Abstract: A crystal foundation having dislocations is used to obtain a crystal film of low dislocation density, a crystal substrate, and a semiconductor device. One side of a growth substrate (11) is provided with a crystal layer (13) with a buffer layer (12) in between. The crystal layer (13) has spaces (13a), (13b) in an end of each threading dislocation D1 elongating from below. The threading dislocation D1 is separated from the upper layer by the spaces (13a), (13b), so that each threading dislocation D1 is blocked from propagating to the upper layer. When the displacement of the threading dislocation D1 expressed by Burgers vector is preserved to develop another dislocation, the spaces (13a), (13b) vary the direction of its displacement. As a result, the upper layer above the spaces (13a), (13b) turns crystalline with a low dislocation density.

Abstract: A GaN-based semiconductor light-emitting element capable of suppressing the occurrence of piezoelectric spontaneous polarization in the thickness direction of an active layer and reducing the driving voltage of a light-emitting diode is provided. The GaN-based semiconductor light-emitting element has a structure with a first GaN-based compound semiconductor layer 21 having the top face parallel to the a-plane and having a first conductivity type, an active layer 22 having the top face parallel to the a-plane, a second GaN-based compound semiconductor layer 23 having the top face parallel to the a-plane and having a second conductivity type, and a contact layer 24 composed of a GaN-based compound semiconductor and having the top face parallel to the a-plane, stacked in that order. The GaN-based semiconductor light-emitting element further includes a first electrode 25 disposed on the first GaN-based compound semiconductor layer 21 and a second electrode 26 disposed on the contact layer 24.

Abstract: An image forming apparatus includes a storage section which stores image data for each page, an identification information generating section which generates identification information for identifying the type of the image data for each page, an engine image processor section has a plurality of processor sections for processing the image data to form an image, and a selector section which selects and outputs image data corresponding to the identification information, out of the image data processed by means of the processor section. The apparatus further includes an engine section which forms the image in accordance with the outputted image data.

Abstract: A GaN-based semiconductor light-emitting device includes (A) a first GaN-based compound semiconductor layer 13 having n-type conductivity, (B) an active layer 15 having a multi-quantum well structure including well layers and barrier layers for separating between the well layers, and (C) a second GaN-based compound semiconductor layer 17 having p-type conductivity. The well layers are disposed in the active layer 15 so as to satisfy the relation d1<d2 wherein d1 is the well layer density on the first GaN-based compound semiconductor layer side in the active layer and d2 is the well layer density on the second GaN-based compound semiconductor layer side.

Abstract: An image forming apparatus according to the invention is characterized by including; an input unit that inputs first color data; a first color converting unit that converts the first color data into a black single color data; a second color converting unit that converts the first color data into second color data; a brightness correcting unit that corrects brightness of the black single color data such that brightness of the black single color data converted by the first color converting unit is equal to brightness of the second color data converted by the second color converting unit; and an image forming unit that prints image data on a recording medium. According to the image forming apparatus, in the image forming apparatus that uses both color conversion processing and black conversion processing, even if image data continuously changes from a chromatic color to an achromatic color, it is possible to reduce “brightness discontinuity”.

Abstract: An image forming apparatus according to the invention is characterized by including: a first input unit that inputs image data having attribute information and color information; a second input unit that inputs designated attribute information and designated color information designated by a user; a limited image generating unit that generates, when attribute information of a certain area in the image data and the designated attribute information coincide with each other and color information of the area and the designated color information coincide with each other, limited image data for limiting printing of the area from the image data; and an image recording unit that prints the limited image data. According to the image forming apparatus, it is possible to easily limit printing of a specific image designated in document data without changing the document data itself.

Abstract: An image forming apparatus has a collating section which collates image information from a scanner with a specific image and determines whether or not there is a same portion, and a line delay section which outputs the image information after delaying the image information in accordance with time spent on collation processing. Because a dedicated memory is unnecessary due to timing between processing of the collation processing section and other processings being coordinated at the line delay section, a large reduction in costs can be realized.

