Abstract: A radiographic apparatus includes a radiation detection panel configured to detect radiation, and a housing that covers the radiation detection panel. The housing includes an incident surface receiving the radiation, a side surface adjacent to the incident surface, a rear surface opposing the incident surface, and an inclined surface adjacent to each of the side surface and the rear surface. A recessed handle portion is provided on the inclined surface.

Abstract: Pixel array includes pixels each including conversion element, and switch having control terminal, first primary terminal connected to the conversion element, and second primary terminal connected to one of signal lines. The pixel array includes pixel groups each including pixels arrayed to form at least 2 row×2 column pattern. In pixels of each pixel group, the control terminals are connected to different driving lines and the second primary terminals are commonly connected to one of the signal lines. In the pixel groups, first and second pixel groups are arranged adjacent to each other in column direction. Signal is read from the first pixel group via the first signal line of the single lines. Signal is read from the second pixel group via the second signal line of the single lines.

Abstract: Provided is a field shaping multi-well photomultiplier and method for fabrication thereof. The photomultiplier includes a field-shaping multi-well avalanche detector, including a lower insulator, an a-Se photoconductive layer and an upper insulator. The a-Se photoconductive layer is positioned between the lower insulator and the upper insulator. A light interaction region, an avalanche region, and a collection region are provided along a length of the photomultiplier, and the light interaction region and the collection region are positioned on opposite sides of the avalanche region.

Abstract: Disclosed herein is an apparatus suitable for detecting X-ray. The apparatus may comprise an X-ray absorption layer, an electronics layer and a distribution layer. The X-ray absorption layer may comprise a first plurality of electric contacts and configured to generate electrical signals on the first plurality of electric contacts from X-ray incident on the X-ray absorption layer. The electronics layer may comprise a second plurality of electric contacts and an electronic system, wherein the electric system electrically connects to the second plurality of electric contacts and is configured to process or interpret the electrical signals. The first plurality of electric contacts and the second plurality of electric contacts have different spatial distributions. The distribution layer is configured to electrically connect the first plurality of electric contacts to the second plurality of electric contacts.

Abstract: A photo-detection device includes a quench resistor having one terminal connected to a first node, an avalanche photodiode having one terminal connected to a second node, a waveform shaping circuit having an input terminal connected to the other terminal of the quench resistor and the other terminal of the avalanche photodiode, and a switch arranged on a path between the second node and the input terminal of the waveform shaping circuit.

Abstract: A semiconductor radiation monitor (i.e., dosimeter) is provided that has an oxide charge storage region located on a first side of a semiconductor fin and a functional gate structure located on a second side of the semiconductor fin that is opposite the first side. Charges are created in the oxide charge storage region that is located on the first side of the semiconductor fin and detected on the second side of the semiconductor fin by the functional gate structure. Multiple semiconductor fins in parallel can form a dense and very sensitive semiconductor radiation monitor.

Abstract: Examples of systems and methods for monitoring metabolic activity and detectors for detecting photons are disclosed. The methods can include detection in a front and a rear detector of a photon to determine a Compton cone. This Compton cone may be combined with further Compton cone, or Line of Response calculation to determine an origin of nuclear decay. In examples of the systems and methods, substantially real-time visualization of nuclear decay can be achieved.

Abstract: In a radiographing apparatus, a buffer material is arranged between a support base and a side wall portion to which an incidence surface (first surface) of a casing that is positioned on an incident side of radiation R, and a back surface (second surface) of the casing that is opposite to the incidence surface are bonded, the support base is provided with a first protruding portion protruding toward the back surface, the casing is provided with a second protruding portion protruding from the back surface toward the support base, and the following relationship is satisfied: distance X<distance Y, where a distance between the buffer material and the support base is a distance X, and a distance between the first protruding portion of the support base and the second protruding portion of the casing is a distance Y.

Abstract: An edge incident type light receiving element unit capable of receiving optical signals in different wavelength ranges incident from the edge side comprises a first light receiving element for receiving optical signals in a first wavelength range and a second light receiving element for receiving optical signals in a second wavelength range, and configured so that optical signals transmitted through a first light receiving portion formed vertically on a wall portion of a first semiconductor substrate incident via a reflecting portion on a second light receiving portion formed on a second semiconductor substrate fitted on the first semiconductor substrate.

