Floating Dock with Automatic Early Detection for Tidal Mitigation and Tidal Flooding with IOT-Based Instruments
DOI:
https://doi.org/10.32815/jpm.v6i2.2829Keywords:
Floating Dock, Desa Palaes; kelompok wanita; air kelapa; probiotik; yogurt, Tidal Mitigation, Tidal Flooding, Early Warning SystemAbstract
Purpose: Coastal areas frequently face the threat of increasingly intense tidal and tidal flooding due to climate change and sea level rise. These conditions disrupt dock operations and endanger the safety of infrastructure and surrounding communities. To address these challenges, this research designed and developed a new system.
Method: An Internet of Things (IOT)-based Automatic Early Detection Floating Dock is an adaptive mitigation solution. The system is equipped with various sensors, including ultrasonic sensors, water pressure sensors, and a GPS module, to monitor sea level in real time.
Practical Applications: Collected data is automatically transmitted to an online monitoring platform using a wireless connection, enabling rapid analysis and early warnings to stakeholders. An adaptive floating mechanism allows the pier to automatically adjust its height according to changing water levels, ensuring its operational and safe operation.
Conclusion: System testing demonstrated that the tool can predict potential tidal flooding early and function stably in dynamic marine conditions. This innovation not only increases the resilience of dock infrastructure but also provides direct benefits for early warning systems in coastal areas. The application of this technology is expected to be part of a long-term adaptation strategy to the impacts of climate change in coastal areas.
References
Alfonso Macías-Tapia, M. R. (2021). Effects of tidal flooding on estuarine biogeochemistry: Quantifying flood-driven nitrogen inputs in an urban, lower Chesapeake Bay sub-tributary. Water Research.
Byungho Kang, S. X. (2025). Accelerated land loss and nuisance flooding potential in the Barataria Basin: The impacts of land subsidence, sea-level rise, and tidal dynamics. Journal of Sea Research.
Faria T. Zahura, J. L. (2022). Kai Wang, F. Z. (2025). The response of dissolved organic matter dynamics to flood events in tidal estuaries. Journal of Environmental Management Journal of Hydrology: Regional Studies.
Kenneth B. Raposa, K. W. (2016). Assessing tidal marsh resilience to sea-level rise at broad geographic. Biological Conservation, 263-275.
Laura Falchi, P. L. (2024). On the contribution of tidal floods on damp walls of Venice. International Journal of Disaster Risk Reduction, 110.
Makan A. Karegar, T. H. (2015). A three-dimensional surface velocity field for the Mississippi Delta: Implications for coastal restoration and flood potential. Geology.
Manoochehr Shirzaei, J. F. (2021). Measuring, modelling and projecting coastal land subsidence. Nature Reviews Earth & Environment.
Rachel A. Burns, R. P. (2025). Numerical modelling of the hydrodynamics driven by tidal flooding of the land surface after dyke breaching. Nature-Based Solutions, 7.
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Copyright (c) 2025 Sinung Widiyanto, G. A. P. Poundra, B. K. Aditya, H. Suyanto, M. I. Z. Ramadhon, F. H. Prihantoro
This work is licensed under a Creative Commons Attribution 4.0 International License.
