A control apparatus that controls, using automatic exposure control of controlling a radiation generation apparatus by comparing a radiation dose from the radiation generation apparatus with a target dose, radiation imaging using radiation from the radiation generation apparatus, comprises a processing unit that executes image processing on a radiation image obtained by the radiation imaging; and a setting unit that sets, as the target dose used in the automatic exposure control, a dose which is changed in accordance with an image processing parameter for executing the image processing.

A control apparatus that controls, using automatic exposure control of controlling a radiation generation apparatus by comparing a radiation dose from the radiation generation apparatus with a target dose, radiation imaging using radiation from the radiation generation apparatus, comprises a processing unit that executes image processing on a radiation image obtained by the radiation imaging; and a setting unit that sets, as the target dose used in the automatic exposure control, a dose which is changed in accordance with an image processing parameter for executing the image processing.

A method is disclosed for automatically controlling the exposure in an X-ray imaging of a moving object to be irradiated. An embodiment of the method includes generating X-ray images at different times with a predeterminable pulse width of X-ray radiation; determining at least one moving image region from at least two of the generated X-ray images; determining at least one moving edge of the moving image region; selecting at least one pixel of the edge; determining the time dependence of the intensity of the pixel from the generated X-ray images; evaluating the time dependence of the intensity; and changing the pulse width in accordance with the evaluation. Alternatively, the spatial dependency of the intensity can also be evaluated close to the edge. Advantages of ensuring an optimum image quality and reducing negative influences of a sub-optimum parameter selection are realized.

A method is disclosed for automatically controlling the exposure in an X-ray imaging of a moving object to be irradiated. An embodiment of the method includes generating X-ray images at different times with a predeterminable pulse width of X-ray radiation; determining at least one moving image region from at least two of the generated X-ray images; determining at least one moving edge of the moving image region; selecting at least one pixel of the edge; determining the time dependence of the intensity of the pixel from the generated X-ray images; evaluating the time dependence of the intensity; and changing the pulse width in accordance with the evaluation. Alternatively, the spatial dependency of the intensity can also be evaluated close to the edge. Advantages of ensuring an optimum image quality and reducing negative influences of a sub-optimum parameter selection are realized.

A radiation imaging control apparatus includes an exposure switch configured to instruct radiation emission, an acquisition unit configured to acquire a first signal indicating that the exposure switch is pressed, a first connection unit configured to detachably connect with a control unit of a radiant ray detector to transmit a second signal indicating the driving state of the radiant ray detector, a second connection unit configured to detachably connect with a control unit of a radiant ray generation apparatus to transmit a specific signal, and a control unit configured to perform control to output the specific signal via the second connection unit upon acquisition of the first and second signals, wherein the second connection unit is a connector for making wired connection.

A radiation imaging control apparatus includes an exposure switch configured to instruct radiation emission, an acquisition unit configured to acquire a first signal indicating that the exposure switch is pressed, a first connection unit configured to detachably connect with a control unit of a radiant ray detector to transmit a second signal indicating the driving state of the radiant ray detector, a second connection unit configured to detachably connect with a control unit of a radiant ray generation apparatus to transmit a specific signal, and a control unit configured to perform control to output the specific signal via the second connection unit upon acquisition of the first and second signals, wherein the second connection unit is a connector for making wired connection.

A reference image of a patient may be generated. A subsequent x-ray image of the patient may be generated after the generating of the reference image where the subsequent x-ray image is associated with a low dosage. A difference between the reference image and the subsequent x-ray image that is associated with the low dosage may be determined. A motion of the patient may be identified as having occurred based on the determined difference.

A reference image of a patient may be generated. A subsequent x-ray image of the patient may be generated after the generating of the reference image where the subsequent x-ray image is associated with a low dosage. A difference between the reference image and the subsequent x-ray image that is associated with the low dosage may be determined. A motion of the patient may be identified as having occurred based on the determined difference.

A method is disclosed for automatically controlling the exposure in an X-ray imaging of a moving object to be irradiated. An embodiment of the method includes generating X-ray images at different times with a predeterminable pulse width of X-ray radiation; determining at least one moving image region from at least two of the generated X-ray images; determining at least one moving edge of the moving image region; selecting at least one pixel of the edge; determining the time dependence of the intensity of the pixel from the generated X-ray images; evaluating the time dependence of the intensity; and changing the pulse width in accordance with the evaluation. Alternatively, the spatial dependency of the intensity can also be evaluated close to the edge. Advantages of ensuring an optimum image quality and reducing negative influences of a sub-optimum parameter selection are realized.

A method is disclosed for automatically controlling the exposure in an X-ray imaging of a moving object to be irradiated. An embodiment of the method includes generating X-ray images at different times with a predeterminable pulse width of X-ray radiation; determining at least one moving image region from at least two of the generated X-ray images; determining at least one moving edge of the moving image region; selecting at least one pixel of the edge; determining the time dependence of the intensity of the pixel from the generated X-ray images; evaluating the time dependence of the intensity; and changing the pulse width in accordance with the evaluation. Alternatively, the spatial dependency of the intensity can also be evaluated close to the edge. Advantages of ensuring an optimum image quality and reducing negative influences of a sub-optimum parameter selection are realized.