Abstract: Some embodiments include an x-ray detector, comprising: a plastic housing; a two-dimensional sensor array disposed in a within the plastic housing and configured to generate image data in response to incident x-rays; a front plate connected to the plastic housing, the front plate and the plastic housing forming an enclosure surrounding the two-dimensional sensor array; and a printed circuit board mounted to the plastic housing at a plurality of mount points. wherein a centroid of the printed circuit board is closer to a center of the plastic housing than a centroid of the mount points.

Abstract: Some embodiments include an x-ray device comprising: an access port configured to receive a cathode within an interior volume of an enclosure of the x-ray device; a first vacuum seal configured to seal a cover over the access port; and a second seal configured to seal the cover over the access port, the second seal maintained between the first vacuum seal and the interior volume of the enclosure during removal of the first vacuum seal.

Abstract: Some embodiments include an x-ray system, comprising: a vacuum enclosure; a plurality of electron sources disposed within the vacuum enclosure; an anode including at least one target with a plurality of focal spots disposed in a planar array within the vacuum enclosure, each focal spot configured to generate an x-ray beam in response to an electron beam from a corresponding one of the electron sources; a plurality of first collimators disposed within the vacuum enclosure, each first collimator associated with a corresponding one of the focal spots and configured to collimate the x-ray beam of the corresponding focal spot; and a second collimator integrated with a housing of the vacuum enclosure or external to the vacuum enclosure, the second collimator configured to collimate each of the x-ray beams.

Abstract: Some embodiments include an x-ray system, comprising: a housing; a plurality of overlapping imaging layers disposed in the housing, each imaging layer configured to generate an image in response to a corresponding incident x-ray beam; and a plurality of x-ray markers attached to the housing and disposed to affect the incident x-ray beam for each of the imaging layers.

Abstract: An x-ray tube, comprising: a field emitter including an emission surface; an anode; and a focus electrode disposed between the field emitter and the anode; wherein: the focus electrode includes: a first surface that is substantially perpendicular to the field emitter emission surface and nearest to the field emitter; a second surface that is axially nearest to the anode, wherein the field emitter and the anode form an axis; and a third surface that extends between the first surface and the second surface; and a first location on the focus electrode between the first surface and the third surface is further from the anode than a second location on the focus electrode between the third surface and the second surface.

Abstract: A detector, comprising: a plurality of first pixels, each first pixel configured to convert radiation into an electrical signal; a plurality of second pixels; and a plurality of data lines coupled to the first pixels and the second pixels; control logic configured to combine a signal from at least one of the second pixels with an electrical signal from one of the first pixels; wherein electrical connections of each of the second pixels are different from electrical connections of the first pixels such that for each second pixel: components of the second pixel are different from components of each of the first pixels; electrical connections between components of the components of the second pixel are different from electrical connections between the components of each of the first pixels; or a number of electrical connections to the second pixel are different from a number of electrical connections to each of the first pixels.

Abstract: Some embodiments include a radiographic inspection system, comprising: a drive mechanism configured to move along a structure; a detector attached to the drive mechanism; a radiation source attached to the drive mechanism and positionable relative to the detector such that a width of the structure casts a radiation shadow on an active area of the detector; and control logic coupled to the detector and configured to: receive an image from the detector; generate side wall loss information based on the image; and generate bottom wall loss information based on the image.

Abstract: Some embodiments include an x-ray system, comprising: an x-ray imager including a plurality of imaging layers; an x-ray source configured to generate an x-ray beam; and an x-ray prefilter; wherein: the x-ray prefilter is configured to adjust an energy spectrum of the x-ray beam to create or decrease a level of x-ray fluence of a local minimum between two of a plurality of local maximums.

Abstract: Some embodiments include an x-ray source, comprising: an anode; a field emitter configured to generate an electron beam; a first grid configured to control field emission from the field emitter; a second grid disposed between the first grid and the anode; a third grid disposed between the first grid and the anode; and a middle electrode disposed between the first grid and the anode wherein the second grid is either disposed between the first grid and middle electrode or between the middle electrode and the anode; wherein the third grid is a mesh grid.

Abstract: Some embodiments include a system, comprising: a housing; an imaging array disposed within the housing; an imaging strip disposed within the housing; a first readout circuit coupled to the imaging array; a second readout circuit coupled to the imaging strip; and common electronics coupled to the first readout circuit and the second readout circuit and configured to generate image data in response to at least one of the first readout circuit and the second readout circuit.

