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Journals >Chinese Optics Letters >Volume 22 >Issue 11 >Page 110603 > Article

Chinese Optics Letters
Vol. 22, Issue 11, 110603 (2024)

Advanced optical modulation for integrated computing and networking toward 6G requirement

Zhou He^1,2, Hao Huang³, Peng Zhang^4,5, Dongrong Ma¹..., Binghua Shi^1,2, Tong Wang^1,2, Yuanyuan Huang¹ and Jia Guo^1,2,*|Show fewer author(s)

Author Affiliations

¹Hubei Key Laboratory of Digital Finance Innovation, Hubei University of Economics, Wuhan 430205, China

²School of Information Engineering, Hubei University of Economics, Wuhan 430205, China

³Wuhan Second Ship Design and Research Institute, Wuhan 430205, China

⁴School of Electronic Information and Communications, Huazhong University of Science and Technology, Wuhan 430073, China

⁵Wuhan Fiberhome Technical Services Co., Ltd., Wuhan 430073, China

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DOI: 10.3788/COL202422.110603 Cite this Article Set citation alerts

Zhou He, Hao Huang, Peng Zhang, Dongrong Ma, Binghua Shi, Tong Wang, Yuanyuan Huang, Jia Guo, "Advanced optical modulation for integrated computing and networking toward 6G requirement," Chin. Opt. Lett. 22, 110603 (2024) Copy Citation Text

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References

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[2] . 6G Typical Scenarios and Key Capabilities White Paper(2022).

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[10] H. Yi. A secure blockchain system for internet of vehicles based on 6G-enabled network in box. Comput. Commun., 186, 45(2022).

[11] L. J. Vinita, V. Vetriselvi. Federated learning-based misbehaviour detection on an emergency message dissemination scenario for the 6G-enabled Internet of Vehicles. Ad Hoc Netw., 144, 103153(2023).

[12] A. Kumari, R. Gupta, S. Tanwar. Amalgamation of blockchain and IoT for smart cities underlying 6G communication: a comprehensive review. Comput. Commun., 172, 102(2021).

[13] P. R. Singh, V. K. Singh, R. Yadav et al. 6G networks for artificial intelligence-enabled smart cities applications: a scoping review. Telematics Inform. Rep., 9, 100044(2023).

[14] M. H. Alsharif, A. Jahid, R. Kannadasan et al. Unleashing the potential of sixth generation (6G) wireless networks in smart energy grid management: a comprehensive review. Energy Rep., 11, 1376(2024).

[15] P. Shukla, P. K. Sadhu, S. Dutta et al. An island detection approach in 6G paradigm for an active distribution network–a future perspective for next generation smart grids. Comput. Electr. Eng., 111, 108932(2023).

[16] R. Sitharthan, M. Rajesh, S. Vimal et al. A novel autonomous irrigation system for smart agriculture using AI and 6G enabled IoT network. Microprocess. Microsyst., 101, 104905(2023).

[17] H. F. Ahmad, W. Rafique, R. U. Rasool et al. Leveraging 6G, extended reality, and IoT big data analytics for healthcare: a review. Comput. Sci. Rev., 48, 100558(2023).

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[21] A. Sueyoshi, D. Hisano, A. Maruta et al. Transmission characteristics of all-optically converted QPSK and 16QAM signals. Opt. Commun., 537, 129432(2023).

[22] W. Yan, B. Wu, F. Wen et al. All-fiber mode exchange of high-speed DP-QPSK signals using mechanical long-period fiber grating. Opt. Commun., 554, 130140(2024).

[23] E. Ehsan, R. Ngah, N. A. B. Daud. A 1.792 Tbps RoF-based PDM-DQPSK DWDM system for high-capacity long-haul 5G and beyond optical network. Optik, 269, 169858(2022).

[24] F. Gozalpour, M. Yavari. An improved FSK-modulated class-E power and data transmitter for biomedical implants. Int. J. Electron. Commun., 170, 154786(2023).

[25] M. W. Sadiq, M. A. Kabir. Design and implementation of reconfigurable ASK and FSK modulation and demodulation algorithm on FPGA (field programmable gate array). Sens. Int., 3, 100155(2022).

[26] Z. He, F. Hu. Research on novel modulation format Apol-FSK for optical transport network of 5G. Opt. Commun., 474, 126055(2020).

[27] H. Zhou, Y. Di, Z. Wang et al. 160 Gbit/s Apol-FSK modulation format for 5G backhaul network. Proc. SPIE, 12154, 1215407(2022).

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Zhou He, Hao Huang, Peng Zhang, Dongrong Ma, Binghua Shi, Tong Wang, Yuanyuan Huang, Jia Guo, "Advanced optical modulation for integrated computing and networking toward 6G requirement," Chin. Opt. Lett. 22, 110603 (2024)

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