Evaluating AAM Fitting Methods for Facial Expression Recognition

1. Evaluating AAM Fitting Methods for Facial Expression Recognition Akshay Asthana, Jason Saragih, Michael Wagner and Roland Göcke ANU, CMU & U Canberra In part funded by ARC grant TS0669874

2. Background • Thinking Head project • http://thinkinghead.edu.au/ • 5-year multi-institution (Canberra, UWS, Macquarie, Flinders) project in Australia • Develop a research platform for human communication sciences • “An Approach for Automatically Measuring Facial Activity in Depressed Subjects”, McIntyre, Göcke, Hyett, Green, Breakspear, ACII 2009

3. Aim for this Study • Active Appearance Models (AAM) have become a popular tool for markerless face tracking in recent years • A number of different AAM fitting methods exist • Which one should we use? • We wanted to evaluate these in the context of facial expression recognition (FER) • How well do AAMs generalise? • How robust are these methods w.r.t. initialisation error? • How does their fitting accuracy affect the FER accuracy?

4. AAM • Shape: • Texture:

5. AAM – Shape Variation • Shape variation Mean

6. AAM – Texture Variation • Texture variation Mean

7. AAM – Modelling Appearance • Appearance = Shape + Texture Mean

8. AAM (cont.) • Alignmentbased on finding model parameters that iteratively fit learnt model to the image Initialisation After 5 iterations Converged

9. AAM Fitting Methods Compared in this Study • Fixed Jacobian (FJ): Cootes, Edwards & Taylor, 1998 • Project-Out Inverse Compositional (POIC): Baker & Matthews, 2001 • Simultaneous Inverse Compositional (SIC): Baker, Gross & Matthews, 2003 • Robust Inverse Compositional (RIC): Gross, Matthews & Baker, 2005 • Iterative Error-Bound Minimisation (IEBM), aka Linear Discriminative-Iterative: Saragih & Goecke, 2006 • Haar-like Feature Based Iterative-Discriminative Method (HFBID): Saragih & Goecke, 2007

10. System Overview 2 1

11. Experiments • (1) Generalisation, (2) Robustness to initialisation error • Person-dependent models (PDFER): individual models • Person-independent models (PIFER): general models • Not for POIC as has previously been shown to not generalise well across different people • Cohn-Kanade database: • Subset of 30 subjects (15f / 15m) • Total of 3424 images: • 992 images for Neutral, 448 images for Anger, 296 images for Disgust, 346 images for Fear, 532 images for Joy, 423 images for Sorrow and 387 images for Surprise.

12. Initialisation • Traditionally, beside generalisation, one of the most challenging problems for AAMs has been robustness to initialisation error • Common face detectors, e.g. Viola-Jones, often give you an error (translation) of up to 30 pixels • We simulate this by deliberately misaligning the initial AAM: ±5, ±10, ±20, ±25 (PIFER) / ±30 pixels (PDFER) • Multi-class SVM using a linear kernel for PDFER and a Radial Basis Function kernel for PIFER • Classify expressions as Neutral or one of the ‘Big 6’ (7-class problem

13. Facial Expression Recognition • In this study, we were interested in recognising the ‘Big 6’ + Neutral expressions • Sincethe scope of most of the vision based expression recognition systems is based on changes in appearance, we grouped AUs together on a ‘regional basis’ • In that way, we did not have to recognise individual AUs but analysed movement patterns in various facial regions, which made the FER process more robust

14. FER (2)

15. FER Results - Video Ground truth

16. Results – Person-dependent Models Stable “Unstable”

17. Results – Person-independent Models Stable “Unstable”

18. Conclusions • Investigate the utility of different AAM fitting algorithms in the context of real-time FER • Iterative-Discriminative (ID) approach adopted in IEBM and HFBID boosts the fitting performance significantly and thus leads to improved FER results • More robust to initialisation error than other methods • IEBM and HFBID generalise well • Rapid fitting (real-time capable) ~ as fast as POIC • Future work: • Pose-invariant FER