eISSN: 3087-4270 editor@aimjournals.com
All Journals
Submit your article

International Journal of Advanced Artificial Intelligence Research

Open Access Peer Review International
Open Access

Computational Representation and Structural Enhancement of Nature-Derived Collective Monitoring Behaviors

DOI https://doi.org/10.55640/
PDF
Rizky Pratama 1 , Dinda Maharani 1 ,
4 Department of Computer Science, Universitas Indonesia, Depok, Indonesia
4 School of Electrical Engineering and Informatics, Institute Technology Bandung, Bandung, Indonesia

Abstract

Collective monitoring behaviors observed in biological systems, particularly vigilance mechanisms in social animals, represent highly optimized solutions to distributed sensing, coordination, and risk mitigation. Translating these naturally evolved strategies into computational frameworks offers significant potential for advancing multi-agent systems, optimization algorithms, and intelligent surveillance applications. This study proposes a comprehensive computational representation and structural enhancement methodology for nature-derived collective monitoring behaviors, integrating insights from behavioral ecology, multi-agent reinforcement learning, and evolutionary optimization techniques.

The research begins by formalizing vigilance behavior through mathematical and algorithmic abstractions, capturing key dynamics such as group size effects, synchronization, stochastic decision-making, and adaptive coordination. Foundational theories from ecological studies on vigilance and cooperative behavior are integrated with computational paradigms, enabling the transformation of qualitative biological observations into quantitative models. Subsequently, the study introduces a hybrid optimization framework that combines genetic algorithms and particle swarm optimization to enhance structural efficiency in simulated multi-agent monitoring systems.

The proposed methodology is evaluated through simulated scenarios reflecting real-world applications, including distributed surveillance, environmental monitoring, and autonomous system coordination. Performance metrics such as detection latency, resource utilization, scalability, and robustness against uncertainty are analyzed. Results demonstrate that incorporating biologically inspired synchronization patterns and adaptive vigilance strategies significantly improves system performance compared to conventional approaches.

Furthermore, the study critically examines the trade-offs between model interpretability and computational complexity, highlighting the importance of balancing biological fidelity with algorithmic efficiency. Limitations related to environmental variability, parameter sensitivity, and scalability constraints are also discussed.

This research contributes to the interdisciplinary integration of ecological theory and computational intelligence by providing a structured framework for modeling and optimizing collective monitoring behaviors. The findings offer valuable insights for designing robust, scalable, and adaptive multi-agent systems applicable across domains such as smart cities, industrial monitoring, and autonomous networks.

Keywords

Collective vigilance, multi-agent systems, genetic algorithms, particle swarm optimization

