Abstract: An information processing device has an obtaining unit, a controller, and a giving unit. The obtaining unit can obtain vehicle information. The controller creates first warning information when the passability of a road in the vehicle information indicates non-passable. The controller creates recovery information when the passability of the road at the same position in the vehicle information indicates passable, after creation of the first warning information. The giving unit gives the recovery information.

Abstract: An information processing apparatus includes an acquisition unit, a controller, a storage unit, and a providing unit. The acquisition unit is configured to acquire vehicle information from a vehicle-mounted information processing device. The controller is configured to recognize the position of a target in a case where vehicle information including the target in the vicinity of a vehicle is acquired. The controller is configured to accumulate the target in a habitat database such that the target is correlated with the position. The controller is configured to generate habitat information of the target based on a habitat database. The providing unit is configured to provide the habitat information to a terminal device.

Abstract: An information processing device has an obtaining unit, a controller, and a giving unit. The obtaining unit can obtain vehicle information. The controller creates first warning information when the passability of a road in the vehicle information indicates non-passable. The controller creates recovery information when the passability of the road at the same position in the vehicle information indicates passable, after creation of the first warning information. The giving unit gives the recovery information.

Abstract: An oxide sintered body having metal elements composed of In, Ga, Zn and Sn and containing a hexagonal layered compound represented by InGaO3(ZnO)m (m is an integer of 1 to 6). When ratios (atomic %) of contents of In, Zn and Sn to all metal elements excluding oxygen contained in the oxide sintered body are taken as [In], [Zn] and [Sn], respectively, the relations [Zn]?40 atomic %, [In]?15 atomic %, [Sn]?4 atomic % are satisfied.

Abstract: An oxide sintered body has metal elements of In, Ga, Zn, and Sn and contains Ga2In6Sn2O16, ZnGa2O4, and InGaZnO4. The contents of In, Ga, Zn, and Sn in the oxide sintered body satisfy the relations [Ga]?37 atomic %, [Sn]?15 atomic %, and [Ga]/([In]+[Zn])?0.7, where [In], [Ga], [Zn], and [Sn] represent ratios (atomic %) of In, Ga, Zn, and Sn with respect to all metal elements contained in the oxide sintered body, respectively.

Abstract: An information processing device has an obtaining unit, a controller, and a giving unit. The obtaining unit can obtain vehicle information. The controller creates first warning information when the passability of a road in the vehicle information indicates non-passable. The controller creates recovery information when the passability of the road at the same position in the vehicle information indicates passable, after creation of the first warning information. The giving unit gives the recovery information.

Abstract: An oxide sintered body has metal elements of In, Ga, Zn, and Sn and contains Ga2In6Sn2O16, ZnGa2O4, and InGaZnO4. The contents of In, Ga, Zn, and Sn in the oxide sintered body satisfy the relations [Ga]?37 atomic %, [Sn]?15 atomic %, and [Ga]/([In]+[Zn])?0.7, where [In], [Ga], [Zn], and [Sn] represent ratios (atomic %) of In, Ga, Zn, and Sn with respect to all metal elements contained in the oxide sintered body, respectively.

Abstract: An information processing device has an obtaining unit, a controller, and a giving unit. The obtaining unit can obtain vehicle information. The controller creates first warning information when the passability of a road in the vehicle information indicates non-passable. The controller creates recovery information when the passability of the road at the same position in the vehicle information indicates passable, after creation of the first warning information. The giving unit gives the recovery information.

Abstract: An information processing apparatus includes an acquisition unit, a controller, a storage unit, and a providing unit. The acquisition unit is configured to acquire vehicle information from a vehicle-mounted information processing device. The controller is configured to recognize the position of a target in a case where vehicle information including the target in the vicinity of a vehicle is acquired. The controller is configured to accumulate the target in a habitat database such that the target is correlated with the position. The controller is configured to generate habitat information of the target based on a habitat database. The providing unit is configured to provide the habitat information to a terminal device.

Abstract: An information processing device includes an acquisition unit, a control unit and a giving unit. The acquisition unit can acquire vehicle information from an in-vehicle information processing device. The acquisition unit can acquire condition information from a terminal device. When acquiring the vehicle information, the control unit recognizes a weather when a vehicle detects clothes in the vehicle information. The control unit accumulates the clothes in a clothes database, in association with the weather and a position. When acquiring the condition information, the control unit recognizes a predicted weather at a designated time and a designated position. The control unit selects at least one kind of clothes, based on the clothes in the clothes database that are associated with the predicted weather and the position. The giving unit gives the at least one kind of clothes, to the terminal device that gives the condition information.

Abstract: An oxide sintered body having metal elements composed of In, Ga, Zn and Sn and containing a hexagonal layered compound represented by InGaO3(ZnO)m (m is an integer of 1 to 6). When ratios (atomic %) of contents of In, Zn and Sn to all metal elements excluding oxygen contained in the oxide sintered body are taken as [In], [Zn] and [Sn], respectively, the relations [Zn]?40 atomic %, [In]?15 atomic %, [Sn]?4 atomic % are satisfied.

Abstract: An oxide sintered body is obtained by sintering indium oxide, gallium oxide and tin oxide. The oxide sintered body has a relative density of 90% or more and an average grain size of 10 ?m or less. In the oxide sintered body, the relations 30 atomic %?[In]?50 atomic %, 20 atomic %?[Ga]?30 atomic % and 25 atomic %?[Sn]?45 atomic % are satisfied. [In], [Ga] and [Sn] are ratios of contents (atomic %) of indium gallium and tin, respectively, to all metal elements contained in the oxide sintered body. The oxide sintered body has an InGaO3 phase which satisfies the relation [InGaO3]?0.05.

