An Examination of Deep-Learning Based Landmark Detection Methods on Thermal Face Imagery

Abstract

Thermal-to-visible face recognition is an emerging technology for low-light and nighttime human identification, for which detection of fiducial landmarks is a critical step required for face alignment prior to recognition. However, thermal images with their low contrast, low resolution, and lack of textural information have proven a challenging obstacle for the detection of the fiducial landmarks used for image alignment. This paper analyzes the ability of modern landmark detection algorithms to cope with the adversarial conditions present in the thermal domain by exploring the strengths and weaknesses of three deep-learning based landmark detection architectures originally developed for visible images: the Deep Alignment Network (DAN), Multi-task Convolutional Neural Network (MTCNN), and a Multi-class Patch-based fullyconvolutional neural network (PBC). Our experiments yield a normalized mean squared error of 0.04 at an offset distance of 2.5 meters using the DAN architecture, indicating an ability for cascaded shape regression neural networks to adapt to thermal images. However, we find that even small alignment errors disproportionately reduce correct recognition rates. With images aligned using the best performing model, an 8.2% drop in EER is observed as compared with ground truth alignments, leaving further room for improvement in this area.