Various systems are provided for medical imaging systems. In one example, an assembly for a C-arm comprises: a casing including a first extension housing a first component, a second extension housing a second component, and a clearance formed between the first extension and the second extension; and a collimator seated within the clearance, with an outlet end of the collimator substantially aligned with a terminating end of the first extension and a terminating end of the second extension. An x-ray tube insert may be aligned with the collimator and configured to emit x-ray radiation between the first component and the second component.

A radiation imaging apparatus including: a first scintillator layer configured to convert a radiation (R) which has entered the first scintillator layer into light; a second scintillator layer configured to convert a radiation transmitted through the first scintillator layer into light; a fiber optic plate (FOP) provided between the first scintillator layer and the second scintillator layer; and an imaging portion configured to convert the light generated in the first scintillator layer and the light generated in the second scintillator layer into an electric signal.

In a system for the administration of a group of imaging devices which are equipped with a corresponding device hosts, device software and a configuration protocol are executably stored on the device host. The system can include a distributed database system which configured to receive configuration protocols from the device host and to store modified configuration protocols for the respective device host, and to distribute modified configuration protocols. The received and/or stored configuration protocols are made available via a central write access. The system can include an administrator having a memory, a user interface and a processor for communicating with the distributed database system. Configuration protocols can be modified via the user interface and sent to the distributed database system for storage and/or distribution to at least one selected imaging device. These aspects are also applicable to a method for the administration of imaging devices.

The present invention relates to a lifting apparatus for a pressure paddle, the lifting apparatus for the pressure paddle comprising: a lifting belt rotated by a driving means; a lifting pulley manually rotated by the lifting belt hung thereon; a lifting frame on which the lifting pulley is mounted; and a pressure paddle mounted on the lifting frame.

Provided is a radiation irradiation device that can improve the degree of freedom of an arm part and can reduce the number of noise suppression components, such as a ferrite core. A radiation irradiation device includes a radiation generating part having a radiation source that generates radiation; an arm part having the radiation generating part attached to one end thereof; and a main body part having the other end of the arm part connected thereto. The main body part has a power source part including a three-phase inverter circuit. The power source part supplies a three-phase alternating current voltage to the radiation generating part via the arm part.

A coupler provides a high speed datalink between rotating parts and comprises a circular channel, enclosing a hollow-cylindric volume, and at least two antennas. The circular channel is made of electrically conductive material and includes an inner ring, an outer ring rotatable against the inner ring, and two sidewalls on the sides of the rings. An inner antenna is mechanically coupled to the inner ring and an outer antenna is mechanically coupled to the outer ring. The antennas are configured to establish a microwave signal connection between them based on multiple reflections of an electromagnetic wave at the rings.

In some implementations, a device may produce, via an x-ray module, x-rays to be directed towards a body part. The device may detect, via a sensor, the x-rays reflected from the body part. The device may generate, via the sensor, signals based on the x-rays reflected from the body part. The device may generate, via a processor, an x-ray image of the body part based on the first signals. The device may transmit the x-ray image to a server. The device may receive, from the server, a message that indicates a diagnosis associated with the x-ray image. The device may display, via a user interface, the x-ray image and information associated with the diagnosis associated with the x-ray image.

A radiographic imaging system includes a portable information terminal 16 and a console 18 which are plural control devices of which each one performs a control relating to imaging of a radiographic image and of which at least one is selectively used; and a terminal control unit 30 of the portable information terminal 16 and a control unit 50 of the console 18 that respectively function as a setting unit that sets, with respect to at least one of usage control devices which is control device to be selectively used, control content based on one usage control device in a case where the number of usage control devices is one, and sets control content based on a combination of plural usage control devices in a case where the number of usage control devices is plural.

Methods and systems for X-ray and fluoroscopic image capture and, in particular, to a versatile, multimode imaging system incorporating a handheld X-ray emitter operative to capture non-invasive images of a target; a stage operative to capture static X-ray and dynamic fluoroscopic images of the target; a system for the tracking and positioning of the X-ray emission to improve safety of obtaining X-ray images as well as improve the quality of X-ray images. Where the devices can automatically limit the field of the X-ray emission.

A power supply apparatus of a computerized tomography (CT) shelter system is provided. The power supply apparatus comprises a power source buffer unit and a generator. The power source buffer unit comprises a battery module and an inverter module. The battery module is used to store electric energy. The inverter module may convert low-level alternating-current power into direct-current power, which is then stored in the battery module, and may also convert the direct-current power stored in the battery module into high-level alternating-current power that is then supplied to a CT apparatus of the CT shelter system. The generator may generate the low-level alternating-current power that is then supplied to the inverter module, and the generator may also supply the generated low-level alternating-current power to an air conditioning apparatus of the CT shelter system.