Recognition of driver’s fatigue expression using Local Multiresolution Derivative Pattern

Abstract

To develop the human-centric driver fatigue monitoring system for automatic understanding and charactering of driver’s conditions, a novel, efficient feature extraction approach, named Local Multiresolution Derivative Pattern (LMDP), is proposed to describe the driver’s fatigue expression images, and the Intersection Kernel Support Vector Machines classifier is then exploited to recognize three pre-defined classes of fatigue expressions, i.e., awake expressions, moderate fatigue expressions and severe fatigue expressions. With features extracted from a fatigue expressions dataset created at Southeast University, the holdout and cross-validation experiments on fatigue expressions classification are conducted by the Intersection Kernel Support Vector Machines classifier, compared with three commonly used classification methods including the k-nearest neighbor classifier, the multilayer perception classifier and the dissimilarity-based classifier. The experimental results of holdout and cross-validation showed that LMDP offers the better performance than Local Derivative Pattern, and the second order LMDP exceeds other order LMDP. With the second order LMDP and the Intersection Kernel Support Vector Machines classifier, the classification accuracies of the severe fatigue are over 90% in the holdout and cross-validation experiments, thus demonstrating the effectiveness of the proposed feature extraction method in automatically understanding the driver’s conditions towards the human-centric driver fatigue monitoring system.

Keywords

Fatigue expression feature extraction Local Multiresolution Derivative Pattern (LMDP)Local Derivative Pattern (LDP)Human-centric Driver Fatigue Monitoring System (DFMS)

Get full access to this article

View all access options for this article.

References

Croo

H.D.

, Bandmann

, Mackay

G.M.

, et al., The role of driver fatigue in commercial road transport crashes, Eur Transp Safety Council, Brussels, Belgium, Tech Rep, 2001.

The Royal Society for the Prevention of Accidents. Driver fatigue and road accidents: A literature review and position. Birmingham, UK, 2001

Bergasa

, Nuevo

, Sotelo

, et al., Real-time system for monitoring driver vigilance, IEEE Trans Intell Transp Syst 7(1) (2006), 63–77.

Suzuki

, Yamamoto

, et al., Measurement of driver’s consciousness by image processing–A method for presuming driver’s drowsiness by eye-blinks coping with individual differences, Proc IEEE Int Conf Syst, Man, Cybern 4 (2006), 2891–2896.

Eskandarian

, Sayed

, Delaigue

, et al., Advanced driver fatigue research, U.S. Dept Transp, Fed Motor Carrier Safety Admin, Washington, DC, Tech Rep, Rep 2007.

Orazio

T.D.

, Leo

and Guaragnella

, A visual approach for driver inattention detection, Pattern Recognit 40(8) (2007), 2341–2355.

Barr

, Howarath

, Popkin

, et al., A review and evaluation of emerging driver fatigue detection, measures and technologies, A Report of U.S. Department of Transportation, Washington, DC, 2009.

Friedrichs

and Yang

, Camera-based drowsiness reference for driver state classification under real driving conditions, Proc IEEE Intell Veh Symp (2010), 101–106.

Fan

, Sun

and Yin

, Gabor-based dynamic representation for human fatigue monitoring in facial image sequences, Pattern Recognit Lett 31(3) (2010), 234–243.

10.

Dong

Y.C.

, Hu

Z.C.

, Uchimura

, et al., Driver inattention monitoring system for intelligent vehicles: A review, IEEE Transactions on Intellignet Transportation Systems 12(2) (2011), 596–614.

11.

Lin

C.T.

, Wu

R.C.

, Liang

S.F.

, et al., EEG-based drowsiness estimation for safety driving using independent component analysis, IEEE Trans Circuits Syst I, Reg Papers 52(12) (2005), 2726–2738.

12.

Lin

C.T.

, Chen

Y.C.

, Huang

T.Y.

, et al., Development of wireless brain computer interface with embedded multitask scheduling and its application on real-time driver’s drowsiness detection and warning, IEEE Trans Biomed Eng 55(5) (2008), 1582–1591.

