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Neural Computing and Applications

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09.01.2021 | Original Article

FER-net: facial expression recognition using deep neural net

verfasst von: Karnati Mohan, Ayan Seal, Ondrej Krejcar, Anis Yazidi

Erschienen in: Neural Computing and Applications | Ausgabe 15/2021

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Abstract

Automatic facial expression recognition (FER) is one of the most challenging tasks in computer vision. FER admits a wide range of applications in human–computer interaction, behavioral psychology, and human expression synthesis. Extensive works have been reported in this field, mainly, based on handcrafted features. However, it is a challenging task to accurately extract all the correlated handcrafted features due to the effect of variations caused by emotional state. Therefore, there is a quest for further research on accurately extracting relevant features that can capture changes in facial expressions (FEs) with high fidelity. In this study, we propose FER-net: a convolution neural network to distinguish FEs efficiently with the help of the softmax classifier. We implement our method FER-net along with twenty-one state-of-the-art methods and test them on five benchmarking datasets, namely FER2013, Japanese Female Facial Expressions, Extended CohnKanade, Karolinska Directed Emotional Faces, and Real-world Affective Faces. Seven FEs, namely neutral, anger, disgust, fear, happiness, sadness, and surprise, are considered in this work. The average accuracies on these datasets are 78.9%, 96.7%, 97.8%, 82.5% and 81.68%, respectively. The obtained results demonstrate that FER-net is preeminent in comparison with twenty-one state-of-the-art methods.

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Yeasin M, Bullot B, Sharma R (2006) Recognition of facial expressions and measurement of levels of interest from video. IEEE Trans Multimed 8(3):500–508CrossRef

Lola C, Philippe G (2005) Emotion understanding: robots as tools and models. University Press England, Oxford

Dornaika F, Raducanu B (2009) Facial expression recognition for hci applications. In: Encyclopedia of artificial intelligence. IGI Global, pp 625–631

Shakya S, Sharma S, Basnet A (2016) Human behavior prediction using facial expression analysis. In: 2016 international conference on computing, communication and automation (ICCCA). IEEE, pp 399–404

Dickey CC, Panych LP, Voglmaier MM, Niznikiewicz MA, Terry DP, Murphy C, Zacks R, Shenton ME, McCarley RW (2011) Facial emotion recognition and facial affect display in schizotypal personality disorder. Schizophr Res 131(1–3):242–249CrossRef

Jeong M, Ko BC (2018) Driver’s facial expression recognition in real-time for safe driving. Sensors 18(12):4270CrossRef

Zhou Y, Shi BE (2017) Photorealistic facial expression synthesis by the conditional difference adversarial autoencoder. In: 2017 seventh international conference on affective computing and intelligent interaction (ACII). IEEE, pp 370–376

Viola P, Jones P et al (2001) Rapid object detection using a boosted cascade of simple features. In: CVPR 2001, vol 1, no 511–518, p 3

Siswanto ARS, Nugroho AS, Galinium M (2014) Implementation of face recognition algorithm for biometrics based time attendance system. In: 2014 international conference on ICT For Smart Society (ICISS). IEEE, pp 149–154

10.

Turk MA, Pentland AP (1991) Face recognition using eigenfaces. In: Proceedings. 1991 IEEE computer society conference on computer vision and pattern recognition. IEEE, pp 586–591

11.

Lundqvist D, Flykt A, Öhman A (1998) The karolinska directed emotional faces (kdef), vol 91. CD ROM from Department of Clinical Neuroscience, Psychology section, Karolinska Institutet, Solna, p 30

12.

Mohammadi MR, Fatemizadeh E, Mahoor MH (2014) Pca-based dictionary building for accurate facial expression recognition via sparse representation. J Vis Commun Image Represent 25(5):1082–1092CrossRef

13.

Liu C, Wechsler H (2002) Gabor feature based classification using the enhanced fisher linear discriminant model for face recognition. IEEE Trans Image Process 11(4):467–476CrossRef

14.

