Differential Sensing Approaches for Scattering-Based Holographic Encryption

Mohammadrasoul Taghavi, Edwin A. Marengo
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Abstract

We develop a new scattering-based framework for the holographic encryption of analog and digital signals. The proposed methodology, termed "differential sensing", involves encryption of a wavefield image by means of two hard-to-guess, complex and random scattering media, namely, a background and a total (background plus scatterer) medium. Unlike prior developments in this area, not one but two scattering media are adopted for scrambling of the probing wavefields (as encoded, e.g., in a suitable ciphertext hologram) and, consequently, this method offers enhanced security. In addition, while prior works have addressed methods based on physical imaging in the encryption phase followed by computational imaging in the decryption stage, we examine the complementary modality wherein encryption is done computationally while decryption is done analogically, i.e., via the materialization of the required physical imaging system comprising the ciphertext hologram and the two unique (background and total) media. The practical feasibility of the proposed differential sensing approach is examined with the help of computer simulations incorporating multiple scattering. The advantages of this method relative to the conventional single-medium approach are discussed for both analog and digital signals. The paper also develops algorithms for the required in situ holography as well as a new wavefield-nulling-based approach for scattering-based encryption with envisioned applications in real-time customer validation and secure communication.
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基于散射的全息加密的差分传感方法
我们为模拟和数字信号的全息加密开发了一种基于散射的新框架。所提出的方法被称为 "差分传感",涉及通过两种难以猜测的复杂随机散射介质,即背景介质和总(背景加散射体)介质,对波场图像进行加密。与之前在这一领域的发展不同的是,采用的不是一种而是两种散射介质来扰乱探测波场(如在合适的密文全息图中编码),因此,这种方法提供了更高的安全性。此外,以前的研究都是在加密阶段基于物理成像,然后在解密阶段基于计算成像的方法,而我们则研究了一种互补模式,即加密是通过计算完成的,而解密则是类比完成的,即通过所需的物理成像系统(包括密文全息图和两种独特的(背景和总体)介质)的具体化来实现。在计算机模拟的帮助下,结合多重散射研究了所提出的差分传感方法的实际可行性。论文讨论了这种方法相对于传统单介质方法的优势,既适用于模拟信号,也适用于数字信号。论文还开发了 situholography 所需的算法,以及一种基于波场归零的新方法,用于基于散射的加密,预计可应用于实时定制验证和安全通信。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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