@article{1909,
  author = {Ramiro Sámano-Robles1, Atílio Gameiro2, Nuno Pereira1, Eduardo Tovar 1},
  title = {System-Level Simulation and Radio Resource Management for Distributed Antenna Systems with Cognitive Radio and Multi-Cell Cooperation using Imperfect Information},
  journal = {Journal of Electronic Systems},
  year = {2015},
  volume = {5},
  number = {3},
  doi = {},
  url = {http://www.dline.info/jes/fulltext/v5n3/v5n3_2.pdf},
  abstract = {The performance of cellular networks will experience a considerable improvement by the use of newtechnologies
such as distributed antenna systems (DASs), multi-cell cooperation (MCC), and cognitive radio (CR).However, several
issues remain open in the system-level evaluation, radio resource management (RRM), and particularlyin the design of
billing/licensing schemes for these types of system. This paper proposes a system-level simulator(SLS) that will help us
address these issues. An advanced RRM solution is also proposed for a multi-cell DAS in adense urban Manhattan scenario
with two levels of cooperation: inside the cell (intra-cell) to coordinate the transmissionof distributed nodes controlled by
the base station of the cell, and between cells of a cluster (inter-cell) toadapt cell transmissions according to updated intercell
interference measurements. The RRM solution blends networkand financial metrics using the theory of multi-objective
and financial portfolio optimization. In this paper each network/spectrum resource is considered as a financial asset whose
allocation has to be optimized based on economic metrics such as return and risk (i.e., variation of the return). The core of the
intra-cell RRM algorithm is based on an iterative weighted least squares (WLS) optimization scheme where power levels and
beam-forming vectors are jointlydesigned to comply with a target instantaneous SINR (signal-to-interference-plus-noise
ratio) threshold for each transmission.This instantaneous SINR threshold ensures the transmission of the selected modulation
and coding scheme(MCS) with a given value of BLER (block error rate) and spectral efficiency. The WLS scheme allows for
a smoothintegration of scheduling and adaptive modulation and coding (AMC) schemes with the underlying space division
multiplexing(SDM) physical layer. Convergence speed is improved by reusing the outcome of previous WLS iterations.The
weight coefficients of the WLS optimization contain network metrics such as queue length and fairness, as well aseconomic
metrics such as return and risk. This process is complemented with a multi-objective and financial portfoliooptimization
stage for joint spectrum selection and resource (chunk) allocation that attempts to maximize return and minimize risk. Cells
within a cluster exchange the results of their optimization processes for purposes of rejectinginter-cell interference, thereby
achieving MCC. All resource allocation schemes use an imperfect copy of channel and queueing state information, which is
the result of inaccurate measurements, imperfect feedback, or sensing errors.},
}