Abstract: A multiple waveguide edge lit structure includes a frame structure including a first heat sink and a second heat sink. The multiple waveguide edge lit structure also includes a circuit board including a first plurality of light emitting diodes (LEDs) and a second plurality of LEDs, where a portion of the circuit board is sandwiched between the first heat sink and the second heat sink. The multiple waveguide edge lit structure further includes a first waveguide and a second waveguide. A light receiving edge of the first waveguide is positioned proximal to the first plurality of LEDs, and a light receiving edge of the second waveguide is positioned proximal to the second plurality of LEDs. The multiple waveguide edge lit structure also includes a pair of attachment structures configured to keep the first waveguide and the second waveguide attached to the frame structure.

Abstract: In a gas discharge tube there is carried out narrowing of the discharge path with cooperation of the first opening 20 and second opening 12 in order to obtain higher luminance of light. Further, in order to maintain excellent starting-properties of a lamp even if the discharge path is narrowed, a predetermined voltage is applied to a second discharge path limit portion 11 externally. Thereby, a positive or active starting discharge is produced in such a manner as to pass through the first opening 20. Further, the second opening 12 is comprised of not only a straight section 13 extending in a direction of an optical axis Y, but also a spread section 14 extending from an end portion of the straight section 13 toward the first opening 20.

Abstract: In a gas discharge tube, a first discharge path-induction portion is arranged between a first discharge path-limit portion and a second discharge path-limit portion. A voltage is applied to the first discharge path-induction portion from the outside. As a result, an active starting discharge capable of passing through a first opening of the first discharge path-limit portion is produced between a cathode portion and the first discharge path-induction portion. As a consequence, there is facilitated the discharge at a starting time to pass through a second opening. As a consequence, there is achieved a rapid starting of discharge between the cathode portion and an anode portion.

Abstract: A gas discharge tube 10 of the present invention generates an electric discharge between an anode part 24 and a cathode part 56 disposed inside a sealed container 12 in which gas has been contained. The gas discharge tube 10 comprises an electric discharge path restricting part 28 which is cylindrical and disposed between the anode part and the cathode part, and which has a throughhole 42 for narrowing an electric discharge path between the anode part and the cathode part; and an electric discharge shielding part 50 which is disposed to surround the electric discharge path restricting part so as to restrict an electric discharge from the outer peripheral surface of the electric discharge path restricting part to the cathode part, and which is electrically isolated from the electric discharge path restricting part.

Abstract: The gas discharge tube in accordance with the present invention comprises at least two electrically conductive aperture members disposed within a thermoelectron transmission path between a cathode and an anode, and an insulator for electrically insulating the electrically conductive aperture members from each other, thereby being able to emit light with a high luminance. Its startability at the time of emitting light can be enhanced in particular when the aperture area of the electrically conductive aperture member on the downstream side in the thermoelectron transmission path is set favorably.

Abstract: Disclosed is a member for display apparatus used in a display apparatus comprising a back panel 1 on which electron sources are provided and a front panel 2 that are disposed to oppose the back panel 1 via spacers 3, said member comprising a ceramic that has a Young's modulus (E) of not lower than 120 GPa, a specific rigidity (E/?) of not lower than 40×109 cm, a coefficient of linear expansion of 7.5×10?6 to 10×10?6/° C. in a temperature range from ordinary temperature to 400° C., and a void-occupying area ratio of 6% or less. This member allows it to prevent the accuracy of the apparatus from lowering and cracks from occurring.

Abstract: A flat lamp for emitting light to a surface area of a liquid crystal display device includes a bottom having a channel uniformly crossing an entire surface of the bottom, an arc-discharging gas is disposed within the channel, a cover disposed upon an upper junction surface of the bottom, the cover is coated with a fluorescent material, and an electric field generating means for generating an electric field, wherein the electric field generating means is placed along opposing lateral sides of the channel.

Abstract: A structure suitable for partial or full use in a spacer (24) of a flat-panel display has a porous face (54). The structure may be formed with multiple aggregates (100) of coated particles (102) bonded together in an open manner to form pores (58). A coating (88) consisting primarily of carbon and having a highly uniform thickness may extend into pores of a porous body (46). The coating can be created by removing non-carbon material from carbon-containing species provided along the pores. A solid porous film (82) whose thickness is normally no more than 20 &mgr;m has a resistivity of 108-1014 ohm-cm. A spacer for a flat-panel display contains a support body (80) and an overlying, normally porous, layer (82) whose resistivity is greater parallel to a face of the support body than perpendicular to the body's face.

