The Internet of Things How the Next Evolution of the Internet The Internet of Things How the Next Evolution of the Internet Is Changing Everything, 2011. ,
, 5G Backhaul Challenges and Emerging Research Directions : A Survey, vol.4, pp.1743-1766, 2016.
, Framework and overall objectives of the future development of IMT for 2020 and beyond, 2015.
The first 5G system PoC in conjunction with the PyeongChang winter Olympics, 2018. ,
L'UIT dévoile IMT-2020, le petit nom normatif de la 5G ,
5G Wireless Network Slicing for eMBB , URLLC , and mMTC : A Communication-Theoretic View, 2016. ,
5G systems: 5G for humans and machines: use cases and requirements, White Pap, vol.284, pp.3-5, 2017. ,
Scenarios , requirements and KPIs for 5G mobile and wireless system Scenarios , requirements and KPIs for 5G mobile and wireless system, 2013. ,
, , 2015.
5G Vision , Requirements , and Enabling Technologies, Deliverable, vol.2, issue.0, pp.10-14, 2016. ,
What Will 5G Be ?, vol.32, pp.1065-1082, 2014. ,
Massive MIMO for Next Generation Wireless Systems, IEEE Commun. Mag, vol.52, issue.2, pp.186-195, 2014. ,
Coordinated Multipoint Transmission and Reception in LTE-Advanced : Deployment Scenarios and Operational Challenges, IEEE Commun. Mag, vol.50, issue.12, pp.148-55, 2012. ,
Deep Learning for Massive MIMO CSI Feedback, IEEE Wirel. Commun. Lett, vol.7, issue.5, pp.748-75, 2018. ,
What Is Massive MIMO Technology? ,
Scaling Up MIMO: Opportunities and Challenges with Very Large Arrays, IEEE Signal Processing Magazine, vol.30, issue.1, pp.40-60, 2012. ,
Energy and Spectral Efficiency of Very Large Multiuser MIMO Systems, IEEE Trans. Commun, vol.61, issue.4, pp.1436-1449, 2013. ,
Effect of element mutual coupling on the capacity of fixed length linear arrays, IEEE Antennas Wirel. Propag. Lett, vol.1, pp.157-160, 2002. ,
Full-duplex wireless communications using off-the-shelf radios: Feasibility and first results, Conf. Rec. -Asilomar Conf. Signals, Syst. Comput, pp.1558-1562, 2010. ,
Practical, real-time, full duplex wireless, Proc. 17th Annu. Int. Conf. Mob. Comput. Netw. -MobiCom '11, p.301, 2011. ,
The Evolution Path of 4G Networks : FDD or TDD ?, IEEE Commun. Mag, vol.44, issue.12, pp.42-50, 2006. ,
Applications of self-interference cancellation in 5G and beyond, IEEE Communications Magazine, vol.52, issue.2, pp.114-121, 2014. ,
Inband full-duplex wireless: Challenges and opportunities, IEEE J. Sel. Areas Commun, vol.32, issue.9, pp.1637-1652, 2014. ,
A Survey of In-Band Full-Duplex Transmission: From the Perspective of PHY and MAC Layers, IEEE Commun. Surv. Tutorials, vol.17, issue.4, pp.2017-2046, 2015. ,
In-band full-duplex transceiver technology for 5G mobile networks, Eur. Solid-State Circuits Conf, pp.84-87, 2015. ,
Full duplex radios, Proc. ACM SIGCOMM 2013 Conf. SIGCOMM -SIGCOMM '13, p.375, 2013. ,
The Case for Antenna Cancellation for Scalable Full-Duplex Wireless Communications, Hotnets, pp.0-5, 2011. ,
Single antenna full duplex communications using a common carrier, 2012 IEEE 13th Annu. Wirel. Microw. Technol. Conf. WAMICON 2012, 2012. ,
Simultaneous Transmission and Reception for Improvedwireless Network Performance, Stat. Signal Process, pp.478-482, 2007. ,
Full duplex MIMO radios, Proc. 11th USENIX Syposium Networked Syst. Des. Implement, pp.359-372, 2014. ,
Can full duplex reduce the discovery time in D2D communication?, Proc. Int. Symp. Wirel. Commun. Syst, pp.27-31, 2016. ,
DOCOMO 5G White Paper Requirements , Concept and Technologies, 2014. ,
Millimeter Wave Mobile Communications for 5G Cellular : It Will Work !, IEEE Access, vol.1, pp.335-349, 2013. ,
, Telecommunications Network and Service Architectures Principles , Concepts and Architectures 2 Global System for Mobile Communications ( GSM ), 2010.