Lucey P, Cohn JF, Kanade T, Saragih J, Ambadar Z, Matthews I (2010) The extended cohn-kanade dataset (ck+): a complete dataset for action unit and emotion-specified expression. In: 2010 IEEE computer society conference on computer vision and pattern recognition-workshops. IEEE, pp 94–101

15.

Shan C, Gong S, McOwan PW (2009) Facial expression recognition based on local binary patterns: a comprehensive study. Image Vis Comput 27(6):803–816CrossRef

16.

Kobayashi H, Hara F (1997) Facial interaction between animated 3d face robot and human beings. In: 1997 IEEE international conference on systems, man, and cybernetics. Computational cybernetics and simulation, vol 4. IEEE, pp 3732–3737

17.

Zhong L, Liu Q, Yang P, Huang J, Metaxas DN (2014) Learning multiscale active facial patches for expression analysis. IEEE Trans Cybern 45(8):1499–1510CrossRef

18.

Mase K (1991) Recognition of facial expression from optical flow. IEICE Trans Inf Syst 74(10):3474–3483

19.

Chen C-R, Wong W-S, Chiu C-T (2010) A 0.64 mm \(^{2}\) real-time cascade face detection design based on reduced two-field extraction. IEEE Trans Very Large Scale Integr (VLSI) Syst 19(11):1937–1948CrossRef

20.

Kotsia I, Pitas I (2006) Facial expression recognition in image sequences using geometric deformation features and support vector machines. IEEE Trans Image Process 16(1):172–187MathSciNetCrossRef

21.

Sohail ASM, Bhattacharya P (2007) Classification of facial expressions using k-nearest neighbor classifier. In: International conference on computer vision/computer graphics collaboration techniques and applications. Springer, pp 555–566

22.

Li X, Ji Q (2004) Active affective state detection and user assistance with dynamic Bayesian networks. IEEE Trans Syst Man Cybern Part A Syst Huma 35(1):93–105MathSciNetCrossRef

23.

Fanelli G, Gall J, Van Gool L (2011) Real time head pose estimation with random regression forests. In: CVPR 2011. IEEE, pp 617–624

24.

Salmam FZ, Madani A, Kissi M (2016) Facial expression recognition using decision trees. In: 2016 13th international conference on computer graphics, imaging and visualization (CGiV). IEEE, pp 125–130

25.

Sebe N, Lew MS, Cohen I, Garg A, Huang TS (2002) Emotion recognition using a Cauchy naive Bayes classifier. In: Makihara Y, Takizawa M, Shirai Y, Miura J, Shimada N (eds) Object recognition supported by user interaction for service robots, vol 1. IEEE, New York, pp 17–20CrossRef

26.

Chen J, Chen Z, Chi Z, Hong F (2016) Facial expression recognition in video with multiple feature fusion. IEEE Trans Affect Comput 9(1):38–50CrossRef

27.

Karlekar A, Seal A (2020) Soynet: Soybean leaf diseases classification. Comput Electron Agric 172:105342CrossRef

28.

Mohan K, Seal A, Krejcar O, Yazidi A (2020) Facial expression recognition using local gravitational force descriptor based deep convolution neural networks. IEEE Trans Instrum Meas 70:1–12CrossRef

29.

Zhao K, Chu W-S, Zhang H (2016) Deep region and multi-label learning for facial action unit detection. In Proceedings of the IEEE conference on computer vision and pattern recognition, pp 3391–3399

30.

Sun N, Li Q, Huan R, Liu J, Han G (2017) Deep spatial-temporal feature fusion for facial expression recognition in static images. Pattern Recogn Lett 119:49–61CrossRef

31.

Orozco D, Lee C, Arabadzhi Y, Gupta D. Transfer learning for facial expression recognition

32.

Alizadeh S, Fazel A (2017) Convolutional neural networks for facial expression recognition arXiv:1704:06756

33.

Zhao G, Pietikainen M (2007) Dynamic texture recognition using local binary patterns with an application to facial expressions. IEEE Trans Pattern Anal Mach Intell 6:915–928CrossRef

34.

