Patent application number | Description | Published |
20090245664 | IMAGE ENCODING DEVICE - The present invention provides an image encoding device which does not necessitate reference of a quantization parameter between consecutive macroblocks across a parallel processing area boundary without forming slices. The image encoding device encodes a macroblock of an encoding target image by parallel processing sequentially from the top of a parallel processing area, and possesses an encoding element for every parallel processing area. When all the quantized orthogonally-transformed coefficients of a top macroblock of the parallel processing area are zero, the encoding element adds a non-zero coefficient to a part of the coefficients, making the coefficients non-zero. Accordingly, generation of a skip macroblock in the top macroblock of each parallel processing area is suppressed. Since slice formation is not necessary, the prediction over a parallel processing area boundary is applied, and encoding efficiency improves. Errors are not generated in decoding and the decoded image quality does not deteriorate. | 10-01-2009 |
20110305255 | SEMICONDUCTOR OPTICAL INTEGRATED ELEMENT AND METHOD FOR MANUFACTURING THE SAME - A semiconductor optical integrated element includes: a substrate; and a laser diode and a modulator which are integrated on the substrate. The laser diode includes an embedded waveguide having a core layer, both sides of which are embedded in a semiconductor material. The modulator includes a high-mesa ridge waveguide having a core layer, neither side of which is embedded in the semiconductor material. The core layers in the laser diode and the modulator are stripe-shaped. | 12-15-2011 |
20120087614 | OPTICAL MODULATOR - An optical modulator includes: a semiconductor chip; a waveguide in the semiconductor chip; a traveling wave electrode including an input portion and an output portion, to which a signal is applied for modulating light passing through the waveguide; a power supply line connected to the input portion via a first wire; and a termination resistor connected to the output portion via a second wire. Capacitance between the output portion and a grounding point is larger than capacitance between the input portion and the grounding point. | 04-12-2012 |
20130122623 | METHOD OF MANUFACTURING OPTICAL SEMICONDUCTOR DEVICE - A method of manufacturing an optical semiconductor device includes: forming first and second optical semiconductor elements separated from each other by a separation groove on a semiconductor substrate; forming first and second electrodes containing Pt on top surfaces of the first and second optical semiconductor elements, respectively; forming a third electrode electrically connected to the first and second electrodes and preventing the third electrode from being formed in the separation groove; forming first and second Au plated layers on the first and second electrodes, respectively, by electrolytic plating, using the third electrode as a power supply layer; forming a resist covering the first and second Au plated layers by photolithography; and etching the third electrode, using the resist as a mask, to electrically separate the first electrode from the second electrode. | 05-16-2013 |
20130208350 | OPTICAL SEMICONDUCTOR DEVICE - An optical semiconductor device includes: semiconductor lasers; a wave coupling section multiplexing light output by the semiconductor lasers; an optical amplifying section amplifying output light of the wave coupling section; a first optical waveguide optically connecting respective semiconductor lasers to the wave coupling section; a second optical waveguide optically connecting the wave coupling section to the optical amplifying section; a third optical waveguide optically connected to an output of the optical amplifying section; and a phase regulator located in at least one of the first, second, and third optical waveguides, and regulating phase of reflected light that is reflected at a reflecting point in the optical semiconductor device and that returns to the semiconductor lasers. The phase regulator adjusts the phase of the reflected light to decrease line width of the light output by the semiconductor lasers. | 08-15-2013 |
20140056556 | OPTICAL SEMICONDUCTOR DEVICE - An optical semiconductor device includes: semiconductor lasers separated into two groups; an optical coupler combining light output from the semiconductor lasers; an optical amplifier amplifying light output from the optical coupler; and waveguides respectively connecting the semiconductor lasers to the optical coupler. Each of the waveguides includes a respective bent waveguide. The bent waveguides have the same radius of curvature. | 02-27-2014 |
20140198378 | OPTICAL SEMICONDUCTOR DEVICE - An optical semiconductor device includes: semiconductor lasers; a wave coupling section multiplexing light output by the semiconductor lasers; first optical waveguides respectively optically connecting respective semiconductor lasers to the wave coupling section; a phase regulator regulating phase of reflected light that is reflected at a reflecting point located in the optical semiconductor device and that returns to the semiconductor lasers; a second optical waveguide optically connecting the wave coupling section to the phase regulator; an optical amplifying section amplifying output light of the phase regulator; and a third optical waveguide optically connecting an output of the phase regulator to the optical amplifying section. The phase regulator adjusts the phase of reflected light that returns to the semiconductor lasers to decrease line width of the light output by the semiconductor lasers. | 07-17-2014 |