Described herein are examples of industrial radiography systems that may control, or recommend, certain parameter values of a high resolution, continuous rotation, radiographic imaging process. By controlling, or recommending, the particular parameter values, it may be possible to mitigate certain synchronization issues that occur during the high resolution, continuous rotation, radiographic imaging process. With the synchronization issues mitigated, a user may be able to perform the high resolution, continuous rotation, radiographic imaging process at a high speed, without the loss of detail and/or blur that sometimes occurs due to the synchronization issues.

A flexible digital radiographic detector assembly uses a conformable bag having granular media therein to enclose the detector and to help fit the detector onto a curved object. The conformable bag is evacuated to hold the detector against the object to be imaged. An image of the object is acquired by aiming x-rays through the object toward the detector.

A method of detecting a defect in a wind turbine blade uses a system that includes an X-ray generator, moved by a first transporting means, that generates X-ray to be irradiated to the wind turbine blade; an X-ray detector, moved by a second transporting means, that detects the X-ray generated by the X-ray generator and transmitted through the wind turbine blade; and a control unit. To detect a defect, the control unit divides virtually the wind turbine blade into a plurality of lengthwise sections based on a thickness profile thereof, receives a location of the X-ray generator, and controls output of the X-ray generator based on the location of the X-ray generator relative to the plurality of lengthwise sections. In particular, the output of the X-ray generator is decreased for a section among the plurality of lengthwise sections that is farther from a hub of the wind turbine blade.

A cabinet x-ray device for imaging seeds includes an x-ray source configured to transmit an x-ray beam along a beam path. A seed holder is configured to hold seeds and be selectively positioned in the x-ray device such that the beam path crosses the seed holder and the x-ray beam passes through at least some of the seeds. An x-ray detector is configured to detect the x-ray beam after passing through the seeds such that one or more x-ray images of the seeds can be formed. Self-supporting x-ray shielding can extend circumferentially around the x-ray beam to mitigate x-ray transmission outside the device. A drive mechanism can automatically move the seed holder so that discrete x-ray images of subsets of seeds are taken in an automatic seed imaging operation. Various seed evaluations and seed process evaluations can be made using the device.

In one embodiment, a sample surface of a biosensor includes pixel areas and holds a plurality of clusters during a sequence of sampling events such that the clusters are distributed unevenly over the pixel areas. In another embodiment, a biosensor has a sample surface that includes pixel areas and an array of wells overlying the pixel areas, the biosensor including two wells and two clusters per pixel area. The two wells per pixel area include a dominant well and a subordinate well. The dominant well has a larger cross section over the pixel area than the subordinate well. In yet another embodiment, an illumination system is coupled to a biosensor that illuminates the pixel areas with different angles of illumination during a sequence of sampling events, including, for a sampling event, illuminating each of the wells with off-axis illumination to produce asymmetrically illuminated well regions in each of the wells.

A radiation source applies radiation to a subject. A radiation generation apparatus controls the radiation source. A radiation imaging apparatus includes a pixel array including a plurality of image signal output pixels that outputs image signals based on the radiation applied from the radiation source and a plurality of dose detection pixels that detects a dose based on the radiation applied from the radiation source, and includes a control unit that controls driving of the radiation imaging apparatus and a radiation irradiation timing. The control unit includes a prediction unit that predicts an irradiation time from a result of detection of an integrated irradiation amount by the dose detection pixels, and a drive control unit that changes at least one of the number of frames to be captured and an offset correction processing method based on the prediction result.

An X-ray radiation imaging system is for imaging a tubular object. The X-ray radiation imaging system may include an enclosure, a motorized base to be positioned within the enclosure and configured to rotate the tubular object, and a gantry within the enclosure. The X-ray radiation imaging system may further include an X-ray source coupled to the gantry and being adjacent the motorized base. The X-ray source may be configured to irradiate the tubular object with X-ray radiation while the motorized base rotates the tubular object. The X-ray radiation imaging system may also include an X-ray detector coupled to the gantry and being adjacent the tubular object, and the X-ray detector may receive the X-ray radiation from the tubular object. The X-ray radiation imaging system may include a processor coupled to the X-ray source and the X-ray detector and configured to generate an image of the tubular object.

Embodiments of the present disclosure disclose a combined scanning X-ray generator, a composite inspection apparatus and an inspection method. The combined scanning X-ray generator includes: a housing; an anode arranged in the housing, the anode including a first end of the anode and a second end of the anode opposite the first end of the anode; a pencil beam radiation source arranged at the first end of the anode and configured to emit a pencil X-ray beam; and a fan beam radiation source arranged at the second end of the anode and configured to emit a fan X-ray beam; wherein the pencil beam radiation source and the fan beam radiation source are operated independently.

A radiation detector including: a sensor substrate including a flexible base member and a layer provided on a first surface of the base member and formed with plural pixels that accumulates electrical charge generated in response to light converted from radiation; a conversion layer provided on the first surface side of the sensor substrate, the conversion layer converts radiation into the light; and an elastic layer provided on the opposite side of the conversion layer to a side provided with the sensor substrate, the elastic layer having a greater restoring force with respect to bending than the sensor substrate.

Disclosed herein is a method of operating an imaging system which comprises (A) an image sensor comprising (a) a top surface, (b) M physically separate active areas on the top surface, and (c) a dead zone on the top surface and between the M active areas, and (B) a radiation source system which comprises an electron bombardment target, the method comprising: for i=1, . . . , N, sequentially causing emission of X-ray photons (i) from a radiation position (i) by causing electrons to bombard a target surface of the electron bombardment target at the radiation position (i); and for i=1, . . . , N, in response to the emission of the X-ray photons (i), capturing M images (i) of portions (i) of a same object, respectively in the M active areas, resulting in M×N images, wherein each point of the object is captured in at least one image of the M×N images.