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1. Learning in the Frequency Domain

   https://doi.org/10.1109/CVPR42600.2020.00181  

   Xu, Kai; Qin, Minghai; Sun, Fei; Wang, Yuhao; Chen, Yen-Kuang; Ren, Fengbo (January 2020, IEEE Conference on Computer Vision and Pattern Recognition)

   null (Ed.)

   Deep neural networks have achieved remarkable success in computer vision tasks. Existing neural networks mainly operate in the spatial domain with fixed input sizes. For practical applications, images are usually large and have to be downsampled to the predetermined input size of neural networks. Even though the downsampling operations reduce computation and the required communication bandwidth, it removes both redundant and salient information obliviously, which results in accuracy degradation. Inspired by digital signal processing theories, we analyze the spectral bias from the frequency perspective and propose a learning-based frequency selection method to identify the trivial frequency components which can be removed without accuracy loss. The proposed method of learning in the frequency domain leverages identical structures of the well-known neural networks, such as ResNet-50, MobileNetV2, and Mask R-CNN, while accepting the frequency-domain information as the input. Experiment results show that learning in the frequency domain with static channel selection can achieve higher accuracy than the conventional spatial downsampling approach and meanwhile further reduce the input data size. Specifically for ImageNet classification with the same input size, the proposed method achieves 1.60% and 0.63% top-1 accuracy improvements on ResNet-50 and MobileNetV2, respectively. Even with half input size, the proposed method still improves the top-1 accuracy on ResNet-50 by 1.42%. In addition, we observe a 0.8% average precision improvement on Mask R-CNN for instance segmentation on the COCO dataset. 

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2. Mirror-induced reflection in the frequency domain

   https://doi.org/10.1038/s41467-022-33529-w  

   Hu, Yaowen; Yu, Mengjie; Sinclair, Neil; Zhu, Di; Cheng, Rebecca; Wang, Cheng; Lončar, Marko (October 2022, Nature Communications)

   Abstract Mirrors are ubiquitous in optics and are used to control the propagation of optical signals in space. Here we propose and demonstrate frequency domain mirrors that provide reflections of the optical energy in a frequency synthetic dimension, using electro-optic modulation. First, we theoretically explore the concept of frequency mirrors with the investigation of propagation loss, and reflectivity in the frequency domain. Next, we explore the mirror formed through polarization mode-splitting in a thin-film lithium niobate micro-resonator. By exciting the Bloch waves of the synthetic frequency crystal with different wave vectors, we show various states formed by the interference between forward propagating and reflected waves. Finally, we expand on this idea, and generate tunable frequency mirrors as well as demonstrate trapped states formed by these mirrors using coupled lithium niobate micro-resonators. The ability to control the flow of light in the frequency domain could enable a wide range of applications, including the study of random walks, boson sampling, frequency comb sources, optical computation, and topological photonics. Furthermore, demonstration of optical elements such as cavities, lasers, and photonic crystals in the frequency domain, may be possible. 

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3. Nonlinearity parameter imaging in the frequency domain

   https://doi.org/10.3934/ipi.2023037  

   Kaltenbacher, Barbara; Rundell, William (January 2024, Inverse Problems and Imaging)
4. Quasimonochromatic LISA sources in the frequency domain

   https://doi.org/10.1103/PhysRevD.109.104013  

   Strokov, Vladimir; Berti, Emanuele (May 2024, Physical Review D)
5. Skip-sampling: subsampling in the frequency domain

   McElroy, T; Politis, D (September 2024, Biometrika)