Abstract: A server is configured to: determine a ratio of each of a first group and a second group to be allocated to the multiple display objects according to a third user situation of a presentation target user or a schedule information; determine a display mode of each of multiple first display objects allocated to the first group in accordance with the determined ratio based on multiple first user situations, and determine a display mode of each of multiple second display objects allocated to the second group in accordance with the determined ratio based on multiple second user situations; and output setting information for displaying the multiple first display objects and the multiple second display objects in the determined display mode.

Abstract: According to one embodiment, a semiconductor storage device includes a plurality of electrode films on a substrate, spaced from one another in a first direction. A charge storage film is provided on a side face the electrode films via a first insulating film. A semiconductor film is provided on a side face of the charge storage film via a second insulating film. The charge storage film includes a plurality of insulator regions contacting the first insulating film, a plurality of semiconductor or conductor regions provided between the insulator regions and another insulator region.

Abstract: A method for manufacturing a substrate according to the first disclosure includes immersing a substrate on which a plurality of circuit patterns are formed in pure water or a corrosive solution, applying voltage between the plurality of circuit patterns in a state in which the substrate is immersed in the pure water or the corrosive solution and determining the substrate to be a defective product when a tree is generated in the plurality of circuit patterns due to the voltage application and determining the substrate to be a non-defective product when the tree is not generated.

Abstract: Provided is a radioactive contamination inspection device, including: a detection unit having a sensitive surface that has a shape conforming to a shape of an object surface, which is a measurement target and a radioactive contamination amount of which is to be measured; a mechanism unit for holding the detection unit in a state in which a distance from the sensitive surface to the object surface falls within a desired range set in advance; and a measurement unit for calculating the radioactive contamination amount of the object surface on the basis of a measurement result from the detection unit.

Abstract: Provided is a vehicle gate monitor including a gate on which a detector group is mounted, the detector group including: a first detector, which is arranged in a manner that allows vertical and horizontal movement, and is configured to measure radiation levels of both side surfaces of the vehicle; a second detector, which is arranged in a manner that allows vertical, rotational, and horizontal movement, and is configured to measure radiation levels of a front surface, a rear surface, an upper surface, and a cargo bed surface of the vehicle; and a third detector, which is arranged in a manner that allows vertical and horizontal movement, and is configured to measure a radiation level of an inner-side side surface of the cargo bed, the gate including a control unit configured to identify, while moving the gate with respect to a stationary vehicle, presence/absence of a contaminated place.

Abstract: Provided is a vehicle gate monitor including a gate on which a detector group is mounted, the detector group including: a first detector, which is arranged in a manner that allows vertical and horizontal movement, and is configured to measure radiation levels of both side surfaces of the vehicle; a second detector, which is arranged in a manner that allows vertical, rotational, and horizontal movement, and is configured to measure radiation levels of a front surface, a rear surface, an upper surface, and a cargo bed surface of the vehicle; and a third detector, which is arranged in a manner that allows vertical and horizontal movement, and is configured to measure a radiation level of an inner-side side surface of the cargo bed, the gate including a control unit configured to identify, while moving the gate with respect to a stationary vehicle, presence/absence of a contaminated place.

Abstract: An intensity modulated radio therapy (IMRT) dosimeter measuring a three-dimensional absorption dose distribution in a transparent plastic phantom readily and accurately. In the IMRT dosimeter, radiation beams are directed to a phantom assembly having a scintillation fiber block sandwiched between two blocks of the phantom. As an intensity of light proportional to the radiation beam is emitted from one side of the scintillation fiber block, its profile is measured by an image sensor. Then, the three-dimensional absorption dose distribution is obtained from the light intensity distribution data. By summing the three-dimensional absorption dose distribution data measured with the radiation beam at different angles, an integrated three-dimensional absorption dose distribution in the phantom can be calculated readily and accurately.

Abstract: An IMRT dosimeter is capable of measuring a three-dimensional absorption dose distribution in a transparent plastic phantom (202a) readily and accurately. In the IMRT dosimeter, radiation beams (201a, 201b) are directed to a phantom assembly having a scintillation fiber block (204a) sandwiched between two blocks of the phantom (202a). As an intensity of light proportional to the radiation beam is emitted from one side of the scintillation fiber block (204a), its profile is measured by an image sensor (205). Then, the three-dimensional absorption dose distribution is obtained from the light intensity distribution data. By summing the three-dimensional absorption dose distribution data measured through the radiation beam at different angles, an integrated three-dimensional absorption dose distribution in the phantom (202a) can be calculated readily and accurately.