A method includes moving one or more transmit facility or transmit facilities attached to a first component with regard to at least two receive facilities attached at a fixed position to the second component; and at least one of registering a respective error if an error condition exists for the respective receive facility or modifying an operation of an apparatus comprising the first and a second component if the error condition exists for the respective receive facility, the error condition for the respective receive facility depends on location information relating to at least one of the position of the first component with regard to the second component or orientation of the first component with regard to the second component, and/or at least one of a measure for a receive quality of the signals or data packets received from the transmit facility or from at least one of the transmit facilities.

A radiation imaging system includes a communication device configured to perform wireless communication with a radiation imaging apparatus configured to capture a radiographic image, and an information processing apparatus. The information processing apparatus causes the communication device to perform the wireless communication with the radiation imaging apparatus, based on information about a distance between the communication device and the radiation imaging apparatus and a threshold value set in advance.

High voltage assemblies and detectors are provided. In one aspect, a high voltage assembly includes a high voltage base board and a plurality of sub-detectors. Each sub-detector includes a crystal substrate, a crystal, a high voltage transfer board, and a high voltage cathode board. One of the high voltage transfer board and the high voltage base board includes first and second connection members, and the other one includes first and second contact members. The first connection member is configured to shift relative to the first contact member in response to a first force, and the second connection member is configured to shift relative to the second contact member in response to a second force. A high voltage is applied at both ends of the crystal through electrically contacting the first connection member with the first contact member and electrically contacting the second connection member with the second contact member.

A radiation imaging system is provided. The system comprises a radiation imaging apparatus including a plurality of pixels for acquiring radiation image data and a detection unit for performing exposure control during radiation irradiation, and a radiation control apparatus configured to control a radiation source that irradiates radiation to the radiation imaging apparatus. The radiation imaging apparatus and the radiation control apparatus transmit signals that relate to exposure control by wireless communication. The radiation imaging apparatus, in a case where an irradiation stop signal indicating that radiation irradiation has been stopped is not received from the radiation control apparatus after a signal instructing to stop radiation irradiation has been transmitted to the radiation control apparatus and until a first time interval has elapsed, transmits a signal instructing to stop radiation irradiation to the radiation control apparatus again.

The invention concerns a storage device for cleaning and charging portable X-ray detectors, and an X-ray system comprising such storage device. The storage device comprises a receiving unit for receiving at least one portable X-ray detector, a cleaning unit for cleaning the portable X-ray detector when being received by the receiving unit, and a charging unit for charging the portable X-ray detector, wherein the cleaning unit is configured for mechanically and/or chemically cleaning the portable X-ray detector. Further, the invention concerns a method of cleaning and charging a portable X-ray detector in a storage device.

A control terminal includes a hardware processor. The processor performs a synchronization process to synchronize irradiation timing signals between an imaging device among multiple radiographic imaging devices and a radiation irradiation device, the radiographic imaging devices generating dynamic image data, the radiation irradiation device controlling continuous irradiation of a subject with radiation. The processor identifies, among the radiographic imaging devices, the radiographic imaging device that has an irradiation timing signal synchronized with an irradiation timing signal of the radiation irradiation device.

A radiation device is wirelessly connected to a radiography device that generates dynamic image data and which controls sequential radiation. The radiation device includes a signal generator and a first determiner. The signal generator generates (i) first pulse signals emitted by the radiography device, (ii) second pulse signals synchronized with a first count value obtained by counting up the first pulse signals, and (iii) a second count value obtained by counting up the second pulse signals. The first determiner determines whether to start radiation based on a delay time which is a difference between a first time point count value and a second time point count value. The first time point count value indicates a time point at which a radiation permission signal is transmitted. The second time point count value indicates a time point at which the radiation permission signal is received.

Various methods and systems are provided for a power supply system. In one example, a method and system includes a power distribution unit (PDU) configured to receive power from a main power source and an uninterruptible power supply (UPS). The UPS includes a timer and the UPS is configured to directly power an output alternating current (AC) load after the main power source in unavailable. The UPS is also configured to power an output high voltage direct current (HVDC) load after the main power source is unavailable for a time delay measured by the timer.

Various systems are provided for a power supply system. In one example, the system includes a power distribution unit configured to receive power from a main power source and an uninterruptible power supply (UPS), wherein the UPS is configured to directly power an output AC load, the UPS is further configured to power an output DC load after coupled through one or more transformers.

A radiographing system includes a radiation generation apparatus emitting a radiation, a radiation detection apparatus detecting the radiation to generate a radiographic image, and a radiographing apparatus controlling operation of the radiation detection apparatus by communicating with the radiation detection apparatus. The radiographing system further includes an acquisition unit configured to acquire information about the radiation detection apparatus, and a determination unit configured to determine whether the radiation detection apparatus includes an automatic exposure control (AEC) function, based on the information about the radiation detection apparatus acquired by the acquisition unit.