多輸入多輸出（MIMO）正交頻分複用（OFDM）技術在多路徑衰落的寬帶無線通道上擁有傳輸高數據速率，但是其對時間和頻率同步誤差非常敏感，導致信道間干擾（ICI）產生。這種現象會導致多輸入多輸出的正交頻分複用系統中的服務質量（QoS）的性能下降。
該研究提出了一種有效率的多目標設計方法，利用適當選擇預編碼矩陣，通過最大化訊號相對於干擾和雜訊比之值來優化服務質量性能以及最小化能量消耗來達到最佳的能量效率在多輸入多輸出的正交頻分複用的系統上。多目標預編碼設計被轉換為等效線性矩陣不等式（LMIs）的多目標最佳化問題（MOP），利用提出的線性矩陣不等式限制多目標演化算法（MOEA）可以保證凸度和總體收斂。由於多目標演化算法可以提供一組Pareto最佳解，我們可以在多輸入多輸出的正交頻分複用系統中選擇一種可以達到最小均方誤差（MMSE）的解決方案作為選擇預編碼設計的方法。最後，模擬結果說明設計過程也同時證實多輸入多輸出的正交頻分複用系統提出的多目標預編碼方法的性能。

Multi-input multi-output (MIMO) orthogonal frequency division multiplexing (OFDM) techniques can allow the transmission of high data rates over broadband wireless channels subject to multipath fading, but they are however very sensitive to time and frequency synchronization errors giving rise to inter-channel interference (ICI). This phenomenon causes the performance degradation of the quality of service (QoS) in MIMO OFDM systems.
In this study, we propose an efficient multiobjective design method by maximizing the SINR value for optimal QoS performance and minimizing power consumption for optimal power efficiency of MIMO OFDM systems simultaneously through a proper selection of a precoding scheme. The multiobjective precoding design is transformed to an equivalent linear matrix inequalities (LMIs)-constrained multiobjective optimization problem (MOP), which could be easily solved by a proposed LMIs-constrained multiobjective evolution algorithm (MOEA) to guarantee the convexity and global convergence. Since the MOEA can provide a set of Pareto optimal solutions, one solution which can also achieve the minimum mean square error (MMSE) equalization is selected as the preferable precoding design in MIMO OFDM systems. Finally, simulation examples are given to illustrate the design procedure and to confirm the performance of the proposed multiobjective precoding scheme of MIMO OFDM systems.

摘要 ii
Abstract iii
致謝 iv
1 Introduction 1
2 System Modeling 6
3 Multiobjective Precoding Scheme Of MIMO OFDM Systems 11
4 LMI-Constrained MOEA Algorithm for Multiobjective Precoding Design 16
5 Multiobjective Optimization Precoding Design with Least MMSE Equalization 20
6 Simulation Results 23
7 Conclusion 34
A Appendix 35
References 39

