Abstract: An amplification optical fiber operable to propagate light beams in a plurality of modes in a predetermined wavelength range through a core doped with a rare earth element, wherein Expression (1) is satisfied, where a cutoff wavelength of a propagated highest mode light beam is defined as ?max, under conditions in which the cutoff wavelength of the highest mode light beam is defined as ?c, a shortest wavelength of the wavelength range is defined as ?min, and a cutoff wavelength of a second-highest mode light beam to the highest mode light beam is ?min. ?c>0.5 ?min+0.

Abstract: Heating an oil from a plant or animal while supplying oxygen at a dissolved oxygen supply speed of not less than 0.058 mg/L/min to the oil from plant or animal is a convenient production method of a material for food or drink, which is capable of imparting an aroma and/or a flavor, which are/is mellow and rich in variety, to a food or drink.

Abstract: An imaging device includes an imaging-lens, an image-sensor, a lens-moving-mechanism, a ROM, and an intersection-point-position-control-section. The lens-moving-mechanism moves an intersection point on the image-sensor by moving a second lens in a plane perpendicular to an optical axis. The ROM stores, in advance, a LUT that stores the intersection point and an image quality evaluation value of an image, which is obtained through image capturing performed at the intersection point, in association with each other. The intersection-point-position-control-section acquires the current intersection point, calculates distances between the current intersection point and the plurality of intersection points stored in the LUT, and selects an intersection point for imaging, at which a ratio of the image quality evaluation value to the distance from the current intersection point is at the maximum, among the positions of the plurality of intersection points stored in the LUT.

Abstract: A plurality of cores 51 is disposed around the center axis of a first cladding 52 in a state in which an inter-core distance ? of cores adjacent to each other is equal, a refractive index n1 of the core 51 is provided higher than a refractive index n2 of the first cladding 52, and the refractive index n2 of the first cladding 52 is provided higher than a refractive index n3 of a second cladding 53. Moreover, 5.8??/MFD(2?c/(?c+?op))?8 is satisfied, where the inter-core distance is defined as ?, a mode field diameter of the core is defined as MFD, a cutoff wavelength is defined as ?c, and a wavelength of communication light incident on the core 51 is defined as ?op.

Abstract: An optical fiber for amplification includes a core having an inner core and an outer core surrounding the outer circumferential surface of the inner core. The relative refractive index difference of the inner core to a cladding is smaller than the relative refractive index difference of the outer core to the cladding. The outer core is entirely doped with erbium. The theoretical cutoff wavelength of an LP11 mode light beam is a wavelength of 1,565 nm or more. The theoretical cutoff wavelength of an LP21 mode light beam is a wavelength of 1,530 nm or less. The theoretical cutoff wavelength of the LP02 mode light beam is a wavelength of 980 nm or less.

Abstract: In one embodiment, a set of training data consisting of inliers may be obtained. A supervised classification model may be trained using the set of training data to identify outliers. The supervised classification model may be applied to generate an anomaly score for a data point. It may be determined whether the data point is an outlier based, at least in part, upon the anomaly score.

Abstract: An organic EL element (1) according to the present invention is such that a positive and negative charge transport layer (30) is interposed between a cathode (20) and an anode (10). The positive and negative charge transport layer (30) is composed of a single host material and has a light-emitting region (33) which is doped with a light-emitting dopant. The positive and negative charge transport layer (30) further has at least one of the following blocking regions: an electron blocking region (32), provided closer to the anode (10) than the light-emitting region (33), having a lowest unoccupied molecular orbital lower than that of the lowest unoccupied molecular orbital of the light-emitting region (33); and a hole blocking region (34), provided closer to the cathode (20) than the light-emitting region (33), having a highest occupied molecular orbital higher than that of the highest occupied molecular orbital of the light-emitting region (33).

Abstract: Detection of one or more transition events.

Abstract: Provided are a barrier laminate, a gas barrier film including the barrier laminate, and a device including the gas barrier film. The barrier laminate includes an inorganic layer and a first organic layer, in which the inorganic layer and the first organic layer are in direct contact with each other, the first organic layer is formed by curing a polymerizable composition containing a polymerizable compound, a polymerization initiator, and a silane coupling agent represented by the following Formula (1) (in Formula (1), R2 represents a halogen element or an alkyl group, R3 represents a hydrogen atom or an alkyl group, L represents a divalent linking group, and n represents an integer of 0 to 2), the first organic layer contains titanium oxide fine particles, and the inorganic layer is formed on a surface of the first organic layer using a chemical vapor deposition method. The barrier laminate has high barrier properties and transparency.

Abstract: A novel method and/or system of feature selection is described.

Abstract: An imaging device includes an imaging-lens, an image-sensor, a lens-moving-mechanism, a ROM, and an intersection-point-position-control-section. The lens-moving-mechanism moves an intersection point on the image-sensor by moving a second lens in a plane perpendicular to an optical axis. The ROM stores, in advance, a LUT that stores the intersection point and an image quality evaluation value of an image, which is obtained through image capturing performed at the intersection point, in association with each other. The intersection-point-position-control-section acquires the current intersection point, calculates distances between the current intersection point and the plurality of intersection points stored in the LUT, and selects an intersection point for imaging, at which a ratio of the image quality evaluation value to the distance from the current intersection point is at the maximum, among the positions of the plurality of intersection points stored in the LUT.

