Interference Mitigation using Conjugate Data Repetition for Cell Edge Users Document Number: IEEE C80216m-09_0020 Date Submitted: Source: Kiran Kuchi, J. Klutto Milleth, Vinod R, Dileep M K, Divagar, Padmanabhan M S, Bhaskar R, Giridhar KVoice: CEWiT, Venue: San Diego, USA. In response to the TGm Call for Contributions and Comments IEEE m-08/052 for Session 59 Topic TGm SDD - section 20 (Interference Mitigation) Base Contribution: IEEE C80216m-09_0020 Purpose: Presentation associated with comment tgmsdd_Kuchi_Kiran.cmtb associated with section 20 in SDD To discuss in TGm for appropriate action. Notice: This document does not represent the agreed views of the IEEE Working Group or any of its subgroups. It represents only the views of the participants listed in the “Source(s)” field above. It is offered as a basis for discussion. It is not binding on the contributor(s), who reserve(s) the right to add, amend or withdraw material contained herein. Release: The contributor grants a free, irrevocable license to the IEEE to incorporate material contained in this contribution, and any modifications thereof, in the creation of an IEEE Standards publication; to copyright in the IEEE’s name any IEEE Standards publication even though it may include portions of this contribution; and at the IEEE’s sole discretion to permit others to reproduce in whole or in part the resulting IEEE Standards publication. The contributor also acknowledges and accepts that this contribution may be made public by IEEE Patent Policy: The contributor is familiar with the IEEE-SA Patent Policy and Procedures: and. Further information is located at and.
Presentation Outline Motivation Conjugate Data Repetition (CDR) – Improving cell edge performance For both data and common control channels Conclusions Proposed SDD Text 3/20/20162
Motivation Limited Spectrum – Frequency reuse-1 is the most likely deployment mode – Typical urban cell size has m radius – Interference limited in both uplink and downlink – Very low cell edge data rates Provide uniform data rates throughout the cell Improve control channel coverage High Spectrum Efficiency 3/20/20163
Interference Mitigation Poor cell edge SINR in reuse-1 networks – Severe co-channel interference (CCI) – Multiple CCI up to 4-dominant interferers – Typically cell edge SINR is in the [-6 0] dB range – Nearly 30% of users in the sector are cell edge users Re-use 1:3 is spectrally inefficient Gain of soft re-use is not adequate for cell-edge users 3/20/20164
Interference Suppression in Legacy WiMax Systems 2-antenna MMSE receiver nulls a single interferer Pre-whitened MLD can suppress two interferers Use single stream transmission i.e., POD/CL-div However, cell edge users typically have 3-4 dominant interferers Existing solutions – For low SINR cell edge users – Rate ½ QPSK and bit-level data repetition up to 6-times Bit level data repetition is spectrally inefficient 3/20/20165CEWiT Confidential Information
Conjugate Data Repetition (CDR) Signal repetition in time/frequency Conjugate symbol repetition across adjacent subcarriers or adjacent OFDM symbols All cells synchronously transmit data in conjugate symbol pairs for select users – The network assigns a CDR frequency partition in which the RBs from different BSs overlap BS co-ordination not required MMSE filtering of complex, and complex-conjugate signals provides a high IC gain MMSE IC for each RB independently BS-1BS-2 F1Y1 F2Y1* F3Y2 F4Y2* F5P2 F6Y3 F7Y3* F8Y4 F9Y4* F1X1 F2X1* F3X2 F4X2* F5P1 F6X3 F7X3* F8X4 F9X4* 3/20/20166
Conjugate Data Repetition Basic Idea – Each BS transmits data in conjugate symbol pairs on a pair of subcarriers – 1 st BS transmits – 2 nd BS transmits – Complex-conjugation on – After complex de-conjugation, the receiver has two copies of signal and interference with different channel states Signal Interference – Receiver jointly filters – Receiver doesnot estimate interference channel. MMSE needs interference covariance only 3/20/20167
