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1 June 1992 Operational characteristics and potential of scientific-grade charge-coupled devices in x-ray imaging applications
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Proceedings Volume 1655, Electron Tubes and Image Intensifiers; (1992) https://doi.org/10.1117/12.60329
Event: SPIE/IS&T 1992 Symposium on Electronic Imaging: Science and Technology, 1992, San Jose, CA, United States
Abstract
In diagnostic imaging, primarily because of the low optical coupling efficiency and the limited sensitivity of video cameras, the use of an x-ray intensifying screen coupled to a camera by a lens is considered suboptimal. Modern electronic x ray acquisition employs image intensification in order to achieve an adequate signal for the camera at the output end of the tube. The high gain of modern intensifiers enables the acquisition of images with noise characteristics limited by the number of detected x-ray photons. However, the advent of ultra- sensitive low-noise CCDs have prompted a re-examination of non-intensified optical coupling approaches for limited applications in medical x-ray imaging where image intensifiers are not optimal. The measured characteristics of a cooled CCD system, with 2048 X 2048 pixels are presented as they apply to the requirements for some x-ray imaging applications. Measurements with a lens coupling suggest that the x-ray quantum limit may be reached in such a system after careful optimization of the components, but much better results may be attained with fiberoptic coupling. The potential merits of intensified versus non-intensified approaches are also discussed.
© (1992) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Andrew Karellas, Hong Liu, Lisa J. Harris, and Carl J. D'Orsi "Operational characteristics and potential of scientific-grade charge-coupled devices in x-ray imaging applications", Proc. SPIE 1655, Electron Tubes and Image Intensifiers, (1 June 1992); https://doi.org/10.1117/12.60329
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