Abstract: An image segmentation method includes displaying, through a display component, an image; receiving, through a user input component, a user command relative to an original designation region of the image; shrinking the original designation region according to first depth information corresponding to the image to generate a shrunk designation region of the image; generating a plurality of seeds according to the shrunk designation region and the user command; and segmenting the image according to the seeds to obtain at least one segmented region.

Abstract: A white light emitting diode comprising a substrate layer, two conductive frames, a light emitting unit, two conductive wires, and a packaging element is provided. The substrate layer is made from a curing reaction of first mixture, and the first mixture includes a curable resin, a curing agent, a phosphor material, and a modified thermal conductive nano-material, wherein the modified thermal conductive nano-material is made from a thermal conductive nano-material and a silane compound. The packaging element is made from a curing reaction of second mixture, and the second mixture includes a curable resin, a curing agent, a phosphor material, and a modified thermal conductive nano-material, wherein the modified thermal conductive nano-material is made from a thermal conductive nano-material and a silane compound. The chip-type white light emitting diode has a good heat-dissipating effect and a good luminous efficiency without additional heat dissipation fins.

Abstract: A system and/or technique for graphical interface presentation comprises receiving a search string and presenting a search result series to a user on a client device. Search results of the search result series are presented in the form of cards, where a first card comprises information associated with a first search result of the search result series and a second card comprises information associated with a second search result of the search result series. A user may navigate through the cards to view various search results.

Abstract: A method to provide a 3D outfit model able to be adjusted corresponding to a 3D human model. The method includes following steps. A three-dimensional (3D) human model is provided, and vertices of the 3D human model are located at first positions. A 3D outfit model is provided, and vertices of the 3D outfit model are located at second positions. In response to that the 3D human model is deformed and the vertices of the 3D human model are displaced from the first positions to third positions, the 3D outfit model is adjusted corresponding to the 3D human model, by setting each of the vertices of the 3D outfit model to fourth positions according to the second positions and displacements of the vertices of the 3D human model between the first positions and the third positions.

Abstract: An optical fiber with a large effective area includes a core layer and a cladding layer. The core layer comprises an inner core layer having a radius of 1-4 ?m and a relative refractive index difference ?12 of ?0.2%??12<0% relative to the outer core layer, and an outer core layer having a radius of 4-7 ?m and a relative refractive index difference ?2 of ?0.15%-0.05%. ?12 remains unchanged or increases as the radius of the inner core layer increases. The cladding layer comprises an inner cladding layer cladding the core layer and having a radius of 7-20 ?m and a relative refractive index difference ?3 of ?0.5%˜?0.1%, a depressed cladding layer has a radius of 12-40 ?m, and a relative refractive index difference ?4 of ?1.0%˜?0.3%, and an outer cladding layer having a relative refractive index difference ?5 of ?0.2%˜?0.4%.

Abstract: A white light emitting diode comprising a substrate layer, two conductive frames, a light emitting unit, two conductive wires, and a packaging element is provided. The substrate layer is made from a curing reaction of first mixture, and the first mixture includes a curable resin, a curing agent, a phosphor material, and a modified thermal conductive nano-material, wherein the modified thermal conductive nano-material is made from a thermal conductive nano-material and a silane compound. The packaging element is made from a curing reaction of second mixture, and the second mixture includes a curable resin, a curing agent, a phosphor material, and a modified thermal conductive nano-material, wherein the modified thermal conductive nano-material is made from a thermal conductive nano-material and a silane compound. The chip-type white light emitting diode has a good heat-dissipating effect and a good luminous efficiency without additional heat dissipation fins.