CDR-MMSE Receiver CDR signal model CDR-MMSE filtering, In Rayleigh fading channels, conjugation ensures that, the signal and interference channel vectors are linearly independent with probability 1 Linear independence ensures that MMSE provides full IC up to 2N-1 interferers MMSE filter is applied to each RB independently – High IC gain for each RB 3/20/20168
CDR Frequency Partition 3/20/20169 CDR Partition Sector 1 Sector 2 Sector 3 Low SINR usersHigh SINR users 1.The CDR region is dedicated for cell edge users 2.CDR implementation In a frequency reuse-1 system, the SINR of all the users in a cell are ranked in descending order All cells in the network synchronously allocate the bottom x% users to a CDR frequency partition which is fixed for the entire network 3.The system can also employ CDR, FFR, and Reuse-1 in multiple disjoint frequency partitions 4.CDR can be implemented using the existing FFR framework 5. Operator can define a CDR frequency partition
Proposed Downlink CDR RB Structure 3/20/ Transmission format with CDR in 18 X 6 resource block Same pilot pattern for 2 and 4-Tx antennas Pilot-on-Pilot mode OL transmit diversity: Phase-Offset-Diversity (a.k.a rank1- precoding) CL transmit diversity: single stream MIMO PPDDPP DDD* DD DD DD DD DD PP PP DDDDDD DDDDDD DDDDDD PPDDPP DD DD DD DD DD DD PP PP
CDR-MMSE Pilot Processing Use BPSK pilots and preferably pilot-on-pilot mode. – Step 1: Collect complex, and complex conjugate copies of the received pilots – Step 2: Estimate channel coefficients of desired signal using 2D-MMSE Assume uniform power-delay-profile Knowledge of interferer pilot sequences improves 2D-MMSE – Step 3: Subtract signal contribution from the received samples – Step 4: Estimate noise-plus-interference covariance matrix Each RB can be processed independently to obtain high IC gain 3/20/201611
Conjugate Data Repetition With N rx antennas, CDR provides 2N observations – CDR doubles the number of copies of signal Full interference suppression up to 2N-1 interferers Typically 3-4 dominant interferers in re-use 1:1 systems – Use POD, CDR, MMSE for cell edge users With 2-receiver antennas CDR-MMSE nulls 3-interferers CDR does not require active cooperation between BSs CDR does not require channel estimates of interferers 3/20/201612
Conjugate Data Repetition Contd. In 16m DL, basic unit for transmission is 1 RB In the CDR region – Data is repeated in conjugate pairs in each RB – CDR RBs can be allocated in localized, block distributed or tone-wise distributed modes – Different sectors can use different permutations – CDR receiver processes each RB independently 3/20/201613
Conjugate Data Repetition Contd. Compatibility with other cell edge features – Works with CL-diversity – Best band scheduling feasible – Restrict MIMO modes to Rank-1 pre-coding (2D-POD) and CL-beam forming 3/20/201614
CDR Requirements Define a CDR resource block structure Pilot support – 16 pilots per RB – Pilot-on-Pilot MIMO support – OL Rank-1 precoding – CL-diversity CDR can be implemented using the FFR framework – The operator can define a CDR frequency partition 3/20/201615
CDR Implementation Define a CDR frequency partition Allocate common control channels in CDR partition Allocate low SINR cell edge users in the remaining CDR partition CDR frequency partition size can be decided by the operator based on QOS requirements 3/20/201616
Conclusions Due to limited spectrum, frequency re-use 1:1 is the expected deployment mode in India Very important to improve cell edge performance CDR and rank-1 transmission (POD/CL-div) ensures high cell edge performance CDR and FFR complement each other CDR can be implemented along with FFR in a frequency partition High cell edge throughput Reliable control channel decoding Use CDR for both common control channel and cell edge data users Define a CDR RB structure 3/20/201617
Proposed SDD Text Add section Interference mitigation using conjugate data repetition (CDR) – Interference mitigation using conjugate data repetition (CDR) will be supported for cell edge users for data and/or control channels. CDR includes simple repetition of modulated data. 3/20/201618