Patent application number | Description | Published |
20100309368 | WAFER-LEVEL LENS MODULE AND IMAGE PICKUP MODULE INCLUDING THE SAME - Provided are a wafer-level lens module and an image pickup module including the same. The wafer lens module includes a plurality wafer-scale lenses. At least one of the plurality of wafer-scale lenses, such as a wafer-scale lens positioned toward an object side, includes a substrate and a glass lens element formed on one side of the substrate. The glass lens element may be a one-sided lens or a double-sided lens. When the glass lens is a double-sided lens, the substrate may have a through hole. The remaining wafer-scale lenses each include a substrate and polymer lens elements made of UV curable polymer and formed on both sides of the substrate. Also, spacers are interposed between the wafer-scale lenses, along the edge portions of the substrates, so as to maintain predetermined intervals between the wafer-scale lenses. | 12-09-2010 |
20110037887 | WAFER-LEVEL LENS MODULE AND IMAGE PICKUP DEVICE INCLUDING THE SAME - Disclosed are a wafer-level lens module including a plurality of wafer-scale lenses that are stacked and an image pickup device including the wafer-level lens module and an image sensor. Each wafer-scale lens includes a substrate with a light-transmission part, and a lens element fixed on one side or both sides of the substrate. The lens element includes an optical zone, corresponding to the light-transmission part of the substrate, and an extended zone disposed outside the optical zone. A trench or protrusion is formed as an alignment guide on one or both sides of the substrate, adjacent to the light-transmission part, and a protrusion or trench, aligned with the trench or protrusion, is formed in the extended zone of the lens element. The lens element is aligned on the substrate such that an inclined portion of the protrusion contacts corners of the trench. | 02-17-2011 |
20120002096 | IMAGING DEVICE INCLUDING A PLURALITY OF IMAGING UNITS - An imaging device with a plurality of imaging units is provided. The imaging device includes a supporting substrate, a flexible substrate and a movable unit. The supporting substrate is formed with a hard material, and the flexible substrate includes a plurality of imaging units positioned at least in a width direction. The flexible substrate is fixed at a first edge portion with the supporting substrate, while an opposite second edge portion of the flexible substrate is connected with the movable unit. The movable unit moves the opposite second edge portion of the flexible substrate in the width direction and bends or flattens the flexible substrate. A degree of curvature at which the flexible substrate is bent may vary based on a distance by which the movable unit moves in the width direction, so that a field of view (FOV) of the plurality of imaging units may be adjusted. | 01-05-2012 |
20120007815 | MULTIPURPOSE SENSING APPARATUS AND ELECTRONIC EQUIPMENT HAVING THE SAME - A multipurpose sensing apparatus and electronic equipment are provided. The sensing apparatus includes planar type compound eyes, each planar type compound eye including ommatidium arranged in a circular arc such that each ommatidium views a contact surface; three-dimensional (3D) compound eyes, each 3D compound eye including ommatidium arranged in an array such that each ommatidium views an area in front of the contact surface; and an image signal processor that is configured to determine a touch position on the contact surface based on image signals transmitted from the planar type compound eyes, and to recognize a motion of an object existing in front of the contact surface based on image signals transmitted from the 3D compound eyes. | 01-12-2012 |
20120081795 | FLUIDIC LENS - A vari-focal fluidic lens is provided. The fluidic lens includes a frame, an first membrane, a second membrane, and an optical fluid. The frame defines an inner space of the fluidic lens including a driving portion and a lens portion that are connected to each other. The elastic membrane is attached to one side of the frame to cover at least the lens portion. The second membrane is attached to an opposite side of the frame to cover at least the driving portion and is deformable in response to temperature change to vary a volume of the inner space. Optical fluid is contained in the inner space. | 04-05-2012 |
20120114961 | BULK NANOCOMPOSITE THERMOELECTRIC MATERIAL, NANOCOMPOSITE THERMOELECTRIC MATERIAL, AND METHOD OF PREPARING THE BULK NANOCOMPOSITE THERMOELECTRIC MATERIAL - A bulk nanocomposite thermoelectric material including: a plurality of grains of a thermoelectric material; and a metal nanolayer on a boundary of the plurality of grains, wherein the metal nanolayer is crystalline, and a glass transition temperature and a crystallization temperature of the nanometal are lower than a melting point of the thermoelectric material. | 05-10-2012 |
