Abstract: To provide an electrode for non-aqueous electrolyte batteries, which traps hydrogen sulfide gas, generated from the inside thereof for some reason, in the electrode, and suppresses the outflow of hydrogen sulfide gas to the outside of the battery. An electrode for lithium ion batteries includes a coating material which contains a silanol group and is present on at least a surface of an active material layer. The active material layer contains a sulfur-based material and a resin-based binder. The sulfur-based material is an active material capable of alloying with lithium metal or an active material capable of occluding lithium ions. The coating material containing the silanol group is a silicate having a siloxane bond or a silica fine particle aggregate having a siloxane bond as a component.

Abstract: A fuel cell module includes a container and a plurality of cell members radially arranged inside the container. Inside the container, a first fluid flow path through which a first fluid that exchanges heat with an inner portion of the plurality of cell members flows is formed, and a second fluid flow path through which a second fluid that exchanges heat with an outer portion of the plurality of cell members flows is formed. A first heat exchange portion that forms the first fluid flow path and exchanges heat with the cell member has a smaller heat transfer area with the cell member than a second heat exchange portion that forms the second fluid flow path and exchanges heat with the cell member. The first fluid having a larger temperature difference with the cell member than the second fluid flows in the first fluid flow path.

Abstract: An embodiment of the present invention relates to protein granules containing a whey protein as a main component, the protein granules having an average particle diameter of 207 ?m to 570 ?m, a homogeneity U of 0.58 or less, a content ratio (volume ratio) of coarse powder having a particle diameter of 500 ?m or more of 22% or less, and a content ratio (volume ratio) of fine powder having a particle diameter of 150 ?m or less of 31% or less.

Abstract: An embodiment of the present invention relates to protein granules containing a soy protein as a main component, the protein granules having an average particle diameter of 150 ?m to 220 ?m, a homogeneity U of 0.58 or less, a content ratio (volume ratio) of a coarse powder having a particle diameter of 300 ?m or more of 27% or less, and a content ratio (volume ratio) of a fine powder having a particle diameter of 100 ?m or less of 30% or less.

Abstract: A current sensor includes a bus bar in which current to be measured flows and a magnetic sensor for detecting a magnetic field generated by the current flowing in the bus bar. The bus bar includes a bypass bus bar having a cylindrical structure and a sensing bus bar disposed in a hollow area surrounded by the bypass bus bar. The magnetic sensor is disposed in the hollow area. An area having a zero magnetic field is formed in the hollow area of the bypass bus bar. Thus, by disposing the sensing bus bar in the zero magnetic field area, it is possible to accurately measure the amount of current flowing in the bus bar while preventing saturation of the magnetic sensor even when the current flowing in the bus bar is large.

Abstract: The store merge apparatus is provided with a processor and a storage storing a plurality of entries that include a plurality of blocks and entry merge state information that represents, for each group into which the plurality of entries are divided, the state of merge in the plurality of entries, the plurality of entries and the entry merge state information being stored in correlation with each other. The processor executes a merge process for storing data in an entry on the basis of a store command to a storage apparatus and updates the entry merge state information associated with a group that includes entries to be merged. The processor preferentially selects, on the basis of the entry merge state information, a group that includes a merge-completed entry in which the data is stored in all blocks, preferentially selects a merge-completed entry from the selected group.

Abstract: Disclosed herein is an inductance element for a magnetic sensor. The inductance element includes a first core comprising a first soft magnetic material and having first and second connecting surfaces, a second core comprising a second soft magnetic material different from the first soft magnetic material and having third and fourth connecting surfaces facing the first and second connecting surfaces, respectively, and a coil wound around the first core between the first and second connecting surfaces, wherein the first core is larger in magnetic field strength at which magnetic saturation occurs than the second core, and wherein the second core is higher in permeability than the first core and has at least partially a meander shape.

Abstract: Disclosed herein is an inductance element that includes a base body, a saturable magnetic thin-plate core provided on the base body, and a coil conductor wound around the saturable magnetic thin-plate core. The saturable magnetic thin-plate core includes a first section linearly extending in a first direction and a second section having a meander-shaped, and the coil conductor is wound around the first section of the saturable magnetic thin-plate core.

Abstract: Disclosed herein is a magnetic sensor that includes a saturable magnetic member that receives magnetic flux flowing in a first axis direction, and a detection coil wound around the saturable magnetic member and having a coil axis aligned with a predetermine direction different from the first axis direction.

Abstract: The store merge apparatus is provided with a processor and a storage storing a plurality of entries that include a plurality of blocks and entry merge state information that represents, for each group into which the plurality of entries are divided, the state of merge in the plurality of entries, the plurality of entries and the entry merge state information being stored in correlation with each other. The processor executes a merge process for storing data in an entry on the basis of a store command to a storage apparatus and updates the entry merge state information associated with a group that includes entries to be merged. The processor preferentially selects, on the basis of the entry merge state information, a group that includes a merge-completed entry in which the data is stored in all blocks, preferentially selects a merge-completed entry from the selected group.

