Mohammadrahim Kazemzadeh, Liam Collard, Linda Piscopo, Massimo De Vittorio, Ferruccio Pisanello
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引用次数: 0
摘要
在2400574号文章中,Mohammadrahim Kazemzadeh、Massimo De Vittorio、Ferruccio Pisanello及其同事介绍了一种仅使用强度测量来表征和创建浑浊介质数字孪生的新方法。与之前作为黑盒子的深度学习方法不同,这种物理信息框架优先考虑可解释性,提供了对光通过散射介质传播的更清晰理解,并能够估计传输矩阵。这种数字孪生的一个关键优势是它的可微特性,允许基于梯度的优化来解决逆问题,例如检索通过介质的光的初始波前。结果表明,与直接针对该任务优化的模型相比,该方法具有更高的精度,突出了所提出方法的精度和鲁棒性。这一进展为使用光子和光学系统的神经形态和深度学习计算的未来发展铺平了道路。作者真诚地感谢帕特里夏·邦迪亚的艺术作品,使他们的研究美观地可视化。
A Physics-Informed Neural Network as a Digital Twin of Optically Turbid Media
Digital Twin
In article number 2400574, Mohammadrahim Kazemzadeh, Massimo De Vittorio, Ferruccio Pisanello, and co-workers introduce a novel methodology for characterizing and creating a digital twin of turbid media using only intensity measurements. Unlike previous deep learning approaches that function as black boxes, this physics-informed framework prioritizes interpretability, providing a clearer understanding of light propagation through scattering media and enabling the estimation of the transmission matrix. A key advantage of this digital twin is its differentiable nature, allowing gradient-based optimization for solving inverse problems, such as retrieving the initial wavefront of light that passed through the medium. The results demonstrate superior accuracy compared to models directly optimized for this task, highlighting the precision and robustness of the proposed approach. This advancement paves the way for future developments in neuromorphic and deep learning computation using photonic and optical systems. The authors sincerely thank Patricia Bondia for the artwork that beautifully visualizes their research.
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