Abstract: An optical fiber with a large effective area includes a core layer and a cladding layer. The core layer comprises an inner core layer having a radius of 1-4 ?m and a relative refractive index difference ?12 of ?0.2%??12<0% relative to the outer core layer, and an outer core layer having a radius of 4-7 ?m and a relative refractive index difference ?2 of ?0.15%-0.05%. ?12 remains unchanged or increases as the radius of the inner core layer increases. The cladding layer comprises an inner cladding layer cladding the core layer and having a radius of 7-20 ?m and a relative refractive index difference ?3 of ?0.5%˜?0.1%, a depressed cladding layer has a radius of 12-40 ?m, and a relative refractive index difference ?4 of ?1.0%˜?0.3%, and an outer cladding layer having a relative refractive index difference ?5 of ?0.2%˜?0.4%.

Abstract: A dispersion compensation fiber comprises a fiber core and cladding. The fiber core is a core layer mainly doped with germanium and having a positive relative refractive index difference. The cladding covering the fiber core comprises a trench cladding mainly doped with fluorine, an annular cladding mainly doped with germanium, a matching cladding mainly doped with fluorine, and an outermost mechanical cladding in order. Relative refractive index differences of the fiber core and the claddings are respectively: ?1% being 1.55% to 2.20%, ?2% being ?0.55% to ?0.30%, ?3% being 0.40% to 0.65%, ?4% being ?0.20% to ?0.01%, and ?5% being 0. Radius ranges, from R1 to R5, of the fiber core and the claddings are respectively: R1 being 1.4 to 1.7 ?m, R2 being 4.1 to 4.8 ?m, R3 being 6.7 to 8.8 ?m, R4 being 10 to 17 ?m, and R5 being 38 to 63 ?m.

Abstract: An image segmentation method includes displaying, through a display component, an original designation region relative to an image; receiving a user input on the image, in which the user input is at least one stroke on the image; segmenting a regional area corresponding to the stroke to update the original designation region, in which the regional area at least partially overlaps with the original designation region.

Abstract: An image segmentation method includes displaying, through a display component, an image; receiving, through a user input component, a user command relative to an original designation region of the image; shrinking the original designation region according to first depth information corresponding to the image to generate a shrunk designation region of the image; generating a plurality of seeds according to the shrunk designation region and the user command; and segmenting the image according to the seeds to obtain at least one segmented region.

Abstract: A method for manufacturing an optical fiber preform, including: a) providing a lining tube as a substrate tube, and doping and depositing by a PCVD or an MCVD process; b) in the reacting gas of silicon tetrachloride and oxygen, introducing a fluorine-containing gas for fluorine doping, introducing germanium tetrachloride for germanium doping, ionizing the reacting gas in the lining tube through microwaves to form plasma, depositing the plasma on the inner wall of the lining tube in the form of glass; c) after the completion of deposition, processing the deposited lining tube into a solid core rod by melting contraction through an electric heating furnace; d) sleeving the solid core rod into a pure quartz glass jacketing tube and manufacturing the two into an optical fiber preform; and e) allowing the effective diameter d of the optical fiber preform to become between 95 and 205 mm.

Abstract: A touch selection method, an electronic apparatus, and a non-transitory computer readable medium are disclosed herein. The touch selection method is able to perform a touch selection on a display of an electronic apparatus, in which the display displays content. The touch selection method includes following operations: assigning a selection unit corresponding to one of zoom levels, in which the selection unit includes pixels on the display that are regarded as a minimum selectable component for the touch selection.

Abstract: A telescopic shaft assembly includes a seat, a shaft body disposed movably in the seat, and a plurality of slide blocks located between the shaft body and the seat. The shaft body has a convex portion and a recessed portion opposite to each other. One end of the convex portion far away from the recessed portion has a top surface. One of the plurality of slide block is disposed on the top surface. The recessed portion has two inner side wall surfaces opposite to each other and a bottom surface located between the two inner side wall surfaces. Each of the two inner side wall surfaces forms an obtuse angle with the bottom surface. Two of the rest of the plurality of slide blocks are disposed on the two inner side wall surfaces respectively.

Abstract: The invention provides a novel polymer platform to deliver a desired combination of therapeutic agents to a site in need thereof for the treatment of cancer. In certain embodiments the platform is a modular polymer platform that allows for customization based upon the tumor of the subject to be treated.

