Adaptively Grouped Multilevel Space–Time Trellis Codes Combined with Beamforming and Component Code Selection
详细信息    查看全文
  • 作者:Dharmvir Jain (1)
    Sanjay Sharma (1)
  • 关键词:Multilevel coding ; Dynamic space–time trellis code ; Rayleigh fading ; Adaptive antenna grouping ; Beamforming
  • 刊名:Wireless Personal Communications
  • 出版年:2014
  • 出版时间:August 2014
  • 年:2014
  • 卷:77
  • 期:4
  • 页码:2549-2563
  • 全文大小:490 KB
  • 参考文献:1. Tarokh, V., Seshadri, N., & Calderbank, A. R. (1998). Space–time codes for high data rate wireless communication: Performance criterion and code construction. / IEEE Transactions on Information Theory, / 44(2), 744-65. CrossRef
    2. Baro, S., Bauch, G., & Hansmanna, A. (2000). Improved codes for space–time trellis-coded modulation. / IEEE Communications Letters, / 4, 20-2. CrossRef
    3. Chen, Z., Vucetic, B., & Yuan, J. (2001). Improved space–time trellis coded modulation scheme on slow Rayleigh fading channels. / Electronics Letters, / 37, 440-41. CrossRef
    4. Mavares, D., & Torres, R. P. (2006). Space–time code selection for transmit antenna diversity systems. In / Proceedings of the first mobile computing and wireless communication international conference (pp. 83-7).
    5. Liu, L., & Jafarkhani, H. (2006). Space–time trellis codes based on channel-phase feedback. / IEEE Transactions on Communications, / 54, 2186-198. CrossRef
    6. Celebi, M. E., Sahin, S., & Aygolu, U. (2007). Full rate full diversity space–time block code selection for more than two transmit antennas. / IEEE Transactions on Wireless Communications, / 6, 16-9. CrossRef
    7. Eksim, A., & Celebi, M. E. (2010). Received SNR based code and antenna selection for limited feedback communication. In / Proceedings of 18th conference of IEEE signal processing and communications applications (pp. 21-4).
    8. Molisch, A. F., & Win, M. Z. (2004). MIMO systems with antenna selection. / IEEE Microwave Magazine, / 5(1), 46-6. CrossRef
    9. Gore, D. A., & Paulraj, A. J. (2002). MIMO antenna subset selection with space-time coding. / IEEE Transactions on Signal Processing, / 50(10), 2580-588. CrossRef
    10. Wong, W. H., & Larsson, E. G. (2003). Orthogonal space–time block coding with antenna selection and power allocation. / Electronics Letters, / 39(4), 379-81. CrossRef
    11. Tao, M., Li, Q., & Garg, H. K. (2007). Extended space–time block coding with transmit antenna selection over correlated fading channels. / IEEE Transactions on Wireless Communications, / 6(9), 3137-141. CrossRef
    12. Chen, Z., Vucetic, B., & Yuan, J. (2003). Space–time trellis codes with transmit antenna selection. / Electronics Letters, / 39(11), 854-55. CrossRef
    13. Tarokh, V., Naguib, A., Seshadri, N., & Calderbank, A. R. (1999). Combined array processing and space–time coding. / IEEE Transactions on Information Theory, / 45(4), 1121-128. CrossRef
    14. Narasimhan, R. (2003). Spatial multiplexing with transmit antenna and constellation selection for correlated MIMO fading channels. / IEEE Transactions on Signal Processing, / 51(11), 2829-838. CrossRef
    15. Yuan, J. (2006). Adaptive transmit antenna selection with pragmatic space–time trellis codes. / IEEE Transactions on Wireless Communications, / 5(7), 1706-715. CrossRef
    16. Huang, Y., Xu, D., & Yang, L. (2006). Adaptive antenna grouping for space–time block coding and spatial multiplexing hybrid system. In / Proceedings of the first mobile computing and wireless communication international conference (MCWC 2006) (pp. 88-2).
    17. Jongren, G., Skoglund, M., & Ottersten, B. (2002). Combining beam forming and orthogonal space–time block coding. / IEEE Transactions on Information Theory, / 48, 611-27. CrossRef
    18. Zhou, S., & Giannakis, G. (2002). Optimal transmitter eigen-beamforming and space–time block coding based on channel mean feedback. / IEEE Transactions on Signal Processing, / 50, 2599-613. CrossRef
    19. Liu, J., & Gunawan, E. (2003). Combining ideal beam forming and Alamouti space–time block codes. / Electronics Letters, / 39, 1258-259. CrossRef
    20. Li, Y., Vucetic, B., Santoso, A., & Chen, Z. (2003). Space–time trellis codes with adaptive weighting. / Electronics Letters, / 39, 1833-834. doi:10.1049/el:20031180 . CrossRef
    21. Santoso, A., Li, Y., & Vucetic, B. (2004). Weighted space–time trellis codes. / Electronics Letters, / 40, 254-56. CrossRef
    22. Imai, H., & Hirakawa, S. (1977). A new multilevel coding method using error correcting codes. / IEEE Transactions on Information Theory, / 23(3), 371-77. CrossRef
    23. Calderbank, A. (1989). Multilevel codes and multistage decoding. / IEEE Transactions on Communications, / 37(3), 222-29. CrossRef
    24. Waschmann, U., Fischer, R. F., & Huber, J. B. (1999). Multilevel codes: Theoretical concepts and practical design rules. / IEEE Transactions on Information Theory, / 45(5), 1361-391. CrossRef
    25. Ma, Shang-Chih, & Lin, Chia-Hao. (2010). Multilevel concatenated space–time block codes. / IEICE Transactions on Fundamentals of Electronics, Communications and Computer, / E93–A(10), 1845-847.
    26. Baghaie, A. M. (2008). / Multilevel space–time trellis codes for Rayleigh fading channels. ME Thesis, University of Canterbury, New Zealand. http://ir.canterbury.ac.nz/bitstream/10092/2101/1/Thesis_fulltext.pdf. Accessed 15 Nov 2009.
    27. Sharma, S. (2012). A novel weighted multilevel space–time trellis coding scheme. / Computers and Mathematics with Applications, / 63(1), 280-87. CrossRef
    28. Baghaie, A. M., Martin, P. A., & Taylor, D. P. (2010). Grouped multilevel space–time trellis codes. / IEEE Communications Letters, / 14(3), 232-34. CrossRef
    29. Jain, D., & Sharma, S. (2013). Adaptively grouped multilevel space–time trellis codes. / Wireless Personal Communications. doi:10.1007/s11277-013-1293-7 .
    30. Blanz, J. (2006). / Dynamic space–time coding for a communication system. US Patent Publication No. 20060209749, September 21.
    31. Jain, D., & Sharma, S. (2013). Adaptive generator sequence selection in multilevel space–time trellis codes. / Wireless Personal Communications. doi:10.1007/s11277-013-1440-1 .
  • 作者单位:Dharmvir Jain (1)
    Sanjay Sharma (1)