Enhanced intercell interference coordination challenges in heterogeneous networks, IEEE Wirel. Commun, vol.18, issue.3, pp.22-30, 2011. ,
LTE Technology Introduction White Paper, 2009. ,
5G Ultra-Dense Cellular Networks, IEEE Wireless Communications, vol.23, issue.1, pp.72-79, 2016. ,
Fronthauling for 5G LTE-U Ultra Dense Cloud Small Cell Networks, IEEE Commun. Mag, vol.23, issue.6, pp.48-53, 2016. ,
Ultra-dense networks in millimeter-wave frequencies, IEEE Commun. Mag, vol.53, issue.1, pp.202-208, 2015. ,
QuickC : Practical sub-millisecond transport for small cells, Proc. 22nd Annu. Int. Conf. Mob. Comput. Netw, pp.109-121, 2016. ,
, The 4G and 5G Spectrum Guide, pp.13-55, 2017.
, International Telecommunications Union-T K-series Recommendations, 2017.
History of millimeter and submillimeter waves, IEEE Trans. Microw. Theory Tech, vol.32, issue.9, pp.1118-1127, 1984. ,
Understanding Millimeter Wave Wireless Communication, Loea Corp, 2008. ,
Edge Computing Meets Millimeter-wave Enabled VR : Paving the Way to Cutting the Cord, Proc. IEEE WCNC, pp.3-8, 2018. ,
Simple Transmission Formula *, Proc. I.R.E. Waves Electrons, vol.34, issue.5, pp.254-256, 1946. ,
, Line-by-line calculation of gaseous attenuation Specific attenuation, 1997.
,
5G Channel Models in mm-Wave Frequency Bands, Proc. Eur. Wireless Conf. (EW), 2016. ,
Interference Study of Micro Licensing for 5G Micro Operator Small Cell Deployments, Proc. Int. Conf. Cogn. Radio Oriented Wirel. Networks, 2017. ,
Array and Phased Array Antenna Basics, 2005. ,
MiniTerminal -a small antenna for satellite reception, INICA 2007 2nd Int. ITG Conf. Antennas, 2017. ,
Fundamentals of 5G Mobile networks, 2015. ,
Antenna Theory: Analysis and Design, 2005. ,
, Conformal array antenna theory and design, 2006.
Basic Array Theory, Proc. IEEE, vol.80, pp.127-140, 1992. ,
Dynamic two-stage beam training for energy-efficient millimeter-wave 5G cellular systems, pp.111-122, 2015. ,
Spatial channels for communicating with waves between volumes, Opt. Lett, vol.23, issue.21, pp.1645-1647, 1998. ,
Communicating with waves between volumes: evaluating orthogonal spatial channels and limits on coupling strengths, Appl. Opt, vol.39, issue.11, pp.1681-1699, 2000. ,
Wide-angle scanning phased array with pattern reconfigurable elements, IEEE Trans. Antennas Propag, vol.59, issue.11, pp.4071-4076, 2011. ,
An Electronically Controlled 8-Element Switched Beam Planar Array, vol.1225, pp.8-11, 2015. ,
A Recon fi gurable Microstrip Antenna With Radiation Pattern Selectivity and Polarization Diversity, vol.11, pp.453-456, 2012. ,
Swith beam dielectric resonator antenna array with four reconfigurable radiation patterns, Indian J. Sci. Technol, vol.6, issue.1, pp.3872-3875 ,
Beam Switching Dual Polarized Antenna Array with Reconfigurable Radial Waveguide Power Dividers, IEEE Trans. Antennas Propag, vol.65, issue.4, pp.1807-1814, 2017. ,
Electromagnetic wave lens and mirror systems, 1961. ,
Beam-scanning improvement of reflectarrays using single-layered sub-wavelength elements, Proc. 2015 IEEE 5th Asia-Pacific Conf. Synth. Aperture Radar, APSAR 2015, vol.51, pp.131-134, 2015. ,
A low-cost 60-GHz switched-beam patch antenna array with butler matrix network, IEEE Antennas Wirel. Propag. Lett, vol.7, pp.432-435, 2008. ,
A Compact 38 GHz Multibeam Antenna Array with Multifolded Butler Matrix for 5G Applications, IEEE Antennas Wirel. Propag. Lett, vol.16, issue.c, pp.2996-2999, 2017. ,
Wide-Angle Microwave Lens for Line Source Applications*, 1963. ,
