Deep Learning-Enabled Orbital Angular Momentum-Based Information Encryption Transmission

Feng, Fu; Hu, Junbao; Guo, Zefeng; Gan, Jiaan; Chen, Pengfei; Chen, Guangyong; Min, Changjun; Yuan, Xiaocong; Somekh, Michael Geoffrey

doi:10.1021/acsphotonics.1c01303

Cited by 53 publications

(18 citation statements)

References 44 publications

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“…This phenomenon indicates that our optical neural network is actually transforming the wavefront of structured field. In this way, our scheme can naturally get rid of the misleading brought by degenerate intensity patterns, as confronted by earlier works using intensity-based DL recognition algorithms [27,28,30,52].…”

Section: Results and Analysismentioning

confidence: 87%

“…In optics, data-driven DL algorithms are becoming pervasive tools to augment performance and to infuse new functionalities in imaging [23], holography [24], ultrafast photonics [25], optical metrology [26], etc. Recently, DL is also introduced to recognize OAM modes [27][28][29][30][31] due to their inherent ability to analyze complex patterns. However, the distinguishment of degenerate intensities patterns carrying different OAM spectra becomes a major challenge.…”

Section: Introductionmentioning

confidence: 99%

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Intelligent optoelectronic processor for orbital angular momentum spectrum measurement

Wang

Zhan

et al. 2023

PhotoniX

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Orbital angular momentum (OAM) detection underpins almost all aspects of vortex beams’ advances such as communication and quantum analogy. Conventional schemes are frustrated by low speed, complicated system, limited detection range. Here, we devise an intelligent processor composed of photonic and electronic neurons for OAM spectrum measurement in a fast, accurate and direct manner. Specifically, optical layers extract invisible topological charge information from incoming light and a shallow electronic layer predicts the exact spectrum. The integration of optical-computing promises us a compact single-shot system with high speed and energy efficiency (optical operations / electronic operations ~$${10}^{3}$$ 10 3 ), neither necessitating reference wave nor repetitive steps. Importantly, our processor is endowed with salient generalization ability and robustness against diverse structured light and adverse effects (mean squared error ~$$10^{(-5)}$$ 10 ( - 5 ) ). We further raise a universal model interpretation paradigm to reveal the underlying physical mechanisms in the hybrid processor, as distinct from conventional ‘black-box’ networks. Such interpretation algorithm can improve the detection efficiency up to 25-fold. We also complete the theory of optoelectronic network enabling its efficient training. This work not only contributes to the explorations on OAM physics and applications, and also broadly inspires the advanced links between intelligent computing and physical effects.

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Section: Results and Analysismentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Intelligent optoelectronic processor for orbital angular momentum spectrum measurement

Wang

Zhan

et al. 2023

PhotoniX

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“…The process of image denoising is considered image restoration [ 11 ]. The authors of [ 12 ] proposed a new cross-image, pixel scrambling-based rotation domain, dual-image encryption technique. In [ 13 ], the authors suggested a dual-image encryption method that incorporates DNA spatiotemporal chaos, deletion, and insertion to improve the security of the encryption process, and scramble real as well as imaginary sections of data produced by every round of encryption [ 14 ].…”

Section: Related Workmentioning

confidence: 99%

Face Image Encryption Based on Feature with Optimization Using Secure Crypto General Adversarial Neural Network and Optical Chaotic Map

Alsafyani

Alhomayani

Alsuwat

et al. 2023

Sensors

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Demand for data security is increasing as information technology advances. Encryption technology based on biometrics has advanced significantly to meet more convenient and secure needs. Because of the stability of face traits and the difficulty of counterfeiting, the iris method has become an essential research object in data security research. This study proposes a revolutionary face feature encryption technique that combines picture optimization with cryptography and deep learning (DL) architectures. To improve the security of the key, an optical chaotic map is employed to manage the initial standards of the 5D conservative chaotic method. A safe Crypto General Adversarial neural network and chaotic optical map are provided to finish the course of encrypting and decrypting facial images. The target field is used as a "hidden factor" in the machine learning (ML) method in the encryption method. An encrypted image is recovered to a unique image using a modernization network to achieve picture decryption. A region-of-interest (ROI) network is provided to extract involved items from encrypted images to make data mining easier in a privacy-protected setting. This study’s findings reveal that the recommended implementation provides significantly improved security without sacrificing image quality. Experimental results show that the proposed model outperforms the existing models in terms of PSNR of 92%, RMSE of 85%, SSIM of 68%, MAP of 52%, and encryption speed of 88%.

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“…Here, they deliberately introduced mechanical stress to the multimode fiber to mix the input OAM modes thus to encrypt the message and then a neural network was trained to recover the initial single or superposition modes that could be read out by Bod via a standard alphabet. Similarly, a dynamically shaking diffuser was also exploited for high-security large-capacity encryption transmission technique where OAM beams with an interval of δ l = 0.01 could be successfully decrypted and decoded, as shown in Figure d . Optical speckle patterns naturally complicated the plain-text information in a random manner, which gave rise to the security.…”

Section: Structured Light As Ultracapacity Information Carriersmentioning

confidence: 99%

Ultra-Degree-of-Freedom Structured Light for Ultracapacity Information Carriers

et al. 2023

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Structured light recently highlighted the higher-dimensional control with many tailored degrees of freedom (DoFs) such as amplitude, wavelength, polarization, and orbital angular momentum (OAM), spurring the extension of fundamental science and advanced applications, especially as the novel information carrier to meet the requirement of everlastingly increasing communication bandwidth and security. In addition to the basic DoFs in light, there are also several complex DoFs hidden in spin−orbital coupled vector beams, ray-wave geometric modes, spatiotemporal vortex rings, etc., extending the structured light manipulation. In this Review, we summarize a systematic technical roadmap on how to extend multiple DoFs step-by-step beyond the conventional OAM beams, creating new forms of ultra-DoF structured light, and present a tutorial on how to exploit multiple DoFs of light as advanced information carriers, especially with the recent assistance of artificial intelligence or deep learning method, enhancing the capacity, security, and dimension for the next-generation information technologies.

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Deep Learning-Enabled Orbital Angular Momentum-Based Information Encryption Transmission

Cited by 53 publications

References 44 publications

Intelligent optoelectronic processor for orbital angular momentum spectrum measurement

Intelligent optoelectronic processor for orbital angular momentum spectrum measurement

Face Image Encryption Based on Feature with Optimization Using Secure Crypto General Adversarial Neural Network and Optical Chaotic Map

Ultra-Degree-of-Freedom Structured Light for Ultracapacity Information Carriers

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