    1. Department of Electronics and Communication Engineering, Thapar University, Patiala, India
  • ISSN:1572-834X
文摘
The performance of adaptively grouped multilevel space–time trellis codes (AGMLSTTCs) is limited due to predefined component space–time trellis codes (STTCs) used in multilevel coding and lack of beamforming. In this paper, we present improvement in performance of AGMLSTTCs by combining beamforming and dynamic selection of component STTCs with AGMLSTTCs to design new codes henceforth referred to as weighted adaptively grouped multilevel dynamic space–time trellis codes. The channel state information at transmitter (CSI) is used to select a code set having different sets of generator sequences. The selected code set is used for generating dynamic STTCs (DSTTCs). The DSTTCs are used as component codes in multilevel coding. We use a single full-diversity DSTTC at some initial levels and multiple DSTTCs at some later levels. The single full diversity DSTTC at each initial level spans all transmit antennas and the DSTTC at each later level spans a group of transmit antennas. The CSI is further used to provide a beam forming scheme by properly weighting transmitted signals. Weights are selected that based on CSI at transmitter. The simulation results show that AGMLSTTCs combined with beamforming and DSTTCs provide significant improved error performance over grouped multilevel space–time trellis codes and AGMLSTTCs.

© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号

地址:北京市海淀区学院路29号 邮编:100083

电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700