Abstract: An active matrix substrate includes a TFT. The TFT includes a gate electrode, a semiconductor layer overlapping the gate electrode with a gate insulating film interposed therebetween, and a source electrode and a drain electrode disposed on the semiconductor layer. The source electrode, the drain electrode, and the semiconductor layer are covered with a first insulating film. The gate insulating film includes a first stepped portion in a portion covering a peripheral portion of the gate electrode. The first insulating film includes a first opening at a position overlapping a portion of the first stepped portion that is not covered with the source electrode and the drain electrode in a plan view.

Abstract: 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.

Abstract: A radiation detector (1a), which is configured to suitably separate information of a low energy component and information of a high energy component of radiation, includes: a sensor panel (2), which includes a plurality of first photoelectric conversion element portions (23) and second photoelectric conversion element portions (24), which are arranged two-dimensionally; a first scintillator (31) arranged to overlap one surface of the sensor panel (2); a second scintillator (32) arranged to overlap a surface on a side opposite to the one surface of the sensor panel (2); and a light shielding portion (26) arranged outside an effective pixel region (22), in which the plurality of the plurality of first photoelectric conversion element portions (23) and second photoelectric conversion element portions (24) are arranged, and between the first scintillator (31) and the second scintillator (32).

Abstract: Described herein are photon counting devices comprising direct mode detectors with improved signal to noise ratios which are suitable for use in X-ray imaging devices, and other imaging devices.

Abstract: The disclosed method enables estimating an initial point of interaction of an x-ray photon in a photon-counting x-ray detector, based on a number of x-ray detector sub-modules or wafers, each including detector elements. The x-ray detector sub-modules are oriented in edge-on geometry with the edge directed towards the x-ray source, assuming the x-rays enter through the edge. Each detector sub-module or wafer has a thickness with two opposite sides of different potentials to enable charge drift towards the side, where the detector elements, also referred to as pixels, are arranged. Basically, the method includes: determining an estimate of charge diffusion originating from a Compton interaction or an interaction through photoeffect related to the x-ray photon in a detector sub-module or wafer of the x-ray detector; and estimating the initial point of interaction along the thickness of the detector sub-module based on the determined estimate of charge diffusion.

Abstract: A radiation imaging apparatus includes a pixel array arranged with a plurality of pixels including conversion units configured to convert radiation into charges and accumulate the charges, a bias line connected to the conversion units of the plurality of pixels, a bias circuit configured to supply a bias potential to the bias line and detect a current flowing in the bias line, a noise reduction circuit configured to reduce, separately from the bias circuit, noise included in the bias potential from the bias circuit, and a switch configured to connect the noise reduction circuit to the bias line.

Abstract: Illustrative embodiments are directed to a method and apparatus for evaluating boundary detection in an image. A processed image is received, wherein a detected boundary of an image of an object is identified in the processed image. A Radon transform is applied to the processed image for a plurality of angles to form a processed image histogram corresponding to the detected boundary for each of the plurality of angles. The processed image histogram for each of the plurality of angles and a corresponding ground truth histogram for each of the plurality of angles is normalized to provide a normalized processed image histogram and a normalized ground truth histogram for each of the plurality of angles, wherein the ground truth histogram corresponds to a ground truth boundary of the object for a corresponding angle. An indication of the edges of the normalized processed image histogram for each of the plurality of angles is plotted to form a boundary detection evaluation visualization.

Abstract: An edge-on photon-counting detector includes at least one detector module having a respective edge facing incident X-rays. The at least one detector module includes a semiconductor substrate. The edge-on photon-counting detector also includes a plurality of active integrated pixels arranged in the semiconductor substrate.

Abstract: The invention relates to radiation detector for registering incident photons, comprising (i) detection circuitry (202, 206, 207) configured to provide an electric output signal in response to incident photons, the output signal comprising pulses having an amplitude indicative of energies deposited in the radiation detector by the incident photons, and (ii) an energy estimating circuit (2081, . . . , 208N; 2091, . . . , 209N) configured to detect that the output signal is larger than at least one threshold corresponding to an energy value in order to determine energies of incident photons. The radiation detector further comprises a registration circuit (211) configured to detect incident photons independent of a comparison of the output signal with the at least one threshold. Moreover, the invention relates to a method for detecting photons using the radiation detector.

