Details
| Original language | English |
|---|---|
| Article number | 108013 |
| Journal | Computers and Structures |
| Volume | 319 |
| Early online date | 28 Oct 2025 |
| Publication status | Published - Dec 2025 |
Abstract
Tuned Mass Dampers (TMDs) are widely used to suppress excessive vibrations in dynamically excited structures. However, traditional optimization techniques such as Genetic Algorithms (GA) and Particle Swarm Optimization (PSO) often struggle with slow convergence and suboptimal tuning. This study introduces a Quantum-Theory-Based Optimization (QPSO) approach for optimizing TMD parameters in Single-Degree-of-Freedom (SDOF) systems. By leveraging quantum mechanics-inspired principles, QPSO enhances global search efficiency, leading to improved damping performance while reducing computational costs (50 and 200 population size). The optimization objective is to minimize peak structural response, ensuring optimal energy dissipation and vibration suppression. The study systematically evaluates the effectiveness of QPSO by comparing its performance with GA in both deterministic and uncertain environments. Deterministic analysis demonstrates that QPSO significantly reduces peak displacement and acceleration, particularly for high-rise structures where longer tuning periods enhance damping efficiency. The uncertainty analysis, conducted using Monte Carlo Simulations (MCS), discloses that QPSO-optimized TMDs remain robust even when structural parameters (stiffness and damping) vary within a ± 15 % range. Additionally, statistical evaluations using Probability Density Functions (PDFs) and Cumulative Distribution Functions (CDFs) confirm that QPSO minimizes the likelihood of extreme vibration events more effectively than GA. The findings establish QPSO as a superior alternative to conventional metaheuristic methods for optimizing TMD parameters. By integrating closed-form solutions (Den Hartog, Sadek) as initial estimates, QPSO achieves faster convergence and ensures globally optimized damping configurations. The proposed method is particularly beneficial for high-rise buildings, bridges, and dynamically sensitive structures, where vibration mitigation under uncertainty is critical. Furthermore, the application of the proposed QPSO approach to Multi-Degree-of-Freedom (MDOF) systems is also presented, demonstrating its effectiveness for more complex structural models.
Keywords
- Quantum-inspired optimization, SDOF, Structural vibration control, Transfer function, Tuned Mass Damper (TMD)
ASJC Scopus subject areas
- Engineering(all)
- Civil and Structural Engineering
- Mathematics(all)
- Modelling and Simulation
- Materials Science(all)
- General Materials Science
- Engineering(all)
- Mechanical Engineering
- Computer Science(all)
- Computer Science Applications
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In: Computers and Structures, Vol. 319, 108013, 12.2025.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - A novel quantum-theory-based optimization of tuned mass dampers for structural vibration control
AU - Elias, Said
AU - Beer, Michael
N1 - Publisher Copyright: © 2025 The Author(s)
PY - 2025/12
Y1 - 2025/12
N2 - Tuned Mass Dampers (TMDs) are widely used to suppress excessive vibrations in dynamically excited structures. However, traditional optimization techniques such as Genetic Algorithms (GA) and Particle Swarm Optimization (PSO) often struggle with slow convergence and suboptimal tuning. This study introduces a Quantum-Theory-Based Optimization (QPSO) approach for optimizing TMD parameters in Single-Degree-of-Freedom (SDOF) systems. By leveraging quantum mechanics-inspired principles, QPSO enhances global search efficiency, leading to improved damping performance while reducing computational costs (50 and 200 population size). The optimization objective is to minimize peak structural response, ensuring optimal energy dissipation and vibration suppression. The study systematically evaluates the effectiveness of QPSO by comparing its performance with GA in both deterministic and uncertain environments. Deterministic analysis demonstrates that QPSO significantly reduces peak displacement and acceleration, particularly for high-rise structures where longer tuning periods enhance damping efficiency. The uncertainty analysis, conducted using Monte Carlo Simulations (MCS), discloses that QPSO-optimized TMDs remain robust even when structural parameters (stiffness and damping) vary within a ± 15 % range. Additionally, statistical evaluations using Probability Density Functions (PDFs) and Cumulative Distribution Functions (CDFs) confirm that QPSO minimizes the likelihood of extreme vibration events more effectively than GA. The findings establish QPSO as a superior alternative to conventional metaheuristic methods for optimizing TMD parameters. By integrating closed-form solutions (Den Hartog, Sadek) as initial estimates, QPSO achieves faster convergence and ensures globally optimized damping configurations. The proposed method is particularly beneficial for high-rise buildings, bridges, and dynamically sensitive structures, where vibration mitigation under uncertainty is critical. Furthermore, the application of the proposed QPSO approach to Multi-Degree-of-Freedom (MDOF) systems is also presented, demonstrating its effectiveness for more complex structural models.
AB - Tuned Mass Dampers (TMDs) are widely used to suppress excessive vibrations in dynamically excited structures. However, traditional optimization techniques such as Genetic Algorithms (GA) and Particle Swarm Optimization (PSO) often struggle with slow convergence and suboptimal tuning. This study introduces a Quantum-Theory-Based Optimization (QPSO) approach for optimizing TMD parameters in Single-Degree-of-Freedom (SDOF) systems. By leveraging quantum mechanics-inspired principles, QPSO enhances global search efficiency, leading to improved damping performance while reducing computational costs (50 and 200 population size). The optimization objective is to minimize peak structural response, ensuring optimal energy dissipation and vibration suppression. The study systematically evaluates the effectiveness of QPSO by comparing its performance with GA in both deterministic and uncertain environments. Deterministic analysis demonstrates that QPSO significantly reduces peak displacement and acceleration, particularly for high-rise structures where longer tuning periods enhance damping efficiency. The uncertainty analysis, conducted using Monte Carlo Simulations (MCS), discloses that QPSO-optimized TMDs remain robust even when structural parameters (stiffness and damping) vary within a ± 15 % range. Additionally, statistical evaluations using Probability Density Functions (PDFs) and Cumulative Distribution Functions (CDFs) confirm that QPSO minimizes the likelihood of extreme vibration events more effectively than GA. The findings establish QPSO as a superior alternative to conventional metaheuristic methods for optimizing TMD parameters. By integrating closed-form solutions (Den Hartog, Sadek) as initial estimates, QPSO achieves faster convergence and ensures globally optimized damping configurations. The proposed method is particularly beneficial for high-rise buildings, bridges, and dynamically sensitive structures, where vibration mitigation under uncertainty is critical. Furthermore, the application of the proposed QPSO approach to Multi-Degree-of-Freedom (MDOF) systems is also presented, demonstrating its effectiveness for more complex structural models.
KW - Quantum-inspired optimization
KW - SDOF
KW - Structural vibration control
KW - Transfer function
KW - Tuned Mass Damper (TMD)
UR - http://www.scopus.com/inward/record.url?scp=105020982897&partnerID=8YFLogxK
U2 - 10.1016/j.compstruc.2025.108013
DO - 10.1016/j.compstruc.2025.108013
M3 - Article
AN - SCOPUS:105020982897
VL - 319
JO - Computers and Structures
JF - Computers and Structures
SN - 0045-7949
M1 - 108013
ER -