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E-Commerce Letters 2024
基于随机微分方程和广义拐点S型故障检测率的银行软件可靠性研究
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Abstract:
在数字经济时代,随着电子商务快速发展,银行软件系统的规模显著扩大,软件故障跟踪系统中故障的报告存在随机性、不规律性以及各种不确定因素,因此故障检测过程可以看作是一个随机过程。在软件可靠性领域,随机微分方程常用于描述软件故障的发生过程及其可靠性的动态变化,在故障检测率方面,广义拐点S型故障检测率往往具有更强的灵活性,因此本文提出一种基于随机微分方程和广义拐点S型故障检测率的软件可靠性模型,并使用极大似然估计方法对模型的参数进行估计。最后在A银行测试中心数据集上进行验证,实验结果表明本文提出模型对实验数据拟合效果最好。因此该模型相较于其他经典软件可靠性模型具有优越性。
In the era of digital economy, with the rapid development of e-commerce, the scale of banking software systems has expanded significantly, and the fault reporting in the software fault tracking system has randomness, irregularity and various uncertain factors, so the fault detection process can be regarded as a random process. In the field of software reliability, stochastic differential equations are often used to describe the occurrence process of software failures and the dynamic changes of their reliability, and the generalized inflection point S-type fault detection rate is often more flexible in terms of fault detection rate, so this paper proposes a software reliability model based on stochastic differential equations and generalized inflection point S-type fault detection rate, and uses the maximum likelihood estimation method to estimate the parameters of the model. Finally, it is verified on the data set of A Bank test center, and the experimental results show that the proposed model has the best fitting effect on the experimental data. Therefore, this model has advantages over other classical software reliability models.
| [1] | Wang, J., Zhang, C. and Yang, J. (2022) Software Reliability Model of Open Source Software Based on the Decreasing Trend of Fault Introduction. PLOS ONE, 17, e0267171. https://doi.org/10.1371/journal.pone.0267171 |
| [2] | Rani, P. and Mahapatra, G.S. (2019) A Novel Approach of NPSO on Dynamic Weighted NHPP Model for Software Reliability Analysis with Additional Fault Introduction Parameter. Heliyon, 5, e02082. https://doi.org/10.1016/j.heliyon.2019.e02082 |
| [3] | Li, Q., Li, H. and Lu, M. (2015) Incorporating S-Shaped Testing-Effort Functions into NHPP Software Reliability Model with Imperfect Debugging. Journal of Systems Engineering and Electronics, 26, 190-207. https://doi.org/10.1109/jsee.2015.00024 |
| [4] | Li, Q. and Pham, H. (2019) A Generalized Software Reliability Growth Model with Consideration of the Uncertainty of Operating Environments. IEEE Access, 7, 84253-84267. https://doi.org/10.1109/access.2019.2924084 |
| [5] | Jain, M., Manjula, T. and Gulati, T.R. (2014) Imperfect Debugging Study of SRGM with Fault Reduction Factor and Multiple Change Point. International Journal of Mathematics in Operational Research, 6, 155-175. https://doi.org/10.1504/ijmor.2014.059526 |
| [6] | Song, K., Chang, I. and Pham, H. (2017) A Software Reliability Model with a Weibull Fault Detection Rate Function Subject to Operating Environments. Applied Sciences, 7, Article 983. https://doi.org/10.3390/app7100983 |
| [7] | Chaudhary, K., Kapur, P.K., Kumar, P. and Kumar, V. (2024) Stochastic Software Reliability Growth Modelling with Fault Introduction and Change Point. International Journal of System Assurance Engineering and Management. https://doi.org/10.1007/s13198-024-02406-8 |
| [8] | Chatterjee, S., Chaudhuri, B. and Bhar, C. (2020) Optimal Release Time Determination via Fuzzy Goal Programming Approach for SDE-Based Software Reliability Growth Model. Soft Computing, 25, 3545-3564. https://doi.org/10.1007/s00500-020-05385-7 |
| [9] | Yang, J., Ding, M., He, M., Zheng, Z. and Yang, N. (2024) SDE-Based Software Reliability Additive Models with Masked Data Using ELS Algorithm. Journal of King Saud University-Computer and Information Sciences, 36, Article 101978. https://doi.org/10.1016/j.jksuci.2024.101978 |
| [10] | Deepika, Singh, O., Anand, A. and Singh, J. (2020) SDE Based Unified Scheme for Developing Entropy Prediction Models for OSS. International Journal of Mathematical, Engineering and Management Sciences, 6, 207-222. https://doi.org/10.33889/ijmems.2021.6.1.013 |
| [11] | Kapur, P.K., Anand, S., Yamada, S. and Yadavalli, V.S.S. (2009) Stochastic Differential Equation‐Based Flexible Software Reliability Growth Model. Mathematical Problems in Engineering, 2009, Article 581383. https://doi.org/10.1155/2009/581383 |
| [12] | Fang, C. and Yeh, C. (2015) Effective Confidence Interval Estimation of Fault-Detection Process of Software Reliability Growth Models. International Journal of Systems Science, 47, 2878-2892. https://doi.org/10.1080/00207721.2015.1036474 |
