Abstract
For accurate and fast detection of facial landmarks, we propose a new facial landmark detection method. Previous facial landmark detection models generally perform a face detection step before landmark detection. This greatly affects landmark detection performance depending on which face detection model is used. Therefore, we propose a model that can simultaneously detect a face region and a landmark without performing the face detection step before landmark detection. The proposed single-shot detection model is based on the framework of YOLOv3, a one-stage object detection method, and the loss function and structure are altered to learn faces and landmarks at the same time. In addition, EfficientNet-B0 was utilized as the backbone network to increase processing speed and accuracy. The learned database used 300W-LP with 64 facial landmarks. The average normalized error of the proposed model was 2.32 pixels. The processing time per frame was about 15 milliseconds, and the average precision of face detection was about 99%. As a result of the evaluation, it was confirmed that the single-shot detection model has better performance and speed than the previous methods. In addition, as a result of using the COFW database, which has 29 landmarks instead of 64 to verify the proposed method, the average normalization error was 2.56 pixels, which was also confirmed to show promising performance.
Highlights
Landmark detection is influenced by the face region detectionmodel
The database used for trainingNand was gle − gre k2 300W-LP, and each image has the i coordinates of 68 landmarks from one face
The database used for verification is Caltech occluded faces in the wild (COFW), and each image has the coordinates of 29 landmarks from one face
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The technique of facial landmark detection includes locating a face in an image and obtaining a key point of the face, and many studies employing faces [1], such as facial recognition, face verification, and face 3D modeling, all rely on this process [2,3,4]. Wearable devices are becoming increasingly popular, and there are many ways to interact with other smart devices. A wearable device requires an IoT-based sensing technology that can measure the physiological and behavioral characteristics of users. The incorporation of biometric authentication, through face and iris, into wearable devices is being investigated [5,6]. Goggle-shaped wearable devices for augmented reality (AR)
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