Abstract: Disclosed herein is an inductance element that includes a base body, a saturable magnetic thin-plate core provided on the base body, and a coil conductor wound around the saturable magnetic thin-plate core. The saturable magnetic thin-plate core includes a first section linearly extending in a first direction and a second section having a meander-shaped, and the coil conductor is wound around the first section of the saturable magnetic thin-plate core.

Abstract: Disclosed herein is an inductance element for a magnetic sensor. The inductance element includes a first core comprising a first soft magnetic material and having first and second connecting surfaces, a second core comprising a second soft magnetic material different from the first soft magnetic material and having third and fourth connecting surfaces facing the first and second connecting surfaces, respectively, and a coil wound around the first core between the first and second connecting surfaces, wherein the first core is larger in magnetic field strength at which magnetic saturation occurs than the second core, and wherein the second core is higher in permeability than the first core and has at least partially a meander shape.

Abstract: Disclosed herein is a magnetic sensor including: a first core made of a first soft magnetic material, the first core having first and second connection surfaces; a second core made of a second soft magnetic material different from the first soft magnetic material, the second core having a third connection surface facing the first connection surface and a fourth connection surface facing the second connection surface; and a coil wound around the first core between the first connection surface and the second connection surface. The first core reaches magnetic saturation at a higher magnetic field intensity than that of the second core, and the second core has a higher magnetic permeability than that of the first core.

Abstract: Disclosed herein is a magnetic sensor including: a first core made of a first soft magnetic material, the first core having first and second connection surfaces; a second core made of a second soft magnetic material different from the first soft magnetic material, the second core having a third connection surface facing the first connection surface and a fourth connection surface facing the second connection surface; and a coil wound around the first core between the first connection surface and the second connection surface. The first core reaches magnetic saturation at a higher magnetic field intensity than that of the second core, and the second core has a higher magnetic permeability than that of the first core.

Abstract: Store merge processing device stores a plurality of entries, with regard to a plurality of first write instructions that are a plurality of write instructions issued by an external device, have access addresses including upper and lower addresses, of which upper addresses are equal and have equal block sizes for writing data to a storage, the entries including identification information for identifying a block size, a plurality of pieces of block data, address information indicating an upper address, and storage information indicating a storage state for each piece of the block data in association with one another; and when the entries include an entry of which identification and address information matches those of a second write instruction, writes the block data included in the second write instruction in a position specified by the access address in the entry, and updates the storage information regarding the block data.

Abstract: It is intended to provide a sterilization method for heat-resistant bacterial spores, with which an effective sterilization effect is attained under heating conditions milder than conventional conditions, and which hardly affects the quality of an object to be sterilized. The sterilization method includes performing a first heat treatment step having the main object of damaging spores and then performing a second heat treatment step having the main object of inactivating the damaged spores and being performed at a temperature lower than that of the first heat treatment step.

Abstract: A multiplier has a multiplication array in which partial products are generated by performing multiplication between a multiplier and a multiplicand, and a partial product control circuit which generates an enable signal for activating an effective region in the multiplication array corresponding to effective figures of the multiplier and the multiplicand. The effective figures depend on the format of the multiplier and the multiplicand. The partial product control circuit controls the status of the enable signal according to a multiplication command designating the format. The multiplication array is constituted by a dynamic circuit. The dynamic circuit in an initial stage of the multiplication array has a switch which is turned on/off by the enable signal. When the enable signal is ineffective, the switch is turned off and a discharging operation in the dynamic circuit is stopped.

Abstract: Intended is to reduce power consumption without requiring shift of an operand. A vector multiplication processing device comprising a speed-up circuit (a fixed point overflow foresight circuit 5 and a sticky bit foresight circuit 6) to calculate a product of a first operand and a second operand input based on a multiplication instruction, which device comprises a multiplication circuit 4 (a partial product generation circuit 41 and a partial product control circuit 42) which uses the speed-up circuit and generates a partial product of the first operand and the second operand input to suppress circuit operation in a specific range resultingly not referred to related to generation of the partial product according to the multiplication instruction and a data format.

Abstract: A SAW device includes one or more surface acoustic wave element which comprises an interdigital transducer on a single crystal piezo-electric substrate and is flip-chip mounted on a base substrate through metal bumps. The IDT transducer is formed of a laminate film including an underlying layer made of titanium nitride or titanium and an aluminum layer. The underlying layer and Al layer are laminated sequentially on the single crystal piezo-electric substrate. The single crystal piezo-electric substrate is a 46°- or more rotation Y-cut X-propagation lithium tantalate substrate. The single crystal piezo-electric substrate may be a 64°-rotation Y-cut X-propagation lithium niobate substrate.

Abstract: A multiplier has a multiplication array in which partial products are generated by performing multiplication between a multiplier and a multiplicand, and a partial product control circuit which generates an enable signal for activating an effective region in the multiplication array corresponding to effective figures of the multiplier and the multiplicand. The effective figures depend on the format of the multiplier and the multiplicand. The partial product control circuit controls the status of the enable signal according to a multiplication command designating the format. The multiplication array is constituted by a dynamic circuit. The dynamic circuit in an initial stage of the multiplication array has a switch which is turned on/off by the enable signal. When the enable signal is ineffective, the switch is turned off and a discharging operation in the dynamic circuit is stopped.