• DocumentCode
    1796462
  • Title

    Trillions of nodes for 5G!?

  • Author

    Chih-Lin, I. ; Shuangfeng Han ; Yami Chen ; Gang Li

  • Author_Institution
    Green Commun. Res. Center, China Mobile Res. Inst., Beijing, China
  • fYear
    2014
  • fDate
    13-15 Oct. 2014
  • Firstpage
    246
  • Lastpage
    250
  • Abstract
    With the rapid development of internet of things (IoT) with various low-cost machine type communications (MTC) devices, intelligent wearable devices, vehicular sensors and environmental sensors etc, it´s anticipated that trillions of wireless nodes in IoT with diversified applications and services may come to life in the fifth generation wireless communication system (5G). These devices, however, may not be handled efficiently by the current wireless communication networks, which were not designed for frequent small data packets and simultaneous massive accesses. In this paper, a novel aggregator based MTC communication architecture is proposed, where the aggregators function as MTC gateways towards the cellular network, combining connections of masive devices into single connection. Correspondingly, based on the aggregated packet characteristics and data relay modes, the aggregators will request for aggregator specific radio resource control (RRC) mechanism. Simply put, always available connectivity is desired for contiguous packets with low latency, while coordinated transmission among multiple aggregators are preferred for packets with larger delay tolerance. Through various analysis and numerical results, MTC communication with aggregators are expected to bring much improved signaling efficiency, thus handling the gigantic pressure on 5G network design from the potential trillions of MTC devices.
  • Keywords
    5G mobile communication; 5G network design; Internet of Things; MTC gateways; RRC mechanism; cellular network; fifth generation wireless communication system; machine type communications devices; novel aggregator based MTC communication architecture; radio resource control mechanism; Frequency division multiaccess; Mobile communication; Mobile computing; Relays; Sensors; Wireless communication; Wireless sensor networks; Machine type communications; data to signaling ratio; radio resource control; service aggregation; signaling reduction;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Communications in China (ICCC), 2014 IEEE/CIC International Conference on
  • Conference_Location
    Shanghai
  • Type

    conf

  • DOI
    10.1109/ICCChina.2014.7008280
  • Filename
    7008280