Abstract: A luminous display device and method of making the same wherein a front member of transparent glass (16) is fused to the rim area (4) of a rear member (1) having a recess (8) therein and protuberances (12) projecting from the base of the recess toward the front member, the protuberances being closely spaced with respect to each other and the front member to provide passages (14) between the protuberances and a light discharge chamber (20) between the front member and the recess. An opening (22) extends through the rear member communicating with the chamber. A tubular member (26) mounted on the rear member communicates with the opening for evacuating the chamber and filling it with ionizable gas. An electrode device (28) is mounted in the tubular member and is operatively connected to a power source (36) for ionizing the gas in the chamber thereby producing light discharge fingers (38,40,42,44) or streaks through the passages providing the desired display of light.

Abstract: Ultraviolet and vacuum ultraviolet radiators for use in the manufacture of semiconductors are provided which have improved lifetimes, improved distribution of radiation generation, improved distribution of emitted radiation, increased efficiency of radiation emission, and improved means for cooling. The radiators have novel electrodes, novel electrode configurations, novel means for distributing plasmas between electrodes, and have novel cooling means. These features enable the miniaturization of the radiators permitting high-intensity and uniform radiation exposure of planar surfaces. The radiators are used in the pre-treatment of semiconductor surfaces, the deposition of semiconductor thin films, and the post-deposition processing of semiconductor thin films.

Abstract: A flat-panel display comprising a hermetically sealed gas filled enclosure. The enclosure includes a top glass substrate having a plurality of electrodes and a thin dielectric film covering the electrodes and a bottom glass substrate spaced from the top glass substrate. The bottom glass substrate includes a plurality of alternating barrier ribs and micro-grooves. An electrode is deposited over each micro-groove and a phosphor is deposited over a portion of each electrode coating.

Abstract: An automotive neon-type discharge lamp assembly is provided including two spaced-apart electrodes; an elongated gaseous path having one of the electrodes approximately at each respective end, the path including a first generally semicircular reflector surface body having opposing ends and a center, a pair of second semiparabolic reflector surfaces, each surface having first and second ends, the first ends being joined to the ends of the first reflector surface and the second ends emanating outwardly therefrom; a transparent, generally concave volumetric concentrator positioned generally opposite the first reflector surface and spaced therefrom, the concentrator having first and second ends; and a transparent cover having two segments, each segment connecting an end of the concentrator with the second end of a respective second reflector surface.

Abstract: A plasma display device having a face plate and a rear plate spaced apart from each other. Parallel sustaining electrodes are arranged preferably on the face plate, while parallel address electrodes are arranged preferably on the rear plate, so that they are spaced apart from and extend perpendicularly to the sustaining electrodes. Barrier ribs are disposed to define discharge gas spaces adjacent to crossovers of the electrodes. At least some of the barrier ribs are transparent barrier ribs made of a light-permeable material, so that, particularly when the rear plate is covered with a reflective layering, light which might otherwise leak from the rear plate is usefully saved and caused to radiate through the face plate, whereby the use ratio of the emitted light increases.

Abstract: A high pressure discharge lamp is disclosed. The high pressure discharge lamp includes: a discharge tube which is filled with gas; a first electrode having a first end, the first electrode being provided in the discharge tube; and a second electrode having a second end which is positioned away from the first end by a certain distance, the second electrode being provided in the discharge tube. In the high pressure discharge lamp, arc discharge is induced by a voltage applied between the first end of the first electrode and the second end of the second electrode. The high pressure discharge lamp further includes a convection regulating member which is electrically insulating and provided in the discharge tube. The convection regulating member suppresses the deformation of the arc discharge caused by the convection of the gas in the discharge tube.

Abstract: An electrodeless low pressure discharge lamp, preferably filled with deuterium gas, is provided with a cylindrical envelope made from quartz glass and surrounded by a cylindrical excitation coil driven at between 10 and 800 MHz. Within the lamp envelope, there is provided a cylindrical aperture member made from boron nitride which in a radial direction extends to the inner surface of the envelope and which is provided with an uninterrupted coaxial channel for confining to a small diameter the plasma discharge arc generated during operation of the lamp, the aperture member having an optical axis extending through coaxially with its channel, the radiation emitting in a directed pattern along the optical axis.

Abstract: A noble-gas flashlamp having a self-replenishing mercury-pool cathode. The lamp includes a lamp envelope which is transparent to UV radiation and which forms a linearly extending discharge chamber for holding a noble gas discharge material. At the cathode end of the discharge chamber the envelope forms a cavity or bubble communicating with the discharge chamber. The cathode of the lamp is formed by a cathode electrode and a pool of liquid mercury in the cavity. The electrode is both electrically and thermally conducting, and the pool of liquid mercury covers the electrode and is in heat exchange relation with the electrode in the cavity. For enhanced heat transfer the cathode electrode extends beyond the lamp envelope so that it may be brought into direct contact with the lamp coolant material. The anode comprises an electrically and thermally conducting anode electrode at said anode end of the discharge chamber.

