Abstract: A display device (1) comprises a display screen (10) which comprises a blue color filter layer (24B) and a blue phosphor (25B). The blue phosphor is provided with or covered by blue pigments.

Abstract: The present invention provides a flat panel display device in which a liquid coating method is used to form various function films that improve contrast and color sense, and prevent external light reflection. The flat panel display device includes a flat display panel for realizing predetermined images and including a front substrate and a rear substrate provided opposing one another with a predetermined gap therebetween, and a filter provided on at least one side of the flat display panel to improve display characteristics. The filter includes a transparent baseplate, and a transmissivity control film that has pigmentation and is formed on at least one side of the baseplate using a liquid coating method. With the use of the liquid coating method to form the filter, productivity is increased, manufacturing costs are minimized, and scratch resistance is provided.

Abstract: A light-emitting device comprises a substrate (13), a light-emissive layer (15) disposed over the substrate, and a grating (17) for aligning the light-emissive layer (15). The grating (17) aligns molecules of the emissive layer (15), so that the device emits polarised. The grating also reduces wave guiding effects in the device, so increasing the useful light output of the device.

Abstract: A light-emitting device is disclosed with improved luminance even with increased arrangement density of a reflector regardless of a light-emitting region. The disclosed device includes a reflector between an electrode for extracting light from a layer including a luminescent material, which serves as a light-emitting region of a light-emitting element, and an exterior space (air). In addition, a light-extraction efficiency can be improved by setting an angle made by a surface of the reflector, which faces the light-emitting element, and a side surface of the reflector (hereinafter, referred to as a slope angle of the reflector) in a predetermined range as for a shape of the reflector.

Abstract: A light extracting sheet is provided on a light extracting surface of an organic EL device. A prism sheet is provided on the light extracting sheet. The light extracting sheet has a first incident surface contacting the light extracting surface and a light exit surface located at an opposite side from the first incident surface. The light exit surface defines a plurality of first projections. Each of the first projections is pyramid. The prism sheet has a second incident surface that is substantially parallel to the light extracting surface and a light exit surface located at an opposite side from the second incident surface. The light exit surface defines a plurality of second projections. Each of the second projections is pyramid.

Abstract: A display device includes a flat display panel in which a plurality of pixels are arrayed in a matrix at an interval and covered with an optically transparent material, and an optical sheet to impart the front directivity of the flat display panel. Light which is emitted from a predetermined one of the plurality of pixels and emerges outside from the surface of the optical sheet located on a region except the pixel to the front direction overlaps neighboring pixels arranged around the pixel in a width equal to or smaller than 20% of the pixel width of the neighboring pixels.

Abstract: Disclosed is a display panel module having a black panel adequate for a film type front filter, and a manufacturing method thereof. The display panel module includes a display panel; a black frame formed on a front surface of the display panel to define an effective screen area; and a front filter formed on the front surface of the display panel on which the black frame is formed, to shield electromagnetic waves and for optical correction.

Abstract: A flat display panel comprising a flat display panel main body, and a front protective plate which comprises an antireflection layer, a translucent electrically conductive layer, containing a metal having an electromagnetic wave shielding property and a near infrared ray shielding property, a highly rigid transparent substrate made of a tempered glass or a semi-tempered glass and an adhesive layer laminated in this order, bonded to the viewer's side surface of the flat display panel main body by means of the adhesive layer.

Abstract: An apparatus and method for blocking ultraviolet radiation from a arc tube includes a coating placed on at least a portion of the arc tube to block the UV radiation but yet pass visible light from the arc tube.

Abstract: A U-shaped compact fluorescent sun-tanning lamp (10) capable of generating and transmitting desired and undesired wavelengths of ultraviolet radiation, for example, the desired wavelength is in the range of 352 nm and the undesired wavelength is in the range of 254 nm. The lamp (10) comprises two lamp tubes (12) that are transparent to the desired wavelength of the ultraviolet radiation and substantially opaque to the undesired wavelength of the ultraviolet radiation. The tubes (12) are connected at the upper portion by a bight (14) that in an unmodified state is transparent to both the desired and the undesired wavelengths of the ultraviolet radiation. A modification (16) on the bight (14) is opaque to at least the undesired wavelength of ultraviolet radiation. In a preferred embodiment the modification is a ceramic paint (18).

