Diversity analysis of smart relaying over Nakagami and Hoyt generalised fading channels

N.H. Vien; H.H. Nguyen; T. Le-Ngoc

Diversity analysis of smart relaying over Nakagami and Hoyt generalised fading channels

Access Full Text

Diversity analysis of smart relaying over Nakagami and Hoyt generalised fading channels

Author(s): N.H. Vien ; H.H. Nguyen ; T. Le-Ngoc
DOI: 10.1049/iet-com.2008.0354

For access to this article, please select a purchase option:

Buy article PDF

Buy Knowledge Pack

IET members benefit from discounts to all IET publications and free access to E&T Magazine. If you are an IET member, log in to your account and the discounts will automatically be applied.

Learn more about IET membership

Recommend Title Publication to library

IET Communications — Recommend this title to your library

Thank you

Your recommendation has been sent to your librarian.

Author(s): N.H. Vien ¹ ; H.H. Nguyen ¹ ; T. Le-Ngoc ²
- Affiliations: 1: Department of Electrical & Computer Engineering, University of Saskatchewan, Saskatoon, Canada
  2: Department of Electrical & Computer Engineering, McGill University, Montreal, Canada
Source: Volume 3, Issue 11, November 2009, p. 1778 – 1789
DOI: 10.1049/iet-com.2008.0354 , Print ISSN 1751-8628, Online ISSN 1751-8636

Published

Signal transmission with the help of relay(s) in wireless networks can achieve spatial diversity without the need of having multiple attennas at the source and/or destination. Among various signal processing techniques proposed for the relays, the adaptive decode-and-forward (DF) relaying strategy, recently proposed by Wang et al. and generally referred to as smart relaying, has been shown to achieve the maximal spatial diversity even when imperfect detection is committed at the relays. The work by Wang et al., however, only considers Rayleigh fading channels. This paper extends the diversity analysis of the smart relaying technique to the important Nakagami and Hoyt generalised fading channels. Performance analysis proves that, at high signal-to-noise ratio, the maximal diversity order achieved by the smart relaying system under the Nakagami channel is m_SD+min{m_SR, m_RD}, where m_SR, m_RD and m_SD are the fading figures of the source–relay (S–R), relay–destination (R–D) and source–destination (S–D) links. Under the Hoyt fading channel, the diversity order is 2. The obtained results on the diversity order are shown to be insensitive to the quality of the R–D feedback channel.