13.

Damousis

I.G.

and Tzovaras

, Fuzzy fusion of eyelid activity indicators for hypovigilance-related accident prediction, IEEE Trans Intell Transp Syst 9(3) (2008), 491–500.

14.

Yeo

M.V.M.

, Li

X.P.

and Shen

, Can SVM be used for automatic EEG detection of drowsiness during car driving?, Safety Sci 47(1) (2009), 115–124.

15.

Jap

B.T.

, Lal

, Fischer

, et al., Using EEG spectral components to assess algorithms for detecting fatigue, Expert Syst Appl 36(2) (2009), 2352–2359.

16.

and Zheng

, Driver drowsiness detection with eyelid-related parameters by support vector machine, Expert Syst Appl 36(4) (2009), 7651–7658.

17.

Yang

, Lin

and Bhattacharya

, A driver fatigue recognition model based on information fusion and dynamic Bayesian network, Inf Sci 180(10) (2010), 1942–1954.

18.

Liu

, Zhang

and Zheng

, EEG-based estimation of mental fatigue by using KPCA–HMM and complexity parameters, Biomed Signal Process Control 5(2) (2010), 124–130.

19.

Sibsambhu

, Mayank

and Aurobinda

, EEG signal analysis for the assessment and quantification of driver’s fatigue, Transportation Research Part F Traffic Psychology and Behaviour 13(5) (2010), 297–306.

20.

Khushaba

R.N.

, Kodagoda

, Sara

, et al., Driver drowsiness classification using fuzzy wavelet-packet-based feature extraction algorithm, IEEE Transactions on Biomedical Engineering 58(1) (2011), 121–131.

21.

Zhang

, Gao

, Zhao

, et al., Local derivative pattern versus local binary pattern: Face recognition with high-order local pattern descriptor, IEEE Transactions on Image Processing 19(2) (2010), 533–544.

22.

Paul

and Michael

J.J.

, Robust real-time face detection, International Journal of Computer Vision 57(2) (2004), 137–154.

23.

Minh

N.D.

and Martin

, Framing pyramids, IEEE Transactions on Signal Processing 51(9) (2003), 2329–2342.

24.

Park

S.I.

, smith

M.J.T.

and Mersereau

R.M.

, Improved structures of maximally decimated directional filter banks for spatial image analysis, IEEE Transactions on Signal Processing 13(9) (2004), 1424–1434.

25.

Cortes

and Vapnik

, Support-vetor networks, Machine Learning 20(3) (1995), 273–297.

26.

Platt

, Fast training of SVMs using sequential minimal optimization, Advances in Kernel Methods Support Vector Machine, MIT Press,Cambridge, 1999. pp. 185–208.

27.

Milgram

, Cheriet

and Sabourin

, One Against One” or “One Against All: Which One is Better for Handwriting Recognition with SVMs?, International workshop on Frontiers in handwriting Recognition, Montreal, Canada, 2006.

28.

Maji

, Berg

A.C.

, Malik

, Classification using Intersection Kernel Support Vector Machines is efficient, IEEE Conference on Computer Vision and Pattern Recognition, Anchorage, 2008, pp. 1–8.

29.

Bremner

, Demaine

, Erickson

, et al., Output-sensitive algorithms for computing nearest-neighbor decision boundaries, Discrete and Computational Geometry 33(4) (2005), 593–604.

30.

Haykin

, Neural Networks: A comprehensive foundation (2ed.). Prentice Hall, 1998.

31.

Pekalska

, Paclik

and Duin

R.P.W.

, A generalized kernel approach to dissimilarity-based classification, Journal of Machine Learning Research 2 (2001), 175–211.

32.

Zhang

B.L.

and Zhang

Y.C.

, Classification of cerebral palsy gait by kernel fisher discriminant analysis, International Journal of Hybrid Intelligent Systems 5(4) (2008), 209–218.