Nonlinear and Inseparable Radar And Data (NIRAD) Transmission Framework for Pareto Efficient Spectrum Access in Future Wireless Networks

NSF Award Number: 2128368

Abstract

Communications and radar are two major applications of electromagnetic waves, which convey information to a destination and glean information from the environment, respectively. Historically, the two technologies were developed and operated independently, thus using different frequency spectrum bands and different hardware. Facing a scarcity of wireless spectrum resources due to the explosive growth in wireless applications, the integration of communications and radar enables sharing of spectrum and hardware, thus substantially reducing the cost and resource demands. Meanwhile, due to the lower amount of electromagnetic emissions, interference to other wireless services will also be substantially reduced. When bandwidth is saved due to the integration of communications and radar sensing, more bandwidth can be committed to each transceiver, thus achieving higher data transmission rates and finer sensing precision, or allowing more wireless devices to be able to access the spectrum. These advantages are of considerable value for applications such as Internet of Things (IoT) and cyber physical systems (CPSs), such as unmanned aerial vehicles (UAVs) and aerial access networks (AANs). The project also will fulfill an education role, including K-12 outreach, and undergraduate/graduate level course design. The findings of the proposed research will disseminated to academic and industrial communities.

This study devises a nonlinear and inseparable radar and data (NIRAD) transmission scheme, in which the functions of communications and radar sensing are integrated in the same waveform and use the same hardware. In contrast to linearly superimposed communications and radar sensing, the NIRAD scheme integrates both functions in an inseparable manner, thus allow each to fully exploit the resources of the other. When a waveform is transmitted, the electromagnetic wave brings information to the communication receiver; upon reflections, the wave brings back information for radar sensing, thus achieving both functions in the same round of transmission. When the different functions of communications and radar sensing are integrated in the same waveform and hardware, they have conflicting interests, due to their different purposes. This project discloses the trade-off between communications and radar sensing and characterizes it in an economics framework. The NIRAD technique is applicable to various practical systems, such as high-definition maps in autonomous driving, space-terrestrial communications, and reconfigurable intelligent surfaces, by improving the efficiencies of bandwidth, power and hardware. The proposed algorithms and protocols will be tested using software simulations and field experiments based on a 5G testbed.

