Systems and methods for digital radiography are provided. The method may be implemented on the implemented on a DR system including an imaging device and a computing device. The computing device may include at least one processor and at least one storage device. The method may include directing multiple dose sensors to detect a dose of radiation rays emitted from a radiation source of the imaging device. The multiple dose sensors may correspond to multiple imaging detectors, respectively. The method may also include determining the dose of the radiation rays. The method may further include directing, based on the dose of the radiation rays, at least one imaging detector of the multiple imaging detectors to proceed to detect the radiation rays for generating an image of a target object to be examined.

A PET apparatus and a timing correction method of this invention select two target gamma-ray detectors which count coincidences, select a reference detector which is one detector out of the two selected gamma-ray detectors, select a gamma-ray detector different from the other, opposite detector, and when repeating the selection, make a time lag histogram concerning two gamma-ray detectors selected in the past a reference, and correct a time lag histogram concerning gamma-ray detectors selected this time based on the reference. By repeating an operation to make the corrected time lag histogram concerning the two gamma-ray detectors a new reference, an optimal time lag histogram can be obtained without repeating many measurements and computations.

The invention relates to a method for providing a first and a second digital panoramic layer image optimized for a comparison, wherein the first and second panoramic layer images each have multiple projections detected and stored for them by means of at least one digital detector during an at least partial revolution of a recording unit around an object to be recorded, and the first and second panoramic layer images are each produced from the multiple projections in accordance with a computation code and by forming a panoramic layer. Differences between the first and second panoramic layer images are minimized by altering at least one parameter of the computation code for fresh production of the first and/or second panoramic layer image. In addition, the invention relates to a corresponding apparatus.

An X-ray detector includes a detection unit to convert X-rays into a signal value and an evaluation unit. The detection unit and the evaluation unit are configured in a common component, the extent of the component along a first direction being not greater than the extent of the detection unit. The evaluation unit includes at least one correction unit to correct the signal values, a computation unit to control the correction, and a memory unit to store at least one correction parameter. The evaluation unit is designed such that the signal values are corrected as a function of the at least one correction parameter. A method and detector group are also disclosed.

An integrated interface of a detector module of a Positron Emission Tomography (PET) may include a power module, a clock module, a synchronization module, and a communication module. In one embodiment, Gigabit Ethernet, 10G Ethernet, Fast Ethernet (100M), 10M Ethernet or custom speed Ethernet based solution can be used in the communication module. In the power module, the power is can be transmitted by standard PoE (Power over Ethernet) method, while the clock can be recovered from Ethernet in the clock module. In the synchronization module, in one embodiment, the synchronization can be done through a dedicated package and/or IEEE1588. The integrated interface can be implemented in other systems. For example, it can be used in a gamma camera system or gamma probe, especially a dynamic gamma camera or handheld gamma camera.

This X-ray phase imaging system includes a plurality of gratings including a first grating that is irradiated with X-rays from an X-ray source and a second grating that is irradiated with X-rays from the first grating. The X-ray phase imaging system includes an imaging unit that optically images a subject and one or both of the first grating and the second grating.

An imaging system for imaging an object, the imaging system comprising: a housing having a center opening; a CT imaging unit mounted to the housing, the CT imaging unit comprising: a rotatable disc extending around the center opening; an X-ray emitter mounted to the rotatable disc and configured to emit an X-ray beam; and an X-ray detector mounted to the rotatable disc in alignment with the X-ray beam; and a digital radiography imager comprising a detector plate mounted to the rotatable disc, the detector plate being configured to assume (i) a retracted position in which the detector plate is not aligned with the X-ray beam, whereby to permit the X-ray beam to contact the X-ray detector, and (ii) an extended position in which the detector plate is aligned with the X-ray beam, whereby to permit the X-ray beam to contact the detector plate.

The radiographic imaging apparatus is configured so that an irradiation device is mounted on a rotary drum of a rotary gantry. A pair of X-ray sources is disposed outside the rotary drum and attached to the outer surface of the rotary drum. A pair of FPDs facing the respective X-ray sources is mounted in the irradiation device. When X-rays are irradiated, X-ray intensity information is calculated by a signal processing device based an output signal from each radiation detection element of each FPD, and stored in a memory. Based on FOV information set by an input device, an X-ray intensity acquisition device acquires multiple pieces of X-ray intensity information that are calculated based on the output signals from the radiation detection elements in small FOV areas (or large FOV areas) of the FPDs, which are included in the X-ray intensity information stored in the memory.

An X-ray detector and an X-ray CT apparatus that facilitate collimator plate arrangement are characterized by comprising radiation detection element arrays in which a plurality of radiation detection elements detecting a radiation generated from a radiation source are arranged in a first direction and a second direction orthogonal to the first direction, collimator plates that are arranged along the first direction on the radiation source side of the radiation detection element arrays to remove scattered radiations, and collimator plate support members that have grooves supporting the collimator plate and are arranged along the second direction between the radiation detection elements.

A radiographic apparatus includes: a plurality of detection elements arranged in a two-dimensional fashion; at least one radiation sensor configured to change a signal value to be output, when radiation is emitted thereto; and an irradiation start detecting unit configured to determine whether X-ray emission from an X-ray generator has been started based on the signal value output from the radiation sensor, wherein, when the signal value output from the radiation sensor moves out of a predetermined range, the irradiation start detecting unit does not determine whether the signal value output from the radiation sensor is a signal value outside the predetermined range at least, and when the number of times the signal value output from the radiation sensor moves out of the predetermined range reaches a predetermined number, the irradiation start detecting unit detects a start of X-ray emission from the X-ray generator.