![]() ![]() Wu Q, Zhang R (2019) Towards smart and reconfigurable environment: intelligent reflecting surface aided wireless network. IEEE Trans Antennas Propagat 11(6):645–651 arXiv preprint arXiv:2007.15221īerry D, Malech R, Kennedy W (1963) The reflectarray antenna. Pham QV, Nguyen DC, Mirjalili S, Hoang DT, Nguyen DN, Pathirana PN, Hwang WJ (2020) Swarm intelligence for next-generation wireless networks: recent advances and applications. In: IEEE global communications conference (GLOBECOM). Xing Y, Rappaport TS (2018) Propagation measurement system and approach at 140 ghz-moving to 6g and above 100 ghz. Khairi MHH, Ariffin SHS, Latiff NMA, Yusof KM, Hassan MK, Al-Dhief FT, Hamdan M, Khan S, Hamzah M (2021) Detection and classification of conflict flows in SDN using machine learning algorithms. EURASIP J Wireless Commun Netw 2019(1):1–20 arXiv preprint arXiv:2002.11040ĭi Renzo M, Debbah M, Phan-Huy D-T, Zappone A, Alouini M-S, Yuen C, Sciancalepore V, Alexandropoulos GC, Hoydis J, Gacanin H et al (2019) Smart radio environments empowered by reconfigurable AI meta-surfaces: an idea whose time has come. Gacanin H, Di Renzo M (2020) Wireless 2.0: towards an intelligent radio environment empowered by reconfigurable meta-surfaces and artificial intelligence. Steder B, Grisetti G, Stachniss C, Burgard W (2008) Visual slam for flying vehicles. Jara AJ, Ladid L, Gómez-Skarmeta AF (2013) The internet of everything through ipv6: an analysis of challenges, solutions and opportunities. IEEE, pp 1–7ĭavid K, Berndt H (2018) 6g vision and requirements: is there any need for beyond 5g? IEEE Vehi Technol Magaz 13(3):72–80 In: IEEE 83rd vehicular technology conference (VTC spring). Haneda K, Zhang J, Tan L, Liu G, Zheng Y, Asplund H, Li J, Wang Y, Steer D, Li C (2016) 5g 3g pp-like channel models for outdoor urban microcellular and macrocellular environments. ![]() IEEE Trans Commun 68(12):7376–7394īariah L, Mohjazi L, Muhaidat S, Sofotasios PC, Kurt GK, Yanikomeroglu H, Dobre OA (2020) A prospective look: key enabling technologies, applications and open research topics in 6g networks. Xu D, Yu X, Sun Y, Ng DWK, Schober R (2020) Resource allocation for IRS-assisted full-duplex cognitive radio systems. Wu Q, Zhang R (2019) Intelligent reflecting surface enhanced wireless network via joint active and passive beamforming. Prasad KSV, Hossain E, Bhargava VK (2017) Energy efficiency in massive MIMO-based 5g networks: opportunities and challenges. Liu C, Natarajan B, Xia H (2015) Small cell base station sleep strategies for energy efficiency. IEEE Trans Wireless Commun 16(3):1834–1850Ĭhen S, Hu J, Shi Y, Peng Y, Fang J, Zhao R, Zhao L (2017) Vehicle-to-everything (v2x) services supported by LTE-based systems and 5g. Ngo HQ, Ashikhmin A, Yang H, Larsson EG, Marzetta TL (2017) Cell-free massive MIMO versus small cells. arXiv preprint arXiv:1902.06700ĭaniel IS (2017) Apparatus, system and method for holographic video conferencing. Tariq F, Khandaker M, Wong KK, Imran M, Bennis M, Debbah M (2019) A speculative study on 6g. GT 38.913 (2017) Technical specification group radio access network study on scenarios and requirements for next generation access technologies The experimental results show that received power can be enhanced by 9%. This paper investigates the impacts of using multiple IRS modules on the received power in an non-line-of-sight outdoor wireless environment considering. Intelligent reflective surfaces (IRSs) are thin and low-cost sheets yet very effective elements consisting of mini passive elements that can either manually be programmed or independently using artificial intelligence (AI) to alter the phase shifts of the impinging signals and proactively control the propagation channel. holographic communication, everything-to-everything (E2E). It is therefore evident that these key technologies alone would not be sufficient to enable intelligent wireless platforms for the next generation communication, i.e. This is because equipments bear zero knowledge on both channel status and its effects on the propagating signals. Despite the significant quality of service (QoS) enhancements these technologies brought, the propagation channel challenge remains unsolvable. The use of small cells, millimetre waves (mmWaves), and ultra-massive multiple-input-multiple-output (MIMO) systems have reshaped the future of wireless communication and showcased fifth generation (5G) to become the most promising communication system. ![]()
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