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Neural Computing and Applications
Erschienen in: Neural Computing and Applications 8/2021

20.07.2020 | Original Article

Deep CNN models-based ensemble approach to driver drowsiness detection

verfasst von: Mohit Dua, Shakshi, Ritu Singla, Saumya Raj, Arti Jangra

Erschienen in: Neural Computing and Applications | Ausgabe 8/2021

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Abstract

Statistics have shown that many accidents occur due to drowsy condition of drivers. In a study conducted by National Sleep Foundation, it has been found that about 20% of drivers feel drowsy during driving. These statistics paint a very scary picture. This paper proposes a system for driver drowsiness detection, in which the architecture detects sleepiness of driver. The proposed architecture consists of four deep learning models: AlexNet, VGG-FaceNet, FlowImageNet and ResNet, which use RGB videos of drivers as input and help in detecting drowsiness. Also, these models consider four types of different features such as hand gestures, facial expressions, behavioral features and head movements for the implementation. The AlexNet model is used for various background and environmental changes like indoor, outdoor, day and night. VGG-FaceNet is used to extract facial characteristics like gender ethnicities. FlowImageNet is used for behavioral features and head gestures, and ResNet is used for hand gestures. Hand gestures detection provides a precise and accurate result. These models classify these features into four classes: non-drowsiness, drowsiness with eye blinking, yawning and nodding. The output of these models is provided to ensemble algorithm to obtain a final output by putting them through a SoftMax classifier that gives us a positive (drowsy) or negative answer. The accuracy obtained from this system came out to be 85%.
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Literatur
1.
2.
Grace R, Byrne VE, Bierman DM, Legrand JM, Gricourt D, Davis BK, Staszewski JJ, Carnahan B (1998) A drowsy driver detection system for heavy vehicles. In: 17th DASC. AIAA/IEEE/SAE. Digital avionics systems conference. Proceedings (Cat. No. 98CH36267) vol 2, pp I36–1. IEEE
3.
Ursulescu O, Ilie B, Simion G (2018). Driver drowsiness detection based on eye analysis. In: 2018 International symposium on electronics and telecommunications (ISETC) pp 1–4. IEEE
4.
Tabrizi PR, Zoroofi RA (2008). Open/closed eye analysis for drowsiness detection. In: 2008 First workshops on image processing theory, tools and applications pp 1–7. IEEE
5.
Dehnavi M, Attarzadeh N, Eshghi M (2011) Real time eye state recognition. In: 2011 19th Iranian conference on electrical engineering pp. 1–4. IEEE
6.
Rahman A, Sirshar M, Khan A (2015) Real time drowsiness detection using eye blink monitoring. In: 2015 National software engineering conference (NSEC) (pp 1–7). IEEE
7.
Viola P, Jones M (2001). Rapid object detection using a boosted cascade of simple features. In: Proceedings of the 2001 IEEE computer society conference on computer vision and pattern recognition. CVPR 2001, vol. 1, pp I–I. IEEE
8.
Lu H, Zhang W, Yang D (2007) Eye detection based on rectangle features and pixel-pattern-based texture features. In: 2007 International symposium on intelligent signal processing and communication systems. pp 746–749. IEEE
9.
Bhone RA (2019). Computer vision based drowsiness detection for motorized vehicles with web push notifications. In: 2019 4th International conference on internet of things: smart innovation and usages (IoT-SIU). pp 1–4. IEEE
10.
Lee Boon-Leng, Lee Boon-Giin, Chung Wan-Young (2016) Standalone wearable driver drowsiness detection system in a smartwatch. IEEE Sens J 16(13):5444–5451CrossRef
11.
Li Zhenlong, Zhang Qingzhou, Zhao Xiaohua (2017) Performance analysis of K-nearest neighbor, support vector machine, and artificial neural network classifiers for driver drowsiness detection with different road geometries. Int J Distrib Sens Netw 13(9):1550147717733391CrossRef
12.
Mahmoodi Mohammad, Nahvi Ali (2019) Driver drowsiness detection based on classification of surface electromyography features in a driving simulator. Proc Inst Mech Engineers Part H J Eng Med 233(4):395–406CrossRef
13.
Arefnezhad S et al (2019) Driver drowsiness detection based on steering wheel data applying adaptive neurofuzzy feature selection. Sensors 19(4):943CrossRef
14.
Gielen Jasper, Aerts Jean-Marie (2019) Feature extraction and evaluation for driver drowsiness detection based on thermoregulation. Appl Sci 9(17):3555CrossRef
15.
Choi IH, Hong SK, Kim YG (2016) Real-time categorization of driver’s gaze zone using the deep learning techniques. In: 2016 International conference on big data and smart computing (BigComp), pp. 143–148. IEEE
16.
Dwivedi K, Biswaranjan K, Sethi A (2014) Drowsy driver detection using representation learning. In: 2014 IEEE International advance computing conference (IACC) pp 995–999. IEEE
17.
Park S, Pan F, Kang S, Yoo CD (2016) Driver drowsiness detection system based on feature representation learning using various deep networks. In: Asian conference on computer vision, Springer, Cham. pp 154–164
18.
Weng CH, Lai YH, Lai SH (2016) Driver drowsiness detection via a hierarchical temporal deep belief network. In: Asian conference on computer vision Springer, Cham, pp 117–133
19.
Zhou ZH, Wu J, Tang W (2002) Ensembling neural networks: many could be better than all. Artif Intell 137(1–2):239–263MathSciNetCrossRef
20.
Alif MAR, Ahmed S, Hasan MA (2017) Isolated Bangla handwritten character recognition with convolutional neural network. In: 2017 20th International conference of computer and information technology (ICCIT), pp 1–6. IEEE
21.
Agrawal S, Das S, Valmiki M, Wandhekar S, Moona R (2017) A case for PARAM Shavak: ready-to-use and affordable supercomputing solution. In: 2017 International conference on high performance computing & simulation (HPCS), pp 396–401. IEEE
22.
23.
He K, Zhang X, Ren S, Sun J (2016) Deep residual learning for image recognition. In: Proceedings of the IEEE conference on computer vision and pattern recognition, pp 770–778
24.
Shakeel MF, Bajwa NA, Anwaar AM, Sohail A, Khan A (2019) Detecting driver drowsiness in real time through deep learning based object detection. In: International work-conference on artificial neural networks, Springer, Cham pp 283–296
Metadaten
Titel
Deep CNN models-based ensemble approach to driver drowsiness detection
verfasst von
Mohit Dua
Shakshi
Ritu Singla
Saumya Raj
Arti Jangra
Publikationsdatum
20.07.2020
Verlag
Springer London
Erschienen in
Neural Computing and Applications / Ausgabe 8/2021
Print ISSN: 0941-0643
Elektronische ISSN: 1433-3058
DOI
https://doi.org/10.1007/s00521-020-05209-7

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