Pendekatan Machine Learning dalam Memetakan Kesesuaian Habitat Mal

Daud Yusuf, Muhammad Karim, Tahir Tahir, Emy Saelan, M. Iqbal Liayong Pratama

Abstract


Climate change and increasing anthropogenic pressure pose serious threats to endemic species with restricted distributions, such as the Maleo (Macrocephalon maleo) of Sulawesi. This study aims to model habitat suitability and potential distribution of the Maleo using an integrated Geographic Information System and Maximum Entropy approach. Presence-only occurrence data were combined with bio-physical and anthropogenic environmental variables to generate spatial predictions of habitat suitability across coastal and lowland landscapes. The model demonstrated strong predictive performance, indicating that the selected variables effectively captured the ecological requirements of the species. Habitat suitability patterns revealed that sandy soil characteristics, proximity to natural heat sources, and river systems were the most influential factors enhancing habitat suitability, reflecting the species’ unique reproductive ecology. In contrast, proximity to roads and settlements consistently reduced suitability, highlighting the negative impact of human disturbance. The continuous suitability output was further classified into core habitat and buffer zones to support conservation-oriented spatial planning. The resulting zoning framework identifies priority areas for protection and management, particularly outside formal protected areas where development pressure is high. Overall, this study provides robust spatial evidence for understanding Maleo habitat requirements and offers a transferable methodological framework for modeling other endemic species. The findings underscore the importance of integrating ecological and human dimensions in habitat modeling to support effective, evidence-based conservation strategies

Keywords


Maleo; habitat suitability modeling; Maximum Entropy; Geographic Information System; endemic species conservation

Full Text:

PDF

References


Bald, L., Gottwald, J., & Zeuss, D. (2023). spatialMaxent: Adapting species distribution modeling to spatial data. Ecology and Evolution, 13(10), e10635.

Datta, P., Behera, B., Rahut, D. B., & Sonobe, T. (2025). Human-Wildlife Dynamics in a Changing Climate. In Living on the Edge: Climate Change and Human-Wildlife Interactions in the Buxa Tiger Reserve of India (pp. 1–14). Springer.

Diko, A. F. C., Yusuf, D., & Rusiyah, R. (2026). Identifikasi Habitat Alami Maleo Senkawor (Macrocephalon Maleo) Di Kawasan Konservasi Hungayono Taman Nasional Bogani Nani Wartabone. Jurnal Riset Dan Pengabdian Interdisipliner, 3(1), 8–15.

Gayo, L. (2025). A review of climate change, human population growth and poverty as potential drivers of human wildlife conflicts in Africa. Discover Animals, 2(1), 49.

Hofmann, G. S., Weber, E. J., Bastazini, V. A. G., Rossatto, D. R., Franco, A. C., Granada, C. E., Kaminski, L. A., Ubaid, F. K., Leandro‐Silva, V., & Borges‐Martins, M. (2025). Climate change in the Brazilian Cerrado: A looming threat to terrestrial biodiversity. Wiley Interdisciplinary Reviews: Climate Change, 16(5), e70022.

INDONESIA, H. (2025). MENGENAL JENIS-JENIS FLORA. Hutan Indonesia Potensi Permasalahan Dan Pengelolaan Berkelanjutan, 25.

Jha, M. K., & Dev, M. (2024). Impacts of climate change. In Smart internet of things for environment and healthcare (pp. 139–159). Springer.

Karim, H. A., Najib, N. N., Ayu, S. M., & Fidel, F. (2023). Characteristics of Maleo bird spawning nests (Macrocephalon maleo) in Lake Towuti, South Sulawesi, Indonesia. Biodiversitas Journal of Biological Diversity, 24(2).

Mehta, P. (2024). The impact of climate change on the environment, water resources, and agriculture: A comprehensive review. Climate, Environment and Agricultural Development: A Sustainable Approach Towards Society, 189–201.

Ong’ondo, F. J., Ambinakudige, S., Malaki, P. A., Njoroge, P., & Ahmad, H. (2025). Using geographic information systems and remote sensing technique to classify land cover types and predict grassland bird abundance and distribution in Nairobi National Park, Kenya. International Journal of Geoheritage and Parks, 13(1), 92–101.

Prins, C., Sreekumar, D., & Sejian, V. (2025). Climate change and wildlife biodiversity: Impact and mitigation strategies. Arch. Life Sci. Res, 1, 6–22.

Radović, A., Kapelj, S., & Taylor, L. T. (2025). Utilizing Remote Sensing Data for Species Distribution Modeling of Birds in Croatia. Diversity, 17(6), 399.

Shaheryar, M., Safiullah, D., Hayat, H. S., Shah, M. N., Akram, M. T., Iqbal, M. U., Hayat, A., & Naseem, M. A. (2025). Climate Change and Environmental Instability: The Rise of Invasive Species and Desertification. In Navigating Climate Change: Impacts on Biodiversity and Ecosystem Resilience (pp. 553–589). Springer.

Summers, M., Geary, M., Tasirin, J. S., Djuni, N., Summers, L. J., Kresno, P. A., Laya, A., Sawuwu, S. M., Bawotong, A., & Abas, W. (2025). Massive declines and local recoveries: First range-wide assessment spotlights ending egg-taking as key to the survival of Macrocephalon maleo (Maleo). Ornithological Applications, duaf022.

Tasirin, J. S., Iskandar, D. T., Laya, A., Kresno, P., Suling, N., Oga, V. T., Djano, R., Bawotong, A., Nur, A., & Isfanddri, M. (2021). Maleo Macrocephalon maleo population recovery at two Sulawesi nesting grounds after community engagement to prevent egg poaching. Global Ecology and Conservation, 28, e01699.

Wu, J., Zheng, M., & Wang, Z. (2025). Integrating MaxEnt and Random Forest Models to Assess Habitat Suitability of Black‐Necked Cranes, A Case Study in Nyingchi City. Ecology and Evolution, 15(9), e72058.

Yusuf, D., Baderan, D. W. K., Hamidun, M. S., Rahim, S., & Dunggio, I. (2024). Analisis bibliometrik penelitian burung maleo. Jurnal Bionatural, 11(1), 74–79.

Zhang, X., Campomizzi, A. J., & Lebrun‐Southcott, Z. M. (2022). Predicting population trends of birds worldwide with big data and machine learning. Ibis, 164(3), 750–770.

Zvidzai, M., Mawere, K. K., N’andu, R., Ndaimani, H., Zanamwe, C., & Zengeya, F. M. (2023). Application of Maximum Entropy (MaxEnt) to Understand the Spatial Dimension of Human–wildlife Conflict (HWC) Risk in Areas Adjacent to Gonarezhou National Park of Zimbabwe. Ecology and Society, 28(3). https://doi.org/10.5751/es-14420-280318




DOI: https://doi.org/10.37905/geojpg.v4i2.36472

Refbacks

  • There are currently no refbacks.


Copyright (c) 2025 Daud Yusuf, Muhammad Karim, Tahir Tahir, Emy Saelan, M. Iqbal Liayong Pratama

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.