Abstract: The first cladding 52 has a two-layer structure formed of a solid inner layer 62A passed through the center axis of the first cladding 52 and an outer layer 62B enclosing the inner layer 62A and the plurality of cores 51 with no gap. A refractive index n1 of the core 51 is provided higher than refractive indexes n2A and n2B of the inner layer 62A and the outer layer 62B, the refractive indexes n2A and n2B of the inner layer 62A and the outer layer 62B are provided higher than a refractive index n3 of the second cladding 53, and the refractive index n2A of the inner layer 62A is provided lower than the refractive index n2B of the outer layer 62B.

Abstract: A plurality of cores 51 is disposed around the center axis of a first cladding 52 in a state in which an inter-core distance ? of cores adjacent to each other is equal, a refractive index n1 of the core 51 is provided higher than a refractive index n2 of the first cladding 52, and the refractive index n2 of the first cladding 52 is provided higher than a refractive index n3 of a second cladding 53. Moreover, 5.8??/MFD(2?c/(?c+?op))?8 is satisfied, where the inter-core distance is defined as ?, a mode field diameter of the core is defined as MFD, a cutoff wavelength is defined as ?c, and a wavelength of communication light incident on the core 51 is defined as ?op.

Abstract: The first cladding 52 has a two-layer structure formed of a solid inner layer 62A passed through the center axis of the first cladding 52 and an outer layer 62B enclosing the inner layer 62A and the plurality of cores 51 with no gap. A refractive index n1 of the core 51 is provided higher than refractive indexes n2A and n2B of the inner layer 62A and the outer layer 62B, the refractive indexes n2A and n2B of the inner layer 62A and the outer layer 62B are provided higher than a refractive index n3 of the second cladding 53, and the refractive index n2A of the inner layer 62A is provided lower than the refractive index n2B of the outer layer 62B.

Abstract: A lighting device includes an LED light source that emits light having a first peak wavelength in a range from 200 to 470 nm and a second peak wavelength in a range from 460 to 700 nm. An emission intensity at the second peak wavelength is greater than an emission intensity at the first peak wavelength, and an emission intensity at a wavelength band of 720 nm or greater is one tenth or less than an emission intensity at the second peak wavelength.

Abstract: A signal processing device processes a plurality of observed signals at a plurality of frequencies. The plurality of the observed signals are produced by a plurality of sound receiving devices which receive a mixture of a plurality of sounds. In the signal processing device, a storage stores observed data of the plurality of the observed signals. The observed data represents a time series of magnitude of each frequency in each of the plurality of the observed signals. An index calculator calculates an index value from the observed data for each of the plurality of the frequencies. The index value indicates significance of learning of a separation matrix using the observed data of each frequency. The separation matrix is used for separation of the plurality of the sounds from each other at each frequency. A frequency selector selects one or more frequency according to the index value of each frequency.

Abstract: An information processing apparatus may generate resource information used for playing back image content that can be divided into a plurality of zones. The information processing apparatus may include an image generator generating a still image from each of the plurality of zones, a face processor setting each of the plurality of zones to be a target zone and determining whether a face of a specific character which is determined to continuously appear in at least one zone before the target zone is contained in the still image generated from the target zone, and an information generator specifying, on the basis of a determination result obtained for each of the plurality of zones by the face processor, at least one zone in which the face of the specific character continuously appears as a face zone, and generating information concerning the face zone as one item of the resource information.

Abstract: A lighting device includes an LED light source that emits light having a first peak wavelength at 430 to 460 nm and a second peak wavelength at 530 to 570 nm.

Abstract: In a plant growing system, a first light source irradiates a plant with light having a peak wavelength in a range from 380 to 560 nm and a peak wavelength in a range from 560 to 680 nm and a second light source irradiates the plant with far-red light having a peak wavelength in a range from 685 to 780 nm. Further, a control unit controls the first and the second light source to perform respective irradiation operations and a time setting unit sets a first and a second time zone in which the control unit controls the first and the second light source to perform the respective irradiation operations. The first time zone ranges from a first predetermined time before sunset to a second predetermined time after sunset, and the second time zone starts after the first light source completes its irradiation operation.

Abstract: Provided are an image display device in which a desired number of panels are combined so that a large light-emitting surface is realized, a panel provided in the image display device, and a method for manufacturing the panel. For this purpose, a panel (11) of the present invention includes a rectangular light-emitting section (13); a substrate (12) having a flat surface (12a?) on which the rectangular light-emitting section (13) is provided and a curved adjacent surface (12b?) that is adjacent to one of edge portions of the flat surface which extend along long sides of the rectangular light-emitting section (13); and a terminal group that is drawn out from a long side of the rectangular light-emitting section (13) and that is disposed in the adjacent surface.