20120170094 | SCANNING LENS APPARATUS ADOPTING BIMORPH ACTUATOR - A scanning lens apparatus with a bimorph actuator is provided. The scanning lens apparatus includes: a housing having a hollow cylindrical shape; a first suspension and a second suspension which are parallel to each other, and a first end of each of the first suspension and the second suspension is fixed on an inner surface of the housing; first bimorphs disposed on first surfaces of the first and second suspensions and second bimorphs disposed on second surfaces facing the first surfaces of the first and second suspensions; a first lens which is fixed between a second end of the first suspension and a second end of the second suspension; a second lens fixed parallel to the first lens between the first and second suspensions; and an object lens disposed on an end of the housing to face the second lens with respect to the first lens. | 07-05-2012 |
20130038944 | DEVICE AND METHOD FOR CONTROLLING CURVATURE OF LENS SURFACE - A curvature control device includes a first fluid that has a light transmitting property and a polar property; a second fluid that has a light transmitting property; a chamber that the first fluid and the second fluid are accommodated without being mixed with each other, wherein a boundary surface between the first fluid and the second fluid comprises a first surface that is a lens surface and a second surface that induces a change in a curvature of the first surface; a first intermediate plate that is disposed in the chamber, and includes a first through-hole that forms a diameter of a lens corresponding to the first surface and a second through-hole that forms a path of the second fluid; and an electrode portion configured to generate an electric field that changes a position of the second surface. | 02-14-2013 |
20130077178 | DEVICE AND MEHTOD FOR CONTROLLING CURVATURE - A curvature control device includes: a first fluid having a light transmitting property and a polarity; a second fluid that has a light transmitting property and is not mixed with the first fluid; a chamber forming an inner space for containing the first fluid F | 03-28-2013 |
20130118572 | CONDUCTIVE PASTE AND ELECTRONIC DEVICE AND SOLAR CELL INCLUDING AN ELECTRODE FORMED USING THE CONDUCTIVE PASTE - A conductive paste includes a conductive powder, a metallic glass having a glass transition temperature of less than or equal to about 600° C. and a supercooled liquid region of greater than or equal to 0 K, and an organic vehicle, and an electronic device and a solar cell include an electrode formed using the conductive paste. | 05-16-2013 |
20130306480 | MICROFLUIDIC DEVICE AND METHOD OF CONTROLLING FLUID IN THE SAME - A microfluidic device and a method of controlling a fluid included in the microfluidic device. The microfluidic device includes: a chamber; a first fluid that is disposed in the chamber and in which a hygroscopic material is dissolved; a second fluid that is disposed in the chamber and is immiscible with the first fluid; and an electrode portion provide in the chamber and is configured to form an electrical field in the chamber when a voltage is applied to the electrode portion, wherein an interface between the first and second fluids is varied according to the electrical field. | 11-21-2013 |
20130333920 | METALLIC GLASS, ARTICLE, AND CONDUCTIVE PASTE - Disclosed are a metallic glass including an amorphous alloy part including a plurality of elements; and an amorphous oxide in a supercooled liquid region, an article including a sintered product of the metallic glass, and a conductive paste including the metallic glass. | 12-19-2013 |
20130340815 | ELECTRODE AND METHOD OF FORMING THE SAME AND ELECTRONIC DEVICE INCLUDING THE SAME - An electrode including a first layer having a sintered product of a metallic glass and a first conductive material, and a second layer including a second conductive material plated using the first layer as a seed layer, a method of manufacturing the same, and an electronic device including the electrode. | 12-26-2013 |
20140000694 | Conductive Paste And Electronic Device And Solar Cell | 01-02-2014 |
20140016253 | SEALING MATERIAL, DISPLAY DEVICE, AND METHOD OF MANUFACTURING THE DISPLAY DEVICE - A sealing material includes a metallic glass | 01-16-2014 |
20140023821 | MAGNETIC COMPOSITE AND METHOD OF MANUFACTURING THE SAME, AND ARTICLE AND DEVICE INCLUDING THE SAME - A magnetic composite including a magnetic material; and a binder including a metallic glass, a glass frit, or a combination thereof. | 01-23-2014 |
