Urbanization and climate change are exerting increasing pressure on urban infrastructures and ecosystems, necessitating advanced rainfall modelling for sustainable city planning and effective water resource management. Accurate urban rainfall modelling is essential for predicting and mitigating flood risks, optimizing drainage systems, and ensuring the resilience of urban environments to climate variability. One critical yet often overlooked component in this modelling process is the resolution of Digital Terrain Models used within 3D city models. The resolution of DTMs significantly influences the precision of rainfall-runoff simulations, which are vital for predicting urban flooding and managing water resources effectively. This study employs a comparative analysis of high-resolution (0.5 meter LiDAR), medium-resolution (5 meter IFSAR), and low-resolution (30 meter SRTM) DTMs to assess their impact on the modelling of rainfall events in Section 13 of Petaling Jaya urban settings. By focusing on Level of Detail 1 building models, which represent the basic geometry of buildings, and open terrain footprints, which are areas without buildings or dense vegetation, this study assesses water level trends in urban environments, identifying areas with increasing (up trends) or decreasing (down trends) water levels. The findings highlight that the high-resolution DTMs provide the most accurate water depth predictions, essential for precise urban flood modelling. Medium-resolution DTMs offer a balance between detail and computational efficiency, while low-resolution DTMs, despite indicating significant trends, show higher variability and less reliability. This study demonstrates that high-resolution DTMs are critical for developing accurate urban rainfall models, which are essential for sustainable urban development and effective flood management.

Keywords: DTMs, rainfall modelling, 3D city models, raster resolutions, climate change, urban study

Agonafir, C., Lakhankar, T., Khanbilvardi, R., Krakauer, N., Radell, D., & Devineni, N. (2023). A review of recent advances in urban flood research. Water Security, 19, 100141.

Escobar-Silva, E. V., Almeida, C. M. D., Silva, G. B. L. D., Bursteinas, I., Rocha Filho, K. L. D., de Oliveira, C. G., Fagundes, M. R., & de Paiva, R. C. D. (2023). Assessing the extent of flood-prone areas in a south american megacity using different high resolution DTMs. Water, 15(6), 19.

Hassan, H., & Abdul Rahman, S. A. F. S. (2021). Integration of aerial photography, airborne LiDAR, and Airborne IFSAR for mapping in Malaysia. IOP Conference Series: Earth and Environmental Science, 767, 012020.

Majlis Bandaraya Petaling Jaya. (2019). Draf Rancangan Kawasan Khas (RKK) Seksyen 13, Petaling Jaya: Pengubahan 1. https://www.mbpj.gov.my/sites/default/files/21122019_draf_rancangan_kawasan_khas_rkk_seksyen_13_petaling_jaya_pengubahan_1.pdf

Md Dali, M., Sharifi, A., & Mohd Adnan, Y. (2022). Envisioning sustainable and resilient Petaling Jaya through low-carbon and smart city framework. In Resilient Smart Cities (pp. 213-238). Springer.

Montero, P., & Vilar, J. A. (2015). TSclust: An R package for time series clustering. Journal of Statistical Software, 62, 1-43.

Pa’suya, F. M., Talib, N., Narashid, R. H., Fauzi, A. A., Mohd, F. A., & Abdullah, M. A. (2022). Quality assessment of TanDEM-X DEM 12m using GNSS-RTK and Airborne IFSAR DEM: A case study of Tuba Island, Langkawi. International Journal of Geoinformatics, 18(5), 87-103.

Qi, W., Ma, C., Xu, H., Chen, Z., Zhao, K., & Han, H. (2021). A review on applications of urban flood models in flood mitigation strategies. Natural Hazards, 108, 31-62

Ramyar, R., Ackerman, A., & Johnston, D. M. (2021). Adapting cities for climate change through urban green infrastructure planning. Cities, 117, 103316

Song, H., & Jung, J. (2023). An object-based ground filtering of airborne LiDAR data for large-area DTM generation. Remote Sensing, 15(16), 4105.

Trepekli, K., Balstrøm, T., Friborg, T., Fog, B., Allotey, A. N., Kofie, R. Y., & Møller-Jensen, L. (2022). UAV-borne, LiDAR-based elevation modelling: A Method for improving local-scale urban flood risk assessment. Natural Hazards, 113(1), 423-451.

Zhao, G. (2020). A Sub-Model Approach for Fast Large-Scale High-Resolution Two-Dimensional Urban Surface Flood Modelling [Doctoral dissertation, University of Copenhagen].