Dhall A, Goecke R, Joshi J, Wagner M, Gedeon T (2013) Emotion recognition in the wild challenge 2013. In: Proceedings of the 15th ACM on international conference on multimodal interaction. ACM, pp 509–516

35.

Yu Z, Zhang C (2015) Image based static facial expression recognition with multiple deep network learning. In Proceedings of the 2015 ACM on international conference on multimodal interaction. ACM, pp 435–442

36.

Jain DK, Shamsolmoali P, Sehdev P (2019) Extended deep neural network for facial emotion recognition. Pattern Recogn Lett 120:69–74CrossRef

37.

Salmam FZ, Madani A, Kissi M (2019) Fusing multi-stream deep neural networks for facial expression recognition. SIViP 13(3):609–616CrossRef

38.

Li K, Jin Y, Akram MW, Han R, Chen J (2019) Facial expression recognition with convolutional neural networks via a new face cropping and rotation strategy. Vis Comput 36:391–404CrossRef

39.

Shao J, Qian Y (2019) Three convolutional neural network models for facial expression recognition in the wild. Neurocomputing 355:82–92CrossRef

40.

Uddin MZ, Hassan MM, Almogren A, Alamri A, Alrubaian M, Fortino G (2017) Facial expression recognition utilizing local direction-based robust features and deep belief network. IEEE Access 5:4525–4536CrossRef

41.

Pons G, Masip D (2017) Supervised committee of convolutional neural networks in automated facial expression analysis. IEEE Trans Affect Comput 9(3):343–350CrossRef

42.

Villanueva MG, Zavala SR, Zavala (2020) Deep neural network architecture: application for facial expression recognition. IEEE Lat Am Trans 18(07):1311–1319CrossRef

43.

Liu X, Vijaya Kumar BV, You J, Jia P (2017) Adaptive deep metric learning for identity-aware facial expression recognition. In: Proceedings of the IEEE conference on computer vision and pattern recognition workshops, pp 20–29

44.

Meng Z, Liu P, Cai J, Han S, Tong Y (2017) Identity-aware convolutional neural network for facial expression recognition. In: 2017 12th IEEE international conference on automatic face & gesture recognition (FG 2017). IEEE, pp 558–565

45.

Minaee S, Abdolrashidi A (2019) Deep-emotion: Facial expression recognition using attentional convolutional network. arXiv:1902.01019

46.

Hua W, Dai F, Huang L, Xiong J, Gui G (2019) Hero: human emotions recognition for realizing intelligent internet of things. IEEE Access 7:24321–24332CrossRef

47.

Kim J-H, Kim B-G, Roy PP, Jeong D-M (2019) Efficient facial expression recognition algorithm based on hierarchical deep neural network structure. IEEE Access 7:41273–41285CrossRef

48.

Kim DH, Baddar WJ, Jang J, Ro YM (2017) Multi-objective based spatio-temporal feature representation learning robust to expression intensity variations for facial expression recognition. IEEE Trans Affect Comput 10(2):223–236CrossRef

49.

Benitez-Quiroz CF, Srinivasan R, Martinez AM (2018) Discriminant functional learning of color features for the recognition of facial action units and their intensities. IEEE Trans Pattern Anal Mach Intell 41(12):2835–2845CrossRef

50.

Zhang T, Liu Z, Wang X-H, Xing X-F, Chen CP, Chen E (2018) Facial expression recognition via broad learning system. In: 2018 IEEE international conference on systems, man, and cybernetics (SMC). IEEE, pp 1898–1902

51.

Zhao X, Shi X, Zhang S (2015) Facial expression recognition via deep learning. IETE Tech Rev 32(5):347–355CrossRef

52.

Chellappa R, Wilson CL, Sirohey S et al (1995) Human and machine recognition of faces: a survey. Proc IEEE 83(5):705–740CrossRef

53.

Samal A, Iyengar PA (1992) Automatic recognition and analysis of human faces and facial expressions: a survey. Pattern Recogn 25(1):65–77CrossRef

54.