Abstract: Monolithic CMOS integrated pixel detector (10, 20, 30, 260, 470, 570), and systems and methods are provided for the detection and imaging of electromagnetic radiation with high spectral and spatial resolution. Such detectors comprise a Si wafer with a CMOS processed readout bonded to an absorber wafer in an electrically conducting covalent wafer bond. The pixel detectors, systems and methods are used in various medical and non-medical types of applications.

Abstract: In accordance with some embodiments, a method is performed at an image processing device with a processor and non-transitory memory. The method includes triggering light emission, over a first emission duration, having a characterizing intensity as a function of time. The method further includes obtaining respective pixel events, from an event camera, corresponding to reflections of the light emission during the first emission duration, each respective pixel event corresponding to a breach of a respective comparator threshold indicative of a brightness level, each respective pixel event characterized by a respective electrical threshold value and a timestamp at which the respective electrical threshold value was breached.

Abstract: Disclosed herein is an apparatus suitable for detecting X-ray, comprising: an X-ray absorption layer comprising an electrode; an electronics layer, the electronics layer comprising: a substrate having a first surface and a second surface, an electronics system in or on the substrate, an electric contact on the first surface, and a first via extending from the first surface toward the second surface; wherein the electrode is electrically connected to the electric contact; wherein the electronics system comprises a controller connected in series with and between the electric contact and the first via.

Abstract: The present invention relates to a CT imaging system as well as a method for CT imaging is provided. For CT imaging, in practice a scout scan and a main scan of a human subject may be performed. It has been found that a detector signal, provided by a detector which detects the X-ray radiation during the scout scan, may be used on the one hand for determining a respective scout image and on the other hand to determine the bone mineral density of the human subject. Although the scout scan is usually primarily performed for determining the scout image, it is of advantage, if the detector used for detecting the X-ray radiation during the scout scan is formed and/or configured to detect X-ray radiation of a first energy spectrum and to detect X-ray radiation of a different, second energy spectrum. In this case, the detector can provide more precise information about the scout region of the human subject and resulting therefrom in a more precise determination of the bone mineral density.

Abstract: Disclosed herein is a system comprising: a first X-ray detector in a first layer; a second X-ray detector in a second layer; wherein the first X-ray detector comprises a first X-ray absorption layer and a first electronics layer; wherein the second X-ray detector comprises a second X-ray absorption layer and a second electronics layer; wherein the first X-ray detector is mounted to a first surface of a first printed circuit board; wherein the second X-ray detector is mounted to a first surface of a second printed circuit board, or to a second surface of the first printed circuit board opposite to the first surface of the first printed circuit board; wherein gaps in the second X-ray absorption layer are shadowed by the first X-ray absorption layer.

Abstract: The disclosure relates to spectroscopic sensors of ionizing radiation, and the use of an application specific integrated circuit to detect both positive features in a pixel anode signal indicative of ionizing radiation interacting with that pixel, and negative features indicative of ionizing radiation interacting in an adjacent or proximal pixel. For this purpose, both positive and negative peak hold circuits may be provided in each ASIC pixel circuit.

Abstract: A control unit of an electronic cassette has a function of switching a power supply state to an ADC between an operating state corresponding to a first state in which first power is supplied and a non-operating state corresponding to a second state in which second power that is lower than the first power per unit time is supplied. The control unit reduces the number of ADCs in the operating state per unit time T in an AED operation for detecting the start of the emission of X-rays to be less than that in an image reading operation for outputting an X-ray image provided for diagnosis.

Abstract: A gamma-ray image acquisition device (1) acquires the direction and energy of a target scattered gamma-ray generated by Compton scattering of an incident gamma-ray and acquires the direction and energy of a recoil electron. These pieces of information are used to acquire the incident direction and energy of the incident gamma-ray. The gamma-ray image acquisition device (1) acquires a two-dimensional image by imaging spectroscopy based on the incident directions and energies of a plurality of incident gamma-rays, the two-dimensional image being an image in which each pixel corresponding to each incident direction includes energy distribution information. In the two-dimensional image, the area and the solid angle of an imaging range are proportional to each other. This enables acquiring the distribution of gamma-ray intensities without depending on distance and thereby acquiring an image that indicates more useful information than conventional images.

