New procedures to characterize the x-ray primary beam, obtaining an accurate assessment of the actual photon spectrum, are needed for quality control of x-ray tubes for medical purposes. The Compton scattering technique is very useful for determining x-ray spectra (in the 10-150 kV(p) range), avoiding the pile-up effect in the detector, since usually there is insufficient space available to apply other techniques. The Compton scattering procedure was simulated using the Monte Carlo method by means of the MCNP code. In order to validate the simulation model, experimental measurements were made at the Centro Nacional de Dosimetria (CND), Valencia, Spain, using a calibrated x-ray tube. Different spectra were measured varying the operational parameters (kV, mA, Al). Furthermore, CND provided the theoretical spectra corresponding to the x-ray measurement conditions. Using the developed model, a response matrix was obtained by simulating the interactions of different monoenergetic beams. During the construction of the primary photon spectrum it is necessary to calculate the inverse of the response matrix. Because this matrix is ill-conditioned, its inversion is not a simple process. This problem was solved using a truncated singular value decomposition (TSVD), method together with variational regularization. The performance of the methodology was tested with experimental and simulated x-ray spectra. Copyright (c) 2005 John Wiley & Sons, Ltd.
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机译:为医疗目的对X射线管进行质量控制,需要新的过程来表征X射线主光束,以获得对实际光子光谱的准确评估。康普顿散射技术对于确定X射线光谱(在10-150 kV(p)范围内)非常有用,避免了检测器中的堆积效应,因为通常没有足够的空间来应用其他技术。借助于MCNP代码,使用蒙特卡罗方法模拟了康普顿散射过程。为了验证仿真模型,使用经过校准的X射线管在西班牙巴伦西亚的国立中央医院(CND)进行了实验测量。通过改变操作参数(kV,mA,Al)来测量不同的光谱。此外,CND提供了与X射线测量条件相对应的理论光谱。使用开发的模型,通过模拟不同的单能光束的相互作用获得了响应矩阵。在构造初级光子光谱期间,有必要计算响应矩阵的逆。由于该矩阵是病态的,因此其求逆不是一个简单的过程。使用截断奇异值分解(TSVD)方法以及变分正则化解决了此问题。通过实验和模拟X射线光谱测试了该方法的性能。版权所有(c)2005 John Wiley&Sons,Ltd.
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