References

📄 T Alam, S Qamar, A Dixit, et al Genetic Algorithm: Reviews, Implementations, and Applications [EB/OL]. ( 2020 - 07 - 05 ) [2025-08-31]. https://arxiv.org/abs/2007.12673.
📄 B Alhijawi, A Awajan. Genetic Algorithms: Theory, Genetic Operators, Solutions, and Applications [J]. Evolutionary Intelligence, 2024, 17 ( 3 ): 1245–1256.
📄 G Beauchamp. Should Vigilance Always Decrease with Group Size? [J]. Behavioral Ecology and Sociobiology, 2001, 51 ( 1 ): 47–52.
📄 G Beauchamp, P Alexander, R Jovani. Consistent Waves of Collective Vigilance in Groups Using Public Information About Predation Risk [J]. Behavioral Ecology, 2012, 23 ( 2 ): 368–374.
📄 P A Bednekoff, S L Lima. Randomness, Chaos and Confusion in the Study of Antipredator Vigilance [J]. Trends in Ecology & Evolution, 1998, 13 ( 7 ): 284–287.
📄 D P Bertsekas. A New Algorithm for the Assignment Problem [J]. Mathematical Programming, 1981, 21 ( 1 ): 152–171.
📄 J J Chai, Z J Zhao, Y H Zhu, et al. A Survey of Cooperative Multi-agent Reinforcement Learning for Multi-task Scenarios [J]. Artificial Intelligence Science and Engineering, 2025, 1 ( 2 ): 98–121.
📄 M Fang, L Ma. Study on a Multi-agent-Based Model for Equipment Maintenance and Repair System in Oil and Gas Production Enterprises [J]. China CIO News, 2012, ( 1 ): 34–36+58. (in Chinese).
📄 E H Houssein, A G Gad, K Hussain, et al. Major Advances in Particle Swarm Optimization: Theory, Analysis, and Application [J]. Swarm and Evolutionary Computation, 2021, 63 : 100868.
📄 X Kong, H Wang, S Li, et al. Searching Method for Maritime Distress Targets Based on Improved Particle Swarm Algorithm [J]. Computer Measurement & Control, 2025, 33 ( 3 ): 183–189. (in Chinese).
📄 Y Li, Y Shi, J Hu, et al. Optimization Method on Complex Product Workshop Layout Based on Improved Genetic Algorithm [J]. Ordnance Industry Automation, 2018, 37 ( 5 ): 67–72. (in Chinese).
📄 Z Li, H Shi, C Li, et al. Image Center Layout Optimization Method Based on Improved Genetic Algorithm [J]. Journal of System Simulation, 2022, 34 ( 6 ): 1173–1184. (in Chinese).
📄 H Lou. Application and Optimization Research of Multi-agent Reinforcement Learning in Smart City [D]. Changchun, China : Jilin University, 2024. (in Chinese).
📄 Pays, P C Renaud, P Loisel, et al. Prey Synchronize Their Vigilant Behaviour with Other Group Members [J]. Proceedings Biological Sciences, 2007, 274 : 1287–1291.
📄 R Papa, C Gargiulo, A Galderis. Toward an Urban Planners' Perspective on Smart City [J]. TeMA: Journal of Land Use, Mobility and Environment, 2013, 1 : 5–17.
📄 H Pan, M Chen. China General Nuclear Power Group (CGN) Research Institute: Enhancing Intelligent Operation and Maintenance Level of Nuclear Power Plants in China Through Innovation and Upgrading [J]. GuangDong Science & Technology, 2022, 31 ( 9 ): 25–28. (in Chinese).
📄 A E Rasa. Coordinated Vigilance in Dwarf Mongoose Family Groups: The “Watchman's Song” Hypothesis and the Costs of Guarding [J]. Ethology, 1986, 71 ( 4 ): 340–344.
📄 R Ren, C Hu, G Wu. Construction and Application Outlook of Agri-agent [J]. Agricultural Outlook, 2024, 20 ( 6 ): 92–106. (in Chinese).
📄 M Shafipour, A Rashno, S Fadaei. Particle Distance Rank Feature Selection by Particle Swarm Optimization [J]. Expert Systems with Applications, 2021, 185 ( 2 ): 115620.
📄 J Wang, J Cao, W Zhang. Animal Vigilance Behavior and Its Chinese Terminology [J]. Gansu Forestry Science and Technology, 2022, 47 ( 4 ): 52–56. (in Chinese).
📄 M A Whiteside, E J G Langley, J R Madden. Males and Females Differentially Adjust Vigilance Levels as Group Size Increases: Effect on Optimal Group Size [J]. Animal Behaviour, 2016, 118 : 11–18.
📄 Y Yin, Z Meng, C Zhao, et al. State-of-the-Art and Prospect of Research on Key Technical for Unmanned Farms of Field Crop [J]. Smart Agriculture, 2022, 4 ( 4 ): 1–25.
📄 Z Zhang, H Y Huang, N Zhao, et al. Improved Event-Triggered Adaptive Neural Network Control for Multi-agent Systems Under Denial-of-Service Attacks [J]. Artificial Intelligence Science and Engineering, 2025, 1 ( 2 ): 122–133.
📄 S Zhang, M Tang. Improved PSO Algorithm and Its Application in Route Planning of UAV [J]. Computer Systems & Applications, 2023, 32 ( 3 ): 330–337. (in Chinese).
📄 X Zhang, X Zheng, R Cheng, et al. A Competitive Mechanism Based Multiobjective Particle Swarm Optimizer with Fast Convergence [J]. Information Sciences, 2018, 427 : 63–76.
📄 Y Zhu. Research on Low-Carbon Logistics Distribution Route Based on Improved Genetic Algorithm [D]. Taiyuan, China : Shanxi University of Finance and Economics, 2023. (in Chinese).
📄 R Zhou. Large-Dimensional Multi-objective Particle Swarm Optimization and Its Application [D]. Nanchang, China : Nanchang Institute of Technology, 2024. (in Chinese).

Similar Articles

41-47 of 47

You may also start an advanced similarity search for this article.