References

1. 1)
  - D. Chen , J.N. Laneman . Modulation and demodulation for cooperative diversity in wireless systems. IEEE Trans. Wirel. Commun. , 1785 - 1794
2. 2)
  - A. Ribeiro , X. Cai , G.B. Giannakis . Symbol error probabilities for general cooperative links. IEEE Trans. Wirel. Commun. , 3 , 1264 - 1273
3. 3)
  - C.D. Iskander , P.T. Mathiopoulos . Exact performance analysis of dual-branch coherent equal-gain combining in Nakagami-m, Rician, and Hoyt fading. IEEE Trans. Veh. Technol. , 921 - 931
4. 4)
  - N.H. Vien , H.H. Nguyen , T. Le-Ngoc . Diversity analysis of smart relaying. IEEE Trans. Veh. Technol.
5. 5)
  - M.K. Simon , M.S. Alouini . (2005) Digital communication over fading channels.
6. 6)
  - C.M. Joshi , S.K. Bissu . Some inequalities of Bessel and modified Bessel functions. J. Aust. Math. Soc. , 2 , 333 - 342
7. 7)
  - T. Wang , A. Cano , G.B. Giannakis . High-performance cooperative demodulation with decode-and-forward relays. IEEE Trans. Commun. , 11 , 1427 - 1438
8. 8)
  - G.K. Karagiannidis . Performance bounds of multihop wireless communications with blind relays over generalized fading channels. IEEE Trans. Wirel. Commun. , 3 , 498 - 503
9. 9)
  - R.U. Nabar , H. Bolcskei , F.W. Kneubuhler . Fading relay channels: performance limits and space-time signal design. IEEE J. Sel. Areas Commun. , 6 , 1099 - 1109
10. 10)
  - P.A. Anghel , M. Kaveh . Distributed space–time cooperative system with regenerative relays. IEEE Trans. Wirel. Commun. , 3130 - 3141
11. 11)
  - Y. Li , S. Kishore . Asymptotic analysis of amplify-and-forward relaying in Nakagami-m fading environments. IEEE Trans. Wirel. Commun. , 4256 - 4262
12. 12)
  - J.N. Laneman , D.N.C. Tse , G.W. Wornell . Cooperative diversity in the wireles networks: efficient protocols and outage behavior. IEEE Trans. Inform. Theory , 3062 - 3080
13. 13)
  - T. Wang , G.B. Giannakis . Complex field network coding for multiuser cooperative communications. IEEE J. Select. Areas Commun. , 561 - 571
14. 14)
  - J.G. Proakis . (1995) Digital communications.
15. 15)
  - T. Wang , G. Giannakis , R. Wang . Smart regenerative relays for link-adaptive cooperative communications. IEEE Trans. Commun. , 1950 - 1960
16. 16)
  - L.-L. Yang , H.-H. Chen . Error probability of digital communications using relay diversity over Nakagami-m fading channels. IEEE Trans. Wirel. Commun. , 1806 - 1811
17. 17)
  - S. Yiu , R. Schober , L. Lampe . Distributed space-time block coding. IEEE Trans. Commun. , 7 , 1195 - 1206
18. 18)
  - R. Radaydeh , M. Matalgah . Non-coherent improved-gain diversity reception of binary orthogonal signals in Nakagami-q (Hoyt) mobile channels. Commun., IET , 2 , 372 - 379
19. 19)
  - Wang, T., Wang, R., Giannakis, G.B.: `Smart regenerative relays for link-adaptive cooperative communications', 40thAnn. Conf. on Information Sciences and Systems, March 2006, p. 1038–1043.
20. 20)
  - Hasna, M.O., Alouini, M.-S.: `A performance study of dual–hop transmissions with fixed gain relays', Proc. IEEE ICASSP, 2003, 4, p. IV–189–92.
21. 21)
  - J.N. Laneman , G.W. Wornell . Distributed space-time-coded protocols for exploiting cooperative diversity in wireless networks. IEEE Trans. Inf. Theory , 10 , 2415 - 2425
22. 22)
  - I. Gradshteyn , I. Ryzhik . (1980) Tables of integrals, series and products.
23. 23)
  - A. Sendonaris , E. Erkrip , B. Aazhang . User cooperation diversity – Part II: implementation aspects and performance analysis. IEEE Trans. Commun. , 11 , 1939 - 1948
24. 24)
  - Song, Y., Sarkar, M., Shin, H.: `Cooperative diversity with blind relays in Nakagami-m fading channels: MRC analysis', Proc. IEEE Veh. Technol. Conf., May 2008, p. 1196–1200.
25. 25)
  - A. Cano , T. Wang , A. Ribeiro , G.B. Giannakis . Link-adaptive distributed coding for multisource cooperation. EURASIP J. Adv. Signal Process
26. 26)
  - D.A. Zogas , G.K. Karagiannidis , S.A. Kotsopoulos . Equal gain combining over Nakagami-n (Rice) and Nakagami-q (Hoyt) generalized fading channels. IEEE Trans. Wirel. Commun. , 2 , 374 - 379
27. 27)
  - A. Sendonaris , E. Erkip , B. Aazhang . User cooperation diversity. Two Parts. IEEE Trans. Commun. , 1927 - 1948
28. 28)
  - Laneman, J.N.: `Cooperative diversity in wireless network: algorithms and architectures', 2002, PhD, MIT, Cambridge, MA.
29. 29)
  - M. Abramowitz , I.A. Stegun . (1964) Handbook of mathematical functions with formulas, graphs, and mathematical tables.
30. 30)
  - Adeane, J., Rodrigues, M.R.D., Wassell, I.J.: `Characterisation of the performance of cooperative networks in Ricean fading channels', Proc. Int. Conf. Telecommunications, May 2005, Cape Town, South Africa.
31. 31)
  - S. Ikki , M. Ahmed . Performance analysis of cooperative diversity wireless networks over Nakagami-m fading channel. IEEE Commun. Lett. , 334 - 336
32. 32)
  - Wang, T., Cano, A., Giannakis, G.B.: `Link-adaptive cooperative communications without channel state information', Proc. IEEE Military Commun. Conf., October 2006, p. 1–7.

Login

Not registered yet?

Share

Tools

Login to add to favourites

Key

Diversity analysis of smart relaying over Nakagami and Hoyt generalised fading channels

Diversity analysis of smart relaying over Nakagami and Hoyt generalised fading channels

Buy article PDF

Buy Knowledge Pack

Thank you

References

Related content