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International Journal of Creative and Open Research in Engineering and Management

A Peer-Reviewed, Open-Access International Journal Supporting Multidisciplinary Research, Digital Publishing Standards, DOI Registration, and Academic Indexing.
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ISSN: 3108-1754 (Online)
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Peer Review: Double Blind
Volume 02, Issue 05

Published on: May 2026

DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS AI-BASED WILD ANIMAL DETECTION AND REPELLENT SYSTEM FOR CROP PROTECTION

Mohamed Mubarak S Kaleel Rahman S Hari Krishnan M Abdul Ahad L A. Asrin Mahmootha

Dr. B. Aysha Banu

Department of Information Technology Mohamed Sathak Engineering College Kilakarai Tamil Nadu India
DOI:https://doi.org/10.55041/ijcope.v2i5.291

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Abstract

Human-wildlife conflict (HWC) causes an estimated 40% crop loss in border farming communities across South Asia, with annual damages exceeding ₹12,000 crore in India alone. Traditional deterrent methods including electric fencing, manual vigilance, and passive infrared (PIR) sensors suffer from high false-positive rates (up to 28%), lack of species specificity, and prohibitive maintenance costs. This paper presents an autonomous, solar-powered, edge-AI system that integrates YOLOv8 object detection, adaptive multi-modal repellent actuation, and real-time GSM-based remote monitoring for precision crop protection. The system employs a Raspberry Pi 4B edge processor running a quantized and pruned YOLOv8n model (12 MB, 0.93 mAP@0.5) that detects elephants, wild boars, and other crop-raiding species at 280 ms latency. Upon detection, species-specific repellent protocols are activated: infrasonic deterrence (10–20 Hz) for elephants, ultrasonic emission (18–25 kHz) for boars, and stroboscopic lights for nocturnal intrusions. Field trials conducted over a 10-acre farm in Tamil Nadu demonstrated a 92% animal repulsion rate, 99.7% system uptime, and a 4.2% false-positive rate—outperforming all baseline methods. A five-year cost-benefit analysis confirms a 340% return on investment versus traditional electric fencing. The proposed system demonstrates that edge AI can deliver sustainable, farmer-affordable, and ecologically non-lethal wildlife management at scale.

 Keywords: YOLOv8, Edge AI, Human-Wildlife Conflict, Crop Protection, Solar-Powered IoT, Precision Agriculture, Wild Animal Deterrent

How to Cite this Paper

S, M. M., S, K. R., M, H. K., L, A. A. & Mahmootha, A. A. (2026). Design and Implementation of An Autonomous AI-Based Wild Animal Detection and Repellent System for Crop Protection. International Journal of Creative and Open Research in Engineering and Management, <i>02</i>(05). https://doi.org/10.55041/ijcope.v2i5.291

S, Mohamed, et al.. "Design and Implementation of An Autonomous AI-Based Wild Animal Detection and Repellent System for Crop Protection." International Journal of Creative and Open Research in Engineering and Management, vol. 02, no. 05, 2026, pp. . doi:https://doi.org/10.55041/ijcope.v2i5.291.

S, Mohamed,Kaleel S,Hari M,Abdul L, and A. Mahmootha. "Design and Implementation of An Autonomous AI-Based Wild Animal Detection and Repellent System for Crop Protection." International Journal of Creative and Open Research in Engineering and Management 02, no. 05 (2026). https://doi.org/https://doi.org/10.55041/ijcope.v2i5.291.

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References

[1] Tamil Nadu Forest Department, "Annual Report on Human-Wildlife Conflict 2022-23," Government of Tamil Nadu, Chennai, India, 2023.

[2] Wildlife Institute of India, "Status of Human-Wildlife Conflict in India," WII Technical Report TR-2022/01, Dehradun, 2022.

[3] Food and Agriculture Organization (FAO), "Human-Wildlife Conflict and Food Security," FAO Forestry Paper 182, Rome, Italy, 2021.

[4] D. Bhatt, A. Chhaya, S. Bhatt, and N. Ghosal, "Effectiveness of Electric Fencing in Mitigating Human-Elephant Conflict in Assam, India," Oryx, vol. 56, no. 3, pp. 412–420, 2022.

[5] R. Ravenscroft, A. Singleton, and J. Vanhinsbergh, "Implications of Rural Labour Shortages for Wildlife Management in South Asia," J. Applied Ecology, vol. 59, no. 4, pp. 880–891, 2022.

[6] G. Jocher, A. Chaurasia, and J. Qiu, "Ultralytics YOLOv8," GitHub Repository, 2023. [Online]. Available: https://github.com/ultralytics/ultralytics

[7] M. Norouzzadeh, A. Nguyen, M. Kosmala, A. Swanson, M. Palmer, C. Packer, and J. Clune, "Automatically Identifying, Counting, and Describing Wild Animals in Camera-Trap Images with Deep Learning," Proc. Natl. Acad. Sci., vol. 115, no. 25, pp. E5716–E5725, 2018.

[8] S. Beery, J. Wu, V. Rathod, R. Votel, and J. Huang, "Context R-CNN: Long Term Temporal Context for Per-Camera Object Detection," in Proc. IEEE/CVF Conf. Comput. Vis. Pattern Recognit. (CVPR), 2023, pp. 8712–8721.

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  • Peer Review Type: Double-Blind Peer Review
  • Published on: May 09 2026
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