Chaos-driven seven-core optical transmission scheme based on DNA full information chained analog-transcription

Author:

Chen Gengyin1,Liu Bo12,Ren Jianxin1,Mao Yaya1,Song Xiumin1,Wu Xiangyu1,Chen Shuaidong1,Ullah Rahat1ORCID,Qi Zhipeng1,Wu Yongfeng1,Sun Tingting1,Li Ying1,Zhao Lilong1,Wang Feng1

Affiliation:

1. Institute of Optics and Electronics

2. School of Electronic Engineering

Abstract

This paper proposes a chaos-driven seven-core optical transmission scheme based on DNA full information chained analog-transcription. Unlike traditional deoxyribonucleic acid (DNA) coded encryption schemes in the bit dimension, this scheme uses chaotic sequences to generate perturbed bit streams corresponding to the initial bit stream. These two sets of bit streams are encoded from a set of DNA double-stranded sequences, which are then intertwined into a single-stranded DNA containing all the information through the full-information class transcription algorithm proposed in this paper. Finally, the DNA decoding process is driven by a set of sequences derived from another chaotic model to transform the DNA sequence containing all information back into a bit sequence for subsequent transmission. Additional chaotic sequences interfere with the subcarriers, symbols, and constellation angles. Moreover, to maintain spectral efficiency, hiding the key in the frame header allows for the dynamic simultaneous transmission of signal and key. The transmission of encrypted 16 quadrature amplitude modulation-orthogonal chirp division multiplexing (16QAM-OCDM) signals is experimentally demonstrated at a net bit rate of 51.72 Gb/s over 2 km weakly coupled seven-core fiber. At the receiving end, the correct key decoder is able to accurately recover the data, while the bit error ratio (BER) at the illegal receiving end is 0.5. Finally, quantitative experiments validate the receiver-side decryption algorithm, showing that the proposed encryption scheme achieves a large key space of 10397. The key can be fully decoded when the optical power is above -20dBm. This scheme significantly enhances the security and flexibility of the communication system, making it a promising candidate for future optical communication physical layer encryption.

Funder

National Key Research and Development Program of China

National Natural Science Foundation of China

Jiangsu Provincial Key Research and Development Program

Publisher

Optica Publishing Group

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