Abstract: A light-emitting apparatus composed of a light source that emits primary light and a phosphor that absorbs the primary light and emits secondary light offers high brightness, low power consumption, and a long lifetime while minimizing adverse effects on the environment. The phosphor is formed of a III-V group semiconductor in the form of fine-particle crystals each having a volume of 2 800 nm3 or less. The light emitted from the fine-particle crystals depends on their volume, and therefore giving the fine-particle crystals a predetermined volume distribution makes it possible to adjust the wavelength range of the secondary light.

Abstract: The present invention is achieved with the object of providing an illumination system formed of an LED light emitting body and a socket which can appropriately release heat from LED chips. This object is achieved in the following manner. A heat conducting layer 12 made of diamond is provided on a substrate 11, and on top of this, a conductive layer 13 having a predetermined pattern is formed. LED chips 16 are mounted in predetermined positions on the conductive layer 13. Terminals of the conductive layer 13 and electrodes of the LED chips 16 are connected to each other. A connector part 14 for the connection to a socket is provided in an end portion of the substrate 11. The heat conducting layer 12 on the connector part 14 makes thermal contact with the heat conducting layer provided on the inner surface of the opening of the socket. A current is supplied to respective LED chips 16 through the conductive layer 13 from the socket, and respective LED chips 16 emit light.

Abstract: The invention provides a nitride semiconductor light-emitting device comprising gallium nitride semiconductor layers formed on a heterogeneous substrate, wherein light emissions having different light emission wavelengths or different colors are given out of the same active layer. Recesses 106 are formed by etching in the first electrically conductive (n) type semiconductor layer 102 formed on a substrate with a buffer layer interposed between them. Each recess is exposed in plane orientations different from that of the major C plane. For instance, the plane orientation of the A plane is exposed. An active layer is grown and joined on the plane of this plane orientation, on the bottom of the recess and the C-plane upper surface of a non-recess portion. The second electrically conductive (p) type semiconductor layer is formed on the inner surface of the recess.

Abstract: In a method of producing bread which includes the steps of mixing separate leaven or yeast into bread dough, fermenting the dough, dividing and forming the dough, fermenting the dough again, and baking the thus fermented dough, the baking step includes at least one baking stage and at least in the final stage of baking, the dough is baked using superheated steam. The dough may be first baked partially, and after storing at room temperature or freezing, the dough may be completely baked. There is also provided a method of producing raisin yeast bread which includes the steps of fermenting water extracts of raisins and flour, further fermenting the mixture for 10 to 20 days while adding flour and water to obtain ripe raisin leaven, mixing the ripe leaven into separate leaven or bread dough, fermenting the mixture, dividing and forming the mixture, fermenting the thus divided and formed dough first at 20-25° C. for 0.5 to 2 hours, then at a low temperature of 2-10° C. for 7 to 22 hours, and finally at 20-25° C.

Abstract: A light-emitting apparatus composed of a light source that emits primary light and a phosphor that absorbs the primary light and emits secondary light offers high brightness, low power consumption, and a long lifetime while minimizing adverse effects on the environment. The phosphor is formed of a III-V group semiconductor in the form of fine-particle crystals each having a volume of 2 800 nm3 or less. The light emitted from the fine-particle crystals depends on their volume, and therefore giving the fine-particle crystals a predetermined volume distribution makes it possible to adjust the wavelength range of the secondary light.

Abstract: A fluorescent material excellent in emission efficiency in white emission and a light-emitting apparatus employing this fluorescent material and having excellent color rendering are provided with a fluorescent material comprising a two-layer structure of a core of a particle size having a quantum effect and a shell covering this core in which the ground state energy of the core is in the range of 1.85 to 2.05 eV, the high order energy of the core is not in the ranges of 2.3 to 2.5 eV and 2.65 to 2.8 eV, or the ground state energy of the core is in the range of 2.3 to 2.5 eV, the high order energy of the core is not in the range of 2.65 to 2.8 eV an light-emitting apparatus employing these fluorescent materials.

