An X-ray diagnostic apparatus according to an embodiment includes a support frame and processing circuitry. The support frame supports an X-ray generator and an X-ray detector. The processing circuitry is configured to, when rotational acquisitions are performed multiple times after a contrast agent is injected one time, previously set a generation condition of an X-ray that is generated by the X-ray generator for each of the rotational acquisitions, the rotational acquisitions being performed while the support frame is rotated around a subject.

An X-ray diagnostic apparatus according to an embodiment includes a support frame and processing circuitry. The support frame supports an X-ray generator and an X-ray detector. The processing circuitry is configured to, when rotational acquisitions are performed multiple times after a contrast agent is injected one time, previously set a generation condition of an X-ray that is generated by the X-ray generator for each of the rotational acquisitions, the rotational acquisitions being performed while the support frame is rotated around a subject.

Presented systems and methods facilitate efficient and effective generation and delivery of radiation. A radiation generation system can comprise: a particle beam gun, a high energy dissipation anode target (HEDAT); and a liquid anode control component. In some embodiments, the particle beam gun generates an electron beam. The HEDAT includes a solid anode portion (HEDAT-SAP) and a liquid anode portion (HEDAT-LAP) that are configured to receive the electron beam, absorb energy from the electron beam, generate a radiation beam, and dissipate heat. The radiation beam can include photons that can have radiation characteristics (e.g., X-ray wavelength, ionizing capability, etc.). The liquid anode control component can control a liquid anode flow to the HEDAT. The HEDAT-SAP and HEDAT-LAP can cooperatively operate in radiation generation and their configuration can be selected based upon contribution of respective HEDAT-SAP and the HEDAT-LAP characteristics to radiation generation.

A method is for closed-loop control of an X-ray pulse chain generated via a linear accelerator system. In an embodiment, the method includes modulating a first electron beam within a first radio-frequency pulse duration, wherein the first multiple amplitude X-ray pulse is produced on modulating the first electron beam; measuring time-resolved actual values of the first multiple amplitude X-ray pulse; adjusting at least one pulse parameter as a function of a comparison of the specified multiple amplitude X-ray pulse profile and the measured time-resolved actual values; and modulating a second electron beam within a second radio-frequency pulse duration as a function of the at least one adjusted pulse parameter for production of the second multiple amplitude X-ray pulse, so the X-ray pulse chain is controlled.

An apparatus including an X-ray tube is provided. The X-ray tube can include a cathode and an input receptacle coupled to the cathode. The input receptacle can include a connector configured within the input receptacle. The connector can operatively couple the cathode and the input receptacle. The connector can include at least one circuit configured to receive an input signal via the input receptacle. The input signal can be between 20 kV and 400 kV. The input signal can be received as an auxiliary supply voltage. The at least one circuit can be configured to generate an output signal indicative of at least one operational characteristic of the X-ray tube. Related systems, and methods of use are also provided.

An apparatus including an X-ray tube is provided. The X-ray tube can include a cathode and an input receptacle coupled to the cathode. The input receptacle can include a connector configured within the input receptacle. The connector can operatively couple the cathode and the input receptacle. The connector can include at least one circuit configured to receive an input signal via the input receptacle. The input signal can be between 20 kV and 400 kV. The input signal can be received as an auxiliary supply voltage. The at least one circuit can be configured to generate an output signal indicative of at least one operational characteristic of the X-ray tube. Related systems, and methods of use are also provided.

Methods, devices, and systems for computed tomography (CT) imaging technologies that are tailored to specific regions of interest and provide a reduced radiation dose. An imaging system for cardiac CT comprises a beam-shaping filtration and exposure control technologies specifically tailored to imaging of the heart.

Methods, devices, and systems for computed tomography (CT) imaging technologies that are tailored to specific regions of interest and provide a reduced radiation dose. An imaging system for cardiac CT comprises a beam-shaping filtration and exposure control technologies specifically tailored to imaging of the heart.

The embodiments of the present disclosure provide a power management system of a mobile X-ray machine and a control method thereof. The power management system comprises a power module group; a main control module being connected with a upper machine, and configured to receive an action signal sent by the upper machine, acquire status information of the power module group, and output a control signal; a functional component power pack being connected with the power module group and the main control module, and configured to convert electrical energy of the power module group according to the control signal and output converted energy to a functional component of a high-voltage generator.

A method, in an embodiment, is for setting an X-ray intensity using a structured anode or a field emitter cathode or a finger-shaped cathode head. Other embodiments include an associated X-ray device, an associated single X-ray tube CT scanner, an associated dual X-ray tube CT scanner, and an associated computer program product.