Abstract: A source of red light includes a double-bore capillary tube having a pair of ends and a convoluted shape. A pair of electrodes is located at one end of the capillary tube and disposed within respective bores. An ionizable medium is enclosed within the capillary tube and includes neon at a pressure from about 300 to 600 torr. When energized, the ionizable medium generates an arc discharge between the electrodes consisting primarily of radiation in the range of from 590 to 670 nanometers. An outer jacket of vitreous material may surround the capillary tube and contain an inert gas (e.g., nitrogen) at a predetermined pressure.

Abstract: A circular fluorescent lamp has a fluorescent tube of a generally circular shape having electrodes fixed gastight in both of its ends respectively to enclose inert gas and mercury therein. A cap is mounted to bridge between the tube ends. The fluorescent tube has an oval section taken along a line perpendicular with respect to its axis. The rate of ovalness y/x, representing the ratio between the larger tube diameter y and the smaller tube diameter x of the tube sectional shape, preferably lies within the range of 1.10 to 1.30.

Abstract: An isolator is provided which has an inlet at ground electrical potential which receives gas, and which has an outlet at a high electrical potential through which gas is discharged, the isolator being compactly and simply constructed while providing a long narrow path that minimizes the possibility of electrical breakdown through the gas. The isolator includes a first element forming a cylindrical core and a cup-shaped second element forming a sleeve portion that closely receives the core. The core has a helical groove on its outside to form a passage between the groove and the inner walls of the sleeve. The core also has a vertical hole extending to the bottom of the core and a radial groove in the bottom of the core that extends between the hole and the bottom of the helical groove.

Abstract: A low pressure discharge lamp, particularly a compact fluorescent lamp, having a plurality of constricting portions axially spaced apart and extending about the circular periphery of the envelope. The constricting portions, which include defined end segments projecting within the envelope, constrict the plasma discharge and spatially separate at least one of the discharge processes occurring within the plasma discharge and cause the separated process to take place in a different portion within the envelope so that the conditions for energy input and energy dissipation may be independently optimized.

Abstract: A luminous tube is provided with three color producing inner tubes and is mounted within a clear outer tube. The luminous gas filling the outer tube also fills the open-ended inner tubes. Each of the color-producing tubes has an electrode to enable the current density to be independently controlled, and thus control of the light-intensity emitted from each of the color-producing tubes. A luminous tube may also be constructed with at least one tube mounted inside an outer tube within a common luminous gas, where the inner tube houses an electrode and has a restricted diameter opening to produce a high-intensity luminous discharge.

Abstract: In a fluorescent lamp of the type in which a lamp envelope comprises an outer bulb having generally a spherical or a partially spherical or a cylindrical configuration and an inner bulb inserted into the outer bulb in predetermined nested relationship; either of the inner surface of the outer bulb or the outer surface of the inner bulb is formed with a groove which defines a zig-zag discharge path between the outer and inner bulbs; a phosphor is formed at least over the wall surfaces of the groove; electrodes are disposed at the ends, respectively, of the discharge path and a uv (ultraviolet) radiation-emitting discharge gas consisting of mercury vapor and a rare gas or a rare gas mixture is filled in the discharge path, both the open end portions of the outer and inner bulbs are flared radially outwardly and inwardly respectively, or either of the open end portion of the outer or inner bulb is flared radially outwardly or inwardly so that glass frit can be filled into the annular space defined between the op

Abstract: An atomic spectral lamp of the type comprising a predominantly glass envelope in which are disposed spaced electrodes for producing an electrical discharge on application of a suitable potential difference thereto and a substance which, on being heated will yield a vapor of an element capable of emitting the resonance line or lines which characterize the lamp. In normal operation of the lamp, there exists between the anode and the cathode a temperature gradient effective to ensure that the vapor pressure of the elemental vapor adjacent the cathode is small relative to the vapor pressure of the elemental vapor in the vicinity of said substance. In another aspect, heating means is provided for heating the substance independently of the discharge to yield the elemental vapor within the envelope.

Abstract: In a fluorescent lamp of the type in which a lamp envelope comprises an outer bulb having generally a spherical or a partially spherical or a cylindrical configuration and an inner bulb inserted into the outer bulb in predetermined nested relationship; either of the inner surface of the outer bulb or the outer surface of the inner bulb is formed with a groove which defines a zig-zag discharge path between the outer and inner bulbs; a phosphor is formed at least over the wall surfaces of the groove; electrodes are disposed at the ends, respectively, of the discharge path and a uv (ultraviolet) radiation-emitting discharge gas consisting of mercury vapor and a rare gas or a rare gas mixture is filled in the discharge path, both the open end portions of the outer and inner bulbs are flared radially outwardly and inwardly respectively, or either of the open end portion of the outer or inner bulb is flared radially outwardly or inwardly so that glass frit can be filled into the annular space defined between the op