With the widespread application of face recognition technology in public safety, identity authentication, and other fields, face recognition under mask cover has gradually become a research hotspot. Traditional methods rely on manual feature extraction and template matching, making it difficult to deal with the loss of face features caused by occlusion. To accurately recognize faces under mask occlusion, an improved principal component analysis network based on multi-scale feature fusion (Multi-Scale PCANet, MPCANet) and a progressively trained multi-scale face restoration generative adversarial network (Multi-Scale Face Restoration Generative Adversarial Network, MFR-GAN) are proposed for face biometric recognition under masks. MPCANet takes multi-layer convolution to extract features, concatenates different levels of feature information through channels, and divides the feature map into multi-scale blocks through pyramid pooling layers to form multi-scale feature vectors for matching and recognizing occluded faces. MFR-GAN utilizes a progressive training strategy to gradually increase the resolution from low resolution images for training, and introduces discrete wavelet transform to extract high-frequency information and calculate high-frequency loss, optimizing the quality of image generation. The experiment was conducted on the Labeled Faces in the Wild (LFW) dataset, with an average accuracy of 94.24% and a computation time of 0.87 seconds for MPCANet. The MFR-GAN had a realism of 0.95 and a peak signal-to-noise ratio of 30.25dB at a 30% occlusion ratio. In practical applications, the new model achieved a recognition accuracy of 98.68%, a false recognition rate of 1.32%, and a recognition rate of 97.58% under occlusion conditions, demonstrating high efficiency and accuracy. This method provides an efficient solution for biometric recognition in mask occlusion scenarios, which is helpful for identity authentication.