Abstract: Provided is an X-ray imaging panel in which leakage current can be reduced, and a method for producing the same. An imaging panel 1 generates an image based on scintillation light that is obtained from X-rays transmitted through an object. The imaging panel 1 includes a photoelectric conversion layer 15 that converts scintillation light into charges, on a substrate. The photoelectric conversion layer 15 has a polygonal shape having a plurality of corner portions 15p when viewed in a plan view. Each of the corner portions 15p has a plurality of corners each of which has an interior angle of greater than 90°.

Abstract: An image processing apparatus includes: an acquisition unit that acquires a radiographic image generated by a radiation detector irradiated with radiation from a radiography apparatus including the radiation detector in which plural pixels, each of which includes a conversion element that generates a larger amount of charge as it is irradiated with a larger amount of radiation, are arranged; and a correction unit that corrects scattered ray components caused by scattered rays of the radiation included in the radiographic image, using correction data for correcting scattered rays which is associated with each of plural regions in the radiographic image.

Abstract: Some embodiments include an electronic device. The electronic device includes a first scintillator layer, a transistor, and one or more device elements over the transistor, and the one or more device elements include a photodetector. Meanwhile, the first scintillator layer is monolithically integrated with at least one of the transistor or the one or more device elements. Other embodiments of related systems, devices, and methods are also disclosed.

Abstract: A radiation detection device includes: a radiation detection panel; a housing in which the radiation detection panel is housed; a support member that is disposed between a surface of the radiation detection panel on a side opposite to a radiation incidence side and an inner surface of the housing; a plurality of columnar first protruding portions that are formed on a surface of the support member on an opposite side to a surface of the support member on a side of the radiation detection panel; and a second protruding portion that is formed at other region of the surface of the support member on the opposite side than regions of the surface of the support member on the opposite side at which the first protruding portions are formed as defined herein.

Abstract: An X-ray apparatus includes a mount, an X-ray source, a detector, an actuator, and a controller. The mount is configured to hold a sample. The X-ray source is configured to direct a beam of X-rays toward a first side of the sample. The detector is positioned on a second side of the sample, opposite the first side, so as to receive at least a portion of the X-rays that have been transmitted through the sample and to output signals indicative of an intensity of the received X-rays. The actuator is configured to scan the detector over a range of positions on the second side of the sample so as to measure the transmitted X-rays as a function of a scattering angle.

Abstract: A radiation image photographing apparatus includes a hardware processor that, at a time of a radiation image photographing process, repeats a reset process of releasing a charge from a radiation detecting element by sequentially applying an on-voltage from a scan driver to scan lines, until a radiation irradiation is started, provides a predetermined waiting time to cause all switches to wait in an off-state after the reset process and before the next reset process, transitions to a charge accumulation mode of accumulating the charge in the radiation detecting element by applying an off-voltage to all scan lines, in response to radiation irradiation start, and transitions to a reading mode of releasing the charge from the radiation detecting element by applying the on-voltage to the scan lines, and performing an image data reading process by converting the released charge into image data, when a predetermined accumulation time has elapsed.

Abstract: Provided is a photo detecting apparatus. The photo detecting apparatus includes a thin film transistor array on a first surface of a substrate having a specific light transmissivity and a photo diode structure between the first surface and the thin film transistor array. The photo diode structure is implemented to receive and process an electromagnetic radiation through a second surface of the substrate.

Abstract: The present invention relates to grating based Dark-Field and/or phase-contrast X-ray imaging. In order to improve the quality of an image, a radiography system (10) for grating based Dark-Field and/or phase-contrast X-ray imaging for imaging a patient by irradiating the patient is provided. The system comprises a source unit (12), a detection unit (14) and a patient support unit (16) with a patient abutting surface (18). The source unit (12) and the detection unit (14) are arranged along an optical axis (13) and the patient support unit (16) is arranged in between. Further, an abutting distance (dA) between the source unit (12) and the patient abutting surface (18) along the optical axis (13) is adaptable. The abutting distance (dA) and an actual sensitivity, based on the abutting distance (dA), are taken into account for imaging, such that a trade-off between sensitivity and field of view in a patient specific manner is achievable, e.g. the best trade-off.

