Abstract: Provided is an anti-fuse memory including a anti-fuse memory cell including an isolation structure, a select gate, first and second gate insulating layers, an anti-fuse gate, and first, second and third doped regions. The isolation structure is disposed in a substrate. The select gate is disposed on the substrate. The first gate insulating layer is disposed between the select gate and the substrate. The anti-fuse gate is disposed on the substrate and partially overlapped with the isolation structure. The second gate insulating layer is disposed between the anti-fuse gate and the substrate. The first doped region and the second doped region are disposed in the substrate at opposite sides of the select gate, respectively, wherein the first doped region is located between the select gate and the anti-fuse gate. The third doped region is disposed in the substrate and located between the first doped region and the isolation structure.

Abstract: A medical imaging system (10) comprises one or more displays (66). A viewer device (86) generates an interactive user interface screen (80) on the display (66), which viewer device (86) enables a user to simultaneously inspect selected image data of multiple patients or multiple images.

Abstract: The present invention is to provide a docking station applicable to a portable electronic device and having an anti-theft mechanism, which includes a positioning base having a top side concavely provided with a positioning space and a first abutting surface provided adjacent to one end of the positioning base and facing the positioning space; a sliding base movably connected to an opposite end of the positioning base and provided with a second abutting surface facing the positioning space, wherein the first and second abutting surfaces are respectively and protrudingly provided with a first plug and a second plug configured to be inserted into and thereby connected with corresponding sockets of the portable electronic device; a first fastener and a second fastener respectively provided at the sliding base and the positioning base and capable of being fastened together to prevent the sliding base from moving with respect to the positioning base.

Abstract: A medical imaging system (10) comprises one or more displays (66). A viewer device (86) generates an interactive user interface screen (80) on the display (66), which viewer device (86) enables a user to simultaneously inspect selected image data of multiple patients or multiple images.

Abstract: In image registration, a similarity measure is computed of first and second images (4, 6) offset at a plurality of relative axial offsets (30). A starting relative axial offset (40) between the first and second images is identified based on the computed similarity measures. An iterative image registration process is performed to relatively register the first and second images (4, 6) using the identified starting relative axial offset between the first and second images as an initial condition for the iterative image registration process. A starting relative in-slice offset (42) may also be identified as an in-slice offset effective to align corresponding slices of the first and second images (4, 6) offset at the starting relative axial offset (40), the identified starting relative in-slice offset also being used as an initial condition for the iterative image registration process.

Abstract: A medical imaging system (10) comprises one or more displays (66). A viewer device (86) generates an interactive user interface screen (80) on the display (66), which viewer device (86) enables a user to simultaneously inspect selected image data of multiple patients or multiple images.

Abstract: A medical imaging system (10) comprises one or more displays (66). A viewer device (86) generates an interactive user interface screen (80) on the display (66), which viewer device (86) enables a user to simultaneously inspect selected image data of multiple patients or multiple images.

Abstract: A medical imaging system (10) comprises one or more displays (66). A viewer device (86) generates an interactive user interface screen (80) on the display (66), which viewer device (86) enables a user to simultaneously inspect selected image data of multiple patients or multiple images.

Abstract: In image registration, a similarity measure is computed of first and second images (4, 6) offset at a plurality of relative axial offsets (30). A starting relative axial offset (40) between the first and second images is identified based on the computed similarity measures. An iterative image registration process is performed to relatively register the first and second images (4, 6) using the identified starting relative axial offset between the first and second images as an initial condition for the iterative image registration process. A starting relative in-slice offset (42) may also be identified as an in-slice offset effective to align corresponding slices of the first and second images (4, 6) offset at the starting relative axial offset (40), the identified starting relative in-slice offset also being used as an initial condition for the iterative image registration process.