20140070148 | CONDUCTIVE POWDER, ARTICLE, AND CONDUCTIVE PASTE - According to example embodiments, a conductive powder includes a metallic glass and a coating on the surface of the metallic glass. The coating includes a metal. An article may include a sintered product of the conductive powder. A conductive paste may include the conductive powder. An electronic device may include a sintered product of the conductive paste. | 03-13-2014 |
20140092388 | OPTICAL ZOOM PROBE - An optical zoom probe is provided. The optical zoom probe includes: an aperture adjuster which adjusts an aperture through which light which is transmitted by a light transmitter propagates; and a focus adjuster which focuses light that propagates through the aperture and which includes first and second liquid lenses for each of which respective curvatures are independently controlled so as to adjust a respective focal length. | 04-03-2014 |
20140109948 | THERMOELECTRIC MODULE, THERMOELECTRIC DEVICE COMPRISING THE SAME, AND PROCESS FOR PREPARING THE THERMOELECTRIC ELEMENT - A thermoelectric module including: an n-type thermoelectric element; a p-type thermoelectric element; a diffusion blocking layer bonded integrally on each of a top and a bottom surface of the n-type thermoelectric element and on each of a top and a bottom surface of the p-type thermoelectric element; an electrode on the n-type thermoelectric element and on the p-type thermoelectric element; and a bonding layer disposed between the electrode and at least one of the n-type thermoelectric element and the p-type thermoelectric element, wherein the bonding layer includes an amorphous metal. | 04-24-2014 |
20140191107 | METHOD AND APPARATUS FOR ADJUSTING AN APERTURE IN AN OPTICAL SYSTEM - An aperture adjusting apparatus is provided. The aperture adjusting apparatus includes: a variable part of which an aperture size varies; an optical sensor configured to sense light incident to the variable device part and light output from the variable device part; an aperture calculator configured to calculate a size of an aperture formed in the variable part from light intensity sensed by the optical sensor; and a driving controller configured to control driving of the variable device part by receiving a calculation result fed back from the aperture calculator. | 07-10-2014 |
20140192218 | APPARATUS FOR ADJUSTING APERTURE USING MICROELECTROFLUIDIC METHOD - Provided is an aperture adjusting apparatus for adjusting an aperture through which light transmits. The aperture adjusting apparatus includes: a chamber configured to have space in which fluid flows, the chamber including a lower channel, an upper channel, and a plurality of reservoir regions connecting the lower channel and the upper channel and each having a non-uniform width crossing a flow direction of a fluid to form a space in which fluid flows; a photo-interceptive first fluid and a photo-transmissive second fluid having a property that the photo-transmissive second fluid does not mix with the first fluid and that are prepared in the chamber; and a first electrode unit in which one or more electrodes to which a voltage is applied are arrayed to form an electric field in the chamber, wherein an aperture through which light transmits is adjusted by a location change of an interface between the first fluid and the second fluid according to the electric field. | 07-10-2014 |
20140194750 | OPTICAL ZOOM PROBE - Exemplary embodiments disclose an optical zoom probe including an aperture adjuster configured to adjust an aperture in which light transmitted by a light transmitter passes, a focus adjuster configured to focus the light passed through the aperture and adjust a focal length to an ultra-close location and a close location, and a filter which includes a center region in which incident light passes without change, and a filter region which surrounds the center region and increases a depth of focus (DOF) of light that is focused on the ultra-close location. | 07-10-2014 |
20140240586 | VARIABLE LIQUID DEVICE HAVING UNEVEN CHANNEL AND APPARATUS INCLUDING THE SAME - The variable liquid device includes: a chamber including a channel, in which a fluid flows, having an inconsistent height in at least a part of the channel; a first fluid filled in the chamber and formed of a non-transmissive material; and a second fluid filled in the chamber and formed of a light transmittable material that does not mix with the first fluid, wherein an aperture, through which light is transmitted, is adjusted according to a variation of an interface between the first fluid and the second fluid. | 08-28-2014 |
