A software reliability growth model for test-effort management

Yamada, Shigeru; Hishitani, Jun; Osaki, Shunji

doi:10.1109/cmpsac.1991.170243

Cited by 4 publications

(4 citation statements)

References 27 publications

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“…The likelihood function L is: m(t) is the estimated model, m k is the cumulative number of faults detected in time interval (0, t k ], and t 0 =m 0 =0. Take the logarithm of the likelihood function in Eq (19),. (20).…”

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confidence: 99%

Software Reliability Modeling withWeibull-type Testing-Effort and Multiple Change-Points

Lin

Huang

2005

TENCON 2005 - 2005 IEEE Region 10 Conference

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Software reliability is defined as the probability of failure-free software operation for a specified period of time in a specified environment. Over the past 30 years, many software reliability growth models (SRGMs) have been proposed for estimation of reliability growth of products during software development processes. SRGMs proposed in the literature took into consideration the amount of testing-effort spent on software testing which can be depicted as a Weibull-type curve. However, in reality, the consumption rate of testing-effort expenditures may not be a constant and could be changed at some time points. Therefore, in this paper, we will incorporate the concept of multiple change-points into the Weibull-type testing-effort function. New model is proposed and the applicability of proposed model is demonstrated through real software failure data set. Our experimental results show that the proposed model has a fairly accurate prediction capability.

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confidence: 99%

Software Reliability Modeling withWeibull-type Testing-Effort and Multiple Change-Points

Lin

Huang

2005

TENCON 2005 - 2005 IEEE Region 10 Conference

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“…[6][7][12][13] and was a simple modification of the NHPP to obtain an S-shaped growth curve for the cumulative number of failures detected. This model's software fault detection process can be viewed as a learning process that the software testers become familiar with the testing environments and tools as time progresses, these testers' skills gradually improve and then level off as the residual faults become more difficult to uncover [1,[6][7][12][13]. Because the original S-shaped model is for the analysis of fault isolation data, i.e.…”

Section: Yamada S-shaped Model With Logistic Testing-effort Functionmentioning

confidence: 99%

“…Musa et al [2][3] and Ohba [6] showed that the effort index or the execution time is a better time domain for software reliability modeling than the calendar time because the shape of observed reliability growth curve depends strongly on the time distribution of the testing-effort. Recently, Yamada et al [10][11][12][13] and Huang et al [14][15][16] proposed a new and simple SRGM which describes the relationship among the calendar testing, the amount of testing-effort, and the number of software faults detected by testing. The test-effort index is measured by the number of CPU hours, the number of test runs, and so on.…”

Section: Introductionmentioning

confidence: 99%

“…significant test-effort is required, such as the number of test cases, human power, and CPU time. As usual, the test-effort during the testing phase and the time-dependent behavior of development effort in the software development process can be described by a Weibull-type consumption curve, see Yamada et al [10][11][12][13]. In fact, since actual testing-effort data represent various expenditure patterns, sometimes the testing-effort expenditures are difficult to be described by only an exponential or a Rayleigh curve.…”

Section: Introductionmentioning

confidence: 99%

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Effort-index-based software reliability growth models and performance assessment

Huang

Kuo

Lyu

Proceedings 24th Annual International Computer Software and Applications Conference. COMPSAC2000

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In this paper, we first show that the logistic testing-effort function is practically acceptable/helpful for modeling software reliability growth and providing a reasonable description of resource consumption. Therefore, in addition to the exponential-shaped models, we will integrate the logistic testing-effort function into S-shaped model for further analysis. The model is designated as the Yamada Delayed S-shaped model. A realistic failure data set is used in the experiments to demonstrate the estimation procedures and results. Furthermore, the analysis of the proposed model under imperfect debugging environment is investigated. In fact, from these experimental results and discussions, it is apparent that the logistic testing-effort function is well suitable for making estimations of resource consumption during the software development/testing phase. 2. Software reliability growth modeling and testing-effort function 2.1 SRGM with logistic testing-effort function In this section, we will first review logistic testing-effort functions. During the software-testing phase,

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Integrating generalized Weibull-type testing-effort function and multiple change-points into software reliability growth models

Lin

Huang

Chang

2005

12th Asia-Pacific Software Engineering Conference (APSEC'05)

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A software reliability growth model for test-effort management

Cited by 4 publications

References 27 publications

Software Reliability Modeling withWeibull-type Testing-Effort and Multiple Change-Points

Software Reliability Modeling withWeibull-type Testing-Effort and Multiple Change-Points

Effort-index-based software reliability growth models and performance assessment

Integrating generalized Weibull-type testing-effort function and multiple change-points into software reliability growth models

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