Look More Into Occlusion: Realistic Face Frontalization and Recognition With BoostGAN.

Abstract

Many factors can affect face recognition, such as occlusion, pose, aging, and illumination. First and foremost are occlusion and large-pose problems, which may even lead to more than 10% accuracy degradation. Recently, generative adversarial net (GAN) and its variants have been proved to be effective in processing pose and occlusion. For the former, pose-invariant feature representation and face frontalization based on GAN models have been studied to solve the pose variation problem. For the latter, frontal face completion on occlusions based on GAN models have also been presented, which is much concerned with facial structure and realistic pixel details rather than identity preservation. However, synthesizing and recognizing the occluded but profile faces is still an understudied problem. Therefore, in this article, to address this problem, we contribute an efficient but effective solution on how to synthesize and recognize faces with large-pose variations and simultaneously corrupted regions (e.g., nose and eyes). Specifically, we propose a boosting GAN (BoostGAN) for occluded but profile face frontalization, deocclusion, and recognition, which has two aspects: 1) with the assumption that face occlusion is incomplete and partial, multiple images with patch occlusion are fed into our model for knowledge boosting, i.e., identity and texture information and 2) a new aggregation structure integrated with a deep encoder-decoder network for coarse face synthesis and a boosting network for fine face generation is carefully designed. Exhaustive experiments on benchmark data sets with regular and irregular occlusions demonstrate that the proposed model not only shows clear photorealistic images but also presents powerful recognition performance over state-of-the-art GAN models for occlusive but profile face recognition in both the controlled and uncontrolled environments. To the best of our knowledge, this article proposes to solve face synthesis and recognition under poses and occlusions for the first time.