Abstract: An optical filter of a plasma display panel (PDP) and its fabrication method are disclosed. The optical filter includes an electromagnetic wave shield layer having a bias angle formed by cutting a mesh film along a predetermined direction.

Abstract: Provided are a transparent substrate capable of improving the light extraction efficiency of an organic electroluminescence device, and a practical organic electroluminescence device using the substrate.

Abstract: A light-emitting unit, including LEDs mounted on both sides of a substrate, simulates a spherical light source. The LED on each side of the substrate is enclosed by a lens made of a material containing light-dispersing particles. The substrate is provided with a wiring pattern connected to the LEDs. Each of the light-dispersing lenses has a circular periphery which is adjacent to an edge of the substrate.

Abstract: The light source has an LED, preferably produced for the surface-mounting technique, embedded in a transparent material filling. A converter substance is integrated in the filling for the at least partial wavelength conversion of the light emitted by the LED. A lens is glued onto the transparent material filling. The material filling has a convex surface and the lens has a concave underside entering into a form fit with the convex surface of the material filling.

Abstract: An illumination system has a light source that is at least partially enclosed within a light-recycling envelope. The light source is a light-emitting diode that emits light, and a fraction of that light will exit the light-recycling envelope through an aperture. The light-recycling envelope recycles part of the light emitted by the light source back to the light source in order to enhance the output radiance of the light exiting the illumination system.

Abstract: An array display may be formed of panels that include a resilient material positioned around their edges. The resilient material may be black to promote a seamless appearance. Because the material is resilient, it may facilitate the interconnection of panels to form the array, preventing damage during assembly or thereafter.

Abstract: A display device comprises a substrate and a laminate structure formed on the substrate and comprising a plurality of layers including a display region. The laminate structure has a recessed/projected portions at least one of an outermost surface of display side and an interface between the layers. The projected portions of the recessed/projected portions have a mean circle-equivalent diameter ranging from 50 nm to 250 nm with the standard deviation of circle-equivalent diameter of the projected portions being within the range of 10 to 50% of the mean circle-equivalent diameter, and a mean height ranging from 100 nm to 500 nm with the standard deviation of height being within the range of 10 to 50% of the mean height. The projected portions have a circularity coefficient ranging from 0.6 to 1, and an area ratio ranging from 20 to 75%.

Abstract: A fluorescent lamp with compensation for ineffective luminance thereof, including a lamp tube; and a fluorescent layer incompletely coated on an inner surface of the lamp tube to define a first light-transmitting section at a middle portion of the lamp tube and a second light-transmitting section at two ends of the lamp tube, wherein the second light-transmitting section has an area larger than that of the light-transmitting section.

Abstract: A plasma lamp and method having high efficacy, high color rendering index, and a desirable correlated color temperature with improved color consistency from lamp to lamp. The lamp may include a vaporizable fill material comprising halides of sodium and scandium and a filter formed from a vitreous material containing a dopant. In one aspect, the filter is formed by a glass shroud containing neodymium oxide that reduces the transmission of yellow light.

Abstract: The invention relates to a lamp comprising a transparent envelope having a first region defining an enclosed interior volume, and a closure region adjacent said first region, a light source located in said interior volume and electrically coupled to the exterior through said closure region, an interference filter coating formed on the exterior of said first region, said interference filter coating defining a spectral region of transparency, a light absorbing coating formed on the exterior of said first region, wherein said light absorbing coating comprises a ring-shaped portion having a layer thickness of at least 20 nanometer.

