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<field name="value">2019-02-15</field>
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<field name="value">2019-03-27</field>
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<field name="value">0890-8044</field>
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<field name="value">http://hdl.handle.net/11000/5073</field>
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<field name="value">10.1109/MNET.2019.1800136</field>
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<element name="description">
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<field name="value">5G networks mainly rely on infrastructure‐centric cellular solutions to address data traffic and service demands. Continuously scaling infrastructure‐centric cellular networks is not exempt of challenges, and beyond 5G networks should consider the active coexistence and coordination of infrastructure‐centric and device‐centric wireless networks. Device‐centric wireless networks will build from device‐to‐device communications (D2D) and multi‐hop cellular networks (MCNs). Device‐centric wireless networks can push the limits of Edge 5G networks mainly rely on infrastructure‐centric cellular solutions to address data traffic and service demands. Continuously scaling infrastructure‐centric cellular networks is not exempt of challenges, and beyond 5G networks should consider the active coexistence and coordination of infrastructure‐centric and device‐centric wireless networks. Device‐centric wireless networks will build from device‐to‐device communications (D2D) and multi‐hop cellular networks (MCNs). Device‐centric wireless networks can push the limits of Edge computing and networking to smart devices (including smartphones, vehicles, machines and robots), and exploit their mobile computing, storage and connectivity capabilities. These capabilities can be more efficiently utilized using demand‐driven opportunistic networking that establishes the connections between devices and nodes not just based on their presence, but also on their capacity to support the requested demand and services. This paper presents results from experimental field tests that demonstrate the cellular spectral efficiency gains that can be achieved from the combined use of device‐centric wireless communications and demand‐driven opportunistic networking. The field trials demonstrate that these technologies can improve the cellular spectral efficiency of conventional cellular communications by up to a factor of 4.7 and 12 in outdoor pedestrian and vehicular scenarios, respectively, under the evaluated scenarios and conditions. These gains have been obtained using 4G and IEEE 802.11 technologies. However, the potential of device‐centric wireless networks is not constrained to any particular radio interface. The results presented in this paper provide empirical evidences that further motivate progressing towards a new paradigm where edge networking capabilities are moved to smart mobile devices that become part of the network fabric, and can opportunistically and locally integrate network management functions to ensure that sufficient resources are placed where the demand arises.</field>
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<field name="value">This work has been supported by the Spanish Ministry of Economy, Industry, and Competitiveness, AEI, and FEDER funds (TEC2017‐88612‐R, TEC2014‐57146‐R),</field>
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<field name="value">Generalitat Valenciana (APOSTD/2016/049)</field>
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<element name="es">
<field name="value">eng</field>
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<field name="value">info:eu-repo/semantics/openAccess</field>
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<field name="value">Device‐centric wireless</field>
<field name="value">opportunistic networking</field>
<field name="value">5G and beyond</field>
<field name="value">mobile relays</field>
<field name="value">multi‐hop cellular networks</field>
<field name="value">UE‐to‐Network relays</field>
<field name="value">experimental</field>
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<field name="value">5G</field>
<field name="value">Beyond 5G</field>
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<field name="value">D2D</field>
<field name="value">vehicular</field>
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<field name="value">621 - Ingeniería mecánica en general. Tecnología nuclear. Electrotecnia. Maquinaria</field>
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<field name="value">5G and Beyond: Smart Devices as part of the Network Fabric</field>
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