Abstract: A technology that contributes to improvement of visibility of an image containing an achromatic color is provided. A color space information acquiring unit for acquiring color space information of a pixel contained in image data; a saturation determination unit for determining the saturation of the pixel whose color space information is acquired on the basis of the color space information acquired by the color space information acquiring unit; and a color space information conversion unit for converting the color space information of the pixel whose saturation is determined not to exceed a predetermined threshold by the saturation determination unit out of the pixels contained in the image data into the color space information to be printed with black toner by a predetermined image forming apparatus are provided.

Abstract: A semiconductor light emitting element, manufacturing method thereof, integrated semiconductor light emitting device, manufacturing method thereof, illuminating device, and manufacturing method thereof are provided. An n-type GaN layer is grown on a sapphire substrate, and a growth mask of SiN, for example, is formed thereon. On the n-type GaN layer exposed through an opening in the growth mask, a six-sided steeple-shaped n-type GaN layer is selectively grown, which has inclined crystal planes each composed of a plurality of crystal planes inclined from the major surface of the sapphire substrate by different angles of inclination to exhibit a convex plane as a whole. On the n-type GaN layer, an active layer and a p-type GaN layer are grown to make a light emitting element structure. Thereafter, a p-side electrode and an n-side electrode are formed.

Abstract: A semiconductor light emitting element, manufacturing method. thereof, integrated semiconductor light emitting device, manufacturing method thereof, illuminating device, and manufacturing method thereof are provided. An n-type GaN layer is grown on a sapphire substrate, and a growth mask of SiN, for example, is formed thereon. On the n-type GaN layer exposed through an opening in the growth mask, a six-sided steeple-shaped n-type GaN layer is selectively grown, which has inclined crystal planes each composed of a plurality of crystal planes inclined from the major surface of the sapphire substrate by different angles of inclination to exhibit a convex plane as a whole. On the n-type GaN layer, an active layer and a p-type GaN layer are grown to make a light emitting element structure. Thereafter, a p-side electrode and an n-side electrode are formed.

Abstract: A semiconductor light emitting element, manufacturing method thereof, integrated semiconductor light emitting device, manufacturing method thereof, illuminating device, and manufacturing method thereof are provided. An n-type GaN layer is grown on a sapphire substrate, and a growth mask of SiN, for example, is formed thereon. On the n-type GaN layer exposed through an opening in the growth mask, a six-sided steeple-shaped n-type GaN layer is selectively grown, which has inclined crystal planes each composed of a plurality of crystal planes inclined from the major surface of the sapphire substrate by different angles of inclination to exhibit a convex plane as a whole. On the n-type GaN layer, an active layer and a p-type GaN layer are grown to make a light emitting element structure. Thereafter, a p-side electrode and an n-side electrode are formed.

Abstract: A GaN semiconductor light-emitting element is provided. The GaN semiconductor light-emitting element includes an island-type seed region composed of a GaN-based compound semiconductor disposed on a substrate; an underlying layer having a three-dimensional shape composed of a GaN-based compound semiconductor, disposed on at least the seed region; a first GaN-based compound semiconductor layer of a first conductivity type, an active layer composed of a GaN-based compound semiconductor, and a second GaN-based compound semiconductor layer of a second conductivity type disposed in that order on the underlying layer; a first electrode electrically connected to the first GaN-based compound semiconductor layer; and a second electrode disposed on the second GaN-based compound semiconductor layer. The top face of the seed region is the A plane, and at least one side face of the underlying layer is the S plane.

Abstract: A method for forming an underlayer composed of a GaN-based compound semiconductor is provided. In this method, at the time of epitaxial growth of an underlayer on the surface of a sapphire substrate, no gap is generated between the underlayer and the surface of the sapphire substrate. The method for forming an underlayer composed of a GaN-based compound semiconductor includes the steps of forming strip seed layers composed of a GaN-based compound semiconductor on the surface of a sapphire substrate, forming a crystal growth promoting layer composed of a GaN-based compound semiconductor on the top surfaces and both the side surfaces of the seed layers, and on the exposed surfaces of the sapphire substrate, and epitaxially growing an underlayer composed of a GaN-based compound semiconductor from the parts of the crystal growth promoting layer.