Abstract: A flat panel display device and process incorporating a light-shield formed on either on a substrate or an encapsulation substrate, blocking ambient external light so that contrast and efficiency are improved, may be constructed with a substrate, a display device formed on the substrate, and an encapsulation substrate that encapsulates the display device. At least one of the substrate and the encapsulation substrate have protrusions for emitting a light emitted from the display device, with each of the protrusions including an aperture on its top surface, and a light-shield. The light-shield includes a light-reflecting layer selectively formed on a side wall of each of the protrusions reflecting internally generated light, and a light-shielding layer formed on the light-reflecting layer to block external light.

Abstract: A light source composed of a planar, or substantially level, flat or curved, rigid or flexible, matrix of microfilaments integrated on a single substrate and capable of emitting light by incandescence when supplied by an electric current.

Abstract: A self-luminous image display apparatus of the present invention includes an output section for displaying an image, a reflection section provided on a rear side of the output section with a reflective surface thereof facing the output section, and a light-emitting section provided on a rear side of the output section. The output section includes a linear polarization device provided so as to cover a display surface for transmitting only predetermined linearly-polarized light of ambient light, and a retardation film provided closer to the light-emitting section than the linear polarization device for turning the linearly-polarized light transmitted through the linear polarization device into circularly-polarized light. The linear polarization device has a degree of polarization greater than 70.0%.

Abstract: A light emitting device that is capable of changing the illumination angle in the transverse direction while efficiently utilizing energy from a light source. An emission unit includes at least an arc tube. A pair of reflecting means are arranged in a longitudinal direction of the arc tube so as to reflect luminous fluxes emitted from the arc tube in a direction which varies according to the distance between the emission unit and each of the reflecting means.

Abstract: A top-emitting OLED display that includes a substrate; an array of OLED light emissive elements formed over the substrate; an encapsulating cover located over the OLED light emissive elements; and a circular light polarizer located between the encapsulating cover and the OLED light emissive elements. The present invention has the advantage that it improves the contrast and robustness of an OLED display by protecting the circular light polarizer from environmental wear and enables the application of additional structures on the top of the encapsulating cover.

Abstract: A light emitting display panel and a manufacturing method thereof capable of improving an extraction efficiency of emitted light, preventing reflection of incident light from outside as well as appearance of the image display, and enhancing current efficiency and a life of the panel including the light emitting element are provided. The light emitting display panel comprises a transparent substrate equipped with a light emitting element on a first surface thereof, a second surface of the transparent substrate defining a display surface; and a microlens array disposed above the second surface of the transparent substrate 1. The method of manufacturing the light emitting display panel comprises the step of adhering the microlens array with the second surface of the transparent substrate via adhesive.

Abstract: The invention relates to a halogen incandescent lamp for motor vehicles with an elongate bulb which is closed at one end and has a vacuumtight pinch seal at the other end, with at least one incandescent element arranged in the bulb, with a lamp cap connected to the pinch seal, and with current supply leads which are passed through the pinch seal to the incandescent element, with an annular optical filter which is provided at the closed end of the bulb. It is possible with such a halogen incandescent lamp in a simple manner both to change the subjective impression of the generated light and to improve the objective properties through emphasizing of a desired region of the spectrum.

Abstract: In a luminous display element, a retro-reflector is provided on the back side of an organic EL layer which includes an emission layer whose state changes between an emission state and a non-emission state. The retro-reflector includes a corner cube array, and reflects incident light in the same direction as an incident direction. A unit structure of the corner cube array is a form of a triangular pyramid which is made up of rectangular equilateral triangles having three faces, and a light shielding process is performed on the periphery of a base angle of the rectangular equilateral triangle. Thus, it is possible to prevent an image from being reflected, so that it is possible to provide the luminous display element whose contrast ratio and the utilization efficiency of emission are high.

