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A Monte Carlo study of x-ray fluorescence in x-ray detectors
1.L. E. Antonuk, Y. el-Mohri, J. H. Siewerdsen, J. Yorkston, W. Huang, V. E. Scarpine, and R. A. Street, “Empirical investigation of the signal performance of a high-resolution, indirect detection, active matrix flat-panel imager (AMFPI) for fluoroscopic and radiographic operation,” Med. Phys. 24, 51–70 (1997).
2.J. H. Siewerdsen, L. E. Antonuk, Y. el-Mohri, J. Yorkston, W. Huang, and I. A. Cunningham, “Signal, noise power spectrum, and detective quantum efficiency of indirect-detection flat-panel imagers for diagnostic radiology,” Med. Phys. 25, 614–628 (1998).
3.T. T. Farman and A. G. Farman, “Clinical trial of panoramic dental radiography using a CCD receptor,” J. Digit. Imaging 11, 169–171 (1998).
4.S. Hejazi and D. P. Trauernicht, “System considerations in CCD-based x-ray imaging for digital chest radiography and digital mammography,” Med. Phys. 24, 287–297 (1997).
5.T. Yu, J. M. Sabol, J. A. Seibert, and J. M. Boone, “Scintillating fiber optic screens: A comparison of MTF light conversion efficiency, and emission angle with Tb screens,” Med. Phys. 24, 279–285 (1997).
6.H. P. Chan and K. Doi, “Energy and angular dependence of x-ray absorption and its effect on radiographic response in screen–film systems,” Phys. Med. Biol. 28, 565–579 (1983).
7.H. P. Chan and K. Doi, “Studies of x-ray energy absorption and quantum noise properties of x-ray screens by use of Monte Carlo simulation,” Med. Phys. 11, 37–46 (1984).
8.C. S. Chen, K. Doi, C. Vyborny, H. P. Chan, and G. Holje, “Monte Carlo simulation studies of detectors used in the measurement of diagnostic x-ray spectra,” Med. Phys. 7, 627–635 (1980).
9.Y. Kodera, K. Doi, and H. P. Chan, “Absolute speeds of screen–film systems and their absorbed-energy constants,” Radiology 151, 229–236 (1984).
10.D. E. Cullen, “A coupled neutron–photon 3D combinatorial geometry Monte Carlo transport code,” UCRL-ID 126455, 1997.
11.The Monte Carlo code was distributed through the Oak Ridge National Laboratory Radiation Safety Information Computational Center: http://www-rsicc.ornl.gov/codes.ccc.ccc6.ccc-638.html.
12.Dr. Red Cullen at Lawrence Livermore National Laboratory provided the TART 98-2 update to the authors (see acknowledgments).
13.J. M. Boone and J. A. Seibert, “An accurate method for computer-generating tungsten anode x-ray spectra from 30 to 140 kV,” Med. Phys. 24, 1661–1670 (1997).
14.J. M. Boone, “Monte Carlo assessment of glandular breast dose for monoenergetic and high-energy polyenergetic x-ray beams,” Radiology (in press).
15.J. M. Boone and A. E. Chavez, “Comparison of x-ray cross sections for diagnostic and therapeutic medical physics,” Med. Phys. 23, 1997–2005 (1996).
16.D. L. Lee, L. K. Cheung, B. G. Rodricks, and G. F. Powell, “Improved imaging performance of a in direct radiography system using a Se/TFT detector,” SPIE 3336, 14–23 (1998).
17.U. Neitzel, I. Maack, and S. Gunther-Kohfahl, “Image quality of a digital chest radiography system based on a selenium detector,” Med. Phys. 21, 509–516 (1994).
18.T. Moeller and M. Tecotzky, “Observations on the rare earths. Naphthazarin complexes of certain rare earth metal ions,” J. Am. Chem. Soc. 77, 2649–2650 (1955).
19.J. Hubert and P. Thouvenot, “Luminescence properties of Eu3+ and Am3+ in thorium oxide,” J. Alloys Compd. 80, 193–200 (1992).
20.J. M. Boone and J. A. Seibert, “A comparison of mono- and polyenergetic x-ray beam performance for radiographic and fluoroscopic imaging,” Med. Phys. 21, 1853–1863 (1994).
21.J. M. Boone, G. S. Shaber, and M. Tecotzky, “Dual-energy mammography: A detector analysis,” Med. Phys. 17, 665–675 (1990).
22.J. T. Dobbins, D. L. Ergun, L. Rutz, D. A. Hinshaw, H. Blume, and D. C. Clark, “ of four generations of computed radiography acquisition devices,” Med. Phys. 22, 1581–1593 (1995).
23.J. P. Bissonnette, I. A. Cunningham, D. A. Jaffray, A. Fenster, and P. Munro, “A quantum accounting and detective quantum efficiency analysis for video-based portal imaging,” Med. Phys. 24, 815–826 (1997).
24.I. A. Cunningham, M. S. Westmore, and A. Fenster, “A spatial-frequency dependent quantum accounting diagram and detective quantum efficiency model of signal and noise propagation in cascaded imaging systems,” Med. Phys. 21, 417–427 (1994).
25.I. A. Cunningham, “Linear systems modeling of parallel cascaded stochastic processes: The NPS of radiographic screens with reabsorption of characterstic x radiation,” SPIE 3336, 220–230 (1998).
26.J. H. Siewerdsen, L. E. Antonuk, Y. el-Mohri, J. Yorkston, W. Huang, J. M. Boudry, and I. A. Cunningham, “Empirical and theoretical investigation of the noise performance of indirect detection, active matrix flat-panel imagers (AMFPIs) for diagnostic radiology,” Med. Phys. 24, 71–89 (1997).
27.J. M. Boudry and L. E. Antonuk, “Radiation damage of amorphous silicon, thin-film, field-effect transistors,” Med. Phys. 23, 743–754 (1996).
28.J. M. Boone, T. R. Fewell, and R. J. Jennings, “Molybdenum, rhodium, and tungsten anode spectral models using interpolating polynomials with application to mammography,” Med. Phys. 24, 1863–1874 (1997).
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