Abstract: An optical member includes a light guide plate, a first low refractive layer, a wavelength conversion layer, and a passivation layer. The first low refractive layer is disposed on the light guide plate. A refractive index of the first low refractive layer is smaller than a refractive index of the light guide plate. The wavelength conversion layer is disposed on the first low refractive layer. The passivation layer is disposed on the wavelength conversion layer. The passivation layer covers a side surface of the wavelength conversion layer and a side surface of the first low refractive layer on at least one side.

Abstract: A phase contrast X-ray imaging system for imaging an object including an X-ray source; and an X-ray detector having a 25 micron or less pixel pitch; wherein a distance between the X-ray source and the object is less than or equal to 10 cm.

Abstract: In described examples, a charge sensitive amplifier (CSA) generates an integrated signal in response to a current signal. A high pass filter is coupled to the CSA and receives the integrated signal and an inverse of an event signal, the high pass filter generates a coarse signal. An active comparator is coupled to the high pass filter and receives the coarse signal and a primary reference voltage signal, the active comparator generates the event signal.

Abstract: A digital radiographic detector detects a first mode signal and dispositions a received digital image according to a procedure associated with the first mode signal. A second mode signal results in dispositioning a second received digital image according to a second image disposition procedure. The detector determines the first mode or second mode based on the signal's pulse width, a number and timing of rising edges (peaks), a digital code, a voltage level, or a combination thereof.

Abstract: A PET detector and method thereof are provided. The PET detector may include: a crystal array including a plurality of crystal elements arranged in an array and light-splitting structures set on surfaces of the plurality of crystal elements, the light-splitting structures jointly define a light output surface of the crystal array; a semiconductor sensor array, which is set in opposite to the light output surface of the crystal array and is suitable to receive photons from the light output surface, the semiconductor sensor array comprises a plurality of semiconductor sensors arranged in an array.

Abstract: The present disclosure relates to the field of the display technology and provides a display substrate and a manufacturing method thereof, a display panel, and a display apparatus. The manufacturing method of the display substrate includes forming an optical compensation control thin film transistor on a side of a base substrate; forming a conductor protective layer on a side of the optical compensation control thin film transistor facing away from the base substrate; forming an optical detecting device material layer on a side of the conductor protective layer facing away from the base substrate; forming an optical detecting device through patterning the optical detecting device material layer; and forming a conductor pattern layer through patterning the conductor protective layer; where, the optical detecting device is electrically connected with a source electrode or a drain electrode of the optical compensation control thin film transistor through the conductor pattern layer.

Abstract: An image sensor includes a substrate, a thin film transistor on the substrate, a dielectric layer over the thin film transistor, a stacked metal layer on and extending through the dielectric layer to the thin film transistor, a bulk heterojunction layer directly coupled to the stacked metal layer, either a hole transport layer directly coupled to the bulk heterojunction layer, and a top contact layer directly coupled to the hole transport layer, or a top contact layer directly coupled to the bulk heterojunction layer. The bulk heterojunction layer includes an electron donor/acceptor material, the hole transport layer includes a transparent conductive polymer material, and the top contact layer includes a transparent conductive material. The image sensor includes a moisture barrier layer directly coupled to the top contact layer, including an optically clear adhesive and a laminated transparent barrier film.

Abstract: An imaging system includes an input voltage setting unit that applies an input voltage to an Amp transistor, a setting output value acquisition unit that acquires a corresponding output for each pixel, and a calibration characteristic deriving unit that derives an input-output characteristic indicating a correspondence relationship between the input voltage and the output and derives a calibration characteristic to be used for calibration based on an inverse characteristic of the input-output characteristic.