Substrate integrated waveguide (SIW) Rotman lens and its Ka-band multibeam array antenna applications, IEEE Trans. Antennas Propag, vol.56, issue.8, pp.2504-2513, 2008. ,
A Novel Electronically Wideband Steering System using Rotman Lens for 5G Applications at 28 GHz, vol.4, pp.2-6, 2018. ,
A Novel Wide-Angle Scanning Phased Array Based on Dual-Mode Pattern-Reconfigurable Elements, IEEE Antennas Wirel. Propag. Lett, vol.16, issue.c, pp.396-399, 2017. ,
Dual-band wide-angle scanning planar phased array in X/Ku-Bands, IEEE Trans. Antennas Propag, vol.62, issue.5, pp.2514-2521, 2014. ,
,
, ANSYS Electronics Desktop: Electromagnetic Analysis
Adaptive Antenna Array Beamforming and Power Management With Antenna Element Selection, 2016. ,
Microstrip Antenna Aperture-Coupled To a Microstripline, Electron. Lett, vol.21, issue.2, pp.49-50, 1895. ,
Aperture-Coupled Microstrip Patch Antenna Array, 1996. ,
Exploitation of Dual-polarization Diversity for 5G Millimeter-Wave MIMO Beamforming Systems, IEEE Trans. Antennas Propag, vol.65, issue.12, pp.6646-6655, 2017. ,
Wireless beam of short electric waves, J. Inst. Elec. Eng, vol.472, issue.452, pp.1209-1219, 1927. ,
Beam transmission of ultra short waves, Proc. IRE, vol.16, pp.715-741, 1928. ,
, b les faisceaux pointent bien dans l'axe z avec un niveau de polarisation principale égal à 15,2dBi grâce à l'effet constructif des différents ports d'excitation. Le niveau de la polarisation croisée est en dessous de 0dBi dans les deux plans. Grâce à cette forte directivité, ce réseau d'antennes offre une faible ouverture à mi-puissance de 21° entre -11° et 10° dans chaque plan orthogonal. Lorsque le port d'excitation P5 est actif et les autres chargés à 50 ?, les quatre éléments rayonnants sont excités formant ainsi un réseau linéaire, p.0
, Le niveau de polarisation principale est égal à 13,2dBi et celui de la polarisation croisée le plus élevé vaut -3dBi. Cette différence de niveau entre les deux polarisations principales entre les ports P5 et P7 est due certainement à cette longueur de 180° entre les deux ports. Dans le plan phi=90°, le diagramme de rayonnent est directif dans la direction ?=25° si le port 6 est excité (Figure 4.39.b) ou dans la direction ?=-25° si le port 8 est actif (Figure 4.40.b). Les mêmes couvertures obtenues dans le plan (xoy) pour les ports 5 et 7 on était retrouvées dans le plan (yoz) lorsqu'uniquement le port 6 ou le port 8 est activé. Dans cette structure, la combinaison des six faisceaux permet d'obtenir une couverture à mi-puissance de 110° dans chaque plan orthogonal
, Liste des publications
A reconfigurable beam dual polarized microstrip cross patch antenna, Proceedings of the 11th European Conference on Antennas and Propagation (EuCAP) 2017 ,
Antenne à double polarisation et diagramme reconfigurable destinée aux « smallcells » pour la 5G, 20 Journées Nationales Microondes, 2017. ,
Aboubaker Chedikh Beye "A Novel Bow-Tie Antenna with Triple Band-Notched Characteristics for UWB Applications, Journal of Electromagnetic Analysis and Applications, vol.8, pp.271-282, 2016. ,
Sous-réseau d'antennes adaptatif destiné aux réseaux 'small cells' pour la 5G" Assemblée générale GDR ONDES "Interférences d'Ondes, 2017. ,
Design of an Adaptive Subarray Antenna for Multi-Beams Wireless Small Cell Backhaul in mmWave, 2018. ,
Efficient Dual-Band PIFA Antenna for the Internet of Things (IoT), Conference on antenna measurement and applications (CAMA2018) ,
URL : https://hal.archives-ouvertes.fr/hal-01825723
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Dual-band pattern reconfigurable 5G antenna using dual-band blc, 2018. ,