Abstract: Disclosed is an oxide sintered body, wherein contents of zinc, indium, gallium and tin relative to all metal elements satisfy the following inequality expressions: 40 atomic %?[Zn]?55 atomic %, 20 atomic %?[In]?40 atomic %, 5 atomic %?[Ga]?15 atomic %, and 5 atomic %?[Sn]?20 atomic %, where the contents (atomic %) of zinc, indium, gallium and tin relative to all metal elements excluding oxygen are respectively taken as [Zn], [In], [Ga] and [Sn], wherein the oxide sintered body has a relative density of 95% or more, and wherein the oxide sintered body includes, as a crystal phase, 5 to 20 volume % of InGaZn2 O5.

Abstract: An oxide sintered body which is obtained by mixing and sintering zinc oxide, indium oxide, gallium oxide and tin oxide. The relative density of the oxide sintered body is 85% or more and the average grain size of crystal grains observed on the surface of the oxide sintered body is less than 10 ?m. X-ray diffraction of the oxide sintered body shows that a Zn2SnO4 phase and an InGaZnO4 phase are the main phases and that an InGaZn2O5 phase is contained in an amount of 3 volume % or less.

Abstract: An oxide sintered body is obtained by mixing and sintering a zinc oxide, an indium oxide, a gallium oxide and a tin oxide. The oxide sintered body has a relative density of 85% or more, and has volume ratios satisfying the following expressions (1) to (3), respectively, as determined by X•ray diffractometry: (1) (Zn2SnO4 phase+InGaZnO4 phase)/(Zn2SnO4 phase+InGaZnO4 phase+In2O3 phase+SnO2 phase+(ZnO)mIn2O3, phase)?75% by volume; (2) Zn2SnO4 phase/(Zn2SnO4 phase+InGaZnO4 phase+In2O3 phase+SnO2 phase+(ZnO)mIn2O3 phase)?30% by volume; and (3) InGaZnO4 phase/(Zn2SnO4 phase+InGaZnO4 phase+In2O3 phase+SnO2 phase+(ZnO)mIn2O3 phase)?10% by volume, and m represents an integer of 2 to 5.

Abstract: Provided is a Li-containing phosphoric-acid compound sintered body of both high relative density and very small crystal grain diameter with reduced incidence of defects (voids) such as air holes, the Li-containing phosphoric-acid compound sintered body causing a Li-containing phosphoric-acid compound thin film useful as a solid electrolyte for a secondary cell or the like to be stabilized without any incidence of target cracking or irregular electrical discharge, and offering high-speed film-forming capability. This Li-containing phosphoric-acid compound sintered body contains no defects measuring 50 ?m or larger within a 1 mm2 cross-sectional region in the interior thereof, while having an average crystal grain diameter of no more than 15 ?m and a relative density of at least 85%.

Abstract: An oxide sintered body is obtained by sintering indium oxide, gallium oxide and tin oxide. The oxide sintered body has a relative density of 90% or more and an average grain size of 10 ?m or less. In the oxide sintered body, the relations 30 atomic %?[In]?50 atomic %, 20 atomic %?[Ga]?30 atomic % and 25 atomic %?[Sn]?45 atomic % are satisfied. [In], [Ga] and [Sn] are ratios of contents (atomic %) of indium gallium and tin, respectively, to all metal elements contained in the oxide sintered body. The oxide sintered body has an InGaO3 phase which satisfies the relation [InGaO3]?0.05.

Abstract: An oxide sintered body which is obtained by mixing and sintering zinc oxide, indium oxide, gallium oxide and tin oxide. The relative density of the oxide sintered body is 85% or more and the average grain size of crystal grains observed on the surface of the oxide sintered body is less than 10 ?m. X-ray diffraction of the oxide sintered body shows that a Zn2SnO4 phase and an InGaZnO4 phase are the main phases and that an InGaZn2O5 phase is contained in an amount of 3 volume % or less.

Abstract: An oxide sintered body is obtained by mixing and sintering a zinc oxide, an indium oxide, a gallium oxide and a tin oxide. The oxide sintered body has a relative density of 85% or more, and has volume ratios satisfying the following expressions (1) to (3), respectively, as determined by X•ray diffractometry: (1) (Zn2SnO4 phase+InGaZnO4 phase)/(Zn2SnO4 phase+InGaZnO4 phase+In2O3 phase+SnO2 phase+(ZnO)mIn2O3, phase)?75% by volume; (2) Zn2SnO4 phase/(Zn2SnO4 phase+InGaZnO4 phase+In2O3 phase+SnO2 phase+(ZnO)mIn2O3 phase)?30% by volume; and (3) InGaZnO4 phase/(Zn2SnO4 phase+InGaZnO4 phase+In7O3 phase+SnO2 phase+(ZnO)mIn2O3 phase)?10% by volume. and m represents an integer of 2 to 5.

Abstract: Provided is a Li-containing phosphoric-acid compound sintered body of both high relative density and very small crystal grain diameter with reduced incidence of defects (voids) such as air holes, the Li-containing phosphoric-acid compound sintered body causing a Li-containing phosphoric-acid compound thin film useful as a solid electrolyte for a secondary cell or the like to be stabilized without any incidence of target cracking or irregular electrical discharge, and offering high-speed film-forming capability. This Li-containing phosphoric-acid compound sintered body contains no defects measuring 50 ?m or larger within a 1 mm2 cross-sectional region in the interior thereof, while having an average crystal grain diameter of no more than 15 ?m and a relative density of at least 85%.