Modeling and analysis of software fault detectability and removability with time variant fault exposure ratio, fault removal efficiency, and change point

Chatterjee, Saikat; Shukla, Ankur; Pham, Hoang

doi:10.1177/1748006x18772930

Cited by 10 publications

(8 citation statements)

References 39 publications

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“…Zhu and Pham 13 introduced a two-phase fault removal process by categorizing faults into independent and dependent types with imperfect fault removal phenomenon. Chatterjee et al 14 proposed a framework to develop fault detection and correction model with time-dependent fault introduction rate, fault removal rate and change point. Later, Chatterjee and Shukla 15 developed a unified approach to develop testing coverage-based SRGM by incorporating fault detection probability, imperfect debugging, and change point.…”

Section: Literature Reviewmentioning

confidence: 99%

Software reliability and cost models with warranty and life cycle

Shrivastava

Sharma

Pham

2022

Proceedings of the Institution of Mechanical Engineers, Part O:

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With increasing number of tech-savvy users, the demand for software with advanced features is also growing exponentially. To meet these expectations, software firms are coming up with innovative strategies to attract customers to buy their products and remain loyal. One of the key strategies is to provide product assurance is post-sales support. Software firms provide a warranty to fix the failures encountered during the operational phase for a pre-defined time period. Software reliability literature consists of various modeling framework to decide release time under pre-defined warranty period under the consideration of no post-release testing. Very limited work has been done in the direction of post-release testing with warranty. In this work, we propose a framework to obtain optimal release and warranty time of software to minimize the overall cost under reliability constraint. We have provided the algorithm to obtain the analytical solution of release and warranty time. To make our proposed work more realistic we have considered the change point phenomenon and imperfect debugging of fault in our modeling framework. We have also conducted a sensitivity analysis on the model parameters to check their impact of the firms scheduling strategy. The proposed work is validated on a real-life data set.

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Section: Literature Reviewmentioning

confidence: 99%

Software reliability and cost models with warranty and life cycle

Shrivastava

Sharma

Pham

2022

Proceedings of the Institution of Mechanical Engineers, Part O:

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“…Chatterjee and Shukla 43 also proposed fault identification and correction process SRGM for reliability estimation. Chatterjee et al 6 developed SRGM for reliability assessment with the incorporation of fault detectability. The fault exposure ratio, fault removability and fault removal efficiency have been studied together during the formulation of SRGM.…”

Section: Model Namementioning

confidence: 99%

“…4 Over the past four decades, many SRGMs have been introduced for fault prediction and reliability growth estimation of software. 5,6 Several studies on software fault prediction have recently gained much attention because they assist the software testing team in improving the software system's quality and productivity. Since the software errors or faults can be detected and corrected, the SRGMs measure the reliability growth.…”

Section: Introductionmentioning

confidence: 99%

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Modelling software reliability growth through generalized inflection S-shaped fault reduction factor and optimal release time

Pradhan

Kumar

Dhar

2021

Proceedings of the Institution of Mechanical Engineers, Part O:

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The fault reduction factor (FRF) is a significant parameter for controlling the software reliability growth. It is the ratio of net fault correction to the number of failures encountered. In literature, many factors affect the behaviour of FRF, namely fault dependency, debugging time-lag, human learning behaviour and imperfect debugging. Besides this, several distributions, for example, inflection S-shaped, Weibull and Exponentiated-Weibull, are used as FRF. However, these standard distributions are not flexible to describe the observed behaviour of FRFs. This paper proposes three different software reliability growth models (SRGMs), which incorporate a three-parameter generalized inflection S-shaped (GISS) distribution as FRF. To model realistic SRGMs, time lags between fault detection and fault correction processes are also incorporated. This study proposed two models for the single release, whereas the third model is designed for multi-release software. Moreover, the first model is in perfect debugging, while the rest of the two are in an imperfect debugging environment. The extensive experiments are conducted for the proposed models with six single release and one multi-release data-sets. The choice of GISS distribution as an FRF improves the software reliability evaluation in comparison with the existing systems in the literature. Finally, the development cost and optimal release time are calculated in a perfect debugging environment.

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“…In the design and implementation phase, which deals with code and its features, supervised methods and fuzzy inference system are the basic methods for evaluating reliability, and in the test phase, if the failure data is based on the number of failures observed in each time period or is recorded according to the time between failures, statistical models indicating the growth rate of reliability can be used to identify the data recording process 21,22 . These are known as software reliability growth models (SRGM) or growth models in general, 23–28 , which are used for both prediction and assessment of software reliability.…”

Section: Introductionmentioning

confidence: 99%

Software reliability prediction: A survey

Oveisi

Moeini

Mirzaei

et al. 2022

Quality & Reliability Eng

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Softwares play an important role in controlling complex systems. Monitoring the proper functioning of the components of such systems is the principal role of softwares. Often, a petite fault in one of the subsystems may cause irreparable damages; therefore, it is of great importance to be able to predict software faults and estimate the reliability of softwares. In this survey, we present a classification of various methods proposed in the literature to predict software reliability. This study summarizes the results of more than 200 research papers in the field. We also discuss the challenges involved in prediction methods along with proposed partial solutions (i.e., Bayesian methods) to improve the accuracy of such predictions. Moreover, we review numerous evaluation measures introduced so far to assess the performance of prediction models, the datasets they are based on, and also the results they yield.

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Modeling and analysis of software fault detectability and removability with time variant fault exposure ratio, fault removal efficiency, and change point

Cited by 10 publications

References 39 publications

Software reliability and cost models with warranty and life cycle

Software reliability and cost models with warranty and life cycle

Modelling software reliability growth through generalized inflection S-shaped fault reduction factor and optimal release time

Software reliability prediction: A survey

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