Pareto Efficient Multi Objective Optimization for Local Tuning of Analogy Based Estimation
Mohammad Azzeh, Ali Bou Nassif, Shadi Banitaan, Fadi Almasalha

TL;DR
This paper presents a multi-objective optimization approach using Particle Swarm Optimization to tune key variables in analogy-based effort estimation, improving accuracy without degrading other evaluation metrics.
Contribution
It introduces a novel multi-objective optimization framework for tuning adaptation variables in analogy-based estimation, enhancing overall prediction performance.
Findings
Optimized decision variables improve estimation accuracy.
Multi-objective approach balances multiple evaluation metrics.
Particle Swarm Optimization effectively finds optimal solutions.
Abstract
Analogy Based Effort Estimation (ABE) is one of the prominent methods for software effort estimation. The fundamental concept of ABE is closer to the mentality of expert estimation but with an automated procedure in which the final estimate is generated by reusing similar historical projects. The main key issue when using ABE is how to adapt the effort of the retrieved nearest neighbors. The adaptation process is an essential part of ABE to generate more successful accurate estimation based on tuning the selected raw solutions, using some adaptation strategy. In this study we show that there are three interrelated decision variables that have great impact on the success of adaptation method: (1) number of nearest analogies (k), (2) optimum feature set needed for adaptation, and (3) adaptation weights. To find the right decision regarding these variables, one need to study all possible…
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Taxonomy
TopicsSoftware Engineering Research · Advanced Multi-Objective Optimization Algorithms · Software Reliability and Analysis Research