Li H, Lin Z, Shen X, Brandt J, Hua G (2015) A convolutional neural network cascade for face detection. In: Proceedings of the IEEE conference on computer vision and pattern recognition, pp 5325–5334

55.

Lyons M, Akamatsu S, Kamachi M, Gyoba J (1998) Coding facial expressions with gabor wavelets. In: Proceedings third IEEE international conference on automatic face and gesture recognition. IEEE, pp 200–205

56.

Li S, Deng W (2019) Reliable crowdsourcing and deep locality-preserving learning for unconstrained facial expression recognition. IEEE Trans Image Process 28(1):356–370MathSciNetMATHCrossRef

57.

Li S, Deng W, Du JP (2017) Reliable crowdsourcing and deep locality-preserving learning for expression recognition in the wild. In: 2017 IEEE conference on computer vision and pattern recognition (CVPR). IEEE, pp 2584–2593

58.

LeCun Y, Haffner P, Bottou L, Bengio Y (1999) Object recognition with gradient-based learning. In: Forsyth DA, Mundy JL, di Gesu V, Cipolla R (eds) Shape, contour and grouping in computer vision. Springer, Berlin, pp 319–345CrossRef

59.

Ding H, Zhou SK, Chellappa R (2017) Facenet2expnet: regularizing a deep face recognition net for expression recognition. In: 2017 12th IEEE international conference on automatic face and gesture recognition (FG 2017). IEEE, pp 118–126

60.

Simonyan K, Zisserman A (2014) Very deep convolutional networks for large-scale image recognition. arXiv:1409.1556

61.

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

62.

Szegedy C, Liu W, Jia Y, Sermanet P, Reed S, Anguelov D, Erhan D, Vanhoucke V, Rabinovich A (2015) Going deeper with convolutions. In: Proceedings of the IEEE conference on computer vision and pattern recognition, pp 1–9

63.

Huang G, Liu Z, Van Der Maaten L, Weinberger KQ (2017) Densely connected convolutional networks. In: Proceedings of the IEEE conference on computer vision and pattern recognition, pp 4700–4708

64.

Chollet F (2017) Xception: deep learning with depthwise separable convolutions. In: Proceedings of the IEEE conference on computer vision and pattern recognition, pp 1251–1258

65.

Krizhevsky A, Sutskever I, Hinton GE (2012) Imagenet classification with deep convolutional neural networks. In: Advances in neural information processing systems, pp 1097–1105

66.

Karlekar A, Seal A, Krejcar O, Gonzalo-Martin C (2019) Fuzzy k-means using non-linear s-distance. IEEE Access 7:55121–55131CrossRef

67.

Sharma KK, Seal A (2019) Modeling uncertain data using Monte Carlo integration method for clustering. Expert Syst Appl 137:100–116CrossRef

68.

Sharma KK, Seal A (2020) Spectral embedded generalized mean based k-nearest neighbors clustering with s-distance. Expert Syst Appl. https://doi.org/10.1016/j.eswa.2020.114326CrossRef

69.

Sharma KK, Seal A (2020) Outlier-robust multi-view clustering for uncertain data. Knowl Based Syst 211:106567CrossRef

70.

Jain S, Seal A, Ojha A, Krejcar O, Bureš J, Tachecí I, Yazidi A (2020) Detection of abnormality in wireless capsule endoscopy images using fractal features. Comput Biol Med 127:104094CrossRef

71.

Sharma KK, Seal A (2020) Clustering analysis using an adaptive fused distance. Eng Appl Artif Intell 96:103928CrossRef

72.

Sharma KK, Seal A (2020) Multi-view spectral clustering for uncertain objects. Inf Sci 547:723–745MathSciNetCrossRef

Titel: FER-net: facial expression recognition using deep neural net
verfasst von: Karnati Mohan
Ayan Seal
Ondrej Krejcar
Anis Yazidi
Publikationsdatum: 09.01.2021
Verlag: Springer London
Erschienen in: Neural Computing and Applications / Ausgabe 15/2021
Print ISSN: 0941-0643
Elektronische ISSN: 1433-3058
DOI: https://doi.org/10.1007/s00521-020-05676-y

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