EM based Multiuser detection in Fading Multipath Environments

1. EM based Multiuser detection in Fading Multipath Environments Mohammad Jaber Borran, Željko akareski, Ahmad Khoshnevis, and Vishwas Sundaramurthy

2. Outline • Motivation • Time-frequency representation • Channel modeling

3. Outline(continued) • Expectation Maximization algorithm • EM algorithm based detector • Performance comparison • Conclusions and future work

4. Multipath • Fading • MAI Environment • Noise

5. Time-Frequency RepresentationWhat is TFR? • A 2-D signal representation • Facilitates signaling by exploiting multipath and Doppler • Identifies Doppler as another dimension for diversity

6.  Tc M 1/T t Doppler -M Multipath Canonical Coordinates Canonical basis corresponding to the uniform grid L

7. Channel ModelingRequirements • Multipath environment • Independent paths • Rayleigh fast fading

8. Channel ModelingOur approach • Jakes’ model for individual paths • Independence assured by having: Spacing >> Tcoh ( ~ ) • Random delays for different multipath components • Canonical representation

9. Channel ModelingCharacterization • Linear time-varying system n(t) s(t) x(t) r(t) + h(t, ) • Represented by its impulse response h(t, )

10. Incorporate the canonical model into h(t, ) Channel ModelingCharacterization • The output r(t) determined as :

11. Channel ModelingCharacterization • Spreading function H(, ) • Canonical finite-dimensional representation : where

12. In our case Channel ModelingCharacterization • Bandlimited approximation of H(, )

13. Channel ModelingCharacterization where Ei(t) : Jakes’ model rep. for path i

14. EM AlgorithmIntroduction • Goal: • K-dim problem, direct approach is difficult. • Define complete data, i.e. y, such that

15. EM AlgorithmIntroduction (cnt’d) and • Since y is unavailable, • b is unknown,

16. EM AlgorithmIterative Nature, Decomposition • Provides an iterative method for ML estimation: • E step: Compute U(b,b(n)) • M step: • K 1-dim problems (with suitable complete data) • The value of b(0) is important.

17. New Multiuser Detection SchemeComplete Data • The log-likelihood function • Define complete data, y(t) = (y1(t), …, yK(t)), as

18. New Multiuser Detection SchemeIterative Expression, Special Cases • Defining • Assuming • bk=1  Multistage • bk=0  Time-Frequency RAKE receiver

19. New Multiuser Detection SchemeBlock Diagram b(0) b(1) b(n-1) b(n) ... sgn I-b sgn I-b sgn + + b b ... TF RAKE + MRC MAI Estimation & Cancellation MAI Estimation & Cancellation ... r(t) HHz

20. Simulation Results(3 paths, Bd=100Hz, 5 users, User 4)

21. Simulation Results(3 paths, Bd=100Hz, 5 users, User 3)

22. Conclusion • Canonical representation + EM algorithm  New Detector for Fast Fading Multipath Env. • Two special cases: TF RAKE and MultiStage • Outperforms TF RAKE and MultiStage • For rapid convergence use appropriatebk

23. Future work • Theoretical error probability analysis • Near-Far resistance analysis • Optimum value for bk • Extension to asynchronous case

24. That’s all Folks!

25. Signal model Cross correlation matrix where

26. New Multiuser Detection SchemeExpectation Calculation Step • The new log-likelihood function • It can be shown that

27. Canonical RAKE • The coordinates for each symbol of a particular user are computed by:

28. Simulation Results(3 paths, Bd=100Hz, 5 users, User 1)

29. Simulation Results(3 paths, Bd=100Hz, 5 users, User 2)

30. Simulation Results(3 paths, Bd=100Hz, 5 users, User 5)

31. Simulation Results(3 paths, Bd=200Hz, 5 users, User 1)

32. Simulation Results(3 paths, Bd=200Hz, 5 users, User 2)

33. Simulation Results(3 paths, Bd=200Hz, 5 users, User 3)

34. Simulation Results(3 paths, Bd=200Hz, 5 users, User 4)

35. Simulation Results(3 paths, Bd=200Hz, 5 users, User 5)

36. Channel Modeling Visualization of