Saved in:
Bibliographic Details
Main Authors: Akande, Hammed A., Gidado, Abdulrauf A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.02260
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917117978214400
author Akande, Hammed A.
Gidado, Abdulrauf A.
author_facet Akande, Hammed A.
Gidado, Abdulrauf A.
contents Increasing climate change and habitat loss are driving unprecedented shifts in species distributions. Conservation professionals urgently need timely, high-resolution predictions of biodiversity risks, especially in ecologically diverse regions like Africa. We propose EcoCast, a spatio-temporal model designed for continual biodiversity and climate risk forecasting. Utilizing multisource satellite imagery, climate data, and citizen science occurrence records, EcoCast predicts near-term (monthly to seasonal) shifts in species distributions through sequence-based transformers that model spatio-temporal environmental dependencies. The architecture is designed with support for continual learning to enable future operational deployment with new data streams. Our pilot study in Africa shows promising improvements in forecasting distributions of selected bird species compared to a Random Forest baseline, highlighting EcoCast's potential to inform targeted conservation policies. By demonstrating an end-to-end pipeline from multi-modal data ingestion to operational forecasting, EcoCast bridges the gap between cutting-edge machine learning and biodiversity management, ultimately guiding data-driven strategies for climate resilience and ecosystem conservation throughout Africa.
format Preprint
id arxiv_https___arxiv_org_abs_2512_02260
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle EcoCast: A Spatio-Temporal Model for Continual Biodiversity and Climate Risk Forecasting
Akande, Hammed A.
Gidado, Abdulrauf A.
Quantitative Methods
Machine Learning
Increasing climate change and habitat loss are driving unprecedented shifts in species distributions. Conservation professionals urgently need timely, high-resolution predictions of biodiversity risks, especially in ecologically diverse regions like Africa. We propose EcoCast, a spatio-temporal model designed for continual biodiversity and climate risk forecasting. Utilizing multisource satellite imagery, climate data, and citizen science occurrence records, EcoCast predicts near-term (monthly to seasonal) shifts in species distributions through sequence-based transformers that model spatio-temporal environmental dependencies. The architecture is designed with support for continual learning to enable future operational deployment with new data streams. Our pilot study in Africa shows promising improvements in forecasting distributions of selected bird species compared to a Random Forest baseline, highlighting EcoCast's potential to inform targeted conservation policies. By demonstrating an end-to-end pipeline from multi-modal data ingestion to operational forecasting, EcoCast bridges the gap between cutting-edge machine learning and biodiversity management, ultimately guiding data-driven strategies for climate resilience and ecosystem conservation throughout Africa.
title EcoCast: A Spatio-Temporal Model for Continual Biodiversity and Climate Risk Forecasting
topic Quantitative Methods
Machine Learning
url https://arxiv.org/abs/2512.02260