Open Access

ARTICLE

Integration of YOLOv11 and Histogram Equalization for Fire and Smoke-Based Detection of Forest and Land Fires

Christine Dewi^1,2, Melati Viaeritas Vitrieco Santoso¹, Hanna Prillysca Chernovita³, Evangs Mailoa¹, Stephen Abednego Philemon¹, Abbott Po Shun Chen^4,*

1 Department of Information Technology, Satya Wacana Christian University, Jalan Diponegoro No. 52-60, Salatiga, 50711, Indonesia
2 School of Information Technology, Deakin University, 221 Burwood Highway, Burwood, VIC 3125, Australia
3 Department of Information Systems, Satya Wacana Christian University, Jalan Diponegoro No. 52-60, Salatiga, 50711, Indonesia
4 Department of Marketing and Logistics Management, Chaoyang University of Technology, 168 Jifeng East Road, Taichung City, 413310, Taiwan

* Corresponding Author: Abbott Po Shun Chen. Email:

Computers, Materials & Continua 2025, 84(3), 5361-5379. https://doi.org/10.32604/cmc.2025.067381

Received 01 May 2025; Accepted 18 June 2025; Issue published 30 July 2025

Abstract

Early detection of Forest and Land Fires (FLF) is essential to prevent the rapid spread of fire as well as minimize environmental damage. However, accurate detection under real-world conditions, such as low light, haze, and complex backgrounds, remains a challenge for computer vision systems. This study evaluates the impact of three image enhancement techniques—Histogram Equalization (HE), Contrast Limited Adaptive Histogram Equalization (CLAHE), and a hybrid method called DBST-LCM CLAHE—on the performance of the YOLOv11 object detection model in identifying fires and smoke. The D-Fire dataset, consisting of 21,527 annotated images captured under diverse environmental scenarios and illumination levels, was used to train and evaluate the model. Each enhancement method was applied to the dataset before training. Model performance was assessed using multiple metrics, including Precision, Recall, mean Average Precision at 50% IoU (mAP50), F1-score, and visual inspection through bounding box results. Experimental results show that all three enhancement techniques improved detection performance. HE yielded the highest mAP50 score of 0.771, along with a balanced precision of 0.784 and recall of 0.703, demonstrating strong generalization across different conditions. DBST-LCM CLAHE achieved the highest Precision score of 79%, effectively reducing false positives, particularly in scenes with dispersed smoke or complex textures. CLAHE, with slightly lower overall metrics, contributed to improved local feature detection. Each technique showed distinct advantages: HE enhanced global contrast; CLAHE improved local structure visibility; and DBST-LCM CLAHE provided an optimal balance through dynamic block sizing and local contrast preservation. These results underline the importance of selecting preprocessing methods according to detection priorities, such as minimizing false alarms or maximizing completeness. This research does not propose a new model architecture but rather benchmarks a recent lightweight detector, YOLOv11, combined with image enhancement strategies for practical deployment in FLF monitoring. The findings support the integration of preprocessing techniques to improve detection accuracy, offering a foundation for real-time FLF detection systems on edge devices or drones, particularly in regions like Indonesia.

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Keywords

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