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Wildlife Watch

Chimwemwe Chawinga*

DMI St. John the Baptist University, Lilongwe, Malawi.

Periodicity:April - June'2024
DOI : https://doi.org/10.26634/jit.13.2.20819

Abstract

The escalating biodiversity loss demands a paradigm shift in wildlife conservation. This paper proposes an innovative AI system for holistic wildlife management. The deep learning algorithms identify individual animals through biometrics in camera traps, drone footage, and bioacoustics. This surpasses traditional methods, enabling tracking across vast landscapes. The real-time animal tracking data, analyzed by machine learning, allows for early detection of poaching, habitat disturbances, and animal distress. Furthermore, the system integrates environmental sensors to provide a holistic understanding of ecological conditions. The correlating animal movement with environmental data helps identify crucial habitats and predict climate threats. This unified platform empowers proactive wildlife management, transitioning conservation from reactive to evidence-based practices for long-term biodiversity preservation.

Keywords

Wildlife Watch, Animal Identification, Wildlife Conservation, Live Location Tracking, Anomaly Detection, Temperature Monitoring, Habitat Conditions, Biodiversity Preservation.

How to Cite this Article?

Chawinga, C. (2024). Wildlife Watch. i-manager’s Journal on Information Technology, 13(2), 24-30. https://doi.org/10.26634/jit.13.2.20819

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