Expanding SimSET to include block detectors: performance with pseudo-blocks and a true block model.

R E Schmitz, S B Gillispie, R L Harrison, L R Macdonald, P E Kinahan, T K Lewellen
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Abstract

We present a study that introduces two approaches to implementing block detectors into SimSET and compares their performance. SimSET is a photon tracking simulation package, which currently incorporates only detectors made of a solid annulus of scinitillator material. A pseudo-block approximation has been imposed on the solid annulus of conventional SimSET by discarding interactions in annulus segments that span the angular block gap. This yields blocks that are annulus segments, not rectangles. This is a quick and easy approximation of block structure, which brings SimSET results closer to actual scanner measurements. Even better agreement is expected with a deeper modification of the SimSET code that implements true rectangular blocks in the detector module (to be released late 2007/early 2008). This approach enables the greatest amount of variability and trueness to detail.We compare results from both block structure implementations to the conventional SimSET results and to measurements from a GE DSTE PET/CT scanner. Differences are evaluated in terms of sensitivities, crystal maps, and energy spectra, as well as in benchmark time tests of the simulation runs and their ease of use.Either implementation of block structure can aid in improving simulation accuracy by ameliorating one known cause of discrepancies, the geometric nature of the block detectors.

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将 SimSET 扩展到区块检测器:伪区块和真正区块模型的性能。
我们的研究介绍了在 SimSET 中实施块状探测器的两种方法,并对它们的性能进行了比较。SimSET 是一个光子跟踪模拟软件包,目前只包含由闪烁体材料的实心环面构成的探测器。在传统 SimSET 的实心环面上采用了伪块近似方法,即剔除跨越角块间隙的环面段中的相互作用。这样得到的块体是环形段,而不是矩形。这是一种快速、简便的块结构近似方法,使 SimSET 结果更接近实际扫描仪测量结果。如果对 SimSET 代码进行更深入的修改,在探测器模块中实现真正的矩形区块(将于 2007 年底/2008 年初发布),预计会有更好的一致性。我们将这两种块结构实现的结果与传统的 SimSET 结果以及 GE DSTE PET/CT 扫描仪的测量结果进行了比较。我们从灵敏度、晶体图和能谱,以及模拟运行的基准时间测试和易用性等方面对差异进行了评估。无论采用哪种块状结构,都可以通过改善造成差异的一个已知原因--块状探测器的几何特性--来帮助提高模拟精度。
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