H-DrowsyNet: Sürücü Yorgunluk Tespiti için Göz Açıklık Oranı (EAR) ve Evrişimli Sinir Ağlarını (CNN) Esas Alan Çift Kollu Hibrit Bir Mimari

Yıl 2026, Cilt: 9 Sayı: 1, 1 - 21, 25.03.2026

Mustafa Tasci

https://doi.org/10.51513/jitsa.1844823

https://izlik.org/JA95NJ86RU

Öz

Sürücü yorgunluğu, dünya genelinde trafik kazalarının başlıca nedenlerinden biri olup, çok sayıda yaralanma ve can kaybına yol açmaktadır. Bunu azaltmak için, tespit yöntemleri Geometrik Teknikler (örneğin Göz Oran Endeksi- EAR) veya Derin Öğrenme Yaklaşımları (örneğin Evrişimli Sinir Ağları - CNN’ler) gibi yöntemler kullanır ve her birinin kendine özgü sınırlamaları vardır. EAR, hesaplama açısından verimlilik sunarken değişen aydınlatma, gözlük ve baş pozisyonlarında yetersiz kalabilir; CNN’ler ise yüksek doğruluk sağlar ancak önemli miktarda kaynak gerektirir ve gölgeler ya da engellemeler tarafından yanıltılabilir. Bu çalışma, bu zayıf yönleri gidermek amacıyla, EAR analizini bir CNN sınıflandırıcıyla birleştirip çıktıları bir karar füzyon modülüyle birleştiren, çift dallı hibrit bir mimari olan H-DrowsyNet’i tanıtmaktadır. Sistem, 9.120 yüz görüntüsünden oluşan ve Uyanık ile Uykulu sınıflarına ayrılmış Kaggle Sürücü Uykululuk Veri seti (DDD) kullanılarak değerlendirilmiştir. Sonuçlar, H-DrowsyNet’in tek başına kullanılan EAR ya da CNN modellerini geride bırakarak, daha yüksek doğruluk ve daha düşük yanlış negatif (FN) oranı elde ettiğini; böylece yolda uykulu sürücü kaçırma ihtimalini azaltarak trafik güvenliğini artırdığını göstermektedir. Her iki analizden de uykulu sınıflandırması için karar füzyon modülü, hata oranını düşürmektedir. Bu hibrit yaklaşım, gerçek zamanlı sürücü izleme sistemleri için uygundur. Gelecekteki çalışmalar, H-DrowsyNet’in genellenebilirliğini artırmak amacıyla, farklı gerçek dünya koşullarında testler yapacaktır. H-DrowsyNet’in başarısı, geometrik ve derin öğrenme yöntemlerini birleştirerek trafik güvenliğini ileriye taşımaktadır.

Anahtar Kelimeler

Sürücü uykululuk tespiti , Göz Açıklık Oranı , Karar Birleştirme Modülü , CNN sınıflandırıcı , Uykululuk sınıflandırması

H-DrowsyNet: A Dual-Branch Hybrid Architecture Based on Eye Aspect Ratio (EAR) and Convolutional Neural Networks (CNN) for Driver Fatigue Detection

https://izlik.org/JA95NJ86RU

Öz

Driver fatigue is a leading cause of traffic accidents worldwide, resulting in numerous injuries and fatalities. To mitigate this, detection methods use geometric techniques, such as the Eye Aspect Ratio (EAR), or deep learning approaches, such as Convolutional Neural Networks (CNNs), each with limitations. EAR offers computational efficiency but struggles with varying lighting, eyewear, and head poses, whereas CNNs provide high accuracy but require significant resources and can be misled by shadows or occlusions. This study introduces H-DrowsyNet, a dual-branch hybrid architecture that addresses these weaknesses by combining EAR analysis with a CNN classifier and fusing their outputs using a decision fusion module. The system was evaluated using the Kaggle Driver Drowsiness Dataset (DDD), which contains 9,120 facial images divided into Awake and Drowsy classes. The results show that H-DrowsyNet outperforms standalone EAR and CNN models, achieving higher accuracy and a reduced false-negative (FN) rate, thereby enhancing road safety by minimizing missed drowsy drivers. The decision fusion module, which requires agreement from both analyses for drowsiness classification, reduces errors. This hybrid approach is suitable for real-time driver-monitoring systems. Future work will test H-DrowsyNet under diverse real-world conditions to improve its generalization. The success of H-DrowsyNet stems from the combination of geometric and deep learning methods, thereby advancing traffic safety.

Anahtar Kelimeler

Driver drowsiness detection , Eye Aspect Ratio , Decision Fusion Module , CNN classifier , drowsiness classification.

Kaynakça

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