20140312283 | METALLIC GLASS, CONDUCTIVE PASTE, AND ELECTRONIC DEVICE - According to example embodiments, a metallic glass includes aluminum (Al), a first element group, and a second element group. The first element group includes at least one of a transition metal and a rare earth element. The second element group includes at least one of an alkaline metal, an alkaline-earth metal, a semi-metal, and a non-metal. The second element group and aluminum have an electronegativity difference of greater than or equal to about 0.25. The second element group is included less than or equal to about 3 at % of the metallic glass, based on the total amount of the aluminum (Al), the first element group, and the second element group. A conductive paste and/or an electrode of an electronic device may be formed using the metallic glass. | 10-23-2014 |
20140345919 | TRANSPARENT CONDUCTOR, METHOD OF MANUFACTURING THE SAME, AND ELECTRONIC DEVICE INCLUDING THE TRANSPARENT CONDUCTOR - A transparent conductor includes a metallic glass, and a method of manufacturing a transparent conductor includes: preparing a metallic glass or a mixture comprising the metallic glass; and firing the metallic glass or the mixture comprising the metallic glass at a predetermined temperature higher than a glass transition temperature of the metallic glass. | 11-27-2014 |
Patent application number | Description | Published |
20080213966 | INDUCTOR EMBEDDED IN SUBSTRATE, MANUFACTURING METHOD THEREOF, MICRO DEVICE PACKAGE, AND MANUFACTURING METHOD OF CAP FOR MICRO DEVICE PACKAGE - An inductor embedded in a substrate, including a substrate, a coil electrode formed by filling a metal in a spiral hole formed on the substrate, an insulation layer formed on the substrate, and an external connection pad formed on the insulation layer to be connected to the coil electrode. The inductor-embedded substrate can be used as a cap for a micro device package by forming a cavity on its bottom surface. | 09-04-2008 |
20090115875 | IMAGE SENSOR MODULE AND FABRICATION METHOD THEREOF - An image sensor module having a sensor chip closely adhered on a concave surface and a fabrication method thereof are disclosed. The image sensor module includes at least one sensor chip, at least one sensor chip-mounting structure comprising a substrate and a polymer layer formed on the substrate, the polymer layer having an concave surface formed on an upper part thereof by a polymer molding method, so that the sensor chip is bent and bonded on the concave surface, and at least one lens fixed on the at least one sensor chip-mounting structure above the sensor chip. | 05-07-2009 |
20100050412 | PART BEING CENTERED DURING ASSEMBLY PROCESS, WAFER LEVEL PARTS ASSEMBLY, AND APPARATUS AND METHOD TO MANUFACTURE WAFER LEVEL PARTS ASSEMBLY - A part to be centered during an assembly process includes an effective portion which performs a function and is shaped for insertion into a hole, a reference portion extended from the effective portion and formed substantially perpendicular to a center axis of the effective portion, and an aligning portion extended from the effective portion and formed around the effective portion. When the effective portion of the part is inserted into the hole, a center of the effective portion is automatically aligned with a centerline of the hole. | 03-04-2010 |
20110282577 | NAVIGATION SYSTEM AND METHOD OF RECOGNIZING TRAFFIC LANE USING THE SAME - Provided are a navigation system and a method of recognizing a traffic lane using the same. The navigation system includes an electronic map in which information about roads and spatial data of topographical features around roads are stored, a satellite navigational device that calculates a position and a transverse point of a vehicle on the road using satellite navigation information and the road information, a radio communication unit that receives information about positions of the navigational satellites from a base station, and a lane recognition unit that calculates the number of lane-specific visible satellites and the number of real visible satellites on the basis of information about a lane position of the electronic map, spatial data of the topographical feature located at the transverse point, and the position information of the navigational satellites, and that compares the number of lane-specific visible satellites with the number of real visible satellites to recognize a lane along which the vehicle is traveling. Thus, there are no restrictions in the aspects of installation and maintenance, and accurate lane recognition is possible without an influence on the weather conditions around the road. | 11-17-2011 |