Abstract: The present invention provides a recombinant expression vector comprising a gene encoding canine parvovirus 2a VP2 or 2b VP2 protein, a recombinant plant into which the vector is transformed, a vaccine composition against canine parvovirus, comprising canine parvovirus 2a VP2 or 2b VP2 protein obtained from the recombinant plant, and a composition for diagnosing canine parvovirus. When the recombinant plant of the present invention is used, canine parvovirus 2a VP2 or 2b VP2 antigen protein can be rapidly produced with high efficiency. Since the composition for diagnosing canine parvovirus according to the present invention uses a recombinant antigen protein, there is no possibility of contamination due to live virus handling, and thus the composition is safe, and the presence or absence of canine parvovirus infection can be rapidly diagnosed from a large amount of samples.

Abstract: The disclosure relates to a powdery filament composition for 3D printing, a 3D printer, and a method of additively manufacturing an object by the 3D printer, and more particularly to a powdery filament composition for 3D printing, which is suitable for home use because it does not produce toxic substances, a 3D printer, the size of which is suitable for home use because it does not require high power energy, high-temperature processing and the like conditions for additive manufacturing, and a method of additively manufacturing an object by the 3D printer.

Abstract: An image forming apparatus for printing through automatic sorting is described. A communication interface obtains data from a plurality of external apparatuses. A processor, in response to the obtaining, collects the obtained data according to a plurality of groups sorted based on identification information included in the obtained data, and generates a print command when a predetermined condition is satisfied. An image forming job performer prints data collected in the plurality of groups according to the generated print command.

Abstract: To inspect a board, first, a measurement area is set on the board and a reference data of the measurement area is obtained. Then, a measurement data of the measurement area is obtained per colors, and a lighting condition is set using the reference data of the measurement area and the measurement data obtained per colors. Next, a feature object in the measurement area is set, and a distortion quantity between the reference data and the measurement data is obtained by comparing the reference data corresponding to the feature object and the measurement data corresponding to the feature object obtained under the lighting condition. Then, an inspection area is set by compensating the distortion quantity. Therefore, it is possible to compensate the distortion and set precisely the inspection area.

Abstract: An image forming apparatus for printing through automatic sorting is described. A communication interface obtains data from a plurality of external apparatuses. A processor, in response to the obtaining, collects the obtained data according to a plurality of groups sorted based on identification information included in the obtained data, and generates a print command when a predetermined condition is satisfied. An image forming job performer prints data collected in the plurality of groups according to the generated print command.

Abstract: Disclosed is a lithium ion-conductive sulfide-based solid electrolyte which includes nickel sulfide and, accordingly, the solid electrolyte can obtain a novel structure and performance. More particularly, the sulfide-based solid electrolyte includes lithium sulfide (Li2S), diphosphorus pentasulfide (P2S5), and nickel sulfide (Ni3S2) in a specific ratio by mol % and exhibits a novel crystal structure due to nickel (Ni). Accordingly, the sulfide-based solid electrolyte has greater lithium ion conductivity than an conventional sulfide-based solid electrolyte and a stable crystal structure.

Abstract: A method of inspecting a substrate is disclosed. The method is performed by a substrate-inspecting apparatus having at least one projecting module projecting a patterned light onto a substrate fixed on a stage and an inspecting module with a camera capturing an image, and inspecting a plurality of inspection regions of the substrate step by step. The method comprises, setting an inspection order of the inspecting regions according to a lengthwise direction of the substrate, estimating height displacement of a target inspection region by using a tendency information regarding at least one previous inspection region that is already inspected, adjusting height of the inspecting module by using the estimated height displacement of the target inspection region, and inspecting the target inspection region by using the inspecting module of which height is adjusted. Therefore, inspection time is reduced.

Abstract: A cloud server is provided. The cloud server includes a memory configured to store usage histories for a plurality of files for each of a plurality of users, a transceiver configured to receive a request for a file list from a user terminal apparatus, and a processor configured to retrieve a file corresponding to the user terminal apparatus, generate an aligned file list for the retrieved file based on the usage history corresponding to the retrieved file, and control the transceiver so that the generated file list is transmitted to the user terminal apparatus.