Abstract: A contact lens fabrication method of fabrication a contact lens by means of: pressing a male molding block of a supplementary tool into a cavity of a mold to squeeze a contact lens material into shape and to simultaneously cut off an excessive part of the contact lens material from a contact lens by means of a cut angle of sharp edge of the mold, and then curing the contact lens, and then separating the supplementary tool from the mold to have the contact lens be adhered to the surface of the male molding block, and then filling a buffer solution into the supplementary tool to have the contact lens be dipped in the buffer solution after quality examination of the contact lens, and then sealing a sealing film to the supplementary tool to form a finished contact lens product for sale.

Abstract: A medical imaging system (10) comprises one or more displays (66). A viewer device (86) generates an interactive user interface screen (80) on the display (66), which viewer device (86) enables a user to simultaneously inspect selected image data of multiple patients or multiple images.

Abstract: A method of fabricating holographic colored contact lens is provided. A lens-making mold having multiple micro-lines on the peripheral surface is used to fabricate the contact lens and at the same time the micro-line pattern is copied onto the contact lens to form a light interference zone, which causes light waves to break up to produce light diffraction around the eyes, such that a holographic impression of a person's eyes can be created through the lenses. The perceived eyes through the lenses change color when looking from a different angle. This contact lens makes use of grating diffraction principles to impart colors on the eyes of a person wearing the contact lenses, without using any chemical colorants in the lens-making process; therefore wearing such contact lens is much healthier as opposed to a conventional colored contact lens.

Abstract: A method of fabricating holographic colored contact lens is provided. A lens-making mold having multiple micro-lines on the peripheral surface is used to fabricate the contact lens and at the same time the micro-line pattern is copied onto the contact lens to form a light interference zone, which causes light waves to break up to produce light diffraction around the eyes, such that a holographic impression of a person's eyes can be created through the lenses. The perceived eyes through the lenses change color when looking from a different angle. This contact lens makes use of grating diffraction principles to impart colors on the eyes of a person wearing the contact lenses, without using any chemical colorants in the lens-making process; therefore wearing such contact lens is much healthier as opposed to a conventional colored contact lens.

Abstract: A holographic image shrinkable film and the manufacture thereof is to spread a UV resin film on a shrinkable film; stick the UV resin film tightly against a metal wheel engraved with a holographic pattern, holographic film or separating type hot stamping film; illuminate the UV resin film with an UV lamp so as to harden the UV resin film instantly; and remove the harden UV resin film from the metal wheel, the holographic film, or separating type hot stamping film; the holographic pattern on the metal wheel or the holographic film is copied onto the UV resin film, or a separating type hot stamping film substrate is combined on the UV resin film. The manufacturing method according to the present invention is rather not dangerous, and a specialist is not need. Therefore, a mass production can be practiced to save production cost can be saved.

Abstract: A laser laminar structure is formed by coating each side of a thin substrate with a bonding resin layer, and then coating each bonding resin layer with a molding resin layer; attaching a transparent laser film provided with fine grooves of a laser image presenting figure, characters or logos to an outer surface of each molding resin layer, so that each molding resin layer is formed at superficial portion with fine lines corresponding to the fine grooves of the laser image on the laser film; baking the molding resin layers at high temperature to harden the fine lines formed thereon; and releasing the transparent laser films from the molding resin layers to provide a thermostable laser laminar structure.

Abstract: A hologram medium printing wheel includes a roller having an outer surface and an ultraviolet curable resin layer formed on the outer surface and completely surrounding the roller. Holographic patterns are formed on the resin layer before it is cured. The resin is then exposed to an ultraviolet source for curing and forms a solid printing mold. If desired, an adhesive layer can be interposed between the resin layer and the roller to more securely attach the resin layer to the roller.

Abstract: A laser laminar structure is formed by coating each side of a thin substrate with a bonding resin layer, and then coating each bonding resin layer with a molding resin layer; attaching a transparent laser film provided with fine grooves of a laser image presenting figure, characters or logos to an outer surface of each molding resin layer, so that each molding resin layer is formed at superficial portion with fine lines corresponding to the fine grooves of the laser image on the laser film; baking the molding resin layers at high temperature to harden the fine lines formed thereon; and releasing the transparent laser films from the molding resin layers to provide a thermostable laser laminar structure.