• DocumentCode
    1410582
  • Title

    Rate Scaling Laws in Multicell Networks Under Distributed Power Control and User Scheduling

  • Author

    Gesbert, David ; Kountouris, Marios

  • Author_Institution
    Mobile Commun. Dept., EURECOM, Sophia Antipolis, France
  • Volume
    57
  • Issue
    1
  • fYear
    2011
  • Firstpage
    234
  • Lastpage
    244
  • Abstract
    We analyze the sum rate performance in multicell single-hop networks where access points are allowed to cooperate in terms of a joint resource allocation. The resource allocation policies considered here combine power control and user scheduling. Although promising from a conceptual point of view, the optimization of the sum of per-link rates hinges on tough issues such as computational complexity and the requirement for heavy receiver-to-transmitter and cell-to-cell channel information feedback. In this paper, however, we show that simple distributed algorithms can scale optimally in terms of rates, when the number of users per cell U is allowed to grow large. We use extreme value theory to provide scaling laws for upper and lower bounds for the network sum-rate (sum of single user rates over all cells), corresponding to zero-interference and worst-case interference scenarios. We show that the scaling is either dominated by path loss statistics or by small-scale fading, depending on the regime and user location scenario. A surprising result is that the well known log log U rate behavior exhibited in i.i.d. fading channels with maximum rate schedulers is transformed into a log U behavior when path loss is accounted for. Additionally, by showing that upper and lower rate bounds behave in fact identically, asymptotically, our results suggest, remarkably, that the impact of multicell interference on the rate (in terms of scaling) actually vanishes asymptotically, when appropriate resource allocation policies are used.
  • Keywords
    cellular radio; computational complexity; fading channels; power control; resource allocation; scheduling; access points; cell-to-cell channel information feedback; computational complexity; distributed algorithm; distributed power control; extreme value theory; fading channels; joint resource allocation; lower bounds; maximum rate scheduler; multicell networks; multicell single-hop networks; network sum-rate; path loss statistics; rate scaling laws; receiver-to-transmitter channel information feedback; resource allocation policies; small-scale fading; sum rate performance; upper bounds; user scheduling; worst-case interference; zero-interference; Encoding; Fading; Interference; Joints; Power control; Resource management; Signal to noise ratio; Cellular networks; cooperation; coordination; distributed; extreme value theory; interference; scheduling; sum rate scaling;
  • fLanguage
    English
  • Journal_Title
    Information Theory, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9448
  • Type

    jour

  • DOI
    10.1109/TIT.2010.2090195
  • Filename
    5673800