1. 802.16m Downlink Interlaced Pilots Link Level Simulation Results
Document Number: IEEE C80216m-09_0026
Date Submitted:
Source: Furuzan Atay, Huaning Niu, Jong-Kae (JK) Fwu, Yuval Lomnitz, Jiacheng Wang, Hujun Yin, Sassan Ahmadi
Venue:
IEEE Session #59, San Diego.
Base Contributions: N/A
Re: m-08/052, Call for Comments on m SDD (802.16m-08/003r6), Section Pilot Structure
Purpose: For TGm discussion and adoption of m SDD text
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2. Outline
Part I: Simulation results for spectral efficiency of interlaced pilot versus non-interlaced pilots without Interference Cancellation
Part II: Simulation results for spectral efficiency of interlaced pilot versus non-interlaced pilots with Interference Cancellation
Part III: Additional results for PER of interlaced pilot versus non-interlaced pilots with Interference Cancellation

3. Part I: Interlace Pilot Gain –
Without Interference Cancellation

4. Simulation Parameters
INR = 10 dB, 2 interferers (1:1), full/half loading
2-D MMSE channel estimation
Pilot pattern based on current SDD text
Channel – Ped-B 3km/h
Pilot boosting scenarios for interlaced pilot:
7/5 dB for SM2
5/3 dB for SIMO 1x2

5. 2x2 SM, No IC, Full Loading, SE
Interlaced 5dB boosting has the best performance
Need 3dB boosting SM for non-interlaced

6. 2x2 SM, No IC, Half Loading, SE
Interlaced pilot enjoys larger gain at partial loading

7. 2x2 SFBC, No IC, Full Loading, SE

8. 2x2 SFBC, No IC, Half Loading, SE

9. 1x2 SIMO, No IC, Full Loading, SE

10. 1x2 SIMO, No IC, Half Loading, SE

11. Conclusion
Interlace pilot enjoys better SE than non-interlaced pilot particularly at low SINR
Interlace gain in partial loading case is significant
Suggested boosting value:
5dB boosting value for 2 SM (net 2dB boosting combining two streams)
3dB for 1 stream

12. Part II: Interlace Pilot Gain –
With Interference Cancellation

13. Interference Scenario
Two interfering basestations, BS2 and BS3
Noise + interference is to be pre-whitened based on estimated covariance of Interference + Noise
Covariance matrix is estimated using pilots (6 pilots per Tx antenna) within one PRU

14. Interference Cancellation (IC) Description
For each subcarrier j,
Filter the signal with before MMSE demodulation
is the channel estimation error for subcarrier j
Interference Cancellation : First estimate pilot channel H1 and then calculate

15. Simulation Parameters
INR = 10 dB, 2 interferers (1:1), full/half loading
2-D MMSE channel estimation
Pilot pattern based on current SDD text
Channel – Ped-B 3km/h
Pilot boost:
5 dB for SM2 and SFBC
3dB for SIMO 1x2

16. 2x2 SM, With IC, Full Loading, SE

17. 2x2 SM, With IC, Half Loading, SE

18. 2x2 SFBC, With IC, Full Loading, SE

19. 2x2 SFBC, With IC, Half Loading, SE

20. 1x2 SIMO, With IC, Full Loading, SE

21. 1x2 SIMO, With IC, Half Loading, SE

22. Conclusion
Interlace pilot enjoys better SE than non-interlaced pilot with interference cancellation in all cases

23. Part III: Additional Results -Interlace Pilot Gain with Interference Cancellation

24. Additional Results I Constant SIR, 2 Interferers (1:1)
2-D MMSE channel estimation
Pilot pattern based on current SDD text
Channel – Ped-B 3km/h
Scenario 1: SIMO 1x2, QPSK ½, SIR = 3dB, Full/half loading
Scenario 2: SIMO 1x2, 16QAM ½, SIR = 10dB, Full/half loading

25. SIMO 1x2, QPSK ½, SIR = 3dB Half loading Full loading
Pilot Pattern 0: non-interlaced pilots.
Pilot pattern 1: interlaced pilots.

26. SIMO 1x2,16QAM ½, SIR = 10dB
Full loading
Half loading

27. Conclusion
Interlace pilot out-perform non-interlaced pilot in different SIR settings with/without interference cancellation

28. Text Change (1/2) In IEEE 802.16m-08/003r4 Section 11.5.3, replace
“The interlaced pilot patterns can be generated by cyclic shifting the base pilot pattern. The interlaced pilot patterns are shown in Figure 33 and can be optionally used by different BSs. The use of interlaced pilot pattern is FFS. …”
with
“For 1 and 2 data streams, BSs use interlaced pilot patterns. The interlaced pilot patterns are generated by cyclic shifting of the base pilot pattern. The interlaced pilot patterns are shown in Figure 33 and are used by different BSs. Each BS chooses one of the pilot pattern in Fig. 33. The index of the pilot pattern used by a particular BS is determined by its Cell_ID according to the following equation:
interlaced_pilot_index_k = mod(Cell_ID,3) ”

29. Text Change (2/2) Fig. 33: caption: (a) k=0, (b) k=1, (c) k=2
Interlaced pilot patterns for 1/2 streams

30. Backup Slides

31. Additional Results for higher MCSs
INR = 10 dB, 2 interferers (1:1)
2-D MMSE channel estimation
Pilot pattern based on current SDD text
Channel – Peb-B 3km/h
Scenario1: SIMO 1x2
Desired Signal: 16 QAM ½
Interfering Signals: 16 QAM
Scenario2: SIMO 1x2
Desired Signal: QPSK ½
Interfering Signals: 64 QAM

32. SIMO 1x2, PER for 16QAM/16QAM
2 Interferers (1:1), Desired BS – 16QAM ½, Interfering BSs – 16QAM

33. SIMO 1x2, PER for QPSK/64QAM
2 Interferers (1:1), Desired BS – QPSK ½, Interfering BSs – 64QAM

34. Conclusion
Interlace pilots out-perform non-interlaced pilots when the interfering signals use higher constellation.

35. Simulation Results for 1-stream, No Pilot Boosting

36. 1 stream: eITU PB3, 1x2, No pilot boosting

37. 1 stream: eITU VA120, 1x2, No pilot boosting

38. 1 stream: eITU VA350, 1x2, No pilot boosting