Intelligent facial expression recognition with adaptive feature extraction for a humanoid robot

Automatic facial expression recognition plays an important role in agent-based interface development and datadriven animation. This paper presents an intelligent facial action and emotion recognition system for a humanoid robot. Motivated by the Facial Action Coding System, this research focuses on...

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Bibliographic Details
Main Authors: Mistry, Kamlesh, Li Zhang, Barnden, John
Format: Conference Proceeding
Language:English
Subjects:
action unit
Active appearance model
Adaptation models
and facial emotion recognition
Automation
Emotion recognition
Emotions
Face recognition
Facial feature extraction
facial point detector
Feature extraction
Gold
Humanoid
Image recognition
Neural networks
Robots
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Summary:Automatic facial expression recognition plays an important role in agent-based interface development and datadriven animation. This paper presents an intelligent facial action and emotion recognition system for a humanoid robot. Motivated by the Facial Action Coding System, this research focuses on the recognition of seven basic emotions and 18 Action Units (AU). Since effective facial representations of original face images are vital for automatic facial emotion recognition, this research implements a novel shape and appearance feature extraction method, which integrates an Independent Active Appearance Model (AAM) with a rotation-invariant feature point detector, BRISK (Binary Robust Invariant Scalable Keypoints). In comparison to AAM with a traditional inverse compositional fitting, our model with BRISK fitting is with less computational cost and is capable of dealing with feature extraction from images of faces with rotations and scaling differences without prior training required. Subsequently shape and appearancebased neural network AU analyzers are used to respectively detect 18 AUs. Emotions are then decoded from the derived AUs using a neural network emotion recognizer. The system is integrated with a modern humanoid robot platform. Evaluation results indicate its high accuracy for AU and emotion recognition. It is also among the top performers on the extended Cohn-Kanade (CK+) database in comparison to other existing state-of-the-art applications.
ISSN:2161-4393
2161-4407
DOI:10.1109/IJCNN.2015.7280323