Abstract: Provided is a method for acquiring information relating to a composition of a detected object from results of a measurement, using radiation, this method including: a step for acquiring by a computer a result of measuring the detected object using radiation; a step for estimating by a computer a chemical composition ratio of the detected object, using an equation that contains a value derived from the measurement result as a constant and contains a value derived from the chemical composition ratio of the detected object as a variable, and then solving the equation; and a step for outputting the estimated chemical composition ratio or a physical property value acquired based on the estimated chemical composition ratio as information relating to the composition of the detected object.

Abstract: A computing device configured to obtain information about a subject using a detection result detected by an X-ray detector which detects an X-ray passing through the subject, which device includes: a unit configured to obtain a detection result of the X-ray detector; a first obtaining unit configured to obtain a complex refractive index of the X-ray after passing through the subject using the detection result; and a second obtaining unit configured to obtain information about the subject in accordance with a correlation between the complex refractive index and a mass absorption coefficient.

Abstract: A computing device configured to obtain information about a subject using a detection result detected by an X-ray detector which detects an X-ray passing through the subject, which device includes: a unit configured to obtain a detection result of the X-ray detector; a first obtaining unit configured to obtain a complex refractive index of the X-ray after passing through the subject using the detection result; and a second obtaining unit configured to obtain information about the subject in accordance with a correlation between the complex refractive index and a mass absorption coefficient.

Abstract: A computing device configured to obtain information about a subject using a detection result detected by an X-ray detector which detects an X-ray passing through the subject, which device includes: a unit configured to obtain a detection result of the X-ray detector; a first obtaining unit configured to obtain a complex refractive index of the X-ray after passing through the subject using the detection result; and a second obtaining unit configured to obtain information about the subject in accordance with a correlation between the complex refractive index and a mass absorption coefficient.

Abstract: Provided is a method for acquiring information relating to a composition of a detected object from results of a measurement, using radiation, this method including: a step for acquiring by a computer a result of measuring the detected object using radiation; a step for estimating by a computer a chemical composition ratio of the detected object, using an equation that contains a value derived from the measurement result as a constant and contains a value derived from the chemical composition ratio of the detected object as a variable, and then solving the equation; and a step for outputting the estimated chemical composition ratio or a physical property value acquired based on the estimated chemical composition ratio as information relating to the composition of the detected object.

Abstract: An apparatus for deriving X-ray absorbing and phase information comprises; a splitting element for splitting spatially an X-ray, a detector for detecting intensities of the X-rays transmitted through an object, the intensity of the X-rays changing according to X-ray phase and also position changes, and an calculating unit for calculating an X-ray transmittance image, and an X-ray differential phase contrast or phase sift contrast image as the phase information. The X-ray is split into two or more X-rays having different widths, and emitted onto the detector unit. And, the calculating unit calculates the X-ray absorbing and phase information based on a difference, between the two or more X-rays, in correlation between the changing of the phase of the X-ray and the changing the intensity of the X-ray in the detector unit.

Abstract: A computing device configured to obtain information about a subject using a detection result detected by an X-ray detector which detects an X-ray passing through the subject, which device includes: a unit configured to obtain a detection result of the X-ray detector; a first obtaining unit configured to obtain a complex refractive index of the X-ray after passing through the subject using the detection result; and a second obtaining unit configured to obtain information about the subject in accordance with a correlation between the complex refractive index and a mass absorption coefficient.

Abstract: An X-ray imaging apparatus and an imaging method capable of acquiring an image of a test object associated with a phase shift in consideration of X-ray absorption is provided. A splitting element configured to spatially split an X-ray into multiple X-ray beams is provided. A shielding unit including a plurality of shielding elements configured to block part of an X-ray acquired by the splitting element is provided. Part of X-ray beams detected at the first detection pixels is blocked by the shielding elements. The X-ray beams detected by the second detection pixels adjoining the first detection pixels are not blocked by the shielding elements.

Abstract: An X-ray imaging apparatus and an X-ray imaging method for use in the X-ray imaging apparatus are provided. The X-ray imaging apparatus includes a separating element configured to spatially separate an X-ray generated by an X-ray generator unit and a scintillator array including a plurality of first scintillators arranged therein, where the separated X-rays are made incident on the first scintillators. Each of the first scintillators is configured to vary an intensity of fluorescence induced by the X-ray in accordance with an incident position of the X-ray. The X-ray imaging apparatus further includes a detector configured to detect the intensity of fluorescence emitted from the scintillator array.

Abstract: The present invention provides an X-ray device and an X-ray measurement method which can acquire a scattering contrast image of an object. The X-ray device includes a detector including a first pixel and a second pixel and an attenuation element which is provided on the second pixel and attenuates intensity of an X-ray beam. The X-ray device also includes an arithmetic device that calculates a pixel value of a scattering contrast of the object from detection intensity of the X-ray beam detected by the first pixel and detection intensity of the X-ray beam detected by the second pixel.

Abstract: The invention provides an X-ray apparatus and an X-ray measurement method that can increase sensitivity to a positional shift of an X-ray as compared with related art. An X-ray apparatus includes a splitting element configured to spatially split an X-ray from an X-ray generator and form an X-ray beam; a detector configured to detect an intensity of the X-ray beam, which has been split by the splitting element and has passed through a detection object, the detector including a plurality of pixels; and an absorbing element arranged at a boundary of two pixels from among the plurality of pixels included in the detector and configured to absorb part of the X-ray beam. The X-ray beam is configured to discretely irradiate the two pixels of the detector.

