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Fahmy, A, Hassan, T, Bassioni, H and McCaffer, R (2019) Dynamic scheduling model for the construction industry. Built Environment Project and Asset Management, 10(03), 313–30.

• Type: Journal Article
• Keywords: Scheduling; Resource management; Multi-objective optimization; Dynamic scheduling; Particle swarm; Resource-constrained project scheduling problem;
• ISBN/ISSN: 2044-124X
• URL: https://doi.org/10.1108/BEPAM-02-2019-0021
• Abstract:
  Basic project control through traditional methods is not sufficient to manage the majority of real-time events in most construction projects. The purpose of this paper is to propose a Dynamic Scheduling (DS) model that utilizes multi-objective optimization of cost, time, resources and cash flow, throughout project construction. Upon reviewing the topic of DS, a worldwide internet survey with 364 respondents was conducted to define end-user requirements. The model was formulated and solution algorithms discussed. Verification was reported using predefined problem sets and a real-life case. Validation was performed via feedback from industry experts. The need for multi-objective dynamic software optimization of construction schedules and the ability to choose among a set of optimal alternatives were highlighted. Model verification through well-known test cases and a real-life project case study showed that the model successfully achieved the required dynamic functionality whether under the small solved example or under the complex case study. The model was validated for practicality, optimization of various DS schedule quality gates, ease of use and software integration with contemporary project management practices. Optimized real-time scheduling can provide better resources management including labor utilization and cost efficiency. Furthermore, DS contributes to optimum materials procurement, thus minimizing waste. Optimized real-time scheduling can provide better resources management including labor utilization and cost efficiency. Furthermore, DS contributes to optimum materials procurement, thus minimizing waste. The paper illustrates the importance of DS in construction, identifies the user needs and overviews the development, verification and validation of a model that supports the generation of high-quality schedules beneficial to large-scale projects.

Geekiyanage, D and Ramachandra, T (2020) Nexus between running costs and building characteristics of commercial buildings: hedonic regression modelling. Built Environment Project and Asset Management, 10(03), 389–406.

Ling, F Y, Zhang, Z and Wong, W T (2020) How personality traits influence management styles of construction project managers. Built Environment Project and Asset Management, 10(03), 453–68.

Mathar, H, Assaf, S, Hassanain, M A, Abdallah, A and Sayed, A M (2020) Critical success factors for large building construction projects. Built Environment Project and Asset Management, 10(03), 349–67.

Mwesigwa, R, Nabwami, R, Mayengo, J and Basulira, G (2020) Contractual completeness as a cornerstone to stakeholder management in public private partnership projects in Uganda. Built Environment Project and Asset Management, 10(03), 469–84.

Shojaei, P and bolvardizadeh, A (2020) Rough MCDM model for green supplier selection in Iran: a case of university construction project. Built Environment Project and Asset Management, 10(03), 437–52.

Shooshtarian, S, Lingard, H and Wong, P S (2020) Using the cost of construction work to trigger legislative duties for WHS: the Australian experience. Built Environment Project and Asset Management, 10(03), 369–87.

Vilventhan, A and Rajadurai, R (2019) 4D Bridge Information Modelling for management of bridge projects: a case study from India. Built Environment Project and Asset Management, 10(03), 423–35.

Wuni, I Y and Shen, G Q (2020) Stakeholder management in prefabricated prefinished volumetric construction projects: benchmarking the key result areas. Built Environment Project and Asset Management, 10(03), 407–21.

Yap, J B H and Chow, I N (2020) Investigating the managerial ‘‘nuts and bolts’’ for the construction industry. Built Environment Project and Asset Management, 10(03), 331–48.