This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

Principal Investigators

  • Dr. Zhu Han
  • Dr. Husheng Li
  • Dr. H. Vincent Poor

    • Publications

    1. Hongliang Zhang, Boya Di, Lingyang Song, and Zhu Han, "Reconfigurable Intelligent Surface-Empowered 6G," Springer Science + Business Media, LLC, 2021. [PDF]
    2. Xiaoyou Yu, Qi Yang, Zhu Xiao, Hongyang Chen, Vincent Havyarimana, and Zhu Han, "A Precoding Approach for Dual-Functional Radar-Communication System With One-Bit DACs," in IEEE Journal on Selected Areas in Communications, v. 40, Jun. 2022. [PDF]
    3. Hongliang Zhang, Boya Di, Kaigui Bian, Zhu Han, H. Vincent Poor, and Lingyang Song "Toward Ubiquitous Sensing and Localization With Reconfigurable Intelligent Surfaces," in Proceedings of the IEEE. [PDF]
    4. Haobo Zhang, Hongliang Zhang, Boya Di, Zhu Han, H. Vincent Poor, and Lingyang Song, “Holographic Integrated Sensing and Communication," IEEE Journal on Selected Areas in Communications, special issue on Integrated Sensing and Communication, v. 40, Jul. 2022. [PDF]
    5. Qixun Zhang, Hao Wen, Ying Liu, Shuo Chang, and Zhu Han, “Federated Reinforcement Learning Enabled Joint Communication, Sensing and Computing Resources Allocation in Connected Automated Vehicles Networks," to appear IEEE Internet of Things Journal. [PDF]
    6. H. Li, "Degrees of freedom in scattered fields for trade-off in joint communications and sensing,'' IEEE International Conference on Communications (ICC), 2022. [PDF] 2022.
    7. J. Liu, S. Shao, W. Zhang, and H. V. Poor, "An Indirect Rate-Distortion Characterization for Semantic Sources: General Model and the Case of Gaussian Observation,'' in IEEE Transactions on Communications, 2022. [PDF]
    8. Y. Wang, M. Chen, T. Luo, W. Saad, D. Niyato, H. V. Poor, and S. Cui, "Performance Optimization for Semantic Communications: An Attention-Based Reinforcement Learning Approach,'' in IEEE Journal on Selected Areas in Communications, 2022. [PDF]
    9. H. D. Tuan, A. A. Nasir, H. Q. Ngo, E. Dutkiewicz, and H. V. Poor, "Scalable User Rate and Energy-Efficiency Optimization in Cell-Free Massive MIMO,'' in IEEE Transactions on Communications, 2022. [PDF]
    10. H. Li, "MAC Scheduling in Joint Communications and Sensing Networks Based on Virtual Queues'', IEEE Global Communication Conference (Globecom), 2022. [PDF]
    11. H. Li, "Dual Function Trade-off in Joint Communications and Radar: An Electromagnetic Field Analysis," in IEEE Global Communications Conference (GLOBECOM), 2021. [PDF]
    12. H. Li, "Inseparable Waveform Synthesis in Joint Communications and Radar via Spatial-Frequency Spectrum," in IEEE Global Communications Conference (GLOBECOM), 2021. [PDF]
    13. H. Li, "Dirty Paper Coding for Waveform Synthesis in Integrated Sensing and Communications: A Broadcast Channel Approach," in IEEE International Conference on Communications (ICC), 2022. [PDF]
    14. H. Li, "Dual-Function Multiplexing for Waveform Design in OFDM-Based Joint Communications and Sensing: An Edgeworth Box Framework," in IEEE International Workshop on Signal Processing Advances in Wireless Communication (SPAWC), 2022. [PDF]
    15. H. Li, "Embedded Radar Sensing in Communication Waveforms: Algorithms and Trade-off," in IEEE Wireless Communications and Networking Conference (WCNC), 2022. [PDF]
    16. H. Li, "Frequency Multiplexing and Waveform Synthesis in Joint Communications and Sensing," in IEEE Wireless Communications and Networking Conference (WCNC), 2022. [PDF]
    17. H. Li, "Interferometry Based Radar Imaging by Leveraging Cellular Communication Networks," in IEEE International Workshop on Signal Processing Advances in Wireless Communication (SPAWC), 2022. [PDF]
    18. Husheng Li, Zhu Han, and H. Vincent Poor, “Cellular System based Integrated Sensing and Communications for Wide-area Monitoring”, invited, International Geoscience and Remote Sensing Symposium (IGARSS), Pasadena, CA, July 2023. [PDF]
    19. Haobo Zhang, Hongliang Zhang, Boya Di, Zhu Han, and Lingyang Song, “Holographic Radar: Optimal Beamformer Design for Detection Accuracy Maximization,” IEEE Radar Conference, San Antonio, TX, May 2023. [PDF]
    20. Husheng Li, Zhu Han, and H. Vincent Poor, “A Broadcast Channel Framework for Joint Communications and Sensing Part I: Feasible Region,” IEEE Global Communications Conference (GLOBECOM), Kuala Lumpur, Malaysia, December 2023.