Abstract: A display structure (200, 500, 600, 700, 800) comprises an emissive layer (260, 360, 460) and an excitation prevention layer (270, 370, 470, 735, 840). The emissive layer includes a set of first color emitting areas (211, 216, 221, 311, 316, 321, 411, 416, 421) that emit a first color light in response to light that is generated by a first set of light emitting diodes (LEDs) (210, 215, 220, 310, 315, 320, 410, 415, 420) that are preferably organic. The excitation prevention layer is disposed at the front side of the emissive layer and includes a first set of excitation prevention filter areas (225, 230, 235, 325, 330, 335, 420, 430, 435). In one embodiment, a first set of excitation prevention filter areas block a band of the light that is incident upon the emissive layer from the front of the display, wherein the blocked band of light is within an excitation band of the first set of LEDs.

Abstract: A light source useful for a wide variety of lighting applications such as signage, architectural or automotive designs, as well as cosmetic and/or functional features for other products can be created by combining a light collector comprising a sheet of material having a fluorescent substance incorporated therein and an optical element juxtaposed adjacent the collector. Light incident on the collector induces fluorescence that is trapped by total internal reflection, concentrated, and radiated from an edge of the collector. The size of collector plate with respect to its thickness is such that it provides an intensified image along its edge that is readily visible during both daytime and nighttime. The optical element modifies the distribution of light output from an edge of the collector. The optical element is preferably configured to decrease divergence of light emitted from the edge. The optical element may also direct the light emitted from the collector above or below the plane of the collector.

Abstract: A cathode ray tube includes a film which is formed on an outer surface of a panel portion. The film is comprised of a first particles which become transparent due to the oxidation and a second particles which are chemically and physically stable and have the light absorbing ability and the conductivity. A number of the transparent first particles is gradually increased toward a peripheral portion from the center portion of the panel portion.

Abstract: A method of making a light source includes the steps of forming a first optical component having a phosphor material in fixed relation to a first multilayer interference reflector, providing a second optical component having an LED capable of emitting light that excites the phosphor material, and positioning the first optical component to receive emitted light from the second optical component.

Abstract: A short arc lamp is optimized for improved thermal performance characteristics. The short arc lamp includes a ceramic body having a concave reflective surface formed in an upper end thereof, a base adapted to receive the base end of the ceramic body in abutting relation, and a window frame assembly positioned in abutting concentric relation with the upper end of the ceramic body. In particular, the ceramic body is formed from beryllia (beryllium oxide) which has superior thermal transfer characteristics. The lamp is further provided with a specialized coating which help keep infra-red (IR) light energy from escaping from the lamp. In one instance, the coating is an IR reflective coating placed on the window of the lamp to reflect IR light energy back into the lamp where it can be conducted outwardly through the beryllium oxide body and base.

Abstract: A color filter substrate includes a transparent substrate with first and second opposed edges, a color filter layer including color filters of first, second and third types extending in a first direction with the third type interposed between the first and second types, and an opaque layer including opaque portions extending in the first direction and another opaque portion connected to the other opaque portions along the second edge. The color filter substrate is fabricated by (a) forming the opaque layer on the transparent substrate, and then (b) forming the color filter layer thereon. The step (a) includes forming an opening between one end of each color filter of the third type and the second edge. The step (b) includes attaching and rolling a dry film in the first direction on the transparent substrate after the color filters of the first and second types have been provided thereon.

Abstract: The light source has an LED, preferably produced for the surface-mounting technique, embedded in a transparent material filling. A converter substance is integrated in the filling for the at least partial wavelength conversion of the light emitted by the LED. A lens is glued onto the transparent material filling. The material filling has a convex surface and the lens has a concave underside entering into a form fit with the convex surface of the material filling.

Abstract: The invention relates to a light source device utilizing an array of discrete light sources and a display having the same and provides a small and thin light source device capable of achieving high display quality and a display having the same. A planar light guide plate is employed which has point light sources that emit light, a first light-emitting region provided in an area other than the neighborhood of one of the point light sources and having a first lighting element for taking out light guided from the side of the point light source, and a second light-emitting region provided in an area other than the neighborhood of the other point light source and having a second lighting element for taking out light guided from the side of the point light source.