Abstract: An n-type GaN layer is grown onto a sapphire substrate and a hexagonal etching mask is formed onto the n-type GaN layer as provided. The n-type GaN layer is etched to a predetermined depth by using the etching mask by the RIE method. A hexagonal prism portion whose upper surface is a C plane is formed. After the etching mask was removed, an active layer and a p-type GaN layer are sequentially grown onto the whole surface of the substrate so as to cover the hexagonal prism portion, thereby forming a light emitting device structure. After that, a p-side electrode is formed onto the p-type GaN layer of the hexagonal prism portion and an n-side electrode is formed onto the n-type GaN layer.

Abstract: A system and method for processing image data generates color image data from a scanned image, the color image data including RGB data, converts the RGB data to CMY data, and translates the CMY data for the pixel to CMYK data. A weighting coefficient is set for a pixel based on the values of the CMY data for the pixel. A particular region in which the pixel is located is identified as a black color region or a non-black color region. The value of the K data for the pixel is altered based on the weighting coefficient if the particular region is a non-black color region.

Abstract: A crystal foundation having dislocations is used to obtain a crystal film of low dislocation density, a crystal substrate, and a semiconductor device. One side of a growth substrate (11) is provided with a crystal layer (13) with a buffer layer (12) in between. The crystal layer (13) has spaces (13a), (13b) in an end of each threading dislocation D1 elongating from below. The threading dislocation D1 is separated from the upper layer by the spaces (13a), (13b), so that each threading dislocation D1 is blocked from propagating to the upper layer. When the displacement of the threading dislocation D1 expressed by Burgers vector is preserved to develop another dislocation, the spaces (13a), (13b) vary the direction of its displacement. As a result, the upper layer above the spaces (13a), (13b) turns crystalline with a low dislocation density.

Abstract: Nitride semiconductor devices and methods of producing same are provided. The present invention includes forming a nitride semiconductor layer on a base body of the nitride semiconductor under selective and controlled crystal growth conditions. For example, the crystal growth rate, the supply of crystal growth source material and/or the crystal growth area can be varied over time, thus resulting in a nitride semiconductor device with enhanced properties.

Abstract: Semiconductor light-emitting devices are provided. The semiconductor light-emitting devices include a substrate and a crystal layer selectively grown thereon at least a portion of the crystal layer is oriented along a plane that slants to or diagonally intersect a principal plane of orientation associated with the substrate thereby for example, enhancing crystal properties, preventing threading dislocations, and facilitating device miniaturization and separation during manufacturing and use thereof.

Abstract: A semiconductor light-emitting device is provided. The semiconductor light-emitting device includes: a substrate having a substrate surface oriented along a substrate surface plane; a first grown layer including a first grown layer conductivity type formed on the substrate; a masking layer formed on the first grown layer; a second grown layer of a second grown layer conductivity type formed by selective growth through an opening in the masking layer and including a crystal surface oriented along a crystal surface plane; a first cladding layer including a first cladding layer conductivity type formed along at least a portion of the crystal surface plane; an active layer; and a second cladding layer including a second cladding layer conductivity type. At least one of the first cladding layer, the active layer, and the second cladding layer cover the masking layer surrounding the opening.

Abstract: An n-type GaN layer is grown onto a sapphire substrate and a hexagonal etching mask is formed onto the n-type GaN layer as provided. The n-type GaN layer is etched to a predetermined depth by using the etching mask by the RIE method. A hexagonal prism portion whose upper surface is a C plane is formed. After the etching mask was removed, an active layer and a p-type GaN layer are sequentially grown onto the whole surface of the substrate so as to cover the hexagonal prism portion, thereby forming a light emitting device structure. After that, a p-side electrode is formed onto the p-type GaN layer of the hexagonal prism portion and an n-side electrode is formed onto the n-type GaN layer.