Abstract: The invention provides methods, compositions and transformation systems for modifying the levels of transcription factors in plants such as Solanaceous plants, and introducing disease resistance genes into plants, to produce products with elevated levels of antioxidant compounds, including but not limited to flavonols and chlorogenic acid, as well as exhibiting enhanced disease resistance, and optionally altered appearance. Preferred plants are those in which introduced genes are from Solanaceous species.

Abstract: A self-service terminal includes a safety box, a main control module, an operating module, and a shielding member. The main control module includes a casing and a mounting frame mounted in the casing. The mounting frame is attached on the safety box. The casing includes a pair of side panels and a top panel connecting between the pair of side panels. The pair of side panels and the top panel is detachably attached to the mounting frame. The operating module is attached to a front side of the main control module. The shielding member is attached to the safety box and encloses the operating module.

Abstract: A stylized QR code generating apparatus is provided, which includes: an image adjusting module having an image detecting unit and a shape distorting unit; and a code stylizing module having a boundary matching unit and a boundary adjusting unit. The image detecting unit detects an error value generated in a QR code when a predetermined image is embedded in the QR code, and the shape distorting unit distorts a plurality of meshes converted from the image to adjust a shape of the image and thereby correct the error value in the QR code. The boundary matching unit matches a plurality of first boundary sections of the QR code with second boundary sections of a predetermined pattern, and the boundary adjusting unit adjusts the first boundary sections to the matched second boundary sections, respectively.

Abstract: A dispersion compensation fiber comprises a fiber core and cladding. The fiber core is a core layer mainly doped with germanium and having a positive relative refractive index difference. The cladding covering the fiber core comprises a trench cladding mainly doped with fluorine, an annular cladding mainly doped with germanium, a matching cladding mainly doped with fluorine, and an outermost mechanical cladding in order. Relative refractive index differences of the fiber core and the claddings are respectively: ?1% being 1.55% to 2.20%, ?2% being ?0.55% to ?0.30%, ?3% being 0.40% to 0.65%, ?4% being ?0.20% to ?0.01%, and ?5% being 0. Radius ranges, from R1 to R5, of the fiber core and the claddings are respectively: R1 being 1.4 to 1.7 ?m, R2 being 4.1 to 4.8 ?m, R3 being 6.7 to 8.8 ?m, R4 being 10 to 17 ?m, and R5 being 38 to 63 ?m.

Abstract: A low attenuation single mode optical fiber includes a core layer and claddings. The core layer has the relative refractive index difference (RRID) ?1 ranging from ?0.1% to +0.1% and the radius R1 ranging from 4.0 ?m to 6.0 ?m. The claddings have three claddings layers surrounding the core layer. The RRID of the first cladding layer ?2 ranges from ?0.2% to ?0.6%, and the radius R2 thereof ranges from 10 ?m to 22 ?m. The RRID of the second cladding layer ?3 is less than ?2. The RRID and radius of the first cladding layer and the RRID and radius of the second cladding layer satisfy the relationship of: V=(?2??3)×(R3?R2), and the value of V ranges from 0.15% ?m to 0.8% ?m. The third cladding layer is all the layers that closely surround the second cladding layer, and the RRID of each layer is greater than ?3.

Abstract: A low attenuation single mode optical fiber includes a core layer and claddings. The core layer has the relative refractive index difference (RRID) ?1 ranging from ?0.1% to +0.1% and the radius R1 ranging from 4.0 ?m to 6.0 ?m. The claddings have three claddings layers surrounding the core layer. The RRID of the first cladding layer ?2 ranges from ?0.2% to ?0.6%, and the radius R2 thereof ranges from 10 ?m to 22 ?m. The RRID of the second cladding layer ?3 is less than ?2. The RRID and radius of the first cladding layer and the RRID and radius of the second cladding layer satisfy the relationship of: V=(?2??3)×(R3?R2), and the value of V ranges from 0.15% ?m to 0.8% ?m. The third cladding layer is all the layers that closely surround the second cladding layer, and the RRID of each layer is greater than ?3.