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Pattern Analysis and Applications

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01-08-2016 | Theoretical Advances

Statistical shape modelling for expression-invariant face analysis and recognition

Authors: Wei Quan, Bogdan J. Matuszewski, Lik-Kwan Shark

Published in: Pattern Analysis and Applications | Issue 3/2016

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Abstract

Paper introduces a 3-D shape representation scheme for automatic face analysis and identification, and demonstrates its invariance to facial expression. The core of this scheme lies on the combination of statistical shape modelling and non-rigid deformation matching. While the former matches 3-D faces with facial expression, the latter provides a low-dimensional feature vector that controls the deformation of model for matching the shape of new input, thereby enabling robust identification of 3-D faces. The proposed scheme is also able to handle the pose variation without large part of missing data. To assist the establishment of dense point correspondences, a modified free-form-deformation based on B-spline warping is applied with the help of extracted landmarks. The hybrid iterative closest point method is introduced for matching the models and new data. The feasibility and effectiveness of the proposed method was investigated using standard publicly available Gavab and BU-3DFE datasets, which contain faces with expression and pose changes. The performance of the system was compared with that of nine benchmark approaches. The experimental results demonstrate that the proposed scheme provides a competitive solution for face recognition.

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Chellappa R, Sinha P, Phillips PJ (2010) Face recognition by computers and humans. Comput IEEE Comput Soc 43(2):46–55CrossRef

Chellppa R, Wilson C, Sirohey C (1995) Human and machine recognition of faces: a survey. Proc IEEE 83(5):705–740CrossRef

Jafri R, Arabnia HR (2009) A survery of face recognition techniques. J Inf Process Syst 53(2):41–66CrossRef

Kong SG, Heo J, Abidi BR, Paik J, Abidi M (2005) Recent advances in visual and infrared face recognition—a review. Comput Vis Image Underst 97:103–135CrossRef

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

Lu Y, Zhou J, Yu S (2003) A survey of face detection. Extract Recognit Comput Inform Pattern Recognit 22:163–195MathSciNet

Hadid A, Pietikainen M, Ahonen T (2004) A discriminative feature space for detecting and recognising faces. In: IEEE conference on computer vision and pattern recognition, pp 797–804

Turk M, Pentland A (1991) Eigenfaces for recognition. J Cogn Neurosci 3(1):71–86CrossRef

Heseltine T, Pears N, Austin J, Chen Z (2003) Face recognition: a comparison of appearance-based approaches. Digital Image Comput Tech Appl 1:59–68

10.

Delac K, Grgic M, Liatsis P (2005) Appearance-based statistical methods for face recognition. In: 47th international symposium ELMAR-2005 focused on multimedia systems and applications, pp 151–158

11.

Hesher C, Srivastava A, Erlebacher G (2003) A novel technique for face recognition using range imaging. In: International symposium on signal processing and its applications, pp 201–204

12.

Belhumeur P, Hespanha J, Kriegma D (1997) Eigenfaces vs. fisheraces: recognition using class specific projection. IEEE Trans Pattern Anal Mach Intell 19(7):328–340CrossRef

13.

Ahonen T, Hadid A, Pietikainen M (2004) Face recognition with local binary patterns. In: European conference on computer vision, pp 469–481

14.

Bronstein A, Bronstein M, Kimmel R (2005) Three-dimensional face recognition. Int J Comput Vis 64(1):5–30CrossRef

15.

Mpiperis I, Malassiotis S, Strintzis M (2007) 3-D face recognition with the geodesic polar representation. IEEE Trans Inform Forensic Secur 2(3):537–547CrossRef

16.

Li X, Jia T, Zhang H (2009) Expression-insensitive 3D face recognition using sparse representation. In: Conference on computer vision and pattern recognition, pp 2575–2582

17.

Huang D, Ardabilian M, Wang Y, Chen L (2012) 3-D face recognition using elbp-based facial description and local feature hybrid matching. IEEE Trans Inf Forensic Secur 7(5):1551–1565CrossRef

18.

Mohammadzade H, Hatzinakos D (2013) Iterative closest normal point for 3D face recognition. IEEE Trans Pattern Anal Mach Intell 35(2):381–397CrossRef

19.

Shi J, Samal A, Marx D (2006) Effective are landmarks and their geometry for face recognition. Comput Vis Image Underst 102(2006):117–133CrossRef

20.