Abstract: Embodiments include a system, comprising: a vacuum enclosure; an anode support structure penetrating the vacuum enclosure and including a plurality of first cooling passages; and an anode disposed within the vacuum enclosure, coupled to and supported by the anode support structure, and including: a target; and a plurality of second cooling passages; wherein: each of the second cooling passages is coupled to a corresponding first cooling passage; the anode is coupled to the anode support structure on a side of the anode different from a side of the anode including the target and different from axial ends of the anode on a major axis of the anode; and the anode is a linear anode.

Abstract: Some embodiments include a device, comprising: a housing; a circuit disposed in the housing, including a sensor array configured to generate electrical signals based on incident x-rays; a memory configured to store data for a plurality of configurations for the circuit; at least one magnetic sensor disposed in the housing; control logic disposed in the housing and configured to: receive a signal from the at least one magnetic sensor; select from among the configurations for the circuit based on the signal received from the least one magnetic sensor; and change an operation of the circuit by applying the data associated with the selected configuration to the circuit.

Abstract: Some embodiments include an x-ray source, comprising: an anode; a field emitter configured to generate an electron beam; a first grid configured to control field emission from the field emitter; a second grid disposed between the first grid and the anode; and a middle electrode disposed between the first grid and the anode wherein the second grid is either disposed between the first grid and middle electrode or between the middle electrode and the anode.

Abstract: Some embodiments include a system, comprising: a plurality of pixels; a plurality of data lines coupled to the pixels; a plurality of switches coupling the pixels to the data lines; a plurality of readout circuits coupled to the data lines; control logic coupled to the readout circuits, the control logic configured to, for one of the pixels: acquire a first value for the pixel while the corresponding switch is in an off state; reset the corresponding readout circuit corresponding for the pixel; acquire a second value for the pixel after resetting the readout circuit; turn on the corresponding switch; acquire a third value for the pixel after turning on the corresponding switch; and combine the first value, the second value, and the third value into a combined value for the pixel.

Abstract: A system, comprising: a vacuum enclosure; an anode support structure penetrating the vacuum enclosure and including a plurality of first cooling passages; and an anode disposed within the vacuum enclosure, coupled to and supported by the anode support structure, and including: a target; and a plurality of second cooling passages; wherein: each of the second cooling passages is coupled to a corresponding first cooling passage; and the anode is coupled to the anode support structure on a side of the anode different from a side of the anode including the target and different from axial ends of the anode on a major axis of the anode.

Abstract: Some embodiments include a radiographic inspection system, comprising: a detector; a support configured to attach the detector to a structure such that the detector is movable around the structure; a radioisotope collimator; and a collimator support arm coupling the detector to the radioisotope collimator such that the radioisotope collimator moves with the detector.

Abstract: A detector includes an enclosure having a side wall, a sensor array positioned in an enclosed portion of the enclosure, a controller connected to the sensor array and positioned in the enclosure, with the controller being connected to a first electrical connector within the enclosure, a second electrical connector positioned external to the side wall, with the first and second electrical connectors being removably connected to each other through the side wall, and a third electrical connector in electrical communication with the second electrical connector, with the third electrical connector configured to contact a fourth electrical connector of an energy storage device.

Abstract: Some embodiments include a radiographic inspection system, comprising: a drive mechanism configured to move along a structure; a detector attached to the drive mechanism; a radiation source attached to the drive mechanism and positionable relative to the detector such that a width of the structure casts a radiation shadow on an active area of the detector; and control logic coupled to the detector and configured to: receive an image from the detector; generate side wall loss information based on the image; and generate bottom wall loss information based on the image.

Abstract: Technology is described to uniformly apply doses of radiation to a target material. An irradiation device may comprise an enclosure configured to receive a target material and a source configured to emit primary radiation within the enclosure. The primary radiation may be configured to irradiate at least a first portion of the target material. The irradiation device may further comprise a scattering medium disposed within the enclosure. The scattering medium may be configured to produce secondary radiation through scatter interactions in response to the primary radiation, the secondary radiation configured to irradiate at least a second portion of the target material. A thickness of the scattering medium relative to the primary radiation may have a thickness of at least 3 millimeters).

Abstract: Technology is described for an electron gun driver including a half bridge driver circuit and a drive controller. The half bridge driver circuit includes a drive circuit configured to generate a grid drive voltage for a grid connection of an electron gun, and a cutoff circuit configured to generate a grid cutoff voltage for the grid connection of the electron gun, and a gate driver configured to switch between the grid drive voltage and the grid cutoff voltage. The drive controller is configured to generate a pulse input to the drive circuit and cutoff circuit and grid switching signals for the gate driver.