A Novel Multiple Access System B ased on TDS-OFDM

1. A Novel Multiple Access System Based on TDS-OFDM Linglong Dai (Ph.D candidate), Jian Song (Professor) Tsinghua University, Beijing, China

2. Contents 1 TDS-OFDMA System 2 Simulation Results 3 Conclusion

3. Time domain synchronous-OFDM (TDS-OFDM) Frame Structure in TDS-OFDM System • Key technology of the Chinese digital television terrestrial broadcasting (DTTB) standard • GI: PN sequence instead of cyclic prefix (CP) [Song07] • Higher spectrum efficiency (10%) • Faster synchronization (5%)

4. Major Problem of TDS-OFDMA: Mixed Interferences • CP-OFDMA • cyclic prefix (CP) • cyclicity property • linear convolution circular convolution • Simple CE and equalization • TDS-OFDMA • PN sequence • Cyclicity destoryed • Mixed interferences • Iterative interference cancellation (IC) • CE and IC are mutually conditional • Impossible for multiple users cyclicity

5. Channel estimation (CE) and interferencecancellation (IC) • CP-OFDMA: • two-dimensional pilots [802.16e06] [Hoeher97] [Li00][Morelli01] • two-dimensional interpolation • MIMO-OFDM: • Orthogonal pilots [Jeon00] [Siew02][Suh03] • WiMAX, LTE, B3G

6. Channel estimation (CE) andinterferencecancellation (IC) • Single-user TDS-OFDM system: • iterative interference subtraction [Wang05] • Long spread of multi-path • High complexity, mutual precondition of CE and IC • Partial-decision aided CE[Tang08] • Partly destroy the mutual precondition of CE and IC • Still High complexity • Based on “virtual frame”[Tang07] • Decrease the complexity • Only suitable for fixed PN • PN reconstruction [Yang08] • Decrease the complexity • Still based on iteration Problems: • CE and IC are mutually conditional • High complexity of iterative IC (30% chip area) • Decreased performance in mobile environment

7. Overview of the TDS-OFDMA System • Key ideas • Separate CE and IC • Joint cyclicity reconstruction • Joint CE TDS-OFDMA System Diagram

8. “time-space two-dimensional frame structure”

9. Joint cyclictiy reconstruction

10. Joint channel estimation

11. Complexity comparison J: iteration number J=1, the complexity of[Tang07]is68%of[Wang05] J=1, the complexity of[Yang08]is24%of [Wang05] Proposed: no iteration, J=0, the complexity is6%of[Wang05]

12. Contents 1 TDS-OFDMA System Introduction 2 Simulation Results 3 Conclusion

13. Simulation Results (1) Static Multi-path • User number M=2 • Modulaton QPSK • Symbol rate 7.56 MSPS • Carrier assignment interleaved • Length Np=255 Ls=76 Lt=153 • Channels Brazil A/D

14. Simulation Results (2) Rayleigh Channel • Modulaton QPSK • Rayleigh channel Brazil A/D • Max. Doppler spread 30Hz

15. Contents 1 TDS-OFDMA System Introduction 2 Simulation Results 3 Conclusion

16. Brief Conclusions • A novel TDS-OFDMA scheme • The new "time-space two-dimensional frame structure " • Joint cyclicity reconstruction • Joint channel estimation • Extend TDS-OFDM from broadcasting to other senarios

17. References • [Song07] J. Song, Z. Yang, L. Yang, et al., “Technique review on Chinese digital terrestrial television broadcasting standard and measurements on some working modes, ” IEEE Trans. Broadcast., vol.53, no.1, pp.1-7, Mar. 2007. • [802.16e 06] IEEE Standard for Local and Metropolitan Area Networks part 16:Air Interface for Fixed and Mobile Broadband Wireless Access Systems,Amendment 2: Physical and Medium Access Control Layers for Combined Fixed and Mobile Operation in Licensed Bands and Corrigendum 1,IEEE Std.802.16e,2006. • [Hoeher97] P.Hoeher,S.Kaiser, “Pilot-aided Channel Estimation in Time and Frequency,” In Proc.IEEE GLOBECOM’97, Phoenix, USA,1997, 1190-1196. • [Li00] Ye Li, “Pilot-symbol-aided channel estimation for OFDM in wireless systems”. IEEE Transactions on Vehicular Technology，2000，49(4)，P:1207-1215. • [Morelli01] Morelli M.and Mengali U.,“A comparison of pilot-aided channel estimation methods for OFDM systems”, IEEE Trans on processing Signal vol.49, pp. 3065-3073, Dec 2001. • [Jeon00] W. G. Jeon，K. H. Paik，and Y. S. Cho, “An Efficient Channel Estimation Technique for OFDM Systems with Transmitter Diversity,” Proc. IEEE International Symposium on Personal，Indoor and Mobile Radio Commun.，vol.2，London，UK，Sept. 2000，P:1246-1250. • [Siew02] J.Siew et al. , “A Channel Estimation Method for MIMO-OFDM Systems,” Proc. London Commun. Symp.，London，England，Sept.2002，P:1-4 • [Suh03] C.Suh，C.-S. Hwang，and H. Choi, “Comarative study of time-domain and Frequency-domain channel estimation in MIMO-OFDM systems,” in Proc. IEEE PIMRC’03，vol.2，pp.1095-1099，7-10 Sept. 2003. • [Yang02] Z. Yang, J. Wang, C. Pan, L. Yang, and Z. Han, “Channel estimation of DMB-T,” in 2002 IEEE Int. Conf. Communications, Circuits and Systems and West Sino Expositions , vol. 2, pp. 1069-1072, 2002. • [Wang05] J. Wang, Z. Yang, C. Pan, J. Song, and L. Yang, “Iterative padding subtraction of the PN sequence for the TDS-OFDM over broadcasting channels,” IEEE Trans. Consumer Electron., vol. 51, no. 4, pp. 1148–1152, Nov. 2005. • [Tang07] S. Tang, F. Yang, K. Peng, C. Pan, and Z. Yang, “Iterative channel estimation for block transmission with know symbol padding - a new look at TDS-OFDM,” in Proc. IEEE 2007 Global Telecommunications Conf. (GLOBECOM’07), Washington, DC, Nov. 2007, pp. 4269–4273. • [Tang08] Shigang Tang, Kewu Peng, Ke Gong, et al., “Novel Decision-Aided Channel Estimation for TDS-OFDM Systems,” in Proc. IEEE International Conference on Communications (ICC '08), May. 2008, pp. 946-950. • [Yang08] Fang Yang, Jintao Wang, Jun Wang, et al., “Channel Estimation for the Chinese DTTB System Based on a Novel Iterative PN Sequence Reconstruction," in Proc. IEEE International Conference on Communications (ICC '08), May. 2008, pp. 285-289. • [Sarwate79] D.S.Sarwate, “Bounds on crosscorrelation and autocorrelation of sequences,” IEEE Trans. Inf. Theory, vol.25, no6, pp.720-724, Nov.1979.

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