Abstract: A distributed Bragg reflector comprising a stack of alternate layers of a first material and a second material wherein the first and second materials are both organic materials. An organic electroluminescent light emitting element comprising: a transparent substrate, a transparent electrode formed on the substrate, a distributed Bragg reflector formed on the transparent electrode, an organic electroluminescent light emitting material formed on the distributed Bragg reflector, and an electrode formed on the light emitting material.

Abstract: An optical filter 17 is attached to the display screen surface of a flat display panel 3 of a flat display apparatus. The optical filter 17 is constituted of a lamination of an electromagnetic-wave blocking sheet 17A, an infrared-radiation absorbing and color-tone correcting sheet 17B and an ambient light antireflective sheet 17C.

Abstract: A light-emitting tube array display device includes a light-emitting tube array constituted of a plurality of light-emitting tubes arranged in parallel with discharge gas filled therein, a light-transmitting supporter abutting the display surface side of the light-emitting tube array for supporting the light-emitting tube array and having electrodes formed on its surface facing the light-emitting tube array for applying a voltage to the light-emitting tubes, and a light-transmitting adhesive layer formed between the supporter and the light-emitting tube array. The adhesive layer has a refractive index equal to or higher than that of a tube body of the light-emitting tube and the supporter has a refractive index equal to or higher than that of the adhesive layer.

Abstract: A lamp system includes an electric lamp having an internal reflector disposed within an envelope for redirecting light emitted from a filament away from a base of the lamp and onto the filament. Utilizing the internal reflector in this manner improves the efficiency and increases the life expectancy of the lamp by reducing the electrical current required to maintain an optimum temperature of the filament for producing light. Additionally, the ability to place the lamp filament in close proximity to the base of an external reflector alters the focal point of a lamp system incorporating the lamp, thereby allowing use of external reflectors of lesser bulk and diameter without sacrificing efficiency and intensity of the light beam emitted therefrom.

Abstract: There is provided a light emitting device that is capable of changing the illumination angle in the transverse and vertical directions. An emission unit includes at least an arc tube being elongated in a longitudinal direction thereof, and a reflection umbrella. A light-permeable optical unit is arranged in front of the emission unit at a side thereof closer to a subject in such a manner that a relative distance between the optical unit and the emission unit is variable. The optical unit includes a plurality of light refracting sections provided at a central portion thereof and arranged in the longitudinal direction of the arc tube, and reflection surfaces provided at the opposite sides of the light refracting sections in the longitudinal direction thereof for reflecting luminous fluxes emitted from the emission unit toward a subject. The light distribution characteristics in transverse and vertical directions can be varied by changing the interval between the emission unit and the optical unit.

Abstract: A reflective light emitting diode (LED) has a pair of leads for supplying an electric power to an LED element. The LED element is mounted on a lower surface of one of the leads. A wire bonds the other lead and the LED element to connect them electrically. An aluminum plate is pressed to form a reflection mirror of concave shape. The reflection mirror is attached to the leads. An encapsulating resin encapsulates the leads and the reflection mirror. At the same time, a flat shape of a radiation portion is molded at a back of the LED element. The lead on which the LED element is mounted is disposed near a flat marginal portion of the reflection mirror with an insulating sheet material having a ring shape of 0.1 mm thick.

Abstract: An organic light-emitting device comprising: a back electrode; an organic light-emitting layer; a transparent electrode; a first reflective mirror; a substrate; and a second reflective mirror in this order, the second reflective mirror having R1(&thgr;=0°) of 80 to 100% and R2(&thgr;=0°) of 0 to 40%, wherein R1(&thgr;) is an average reflectance at a wavelength &lgr; being 400 nm to (&lgr;0−&Dgr;&lgr;) (where &lgr;0 is a resonance wavelength; and &Dgr;&lgr;=&lgr;max−&lgr;0, &lgr;max is a maximum wavelength that is obtained by measuring reflectance having the same value equal to R&agr; in a wavelength range about 400-700 nm, and R&agr; is an average reflectance at a wavelength range from 400 nm to (&lgr;0−100) nm) at an incidence angle &thgr;, and R2(&thgr;) is an average reflectance at a wavelength &lgr; is &lgr;0 to 700 nm at an incidence angle &thgr;.

