Arcface: Additive angular margin loss for deep face recognition
Proceedings of the IEEE/CVF conference on computer vision and …, 2019•openaccess.thecvf.com
One of the main challenges in feature learning using Deep Convolutional Neural Networks
(DCNNs) for large-scale face recognition is the design of appropriate loss functions that can
enhance the discriminative power. Centre loss penalises the distance between deep
features and their corresponding class centres in the Euclidean space to achieve intra-class
compactness. SphereFace assumes that the linear transformation matrix in the last fully
connected layer can be used as a representation of the class centres in the angular space …
(DCNNs) for large-scale face recognition is the design of appropriate loss functions that can
enhance the discriminative power. Centre loss penalises the distance between deep
features and their corresponding class centres in the Euclidean space to achieve intra-class
compactness. SphereFace assumes that the linear transformation matrix in the last fully
connected layer can be used as a representation of the class centres in the angular space …
Abstract
One of the main challenges in feature learning using Deep Convolutional Neural Networks (DCNNs) for large-scale face recognition is the design of appropriate loss functions that can enhance the discriminative power. Centre loss penalises the distance between deep features and their corresponding class centres in the Euclidean space to achieve intra-class compactness. SphereFace assumes that the linear transformation matrix in the last fully connected layer can be used as a representation of the class centres in the angular space and therefore penalises the angles between deep features and their corresponding weights in a multiplicative way. Recently, a popular line of research is to incorporate margins in well-established loss functions in order to maximise face class separability. In this paper, we propose an Additive Angular Margin Loss (ArcFace) to obtain highly discriminative features for face recognition. The proposed ArcFace has a clear geometric interpretation due to its exact correspondence to geodesic distance on a hypersphere. We present arguably the most extensive experimental evaluation against all recent state-of-the-art face recognition methods on ten face recognition benchmarks which includes a new large-scale image database with trillions of pairs and a large-scale video dataset. We show that ArcFace consistently outperforms the state of the art and can be easily implemented with negligible computational overhead. To facilitate future research, the code has been made available.
openaccess.thecvf.com
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