Abstract:
A development server for more easily creating an image having a quality of image matching the desire and preference of the user from image data such as RAW data from which the user cannot develop. A development server (120) comprises a RAW receiving section (122) for receiving undeveloped image data, a temporarily-developed image creating section (124) for creating temporarily-developed images by simply developing undeveloped image data by applying correction parameters corresponding to respective mutually different qualities of image, a temporarily-developed image transmitting section (125) for combining temporarily-developed images with corresponding correction parameters applied to the respective temporarily-developed images and transmitting them to a development client (110), a correction parameter receiving section (126) for receiving a correction parameter applied to one of the temporarily-developed images from the development client (110) as an instruction to develop undeveloped image data, and a digital picture developing section (127) for creating developed image data by developing the undeveloped image data by applying the correction parameter specified by the development instruction.
Abstract:
In a solar battery including: a photoelectric conversion layer that converts light into electricity; and a reflecting electrode layer that is provided on an opposite side of a light incident side in the photoelectric conversion layer and reflects light passed through the photoelectric conversion layer to the photoelectric conversion layer side, to realize a reflecting electrode layer having excellent adhesion and thermal corrosion resistance, stable electrical characteristics and satisfactory light reflection characteristics and to obtain a solar battery having high reliability, excellent electrical characteristics and optical characteristics, the reflecting electrode layer includes, on the photoelectric conversion layer side, a metal layer containing silver as a main component and containing nitrogen.
Abstract:
A duplexer includes a transmit filter connected between a common terminal and a transmission terminal, a receive filter connected between the common terminal and a reception terminal, a capacitor connected in parallel with one of the transmit filter and the receive filter and provided between two terminals of the common terminal, the transmission terminal, and the reception terminal, and a package. The package includes an insulating layer, foot pads that include the common terminal, the transmission terminal and the reception terminal and are formed on one surface of the insulating layer, and interconnections formed on another surface opposite to the one surface of the insulating layer. The capacitor is composed of two capacitor forming units that are connected in parallel with each other and are formed with at least one foot pad of the foot pads and two of the interconnections that overlap with two opposing sides of the at least one food pad respectively.
Abstract:
An elastic wave device includes resonators having a piezoelectric substrate, a resonation unit formed on the piezoelectric substrate, and reflectors formed on respective sides of the resonation unit on the piezoelectric substrate, and bumps formed on the piezoelectric substrate. The resonators are configured such that two or more split resonators are connected in parallel, and a bump is formed in a region sandwiched between reflectors of the split resonators.
Abstract:
An organic electroluminescence type display apparatus according to an aspect of the present invention includes: a thin film transistor formed on an insulating substrate; and an organic EL device connected to the thin film transistor and including at least an anode, an electroluminescence layer, and a cathode stacked on each other in this order. The anode includes: an Al alloy film having conductivity and including at least one kind of Group 8 3d transition metals, and oxygen, the at least one kind of the Group 8 3d transition metals and the oxygen being added to aluminum; and an amorphous ITO film formed on the Al alloy film.
Abstract:
Provided is an image generation device which can reduce the maximum time required until a preview image is displayed without narrowing the selection width of the image quality adjustment. The device includes an image quality parameter reduction object selection unit which selects at least one image quality adjustment content from preset image quality adjustment contents, an image quality parameter application unit which applies the image quality adjustment content selected by the image quality parameter reduction object selection unit to the given image data and performs image quality adjustment of the image data and a transmission/reception unit which transmits the image data subjected to the image quality adjustment by the image quality parameter application unit to the image display unit. When at least two of the image data subjected to the image quality adjustment by applying the image quality adjustment contents are displayed with the same or similar image quality in the image display device, the image quality parameter reduction object selection unit selects only one image quality adjustment content from the image quality adjustment contents applied to the image data.
Abstract:
A semiconductor device includes a semiconductor layer, an Al alloy film electrically connected to the semiconductor layer, and a transparent electrode layer directly contacting with the Al alloy film at least over an insulating substrate. The Al alloy film includes one or more kinds of elements selected from Fe, Co and Ni in total of 0.5 to 10 mol %, and a remaining substantially comprises Al.
Abstract:
According to an aspect of the present invention, there is provided a display apparatus including a TFT array substrate on which TFTs are formed in an array, a counter substrate disposed so as to face the TFT array substrate, and a sealing pattern for adhering the TFT array substrate and the counter substrate to each other, wherein the counter substrate comprises a counter electrode, and the TFT array substrate comprises a first conductive layer, a first insulating film formed on the first conductive layer, a second conductive layer disposed so as to intersect the first conductive layer via the first insulating film, a second insulating film formed on the second conductive layer and having at least two layers, and common electrode wiring provided below the sealing pattern and electrically connected to the counter electrode by the sealing pattern, and the sealing pattern overlaps the second conductive layer via the second insulating film.
Abstract:
A plasma display panel in which projections are formed in grooves between partitions and phosphor layers are provided on the projections so as to increase the area where phosphor adheres and thereby to increase the luminance. A couple of substrates are opposed to each other to form a discharge space. Band-like partitions partitioning the discharge space are arranged on the back or front substrate. Wall-like projections lower than the partitions and high enough to increase the area where phosphor layers are formed are provided in the region where the discharge space is formed in the long grooves between the partitions or around the discharge space. Phosphor layers are formed in the grooves between the partitions including the wall-like projections. A method for producing such a plasma display panel is also disclosed.
Abstract:
A development server for more easily creating an image having a quality of image matching the desire and preference of the user from image data such as RAW data from which the user cannot develop. A development server (120) comprises a RAW receiving section (122) for receiving undeveloped image data, a temporarily-developed image creating section (124) for creating temporarily-developed images by simply developing undeveloped image data by applying correction parameters corresponding to respective mutually different qualities of image, a temporarily-developed image transmitting section (125) for combining temporarily-developed images with corresponding correction parameters applied to the respective temporarily-developed images and transmitting them to a development client (110), a correction parameter receiving section (126) for receiving a correction parameter applied to one of the temporarily-developed images from the development client (110) as an instruction to develop undeveloped image data, and a digital picture developing section (127) for creating developed image data by developing the undeveloped image data by applying the correction parameter specified by the development instruction.