Abstract: A light-emitting apparatus composed of a light source that emits primary light and a phosphor that absorbs the primary light and emits secondary light offers high brightness, low power consumption, and a long lifetime while minimizing adverse effects on the environment. The phosphor is formed of a III–V group semiconductor in the form of fine-particle crystals each having a volume of 2 800 nm3 or less. The light emitted from the fine-particle crystals depends on their volume, and therefore giving the fine-particle crystals a predetermined volume distribution makes it possible to adjust the wavelength range of the secondary light.

Abstract: The present invention is achieved with the object of providing an illumination system formed of an LED light emitting body and a socket which can appropriately release heat from LED chips. This object is achieved in the following manner. A heat conducting layer 12 made of diamond is provided on a substrate 11, and on top of this, a conductive layer 13 having a predetermined pattern is formed. LED chips 16 are mounted in predetermined positions on the conductive layer 13. Terminals of the conductive layer 13 and electrodes of the LED chips 16 are connected to each other. A connector part 14 for the connection to a socket is provided in an end portion of the substrate 11. The heat conducting layer 12 on the connector part 14 makes thermal contact with the heat conducting layer provided on the inner surface of the opening of the socket. A current is supplied to respective LED chips 16 through the conductive layer 13 from the socket, and respective LED chips 16 emit light.

Abstract: The present invention provides a lighting apparatus which improves identification of living body tissues, and is suitable for medical lighting. In the lighting apparatus, the light output in a range of wavelength 525 to 590 nm is not greater than ? of the light output in a range of wavelength 380 to 780 nm corresponding to visible light components. The peak wavelength of a blue or bluish green light component included in the output light is in a range 430 to 520 nm, and the peak wavelength of a red light component is not less than 600 nm. A green light component has the peak in a range of wavelength 520 to 590 nm, its spectral half-value width is not greater than 70 nm, and the light amount of at least the green light component can be independently adjusted.

Abstract: The invention provides a nitride semiconductor light-emitting device comprising gallium nitride semiconductor layers formed on a heterogeneous substrate, wherein light emissions having different light emission wavelengths or different colors are given out of the same active layer. Recesses 106 are formed by etching in the first electrically conductive (n) type semiconductor layer 102 formed on a substrate with a buffer layer interposed between them. Each recess is exposed in plane orientations different from that of the major C plane. For instance, the plane orientation of the A plane is exposed. An active layer is grown and joined on the plane of this plane orientation, on the bottom of the recess and the C-plane upper surface of a non-recess portion. The second electrically conductive (p) type semiconductor layer is formed on the inner surface of the recess.

Abstract: The luminous efficiency of a nitride semiconductor device comprising a gallium nitride-based semiconductor layer formed on a dissimilar substrate is improved. An n-type layer formed on the substrate with a buffer layer interposed between them comprises a portion of recess-and-projection shape in section as viewed in the longitudinal direction. Active layers are formed on at least two side faces of the projection with the recess located between them. A p-type layer is formed within the recess. An insulating layer is formed on the top face of the projection, and on the bottom face of the recess. The n-type layer is provided with an n-electrode while the p-type layer is provided with a p-electrode contact layer. As viewed from the p-type layer formed within the recess in the gallium nitride-based semiconductor layer, the active layer and the n-type layer are located in an opposite relation to each other.

Abstract: According to the present invention, first, a white LED with high color rendering property is realized. In addition, a general object of the present invention is to provide a highly practical light emitting device wherein a rare earth complex is utilized as a wavelength conversion light emitting device of a high efficiency. Such an object is achieved by providing a combined light emitting device wherein a specific complex having a rare earth ion, particularly an Eu (europium) ion, as the central ion, is borne by a transparent solid matrix such as polymer or plastic, and this rare earth complex is excited by an InGaN based blue light emitting diode or by a semiconductor laser utilizing a light emitting layer of InGaN based material. A combination of such a blue light emitting diode, a YAG yellow fluorescent material and such an Eu complex for red light allows for the formation of a white light source with high color rendering property.