Gupta S, Aggatwal JK, Markey MK, Bovik AC (2007) 3D face recognition founded on the structural diversity of human faces. In: IEEE international conference on computer vision and pattern recognition

21.

Zhang L, Razdan A, Farin G, Femiani J, Bae M, Lockwood C (2006) 3D face authentication and recognition based on bilateral symmetry analysis. Vis Comput Comput Vis Image Underst 22(1)

22.

Nagamine T, Uemura T, Masuda I (1992) 3-D facial image analysis for human identification. In: International conference on computer vision and pattern recognition

23.

Samir C, Srivastava A, Acheroy M (2006) Three-dimensional face recognition using shapes of facial curves. IEEE Trans Pattern Anal Mach Intell 28(11):1858–1863CrossRef

24.

Drira H, Amor BB, Mohamed D, Srivastava A (2010) Pose and expression-invariant 3-D face recognition using elastic radial curves. In: British machine vision conference

25.

Queirolo CC, Silva L, Bellon ORP, Segundo MP (2010) 3D face recognition using simulated annealing and the surface interpenetration measure. IEEE Trans Pattern Anal Mach Intell 32(2):206–219CrossRef

26.

Moreno AB, Sanchez A, Velez JF, Diaz FJ (2003) Face recognition using 3D surface-extracted descriptors. In: Conference on Irish machine vision and image processing

27.

Hajati F, Raie AA, Goa Y (2012) 2.5D face recognition using patch geodesic moments. Pattern Recognit 45(2012):969–982CrossRefMATH

28.

Gordan GG (1992) Face recognition based on depth and curvature features. In: International conference on computer vision and pattern recognition, pp 808–810

29.

Tanaka HT, Ikeda M, Chiaki H (1998) Curvature-based face surface recognition using spherical correlation—principal directions for curved object recognition. In: International conference on automatic face and gesture recognition, pp 372–377

30.

Wang Y, Liu J, Tang X (2010) Robust 3D face recognition by local shape difference boosting. IEEE Trans Pattern Anal Mach Intell 32(10):1858–1870CrossRef

31.

Srivastava A, Liu X, Hesher C (2006) Face recognition using optimal linear components of face images. J Image Vis Comput 24(3):291–299CrossRef

32.

Lu X, Jain AK (2008) Deformation modelling for robust 3D face matching. In: International conference on computer vision and pattern recognition

33.

Haar FB, Veltkamp RC (2010) Expression modeling for expression-invariant face recognition. J Comput Graph 34(2010):231–241CrossRef

34.

Besl P, McKay N (1997) A method for registration of 3-D shapes. IEEE Trans Pattern Anal Mach Intell 14(2):239–256CrossRef

35.

Zhang Z (1994) Iterative point matching for registration of free-form curve and surfaces. Int J Comput Vis 13(1):119–152CrossRef

36.

He X, Yan S, Hu Y, Niyogi P, Zhang HJ (2005) Face recognition using Laplacianfaces. IEEE Trans Pattern Anal Mach Intell 27(3):328–340CrossRef

37.

Belkin M, Niyogi P (2001) Laplacian eigenmaps and spectral techniques for embedding and clustering. In: Conference on advances in neural information processing system

38.

Jahne HB, HauBecker F (2000) Computer vision and application. Academic Press, London

39.

Papiez BW, Matuszewski BJ, Shark L-K, Quan W (2012) Facial expression recognition using LOG-euclidean statistical shape models. In: International conference on pattern recognition applications and methods, ICPRAM

40.

Papiez BW, Matuszewski BJ, Shark L-K, Quan W (2012) Facial expression recognition using diffeomorphic image registration framework. Math Methodol Pattern Recognit Mach Learn 30:179–194CrossRefMATH

41.

Rohr K, Stiehl HS, Sprengel R, Buzug TM, Weese J, Kuhn MH (2001) Landmark-based elastic registration using approximating thin-plate splines. IEEE Trans Med Imaging 20(6):526–534CrossRef

42.

Joshi A (2009) Optimization of landmark selection for cortical surface registration. In: International conferences on computer vision and pattern recognition, pp 669–706

43.

Lu X, Jain AK, Colbry D (2006) Matching 2.5D face scans to 3D models. IEEE Trans Pattern Anal Mach Intell 28(1):31–43CrossRef

44.

