Monte Carlo validation in diagnostic radiological imaging.
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[1] J. Boone,et al. Glandular breast dose for monoenergetic and high-energy X-ray beams: Monte Carlo assessment. , 1999, Radiology.
[2] M Caon,et al. An EGS4-ready tomographic computational model of a 14-year-old female torso for calculating organ doses from CT examinations. , 1999, Physics in medicine and biology.
[3] J. Langer. Computing in Physics: Are We Taking It Too Seriously? or Not Seriously Enough? , 1999 .
[4] J A Seibert,et al. A Monte Carlo study of x-ray fluorescence in x-ray detectors. , 1999, Medical physics.
[5] C J Evans,et al. An MCNP-based model of a linear accelerator x-ray beam. , 1999, Physics in medicine and biology.
[6] J. Cygler,et al. Monte Carlo investigation of electron beam output factors versus size of square cutout. , 1999, Medical physics.
[7] The X-ray and electron benchmarking of the Monte Carlo codes MCNP-4A and 4B on different computers. , 1999, The British journal of radiology.
[8] T. R. Fewell,et al. Molybdenum, rhodium, and tungsten anode spectral models using interpolating polynomials with application to mammography. , 1997, Medical physics.
[9] J. Boone,et al. An accurate method for computer-generating tungsten anode x-ray spectra from 30 to 140 kV. , 1997, Medical physics.
[10] W Huda,et al. An approach for the estimation of effective radiation dose at CT in pediatric patients. , 1997, Radiology.
[11] D. Williams,et al. The dissected aorta: part I. Early anatomic changes in an in vitro model. , 1997, Radiology.
[12] J M Boone,et al. Comparison of x-ray cross sections for diagnostic and therapeutic medical physics. , 1996, Medical physics.
[13] G. Barnes,et al. Spectral dependence of glandular tissue dose in screen-film mammography. , 1991, Radiology.
[14] K L Lam,et al. Studies of performance of antiscatter grids in digital radiography: effect on signal-to-noise ratio. , 1990, Medical physics.
[15] J A Seibert,et al. Monte Carlo simulation of the scattered radiation distribution in diagnostic radiology. , 1988, Medical physics.
[16] K. Doi,et al. Some properties of photon scattering in water phantoms in diagnostic radiology. , 1986, Medical physics.
[17] K Doi,et al. Physical characteristics of scattered radiation in diagnostic radiology: Monte Carlo simulation studies. , 1985, Medical physics.
[18] K. Doi,et al. Radiation dose in diagnostic radiology: Monte Carlo simulation studies. , 1984, Medical physics.
[19] D R Dance,et al. The computation of scatter in mammography by Monte Carlo methods. , 1984, Physics in medicine and biology.
[20] K Doi,et al. Studies of x-ray energy absorption and quantum noise properties of x-ray screens by use of Monte Carlo simulation. , 1984, Medical physics.
[21] S L Fritz,et al. Scatter/primary ratios for x-ray spectra modified to enhance iodine contrast in screen-film mammography. , 1983, Medical physics.
[22] H Bernstein,et al. Experimental and theoretical energy and angular dependencies of scattered radiation in the mammography energy range. , 1983, Medical physics.
[23] K Doi,et al. Energy and angular dependence of x-ray absorption and its effect on radiographic response in screen--film systems. , 1983, Physics in medicine and biology.
[24] K Doi,et al. The validity of Monte Carlo simulation in studies of scattered radiation in diagnostic radiology. , 1983, Physics in medicine and biology.
[25] K Doi,et al. Investigation of the performance of antiscatter grids: Monte Carlo simulation studies. , 1982, Physics in medicine and biology.
[26] J. H. Hubbell,et al. Tables and graphs of photon interaction cross-sections from 10-eV to 100-GeV derived from the LLNL evaluated photon data library (EPDL). Part A: Z = 1 to 50 , 1981 .
[27] J. S. Laughlin,et al. Absorbed radiation dose in mammography. , 1979, Radiology.
[28] I A Brezovich,et al. The intensity of scattered radiation in mammography. , 1978, Radiology.
[29] Lellery Storm,et al. Photon cross sections from 1 keV to 100 MeV for elements Z=1 to Z=100 , 1970 .