Abstract: The present embodiment relates to a radiation detector having a structure enabling suppression of polarization in a thallium bromide crystalline body and suppression of corrosion of an electrode in the air. The radiation detector comprises a first electrode, a second electrode, and a thallium bromide crystalline body provided between the first and second electrodes. One of the first and the second electrodes includes an alloy layer and a low-resistance metal layer provide on the alloy layer. The alloy layer is comprised of an alloy of metallic thallium and another metal different from the metallic thallium. The low-resistance metal layer has a resistance value lower than a resistance value of the alloy layer and is electrically connected to a pad on a readout circuit while the radiation detector is mounted on the readout circuit.

Abstract: The present technology relates to an optical pulse detection device, an optical pulse detection method, a radiation counter device, and a biological testing device which are capable of performing radiation counting in a more accurate manner. The optical pulse detection device includes a pixel array unit in which a plurality of pixels are arranged in a two-dimensional lattice shape, an AD converter that converts output signals of each of the pixels in the pixel array unit into digital values with gradation greater than 1 bit, and an output control circuit that performs error determination processing of comparing the digital value with a predetermined threshold value, and discarding a digital value, which is greater than the threshold value, among the digital values as an error. For example, the present technology is applicable to a radiation counter device, and the like.

Abstract: The application relates to a media drawer for a media processing device with a housing and an electrically-driven lift table arranged in the housing, where the media drawer is movable between a first position, in which the media drawer is arranged in the media processing device in such a manner that media can be removed from the media drawer by the media processing device, and a second position, in which media can be inserted into the media drawer, where the lift table can be supplied with power in the first position by the power supply of the media processing device. Further, the media drawer can exhibit a power supply that is independent of the power supply of the media processing device, via which the lift table can be provided with power in the second position.

Abstract: Provided is a field shaping multi-well photomultiplier and method for fabrication thereof. The photomultiplier includes a field-shaping multi-well avalanche detector, including a lower insulator, an a-Se photoconductive layer and an upper insulator. The a-Se photoconductive layer is positioned between the lower insulator and the upper insulator. A light interaction region, an avalanche region, and a collection region are provided along a length of the photomultiplier, and the light interaction region and the collection region are positioned on opposite sides of the avalanche region.

Abstract: Bending a flexible x-ray detector to image a curved structure or object will distort the object appearance when compared to an image captured by a flat/rigid detector. An image distortion of this type can be corrected when the shape (relative bend position) of the x-ray detector is known. Incorporating strain sensors on the flexible x-ray detector makes it possible to record the local bend of the flexible x-ray detector when an image is taken. This shape information can be used to either label or correct for the image distortions created by bending the x-ray detector to assist users more accustomed to viewing images produced by flat/rigid x-ray detectors.

Abstract: The disclosed embodiments include an image sensor and a method to manufacture thereof. In one embodiment, the method includes forming a plurality of semiconductor slices having a uniform width, at least two of the semiconductor slices having different lengths, and each of the semiconductor slices having a slice edge defining a side of the semiconductor slice. The method further includes arranging the semiconductor slices to form a semi-rectangular shape defining boundaries of the image sensor, each of the semiconductor slices being disposed proximate to another semiconductor slice of the plurality of semiconductor slices. Forming each semiconductor slice includes forming a plurality of pixel arrays over the semiconductor slice, the pixel arrays having an approximately uniform pixel pitch, and forming a seal ring around the semiconductor slice, the seal ring enclosing the semiconductor slice and the pixel arrays of the semiconductor slice, and each semiconductor slice having a different seal ring.

Abstract: An inventive assembly method is for the production of an x-ray detector. In an embodiment, the method includes positioning a plurality of sensor surface elements, formed from an x-ray radiation-sensitive material, on an assembly carrier; placing an interposer on a contact side of each of the plurality of sensor surface elements, divided into a plurality of pixels and arranged opposite the assembly carrier, such that respective contact elements arranged on a mating contact side of the interposer, facing towards respective ones of the plurality of sensor surface elements, each contact a pixel; and respectively putting evaluation circuits on a circuit side of the interposer, opposite to the mating contact side of the interposer, for each of the plurality of sensor surface elements.

Abstract: A reference image of a patient may be generated. A subsequent x-ray image of the patient may be generated after the generating of the reference image where the subsequent x-ray image is associated with a low dosage. A difference between the reference image and the subsequent x-ray image that is associated with the low dosage may be determined. A motion of the patient may be identified as having occurred based on the determined difference.