Abstract: A coolable infrared radiator element of quartz glass with at least one heating tube, which has a gas-tight current lead-through at each of its two ends. A long, stretched-out electrical heating conductor in the heating tube serves as the radiation source. At least one cooling element is provided which has at least one cooling channel for a liquid coolant. A metal reflector is provided at least in the area of the heating conductor, which reflector has at least one reflective surface. The problem is to provide an infrared radiator which can deliver high energy concentrations of >500 kW/m2 in conjunction with low radiation losses. The problem is solved in that at least one reflective surface, when seen in cross section, describes a line around a surface, where the opening for the passage of at least some of the liquid coolant is provided in the area of this surface.

Abstract: An optical interference coating for reflecting infra-red radiation and transmitting visible light. The coating comprises alternating layers of high index of refraction material and low index of refraction material. As the total number of layers increases, the ratio of high index of refraction material to low index of refraction material must also increase.

Abstract: The invention relates to a reflector lamp which comprises a reflector body (13) with a concave reflective part; an electric lamp (15) comprising a gastight lamp vessel with at least one end portion (18), an electric element (17) arranged in the lamp vessel, and a current conductor (19) extending through the end portion to the electric element; a support body (23) comprising reflector fastening means (30, 27) for fastening the support body to the reflector body, mechanical lamp vessel fastening means (43, 46) for fastening the support body to the end portion of the lamp vessel, and housing fastening means for fastening the support body inside the housing (2).

Abstract: A bezel-less display is disclosed that includes an electronic display device and a cover. The electronic display device has an image-displaying portion and another portion adjacent the image-displaying portion along at least one side. The cover is positioned adjacent the electronic display device and includes a first portion positioned adjacent the image-displaying portion of the display device and a second portion positioned adjacent the other portion of the display device. The optical properties of the first and second portions of the cover are selected to present an appearance of a uniform cover without a bezel when the display device is not displaying an image. The optical properties of the first portion are also selected to transmit images displayed on the image-displaying portion. Preferably, the optical properties of the second portion are selected to mask the other portion of the display device.

Abstract: A full-color liquid crystal display device (TFT-LCD) installed in a monitor system for a vehicle includes a liquid crystal display (LCD), an LCD electronic control unit (ECU). The LCD has a backlight unit that includes white LEDs and red LEDs. The LCD ECU performs a display control process for selectively displaying navigation information, a tachometer image, or other information. A warning sign is displayed in a single color red in a display area of the LCD if required. The LCD ECU selects information to display and determines whether the information is a warning. If the information is a warning, the white LEDs and the red LEDs are turned on for displaying a warning sign indicative of the warning at high intensity so that the sign is easily recognized. If the information is not a warning, only the white LEDs are turned on.

Abstract: An anti-reflection film, which has a low-refractive-index layer composed of a cured coating of a copolymer that has a main chain consisting of carbon atoms and has a fluorine-containing vinyl monomer polymerizing unit and a polymerizing unit having in its side chain a (meth)acryloyl group.

Abstract: A radiating member, an illuminating device, an electro-optical device, and an electronic device are provided which are capable of absorbing the heat generated from an LED, thereby increasing the amount of electric current flowable through the LED. More particularly, there are provided a point light source, a light guide plate for receiving the light radiated from the point light source, and a radiating plate including an adhesive layer formed to contact the point light source, and a metal layer formed over the adhesive layer and made of the material having a thermal conductivity (&lgr;) equal to or greater than 90 W/mK at room temperature.