Holographic displays have significant potential in virtual reality and augmented reality owing to their ability to provide all the depth cues. Deep learning-based methods play an important role in computer-generated holograms (CGH). During the diffraction process, each pixel exerts an influence on the reconstructed image. However, previous works face challenges in capturing sufficient information to accurately model this process, primarily due to the inadequacy of their effective receptive field (ERF). Here, we designed complex-valued deformable convolution for integration into network, enabling dynamic adjustment of the convolution kernel's shape to increase flexibility of ERF for better feature extraction. This approach allows us to utilize a single model while achieving state-of-the-art performance in both simulated and optical experiment reconstructions, surpassing existing open-source models. Specifically, our method has a peak signal-to-noise ratio that is 2.04 dB, 5.31 dB, and 9.71 dB higher than that of CCNN-CGH, HoloNet, and Holo-encoder, respectively, when the resolution is 19201072. The number of parameters of our model is only about one-eighth of that of CCNN-CGH.
View on arXiv@article{shuyang2025_2506.14542,
title={ MobileHolo: A Lightweight Complex-Valued Deformable CNN for High-Quality Computer-Generated Hologram },
author={ Xie Shuyang and Zhou Jie and Xu Bo and Wang Jun and Xu Renjing },
journal={arXiv preprint arXiv:2506.14542},
year={ 2025 }
}