Advances in information processing and biological imaging using flat optics

Xinwei Wang, Huijie Hao, Xiaoyuan He, Peng Xie, Jian Liu, Jiubin Tan, Haoyu Li, Hao Wang, Patrice Genevet, Yu Luo, Xumin Ding, Guangwei Hu
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Abstract

Flat optical components (metasurfaces) made from artificial electromagnetic materials (metamaterials) have opened new possibilities for the manipulation of electromagnetic waves within compact multifunctional devices. This field encompasses the development of individual optical elements and their integration into systems for use in real-world applications, especially in optical information processing, light detection and ranging (LiDAR), augmented or virtual reality, and biological imaging. This comprehensive Review highlights advances in the use of flat optics in analog computational information processing and imaging applications and emphasizes their fundamental role in transfer function engineering. The natural synergy between flat optics and computational technologies is described in relation to advanced imaging and microscopy solutions that have the potential for simultaneous information acquisition and processing. An outlook on future developments, including critical insights for both newcomers and experts in this field, is also provided. Flat optics enable light manipulation at the subwavelength scale and provide a compact, wave-based, information processing and acquisition platform. Here, Wang et al. focus on the emerging interdisciplinary field of computational flat optic imaging applications and reveal their intrinsic connections.

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利用平面光学技术在信息处理和生物成像方面取得的进展
由人造电磁材料(超材料)制成的平面光学元件(超表面)为在紧凑型多功能设备中操纵电磁波提供了新的可能性。这一领域包括开发单个光学元件并将其集成到系统中,用于实际应用,特别是光学信息处理、光探测和测距(LiDAR)、增强或虚拟现实以及生物成像。本综述重点介绍了平面光学在模拟计算信息处理和成像应用中的应用进展,并强调了平面光学在传递函数工程中的基础作用。平面光学和计算技术之间的自然协同作用与先进的成像和显微镜解决方案有关,这些解决方案具有同时获取和处理信息的潜力。此外,还对未来发展进行了展望,包括对该领域新手和专家的重要见解。
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