An analyzer device can receives a pulse from a photosensor, obtain an initial calculated area under a curve representing the pulse, and obtain a recalculated area under the curve representing the pulse. In an embodiment, the initial calculated area and the recalculated area can base obtained via initial and subsequent integrations, respectively. The initial and subsequent integrations can be performed for different integration time periods. The subsequent integration may allow for the pulse height resolution to be determined more accurately.

An active matrix substrate includes a photoelectric conversion element, an electrode provided on at least one main surface of the photoelectric conversion element, and a first inorganic film covering a side surface of the photoelectric conversion element. The electrode includes an extending section covering the side surface of the photoelectric conversion element through intermediation of the first inorganic film.

An active matrix substrate includes a photoelectric conversion element 12, a first planarizing film 107, a first inorganic insulating film 108a, and a bias wire 16. The first planarizing film 107 covers the photoelectric conversion element 12 and has a first opening 107h at a position at which the first opening 107h overlaps with the photoelectric conversion element 12 in plan view. The first inorganic insulating film 108a has a second opening on an inner side of the first opening h and covers a surface of the first planarizing film 107. The bias wire 16 is provided on a first inorganic insulating film 108a and is connected to the photoelectric conversion element 12 via the second opening CH2.

A flexible DR detector assembly bendable along one axis and not bendable along a second axis is used with an x-ray source for radiographic imaging of a human anatomy, veterinary anatomy, or industrial equipment.

A radiation detector has a photoelectric conversion element array having a light receiving unit and a plurality of bonding pads; a scintillator layer stacked on the photoelectric conversion element array; a resin frame formed on the photoelectric conversion element array so as to pass between the scintillator layer and the bonding pads away from the scintillator layer and the bonding pads and so as to surround the scintillator layer; and a protection film covering the scintillator layer and having an outer edge located on the resin frame; a first distance between an inner edge of the resin frame and an outer edge of the scintillator layer is shorter than a second distance between an outer edge of the resin frame and an outer edge of the photoelectric conversion element array; the outer edge and a groove are processed with a laser beam.

A radiation detector includes a substrate, control lines provided on the substrate and extending in a first direction, data lines provided on the substrate and extending in a second direction crossing the first direction, and detection parts arranged in a matrix. Each detection part includes a thin film transistor and a conversion part converting radiation or light into electricity. Further, a control circuit switches an on state and an off state of each thin film transistor and a signal detection circuit reads out image data in the on state of the thin film transistor. Further, the detector judges a start time of radiation incidence based on a value of the image data read out in the on state of each thin film transistor.

Some embodiments include an imaging system. The imaging system can comprise: a scintillator structure; and an electronic device engaged with the scintillator structure, wherein: the scintillator structure can comprise: a scintillator support layer; and a scintillator layer; the scintillator support layer can comprise: a first substantially non-planar surface; a second substantially non-planar surface, the first substantially non-planar surface can be approximately parallel to the second substantially non-planar surface; and a scintillator support layer thickness greater than approximately 200 micrometers and less than or equal to approximately 300 micrometers; the scintillator layer can comprise: a first surface; a second surface opposite the first surface, the second surface being configured to scintillate; and one or more granular phosphor materials can comprise a diameter of greater than or equal to approximately 2 micrometers and less than or equal to approximately 30 micrometers; the first surface of the scintillator layer can be coupled to the second substantially non-planar surface of the scintillator support layer such that the second surface of the scintillator layer comprises a contour of the second substantially non-planar surface of the scintillator support layer; the electronic device can comprise a device substrate and one or more active sections; the device substrate can comprise a first surface and a second surface opposite the first surface of the device substrate; the one or more active sections are at the second surface of the device substrate; and the second surface of the device substrate and the one or more active sections can conform to the second surface of the scintillator layer. Other embodiments are described herein.

A radiation detection apparatus can include a scintillator to emit scintillating light in response to absorbing radiation; a photosensor to generate an electronic pulse in response to receiving the scintillating light; an analyzer to determine a characteristic of the radiation; and a housing that contains the scintillator, the photosensor, and the analyzer, wherein the radiation detection apparatus to is configured to allow functionality be changed without removing the analyzer from the housing. The radiation detection apparatus can be more compact and more rugged as compared to radiation detection apparatuses that include a photomultiplier tube.

A radiation detection apparatus can include a scintillator to emit scintillating light in response to absorbing radiation; a photosensor to generate an electronic pulse in response to receiving the scintillating light; an analyzer to determine a characteristic of the radiation; and a housing that contains the scintillator, the photosensor, and the analyzer, wherein the radiation detection apparatus to is configured to allow functionality be changed without removing the analyzer from the housing. The radiation detection apparatus can be more compact and more rugged as compared to radiation detection apparatuses that include a photomultiplier tube.

An X-ray detector, an X-ray photographing apparatus including the X-ray detector, and a method of manufacturing the X-ray detector are provided. The X-ray detector includes a photoconversion layer configured to convert an X-ray into light having a wavelength range that is different from a wavelength range of the X-ray, a sensing layer arranged on the photoconversion layer and including a plurality of pixels configured to output the light as an electrical signal, a protective layer arranged on the sensing layer and protecting the sensing layer from physical shocks, and an anti-static layer arranged on the protective layer and preventing an electrostatic charge from being introduced into the sensing layer.