    21. Husheng Li, Zhu Han, and H. Vincent Poor, “A Broadcast Channel Framework for Joint Communications and Sensing Part II: Superposition Coding,” IEEE Global Communications Conference (GLOBECOM), Kuala Lumpur, Malaysia, December 2023.
    22. Eyad Shtaiwi, Hongliang Zhang, Ahmed Abdelhadi, Lee Swindlehurst, Zhu Han, and H. Vincent Poor, “Sum-rate Maximization for RIS-assisted Integrated Sensing and Communication Systems with Manifold Optimization,” to appear IEEE Transaction on Communication.
    23. Haobo Zhang, Hongliang Zhang, Boya Di, Kaigui Bian, Zhu Han, and Lingyang Song, “MetaRadar: Multi-target Detection for Reconfigurable Intelligent Surface Aided Radar Systems,” IEEE Transaction on Wireless Communication, vol. 21, no. 9, pp. 6994 - 7010, September 2022. [PDF]
    24. Hongliang Zhang, Boya Di, Kaigui Bian, Zhu Han, H. Vincent Poor, and Lingyang Song, “Toward Ubiquitous Sensing and Localization With Reconfigurable Intelligent Surfaces,” invited, IEEE Proceeding, special issue on Reconfigurable Intelligent Surfaces, vol. 110, no. 9, pp. 1401 - 1422, September 2022. [PDF]
    25. Haobo Zhang, Hongliang Zhang, Boya Di, Zhu Han, H. Vincent Poor, and Lingyang Song, “Holographic Integrated Sensing and Communication,” IEEE Journal on Selected Areas in Communications, special issue on Integrated Sensing and Communication, vol. 40, no. 7, pp. 2114 - 2130, July 2022. [PDF]
    26. H. Li, “Performance trade-off in inseparable joint communications and sensing: A Pareto analysis,” IEEE International Conference on Communications (ICC), 2022. [PDF]
    27. H. Li, “Joint communications and sensing using millimeter wave networks: A bonus SAR,” IEEE International Conference on Communications (ICC), 2022. [PDF]
    28. H. Li, “Conflict and trade-off of waveform uncertainty in joint communication and sensing systems,” IEEE International Conference on Communications (ICC), 2022. [PDF]
    29. H. Li, “Degrees of freedom in scattered field for trade-off in joint communications and sensing,” IEEE International Conference on Communications (ICC), 2022. [PDF]
    30. H. Li, “Frequency multiplexing and waveform synthesis of dual functions in joint communications and sensing: Exploitation of mutual benefits,” IEEE International Conference on Communications (ICC), 2022. [PDF]
    31. T. N. Guo, H. Li and A. B. MacKenzie, “Efficient and secure spectrum utilization for communication and sensing in UDN by beamspace processing,” IEEE Global Communications Conference (Globecom), 2022. [PDF]
    32. H. Li, “Unified waveform design in joint communications and sensing with clutter: Shannon or Cramer-Rao?” IEEE International Symposium on Joint Communications and Sensing, 2022. [PDF]
    33. H. Li, “Interferometry based radar imaging by leveraging cellular communication networks,” IEEE International Workshop on Signal Processing for Communications, 2022. [PDF]
    34. H. Li, “Turbo Bi-static radar in OTFS based joint communications and sensing,” IEEE International Conference on Communications (ICC), 2023. [PDF]
    35. H. Li, “Waveform synthesis for MIMO joint communications and sensing with clutters: Part I-Space-time-frequency filtering,” IEEE International Conference on Communications (ICC), 2023. [PDF]
    36. H. Li, “Interference mitigation in joint communications and sensing-Part I: Correlation and collision” IEEE International Symposium on Joint Communications and Sensing, 2023. [PDF]
    37. H. Li, “Interference mitigation in joint communications and sensing-Part II: Coding and spreading” IEEE International Symposium on Joint Communications and Sensing, 2023. [PDF]
    38. Y. Fan, J. Bao, K. Wu and H. Li, “Ghost image due to mmWave radar interference: Experiment, mitigation and leverage,” ICC Workshop, 2020. [PDF]
    39. H. Li, “Landscape detection by leveraging millimeter wave communication signals,” IEEE International Conference on Communications, 2019. [PDF]
    40. Y. Fan, J. Bao, M. S. Aljumaily and H. Li, “Communication via frequency-modulated continuous-wave radar in millimeter wave band,” IEEE Global Communications Conference, 2019. [PDF]
    41. Z. Zhang, J. Bao and H. Li, “Wind sensing by millimeter wave communications,” IEEE DySPAN, 2019. [PDF]