Abstract: Disclosed is a lithium ion-conductive sulfide-based solid electrolyte which includes nickel sulfide and, accordingly, the solid electrolyte can obtain a novel structure and performance. More particularly, the sulfide-based solid electrolyte includes lithium sulfide (Li2S), diphosphorus pentasulfide (P2S5), and nickel sulfide (Ni3S2) in a specific ratio by mol % and exhibits a novel crystal structure due to nickel (Ni). Accordingly, the sulfide-based solid electrolyte has greater lithium ion conductivity than an conventional sulfide-based solid electrolyte and a stable crystal structure.

Abstract: In order to inspect a board, a measurement area is set on a board, and reference data and measurement data of the measurement area are acquired. Then, a conversion condition is established for the measurement area, and a conversion relation is acquired according to a distortion degree between reference data and measurement data. Thereafter, validity of the conversion relation is verified by using at least one of verifying that a comparison feature object satisfies the conversion relation, verifying that a verification feature object selected from feature objects satisfies the conversion relation and verifying that a pad formed on the board satisfies the conversion relation. Then, the conversion condition is confirmed, and an inspection area for inspecting a measurement target is set according to the confirmed conversion condition. Thus, an inspection area may be correctly set so that distortion is compensated for.

Abstract: Disclosed are a method for manufacturing a lithium ion conductive sulfide compound, a lithium ion conductive sulfide compound manufactured by the same, and a solid electrolyte and an all solid battery comprising the same. Particularly, the lithium ion conductive sulfide compound that is manufactured by milling at low temperature so as to increase brittleness of raw materials has differentiated particle distribution, crystal structure and mixing property from the conventional one.

Abstract: Disclosed is an electrode catalyst for a hydrocarbon-fueled solid oxide fuel cell. The electrode catalyst includes ceria supports and iridium-nickel alloy nanoparticles dispersed on the surfaces of the ceria supports. The electrode catalyst can be inhibited from carbon deposition, a general phenomenon in conventional hydrocarbon-fueled solid oxide fuel cells. Therefore, the catalytic activity of the electrode catalyst can be maintained even at high temperature for a long period of time. In addition, the electrode catalyst contains a minimum amount of a platinum group metal for inhibiting the occurrence of carbon deposition and has a maximized surface area. Therefore, the electrode catalyst exhibits improved catalytic activity and can be produced at greatly reduced cost while suppressing the occurrence of carbon deposition.

Abstract: To inspect a board, first, a measurement area is set on the board and a reference data of the measurement area is obtained. Then, a measurement data of the measurement area is obtained per colors, and a lighting condition is set using the reference data of the measurement area and the measurement data obtained per colors. Next, a feature object in the measurement area is set, and a distortion quantity between the reference data and the measurement data is obtained by comparing the reference data corresponding to the feature object and the measurement data corresponding to the feature object obtained under the lighting condition. Then, an inspection area is set by compensating the distortion quantity. Therefore, it is possible to compensate the distortion and set precisely the inspection area.

Abstract: A method of inspecting a substrate is disclosed. The method is performed by a substrate-inspecting apparatus having at least one projecting module projecting a patterned light onto a substrate fixed on a stage and an inspecting module with a camera capturing an image, and inspecting a plurality of inspection regions of the substrate step by step. The method comprises, setting an inspection order of the inspecting regions according to a lengthwise direction of the substrate, estimating height displacement of a target inspection region by using a tendency information regarding at least one previous inspection region that is already inspected, adjusting height of the inspecting module by using the estimated height displacement of the target inspection region, and inspecting the target inspection region by using the inspecting module of which height is adjusted. Therefore, inspection time is reduced.

Abstract: In order to inspect a board, a measurement area is set on a board, and reference data and measurement data of the measurement area are acquired. Then, a conversion condition is established for the measurement area, and a conversion relation is acquired according to a distortion degree between reference data and measurement data. Thereafter, validity of the conversion relation is verified by using at least one of verifying that a comparison feature object satisfies the conversion relation, verifying that a verification feature object selected from feature objects satisfies the conversion relation and verifying that a pad formed on the board satisfies the conversion relation. Then, the conversion condition is confirmed, and an inspection area for inspecting a measurement target is set according to the confirmed conversion condition. Thus, an inspection area may be correctly set so that distortion is compensated for.