Image encryption using arbitrary modes of Hermite-Gaussian beams

IF 3.1 3区物理与天体物理 Q2 Engineering

Optik Pub Date : 2025-03-06 DOI:10.1016/j.ijleo.2025.172301

Allarakha Shikder, Naveen K. Nishchal

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引用次数: 0

Abstract

In recent years, use of structured light beams in information processing has gained considerable interest due to their unique intensity and phase distributions. For encoding, optical encryption techniques utilize the spatial distributions of light. Image/data encryption through phase encoding requires complicated interferometric set-up while polarization encoding needs multiple intensity recordings. Such constraints create difficulties during optical implementation. To address these issues, we propose a method of image encryption that requires single recording of intensity distribution containing different modes of a Hermite-Gaussian (HG) beam. In this scheme, the freedom of independent and random choice of different modes of HG beam for encoding enhances the security. Further, we demonstrate an Arnold transformation-based information-sharing scheme, where the information of the decryption key is not required to be shared with the receiver for decryption. To check the effectiveness of the proposed architecture, various performance measure parameters such as correlation coefficient, mean square error, and peak signal-to-noise ratio between the plaintext and decrypted image have been computed.

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利用赫米特-高斯光束的任意模式进行图像加密

近年来，结构光束由于其独特的强度和相位分布，在信息处理中得到了广泛的应用。对于编码，光加密技术利用光的空间分布。通过相位编码进行图像/数据加密需要复杂的干涉设置，而偏振编码需要多次强度记录。这些限制给光学实现带来了困难。为了解决这些问题，我们提出了一种图像加密方法，该方法需要单次记录包含不同模式的厄米-高斯（HG）光束的强度分布。在该方案中，可以独立、随机地选择不同模式的HG波束进行编码，提高了安全性。此外，我们还演示了一种基于Arnold转换的信息共享方案，其中解密密钥的信息不需要与接收方共享以进行解密。为了验证所提架构的有效性，计算了明文和解密图像之间的相关系数、均方误差和峰值信噪比等各种性能度量参数。

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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来源期刊

Optik 物理-光学

CiteScore

6.90

自引率

12.90%

发文量

1471

审稿时长

46 days

期刊介绍： Optik publishes articles on all subjects related to light and electron optics and offers a survey on the state of research and technical development within the following fields: Optics: -Optics design, geometrical and beam optics, wave optics- Optical and micro-optical components, diffractive optics, devices and systems- Photoelectric and optoelectronic devices- Optical properties of materials, nonlinear optics, wave propagation and transmission in homogeneous and inhomogeneous materials- Information optics, image formation and processing, holographic techniques, microscopes and spectrometer techniques, and image analysis- Optical testing and measuring techniques- Optical communication and computing- Physiological optics- As well as other related topics.