Quan W, Matuszewski BJ, Shark L-K (2012) Facial asymmetry analysis based on 3-D dynamic scans. In: IEEE international conference on system, man and cybernetics, pp 2676–2681

45.

Kimmel R, Sethian JA (1998) Computing geodesic on manifolds. US Natl Acad Sci 95:8431–8435MathSciNetCrossRefMATH

46.

Bronstein MM, Bronstein AM, Kimmel R, Yavneh I (2006) Multigrid multidimensional scaling. Numer Linear Algebra Appl 13:149–171MathSciNetCrossRefMATH

47.

Pighin F, Heaker J, Lischinski D, Szeliski R, Salesin DH (1998) Synthesizing realistic facial expression from photographs. In: ACM SIGGRAPH, pp 75–84

48.

Noh J, Neumann U (2001) Expression cloning. In: ACM SIGGRAPH, pp 277–288

49.

Quan W, Matuszewski BJ, Shark L-K, Ait-Boudaoud D (2009) Facial expression biometrics using statistical shape models. EURASIP J Adv Signal Process 1–17

50.

Ruechert D, Sonoda L, Hayes C, Hill D, Leach M, Hawkes D (1999) Nonrigid registration using free-form deformation: application to breast MR images. IEEE Trans Med Imaging 18(8):712–721CrossRef

51.

Sandbach G, Zafeiriou S, Pantic M, Rueckert D (2011) A dynamic approach to the recognition of 3-D facial expressions and their temporal models. In: IEEE conference on automatic face and gesture recognition, pp 406–413

52.

Sandbach G, Zafeiriou S, Pantic M, Rueckert D (2012) Recognition of 3-D facial expression. Image Vis Comput 30(10):762–773CrossRef

53.

Bookstein FL (1989) Principal warps: thin-plate splines and the decomposition of deformation. IEEE Trans Pattern Anal Mach Intell 11(6):567–585CrossRefMATH

54.

Lee S, Wolberd G, Shin S (1997) Scattered data interpolation with multilevel B-splines. IEEE Trans Vis Comput Graph 3(3):228–244CrossRef

55.

Dhillon IS, Guan Y, Kulis B (2007) Weighted graph cuts without eigenvectors: a multilevel approach. IEEE Trans Pattern Anal Mach Intell 29(11):1–14CrossRef

56.

Qiu D, May S, Nuchter A (2009) GPU-accelerated nearest neighbor search for 3D registration. In: Proceedings of the 7th international conference on computer vision systems: computer vision systems, pp 194–203

57.

Yin L, Wei X, Sun Y, Wang J, Rosato M (2006) A 3D facial expression database for facial behaviour research. In: 7th international conference on automatic face and gesture recognition, pp 211–216

58.

Moreno AB, Sanchez A (2004) GavabDB: a 3D face database. In: COST workshop on biometrics on internet: fundamentals, advances and applications, pp 77–82

59.

Moghaddam B, Pentland A (1997) Probabilistic visual learning for object representation. IEEE Trans Pattern Anal Mach Intell 19(6):696–710CrossRef

60.

Phillips PJ (1998) Support vector machines applied to face recognition. Adv Neural Inf Process Syst 11:803–809

61.

Rizvi SA, Philips PJ, Moon H (1998) The FERET verification testing protocol for face recognition algorithms. In: IEEE international conference on automatic face and gesture recognition

62.

Moreno AB, Sanchez A, Velez J, Diaz F (2005) Face recognition using 3D local geometrical features: PCA vs SVM. In: International symposium on image and signal processing and analysis

63.

Mahoor MH, Abdel-Mottaleb M (2009) Face recognition based on 3D ridge images obtained from range data. Pattern Recognit 42(3):445–451CrossRefMATH

64.

Berrett S, Bimbo A, Pala P (2006) 3D face recognition by modeling the arrangement of concave and convex regions. In: Adaptive multimedia retrieval, pp 108–118

Title: Statistical shape modelling for expression-invariant face analysis and recognition
Authors: Wei Quan
Bogdan J. Matuszewski
Lik-Kwan Shark
Publication date: 01-08-2016
Publisher: Springer London
Published in: Pattern Analysis and Applications / Issue 3/2016
Print ISSN: 1433-7541
Electronic ISSN: 1433-755X
DOI: https://doi.org/10.1007/s10044-014-0439-x

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