Investigating the use of pixel scrambling and diffusion in secure radiographic inspections

IF 1.6 3区物理与天体物理 Q2 NUCLEAR SCIENCE & TECHNOLOGY

Radiation Measurements Pub Date : 2024-07-09 DOI:10.1016/j.radmeas.2024.107229

Qing-Hua He , Xiao-Min Dou , Kai-Kai Lu , Xiao-Suo He , Sheng-Kai Wang , Tian-Zhu Mo , Li-Qian Xia , Xiang-Yu Wang , Xiao-Tao He

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引用次数: 0

Abstract

In warhead verification, physical encryption technology could play a critical role in protecting confidential information on geometric structure and isotopic composition of a true warhead. As an important supplement to physical encryption, algorithmic encryption still has great potential in improving defense-in-depth security for nuclear arms control verification. To further supplement feasible nuclear arms control verification technologies, we propose a verification method based on neutron induced fission reactions employing both physical field flux encryption and algorithm encryption. Physical encryption processes the classified geometry or composition information by encrypting the fission neutron signal of the tested item with a randomly shielded mask. Algorithm encryption adopts pixel scrambling, pixel diffusion for secondary encryption. To verify the robustness and security of this new verification method, numerical simulations are performed using the Monte Carlo toolkit Geant4. Verification results indicate a high level of robustness and security with a low level of noise (∼<0.5%).

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研究像素加扰和扩散在安全射线检查中的应用

在弹头核查中，物理加密技术可在保护真正弹头的几何结构和同位素组成的机密信息方面发挥关键作用。作为物理加密的重要补充，算法加密在提高核军控核查的纵深防御安全性方面仍有很大潜力。为了进一步补充可行的核军备控制核查技术，我们提出了一种基于中子诱导裂变反应的核查方法，同时采用物理场通量加密和算法加密。物理加密通过对被测物的裂变中子信号进行随机屏蔽加密，从而处理机密的几何或成分信息。算法加密采用像素加扰、像素扩散等方法进行二次加密。为了验证这种新验证方法的鲁棒性和安全性，使用蒙特卡罗工具包 Geant4 进行了数值模拟。验证结果表明，在较低的噪声水平（∼<0.5%）下，该方法具有很高的鲁棒性和安全性。

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

Radiation Measurements 工程技术-核科学技术

CiteScore

4.10

自引率

20.00%

发文量

116

审稿时长

48 days

期刊介绍： The journal seeks to publish papers that present advances in the following areas: spontaneous and stimulated luminescence (including scintillating materials, thermoluminescence, and optically stimulated luminescence); electron spin resonance of natural and synthetic materials; the physics, design and performance of radiation measurements (including computational modelling such as electronic transport simulations); the novel basic aspects of radiation measurement in medical physics. Studies of energy-transfer phenomena, track physics and microdosimetry are also of interest to the journal. Applications relevant to the journal, particularly where they present novel detection techniques, novel analytical approaches or novel materials, include: personal dosimetry (including dosimetric quantities, active/electronic and passive monitoring techniques for photon, neutron and charged-particle exposures); environmental dosimetry (including methodological advances and predictive models related to radon, but generally excluding local survey results of radon where the main aim is to establish the radiation risk to populations); cosmic and high-energy radiation measurements (including dosimetry, space radiation effects, and single event upsets); dosimetry-based archaeological and Quaternary dating; dosimetry-based approaches to thermochronometry; accident and retrospective dosimetry (including activation detectors), and dosimetry and measurements related to medical applications.