Multi-objective optimization for improved tunneling project management from planning to operation stages
Project management aims to achieve better project performance by making some changes in the construction projects, and a lot of activities could be involved in the process, such as project planning, design, and safety management. The key of achieving project performance improvement is to improve...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2023
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| Online Access: | https://hdl.handle.net/10356/164561 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Project management aims to achieve better project performance by making some
changes in the construction projects, and a lot of activities could be involved in the
process, such as project planning, design, and safety management. The key of achieving
project performance improvement is to improve particular aspects of the target project,
i.e., to realize the project improvement through the optimization of closely related
influential factors that can contribute to the desired project performance. Traditionally,
the optimization problems in construction projects are often set as single-objective
optimization. However, it should be noticed that though many studies focused on the
optimization of one main aspect for improving the project management, the project
integration, i.e., elements of the project that can be effectively coordinated, is
fundamental to achieve the project improvement. Factors in the construction project are
closely related to each other, and even one particular aspect is set as the main objective,
other factors are inevitably involved.
In fact, the construction project has the nature of complexity and uncertainty. The
project improvement tasks often involve many different factors, and a conflicting
relationship could even exist between the factors. The project improvement-related tasks,
such as design, scheduling, safety management, and others, are inherently characterized
by solving the conflicts between those objectives to achieve better performance. With
the recognition of the importance of considering different objectives simultaneously and
the crucial role of the project integration for the project performance, more and more
researchers began to investigate the project improvement from the perspective of
optimizing the desired multi-objectives at the same time, i.e., the multi-objective
optimization (MOO) perspective. However, compared to other industries, the
development and applications of MOO for construction projects have not been as fast
and wide as expected. The complexity of construction projects necessitates the
incorporation of MOO and also poses a huge challenge to solve project problems from
the MOO perspective.
To promote project management and explore the methods of incorporating MOO
into the construction industry, this thesis proposes approaches with the integration of
MOO methods to improve project performance of tunneling projects covering planning,
designing, construction, and operation stages. For the planning stage, a hybrid approach
with the integration of real option theory and MOO is proposed to seek the optimized
concession period that can benefit both the private and public sectors in a public private
partnership (PPP) tunneling project. For the designing stage, a genetic algorithm-based
approach is proposed with the attempt of striking a balance between objectives of the
cost, comfortable degree and headway for a tunnel alignment project. For the
construction stage, an innovative approach with the integration of random forest (RF)
and non-dominant sorting genetic algorithm-II (NSGA-II) is suggested for the
optimization of tunnel-induced damage mitigation during the tunneling process. For the
operation stage, a hybrid approach by incorporating BIM model, evacuation simulation
tool (Anylogic), and MOO algorithms is built to find out the possible optimal solutions
to improve the evacuation efficiency at metro stations in case of emergency events. |
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