable with the faceplate registration affording means, are detachably secured to the mount. A planar metal foil having a predetermined pattern of apertures and formed of a material having a temperature coefficient of expansion not greater than that of the mount is secured to the mount.

Abstract: In a color cathode ray tube having an in-line electron gun with overlapping CFF lenses, the small openings of the focusing electrode apertures are critically enlarged to balance the asymmetry of the lensing field caused by the overlap, and beam spot distortion due to field asymmetries in the focus region is eliminated. Enlargement is achieved by elongating the openings in a direction normal to the in-line plane, and widening the outer openings.

Abstract: In a color cathode ray tube, a shadow mask is stretched on a mask frame and the mask frame is supported on a peripheral inner surface of a skirt of a panel by an elastic deformable plate member. The elastic deformable plate member is formed by bending a metal plate and has a straight plate section with a predetermined analge .alpha. defined by the following inequality.tan (.alpha.)>(.alpha.m/.alpha.f) tan (90-.beta.)where .beta. is an angle formed by a tube axis and one of the electron beams which passes through effective one of apertures of the shadow mask, said one of the apertures being closest to the plate member, and .alpha.m and .alpha.f are thermal expansion coefficients of the shadow mask and mask frame, respectively.

Abstract: A cathode ray tube comprises an envelope, an electron beam source positioned at one end of the envelope, a target positioned at another end of the envelope, and an electrostatic lens means positioned between the electron beam source and the target. The lens means has a first cylindrical electrode and a second cylindrical electrode positioned along the electron beam path to focus the electron beam. The second cylindrical electrode is divided into four patterned electrodes, and each of the deflection electrodes has a lead which is formed across the first cylindrical electrode but is isolated therefrom. The portion of the leads is positioned to cause a predeflection to the electron beam.

Abstract: An electron gun of uni-potential type is disclosed, which includes a main electron lens system consisting of a front electron lens system formed of a third grid and a fourth grid and a rear electron lens system formed of the fourth grid and a fifth grid of which the electron lens action regions are separated from each other. In this case, the electron lens diameter of the front electron lens system is selected smaller than that of the rear electron lens system, and the aperture diameter of the fifth grid in the rear electron lens system is selected larger than that of the fourth grid, and may be nearly as large as the inner diameter of the tube in which it is placed for use.

Abstract: A system for incorporation in ion-beam equipment to provide ion species filtering and optional ion beam blanking. The system has four magnets arranged on an optical axis. In between the two center magnets is arranged a plate having an off-axis aperture. The ion beam is caused to converge to a focus on a midplane in which the aforesaid plate is situated. When the magnets are energized, the ion beam is caused to bend by an amount depending upon the charge-to-mass ratio of the ion species within the beam. If constructed correctly, the aperture can thus be arranged to pass only a single ion species, the remainder colliding with and being absorbed by the plate. Beam blanking may optionally be achieved by blanking plates which may be used to deflect the ion beam in such a way that the resultant focal point of the ion beam is displaced away from the aperture so that the whole ion beam is blanked off. Astigmatism introduced into the system may be reduced or eliminated by the use of octopole electrode sets.

Abstract: A display tube comprising in an evacuated envelope (1) a display screen (7) provided on the inside of a display window (2) in the wall of the envelope (1), which display screen (7) comprises luminescent material (13), and a multilayer interference filter (12) is provided between this material and the display window and compises a number of layers (HL) which alternately are manufactured from a material having a high (H) and a material having a low (L) refractive index. If the filter is composed substantially of 14 to 30 layers, each having an optical thickness nd, wherein n is the refractive index of the material and d is the thickness, which optical thickness is between 0.2 .lambda..sub.f and 0.3 .lambda..sub.f and preferably between 0.23 .lambda..sub.f and 0.27 .lambda..sub.f, wherein .lambda..sub.f is equal to p x .lambda., wherein .lambda. is the desired central wavelength which is selected from the spectrum emitted by the luminescent material (13) and p is a number between 1.18 and 1.