Joint antenna and relay selection strategies for decode-and-forward relay networks
Cooperative diversity systems with optimal and suboptimal antenna and relay selection have been paid significant attention for more than half a decade. However, optimal antenna and relay selection strategies require global channel state information (CSI), which is a cumbersome process. In this paper...
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sg-ntu-dr.10356-814742020-03-07T11:48:52Z Joint antenna and relay selection strategies for decode-and-forward relay networks Swaminathan, Ramabadran Karagiannidis, George K. Roy, Rajarshi School of Computer Science and Engineering Antenna and relay selection strategies Decode-and-forward (DF) Cooperative diversity systems with optimal and suboptimal antenna and relay selection have been paid significant attention for more than half a decade. However, optimal antenna and relay selection strategies require global channel state information (CSI), which is a cumbersome process. In this paper, we propose a diversity-optimal and three suboptimal transmit-receive antenna and relay selection strategies, named S1, S2, and S3, for decode-and-forward cooperative relaying systems, equipped with Nt and Nr antennas at the source (S) and the destination (D), respectively, and considering a multirelay scenario. Furthermore, we study the symbol error probability (SEP) for these strategies, assuming M-ary phase-shift keying signaling over Rayleigh fading channels. In addition, we perform diversity order analysis through closed-form asymptotic SEP expressions. Since the proposed suboptimal strategies, i.e., S2 and S3, involve the socalled switch-and-examine combining scheme, we compare the complexity of S1, S2, and S3 in terms of the average number of CSI required at D to select the best transmit-receive antenna pair and relay. From the derived SEP expressions, it can be concluded that all three suboptimal strategies achieve the same diversity order of NtNr + N, where N is the number of relays, except for the case when the switching threshold signal-to-noise ratio (SNR) is much lower than the average SNR in S2 and S3. Finally, the diversity-optimal strategy achieves full diversity order of NtNr + N min(Nt, Nr). 2017-04-13T04:08:16Z 2019-12-06T14:31:49Z 2017-04-13T04:08:16Z 2019-12-06T14:31:49Z 2016 2016 Journal Article Swaminathan, R., Karagiannidis, G. K., & Roy, R. (2016). Joint antenna and relay selection strategies for decode-and-forward relay networks. IEEE Transactions on Vehicular Technology, 65(11), 9041-9056. 0018-9545 https://hdl.handle.net/10356/81474 http://hdl.handle.net/10220/42254 10.1109/TVT.2016.2515265 192023 en IEEE Transactions on Vehicular Technology © 2016 IEEE |
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Antenna and relay selection strategies Decode-and-forward (DF) |
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Antenna and relay selection strategies Decode-and-forward (DF) Swaminathan, Ramabadran Karagiannidis, George K. Roy, Rajarshi Joint antenna and relay selection strategies for decode-and-forward relay networks |
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Cooperative diversity systems with optimal and suboptimal antenna and relay selection have been paid significant attention for more than half a decade. However, optimal antenna and relay selection strategies require global channel state information (CSI), which is a cumbersome process. In this paper, we propose a diversity-optimal and three suboptimal transmit-receive antenna and relay selection strategies, named S1, S2, and S3, for decode-and-forward cooperative relaying systems, equipped with Nt and Nr antennas at the source (S) and the destination (D), respectively, and considering a multirelay scenario. Furthermore, we study the symbol error probability (SEP) for these strategies, assuming M-ary phase-shift keying signaling over Rayleigh fading channels. In addition, we perform diversity order analysis through closed-form asymptotic SEP expressions. Since the proposed suboptimal strategies, i.e., S2 and S3, involve the socalled switch-and-examine combining scheme, we compare the complexity of S1, S2, and S3 in terms of the average number of CSI required at D to select the best transmit-receive antenna pair and relay. From the derived SEP expressions, it can be concluded that all three suboptimal strategies achieve the same diversity order of NtNr + N, where N is the number of relays, except for the case when the switching threshold signal-to-noise ratio (SNR) is much lower than the average SNR in S2 and S3. Finally, the diversity-optimal strategy achieves full diversity order of NtNr + N min(Nt, Nr). |
| author2 |
School of Computer Science and Engineering |
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School of Computer Science and Engineering Swaminathan, Ramabadran Karagiannidis, George K. Roy, Rajarshi |
| format |
Article |
| author |
Swaminathan, Ramabadran Karagiannidis, George K. Roy, Rajarshi |
| author_sort |
Swaminathan, Ramabadran |
| title |
Joint antenna and relay selection strategies for decode-and-forward relay networks |
| title_short |
Joint antenna and relay selection strategies for decode-and-forward relay networks |
| title_full |
Joint antenna and relay selection strategies for decode-and-forward relay networks |
| title_fullStr |
Joint antenna and relay selection strategies for decode-and-forward relay networks |
| title_full_unstemmed |
Joint antenna and relay selection strategies for decode-and-forward relay networks |
| title_sort |
joint antenna and relay selection strategies for decode-and-forward relay networks |
| publishDate |
2017 |
| url |
https://hdl.handle.net/10356/81474 http://hdl.handle.net/10220/42254 |
| _version_ |
1681045800570847232 |