超几何分布软件可靠性增长模型(HGDM):公式精确，适用性强

Proceedings., Fourteenth Annual International Computer Software and Applications Conference Pub Date : 1990-10-31 DOI:10.1109/CMPSAC.1990.139307

R. Jacoby, Y. Tohma

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引用次数: 23

摘要

超几何分布用于估计软件在测试和调试阶段开始时的初始故障残余数量。超几何分布增长模型(HGD)非常适合于对观测到的累积断层数增长曲线进行估计。该模型的优点是适用于各种观测数据。通过单一模型的应用，可以估计出指数增长曲线和s型增长曲线。给出了HGD模型的精确表达式。给出了该模型与NHPP Goel-Okumoto增长模型和延迟s型增长模型的确切关系。引入可变故障检出率后，估计生长曲线与实际观测到的故障生长曲线的拟合优度显著提高。给出了模型对实际观测数据适用性的不同实例。

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The hyper-geometric distribution software reliability growth model (HGDM): precise formulation and applicability

The hyper-geometric distribution is used to estimate the number of initial faults residual in software at the beginning of the test-and-debug phase. The hyper-geometric distribution growth model (HGD model) is well suited to making estimates for the observed growth curves of the accumulated number of detected faults. The advantage of the proposed model is the applicability to all kinds of observed data. By application of a single model, exponential growth curves as well as S-shaped growth curves can be estimated. The precise formulation of the HGD model is presented. The exact relationship of this model to the NHPP Goel-Okumoto growth model and the delayed S-shaped growth model is shown. With the introduction of a variable fault detection rate, the goodness of fit of the estimated growth curve to the growth curve of real observed faults is increased significantly. Different examples of the applicability of the model to real observed data are presented.<>

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Proceedings., Fourteenth Annual International Computer Software and Applications Conference

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