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50 users per cell (NU=600) NT=6

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Mitigating inter-cell interference (ICI) in multi-cell downlink ... c4. 1) 'A' subset sends pilots and gets CQI from users 'B' and 'C' cell users sense pilots ' ... – PowerPoint PPT presentation

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Title: 50 users per cell (NU=600) NT=6


1
Multi-Cell User Scheduling and Random Beamforming
Strategies for Downlink Wireless Communications
Xiaojun Tang, Sean A. Ramprashad, and Haralabos
Papadopoulos
DOCOMO USA LABS
Background and Motivation
A-B-C Scheme Animated
Overview of Schemes
Results
  • Simulation Layout
  • 12 cells separated by 1 unit on a topology
    wrapped to form a flat 2D torus.
  • All cells are equivalent on such a torus.
  • Mitigating inter-cell interference (ICI) in
    multi-cell downlink is critical to increasing
    throughputs in wireless systems.
  • It is a topic of much interest in research and in
    standards, e.g. in Coordinated Multi-Point (CoMP)
    in LTE/LTE-A.
  • Strategies for SISO include frequency-reuse and
    power control.
  • MIMO provides a new dimension of space.
  • One can leverage space by joint MIMO processing
    across multiple base stations (BS), e.g. by
    Network-MIMO
  • Can remove inter-cell interference within
    clusters of cells.
  • However, it can require a high degree of
    coordination, e.g.
  • Full channel state information (FCSI) feedback,
  • Full data sharing/signaling within clusters of
    cells.

Schemes Interference Management Mechanism
Fully Independent Scheduling No interference management
TDM Scheme Avoid strong interference by dividing transmission resources
Multi-Cell SINR Feedback Mitigating interference via user selection with multiple beam options and pilot sensing across cells
A-B-C Scheme Mitigating interference via joint user selection and joint beam coordination across cells with limited direct information exchange
  • 0) Assign cells to an A, B or C subset
  • Cells in each subset act independently and are
    separated geographically.
  • Shuffle 1

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  • System uses frequency reuse factor 1. This is
    not a frequency reuse pattern.

1) Baseline/Independent Schemes
  • Fully Independent System
  • Cell operate as isolated cells with frequency
    reuse 1.
  • There is no exchange or use of inter-cell
    information.
  • TDM/FDM System
  • Like fully independent but with frequency reuse
    3.
  • 1) A subset sends pilots and gets CQI from
    users
  • B and C cell users sense pilots
  • A users and beams are scheduled
  • 2) B subset sends pilots and gets CQI from
    users
  • Get FCSI or CQI from scheduled A users
  • B users and beams are scheduled
  • Per-User Throughput (Empirical CDF)

Goal
  • NT 6, 50 users per cell, 1 beam/cell,
  • The TDM scheme performs the worst due to loss of
    degrees of freedom.
  • Also the scheduler does not know ICI.
  • The Fully independent scheduling scheme
    increases per-user throughput despite no
    interference management.
  • Also the scheduler does not know ICI.
  • The Multi-cell SINR feedback scheme performs
    well for users relatively close to BSs.
  • The ABC scheme performs the best, especially for
    edge users.
  • Beam coordination benefits edge users greatly.
  • We would like to consider strictly cellular
    transmission that
  • Aligns interference across cells by exploiting
    the spatial dimension without joint-cell
    transmission.
  • Requires minimal intra/inter-cell information
    exchange.

2) SINR Scheme
users sending feedback
SINR Joint Multi-Cell User Scheduling by
Sensing Pilots
illustration of beam pilot
1) Each BS selects m beams for its cell randomly
and independently, and sends pilots.
2) Each user estimates beam CQIs, selects a beam
from its BS, sends the selection and SINR to
its BS .
3) Each BS selects its user based on rate and
beam requests and transmits.
System Model
Fig 4.
  • Consider a multi-cell downlink system consisting
    of
  • NB base stations (BSs), each with NT transmit
    antennas.
  • Each user is served by one (and only one) BS.
  • Per-Cell Throughput
  • 3) C subset sends pilots and gets CQI from
    users
  • Get FCSI or CQI from sched. AB users
  • C users and beams are scheduled
  • 4) All cells transmit at same time with frequency
    reuse 1
  • A cell users tend to get higher rates than B and
    C cell users, and so on...
  • Fig. 1 The received signal of user k (in cell
    0) at time t is
  • hk,i is FCSI from BS i to user k
  • xi is the transmission from BS i.
  • The FCSI accounts for path loss, shadowing and
    block Rayleigh fading.

illustration of data transmission
illustration of beam pilot
illustration of data transmission
users sending feedback
Fig 6.
Fig 5.
50 users per cell (NU600)

NT6

3) A-B-C Multi-Step Scheme
Observations
  • 5) Shuffle A, B or C subset
  • Then go to Step 1 with new assignment.
  • Shuffle 2
  • Shuffle 3
  • Cell Partitioning
  • Cells are partitioned into A, B and C
    subsets
  • Frequency reuse 1 is used.
  • Multi-stage scheduling
  • Limited Inter-Cell Beam Coordination
  • Cells operate with CQI feedback with following
    additions
  • B cells get FCSI or CQI from scheduled A cell
    users.
  • B cells select beams to limit ICI to A cells
  • C cells get FCSI or CQI from scheduled A
    B users.
  • C cells select beams to limit ICI to B and
    C cells
  • A/B/C assignments are shuffled to preserve
    fairness.
  • Increasing the number of beams per cell
    increases intra-cell interference,
  • Can hurt schemes without any interference-avoidanc
    e mechanism.
  • Increasing NU benefits the SINR and ABC schemes
    via user-selection
  • Typical of opportunistic beamforming, but SINR
    has limits vs NT.
  • The ABC scheme, with beam coordination, does
    leverage increased NT .
  • Linear Opportunistic (Random) Beamforming
  • mi data streams sj,i j 1,,mi are multiplexed
    at BS i
  • where qj,i is the (random) beam vector
    assigned to stream sj,i .
  • sj,i is given power 1/mi,
  • The Signal to Noise and Interference Ratio (SINR)
    for user k using beam j from BS 0
  • Achievable rate
  • Opportunistic beamforming requires limited
    feedback
  • No FCSI is needed, only channel quality
    information (CQI) in the scalar forms of
    .
  • Multi-user Proportional Fair Scheduling (MPFS)

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Summary
  • Considered limited coordination (CQI only or
    limited FCSI) random beamforming strategies for
    multi-cell downlink.
  • Opportunistic beamforming does have limits in
    leveraging the spatial dimension for managing
    inter-cell interference
  • Changing NT, without increasing pool of beams and
    using joint beam selection, has little affect on
    ICIs (Fig. 5)
  • To leverage the spatial dimension, some joint
    inter-cell beam selection is required as in A-B-C
    scheme
  • We considered a joint beam scheme which requires
    some limited exchange A cells?B,C cells A,B
    cells ?C cells.
  • CQI could be used in place of Full CSI in the
    A-B-C scheme.
  • Requires larger beam pools and possibly more
    pilots.

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