Abstract: The luminous efficiency of a nitride semiconductor device comprising a gallium nitride-based semiconductor layer formed on a dissimilar substrate is improved. An n-type layer formed on the substrate with a buffer layer interposed between them comprises a portion of recess-and-projection shape in section as viewed in the longitudinal direction. Active layers are formed on at least two side faces of the projection with the recess located between them. A p-type layer is formed within the recess. An insulating layer is formed on the top face of the projection, and on the bottom face of the recess. The n-type layer is provided with an n-electrode while the p-type layer is provided with a p-electrode contact layer. As viewed from the p-type layer formed within the recess in the gallium nitride-based semiconductor layer, the active layer and the n-type layer are located in an opposite relation to each other.

Abstract: A light-emitting apparatus composed of a light source that emits primary light and a phosphor that absorbs the primary light and emits secondary light offers high brightness, low power consumption, and a long lifetime while minimizing adverse effects on the environment. The phosphor is formed of a III-V group semiconductor in the form of fine-particle crystals each having a volume of 2 800 nm3 or less. The light emitted from the fine-particle crystals depends on their volume, and therefore giving the fine-particle crystals a predetermined volume distribution makes it possible to adjust the wavelength range of the secondary light.

Abstract: Liquid crystal is filled between a pair of transparent plate electrodes, and a DC voltage is applied between the electrodes to align the liquid crystal molecules along the electric field. When light enters the liquid crystal cell, the alignment of the liquid crystal molecules deviates due to the electric field of the light. The change in the alignment of the liquid crystal molecules is detected by a change in the capacitance or in the electric resistance between the plate electrodes. A liquid crystal panel 35 constituted by a two-dimensional array of such liquid crystal cells is used as an image sensor, and the interference patterns of an object 38 are produced on and detected by the liquid crystal pattern 35 in real time. The detected interference patterns are recorded continuously, whereby a three-dimensional movie is recorded.

Abstract: A gazing point illuminating device is provided with: a light source; a direction changing mechanism for changing the lighting direction of the light source; a gazing direction detector for detecting the direction of the user's gazing line; and a controller for changing the lighting direction corresponding to the detected gazing direction. When, LEDs are used as the light source, and the light source is attached to the goggles worn by a user, the goggles can be useful gazing point illuminating device by themselves even if they do not include gazing point or direction detectors, because a person normally look straight ahead except for unusual occasions where he/she purposefully avert his/her gaze. Thus, an illuminating device fixed to a person's head for lighting forward is a gazing point illuminating device. It is preferred to provide an LED panel at the left and right ends of goggles.

Abstract: Liquid crystal is filled between a pair of transparent plate electrodes, and a DC voltage is applied between the electrodes to align the liquid crystal molecules along the electric field. When light enters the liquid crystal cell, the alignment of the liquid crystal molecules deviates due to the electric field of the light. The change in the alignment of the liquid crystal molecules is detected by a change in the capacitance or in the electric resistance between the plate electrodes. A liquid crystal panel 35 constituted by a two-dimensional array of such liquid crystal cells is used as an image sensor, and the interference patterns of an object 38 are produced on and detected by the liquid crystal pattern 35 in real time. The detected interference patterns are recorded continuously, whereby a three-dimensional movie is recorded.

Abstract: A gazing point illuminating device is provided with: a light source; a direction changing mechanism for changing the lighting direction of the light source; a gazing direction detector for detecting the direction of the user's gazing line; and a controller for changing the lighting direction corresponding to the detected gazing direction. When, LEDs are used as the light source, and the light source is attached to the goggles worn by a user, the goggles can be useful gazing point illuminating device by themselves even if they do not include gazing point or direction detectors, because a person normally look straight ahead except for unusual occasions where he/she purposefully avert his/her gaze. Thus, an illuminating device fixed to a person's head for lighting forward is a gazing point illuminating device. It is preferred to provide an LED panel at the left and right ends of goggles.