Abstract: An X-ray apparatus and an X-ray measuring method which are capable of obtaining object information including information about scattering of X-rays by an object are provided. The X-ray apparatus includes a detector configured to detect an intensity of an X-ray beam passed through an object. The detector includes a first pixel and a second pixel different from the first pixel. The apparatus is configured such that when the object is not disposed in an optical path of the X-ray beam, the center of an intensity distribution of the X-ray beam applied to the detector does not coincide with a boundary between the first and second pixels.

Abstract: The invention is aimed to provide an X-ray imaging apparatus and the like ensuring a sufficient range of detecting the amount of X-ray movement with respect to the pixel size of a detector in comparison with the method disclosed in International Publication No. WO2008/029107. The X-ray imaging apparatus of the present invention has a splitting element which spatially linearly splits an X-ray beam; and a shielding unit which shields a part of the X-ray beam which is split by the splitting element and whose position is changed by a test object. The shielding unit has a region transmitting X-rays and a region having a shielding element shielding (blocking) X-rays. A dividing line between the X-ray transmitting region and the region having the shielding element is configured to be arranged obliquely so as to cross the linearly split X-ray beam.

Abstract: To provide an X-ray imaging apparatus capable of easily adjusting the sensitivity or capable of easily extracting the amount of refraction of X-rays. An X-ray imaging apparatus irradiating an object to be measured with an X-ray beam from an X-ray source that generates X-rays of a first energy and X-rays of a second energy different from the first energy to measure an image of the object to be measured includes an attenuator and a detector. The attenuator attenuates the X-ray beam transmitted through the object to be measured and is configured so as to vary the amount of attenuation of the X-rays depending on a position on which the X-ray beam is incident. The detector detects the X-ray beam transmitted through the attenuator and is configured so as to detect the X-rays of the first energy and the second energy.

Abstract: An X-ray imaging apparatus acquiring a differential phase contrast image of a test object without using a light-shielding mask for X-ray. The apparatus includes an X-ray source, a splitting element configured to spatially divide an X-ray emitted from an X-ray source and a scintillator configured to emit light when a divided X-ray beam divided at the splitting element is incident on the scintillator. The apparatus also includes a light-transmission limiting unit configured to limit transmitting amount of the light emitted from the scintillator and a plurality of light detectors each configured to detect the amount of light that has transmitted through the light-transmission limiting unit. The light-transmission limiting unit is configured such that a light intensity detected at each of the light detectors changes in response to a change in an incident position of the X-ray beam.

Abstract: There is provided a glass composition containing an oxide containing Lu, Si, and Al, in which the composition of the glass composition lies within a compositional region of a ternary composition diagram of Lu, Si, and Al in terms of cation percent, the compositional region being defined by the following six points: (32.3% LuO3/2, 30.0% SiO2, 37.7% AlO3/2), (32.3% LuO3/2, 37.7% SiO2, 30.0% AlO3/2), (20.8% LuO3/2, 55.0% SiO2, 24.2% AlO3/2), (10.0% LuO3/2, 45.0% SiO2, 45.0% AlO3/2), (20.8% LuO3/2, 24.2% SiO2, 55.0% AlO3/2), and (30.0% LuO3/2, 25.0% SiO2, 45.0% AlO3/2). For the glass composition, a glassy state having low or no intrinsic birefringence in the ultraviolet region is stably obtained.

Abstract: Provided is an X-ray imaging apparatus and an X-ray imaging method that offer an alternative for a refraction contrast method. A first scintillator and a second scintillator are used, the first scintillator generating first fluorescent light when X-rays separated by the separating element are incident thereon, and a second scintillator generating second fluorescent light when X-rays separated by the separating element are incident thereon. The second scintillator has a fluorescence emission intensity gradient such that an amount of emitted fluorescent light changes in accordance with a change in a position at which the X-rays are incident.

Abstract: Provided is an X-ray imaging apparatus and a method of X-ray imaging, with which the apparatus can be reduced in size and a with which differential phase image or a phase image with consideration of an X-ray absorption effect of an object can be obtained. A displacement of X-rays that have been split by a splitting element and have passed through an object is measured. The displacement can be measured by using a first attenuation element having a transmission amount that continuously changes in accordance with the incident position of X-rays. At this time, an X-ray transmittance of an object that is calculated by using a second attenuation element having a transmission amount that does not change in accordance with the incident position of X-rays is used.

Abstract: Provided is an X-ray imaging apparatus and a method of X-ray imaging, with which the apparatus can be reduced in size and a differential phase image or a phase image with consideration of an X-ray absorption effect of an object can be obtained. X-rays are spatially split, and a first attenuation element in which the transmission amount of X-rays continuously changes in accordance with the displacement when the X-rays pass through an object is used. Transmittance is calculated by using the first attenuation element and a second attenuation element that is different from the first attenuation element with respect to an amount of change or a characteristic of change in the transmission amount of X-rays in a direction of a displacement of the X-rays. A differential phase image and the like of the object are calculated using the transmittance.

Abstract: An X-ray imaging apparatus for obtaining information on a phase shift of an X-ray caused by an object comprises: an splitting element for splitting spatially an X-ray emitted from an X-ray generator unit into X-ray beams; an attenuator unit having an arrangement of attenuating elements for receiving the X-ray beams split by the splitting element; and an intensity detector unit for detecting intensities of X-ray beams attenuated by the attenuator unit; and the attenuating element changing continuously the transmission amount of the X-ray depending on the X-ray incident position on the element.