[1] S. Noh, Y. Sung, and M. D. Zoltowski, “A new precoder design for blind channel
estimation in mimo-ofdm systems,” IEEE Transactions on Wireless Communications,
vol. 13, no. 12, pp. 7011–7024, 2014.
[2] Y. Jin and X.-G. Xia, “A robust precoder design based on channel statistics for
mimo-ofdm systems with insufficient cyclic prefix,” IEEE transactions on communications,
vol. 62, no. 4, pp. 1249–1257, 2014.
[3] A. Goldsmith, Wireless communications. Cambridge university press, 2005.
[4] Z. Liu, Y. Xin, and G. B. Giannakis, “Linear constellation precoding for ofdm with
maximum multipath diversity and coding gains,” IEEE Transactions on Communications,
vol. 51, no. 3, pp. 416–427, 2003.
[5] Z. Wang and G. B. Giannakis, “Wireless multicarrier communications,” IEEE signal
processing magazine, vol. 17, no. 3, pp. 29–48, 2000.
[6] Z. Wang and G. B. Giannakis, “Complex-field coding for ofdm over fading wireless
channels,” IEEE Transactions on Information Theory, vol. 49, no. 3, pp. 707–
720, 2003.
[7] R. Van Nee, G. Awater, M. Morikura, H. Takanashi, M. Webster, and K. W. Halford,
“New high-rate wireless lan standards,” IEEE Communications Magazine,
vol. 37, no. 12, pp. 82–88, 1999.
[8] A. Petropulu, R. Zhang, and R. Lin, “Blind ofdm channel estimation through simple
linear precoding,” IEEE Transactions on Wireless Communications, vol. 3,
no. 2, pp. 647–655, 2004.
[9] Z. Ding, T. Ratnarajah, and C. F. Cowan, “Hos-based semi-blind spatial equalization
for mimo rayleigh fading channels,” IEEE Transactions on Signal Processing,
vol. 56, no. 1, pp. 248–255, 2008.
[10] L. Sarperi, X. Zhu, and A. K. Nandi, “Blind ofdm receiver based on independent
component analysis for multiple-input multiple-output systems,” IEEE Transactions
on Wireless Communications, vol. 6, no. 11, 2007.
[11] D. Wulich and L. Goldfeld, “Reduction of peak factor in orthogonal multicarrier
modulation by amplitude limiting and coding,” IEEE Transactions on Communications,
vol. 47, no. 1, pp. 18–21, 1999.
[12] B.-S. Chen, C.-Y. Yang, and W.-J. Liao, “Robust fast time-varying multipath
fading channel estimation and equalization for mimo-ofdm systems via a fuzzy
method,” IEEE Transactions on vehicular technology, vol. 61, no. 4, pp. 1599–
1609, 2012.
[13] T.-J. Ho and B.-S. Chen, “Robust minimax mse equalizer designs for mimo wireless
communications with time-varying channel uncertainties,” IEEE Transactions
on Signal Processing, vol. 58, no. 11, pp. 5835–5844, 2010.
[14] A. J. Al-Dweik, “A novel non-data-aided symbol timing recovery technique for
ofdm systems,” IEEE Transactions on Communications, vol. 54, no. 1, pp. 37–40,
2006.
[15] G. Santella, “A frequency and symbol synchronization system for ofdm signals:
architecture and simulation results,” IEEE Transactions on vehicular Technology,
vol. 49, no. 1, pp. 254–275, 2000.
[16] Q. Zhu and Z. Liu, “Minimum interference blind time-offset estimation for ofdm
systems,” IEEE transactions on wireless communications, vol. 5, no. 8, pp. 2136–
2142, 2006.
[17] W.-L. Chin and S.-G. Chen, “A blind synchronizer for ofdm systems based on
sinr maximization in multipath fading channels,” IEEE Transactions on Vehicular
Technology, vol. 58, no. 2, pp. 625–635, 2009.
[18] O. Popescu and D. C. Popescu, “On the performance of sub-band precoded ofdm
in the presence of narrowband co-channel interference,” IEEE Transactions on
Broadcasting, vol. 62, no. 3, pp. 736–743, 2016.
[19] R. Lin and A. P. Petropulu, “Linear precoding assisted blind channel estimation
for ofdm systems,” IEEE Transactions on Vehicular Technology, vol. 54, no. 3,
pp. 983–995, 2005.
[20] R. T. Marler and J. S. Arora, “The weighted sum method for multi-objective optimization:
new insights,” Structural and multidisciplinary optimization, vol. 41,
no. 6, pp. 853–862, 2010.
[21] J.-h. Ryu, S. Kim, and H. Wan, “Pareto front approximation with adaptive weighted
sum method in multiobjective simulation optimization,” in Winter Simulation Conference,
pp. 623–633, Winter Simulation Conference, 2009.
[22] K. Deb, A. Pratap, S. Agarwal, and T. Meyarivan, “A fast and elitist multiobjective
genetic algorithm: Nsga-ii,” IEEE transactions on evolutionary computation,
vol. 6, no. 2, pp. 182–197, 2002.
[23] B. Suman, “Study of self-stopping pdmosa and performance measure in multiobjective
optimization,” Computers & chemical engineering, vol. 29, no. 5,
pp. 1131–1147, 2005.
[24] B. Suman and P. Kumar, “A survey of simulated annealing as a tool for single and
multiobjective optimization,” Journal of the operational research society, vol. 57,
no. 10, pp. 1143–1160, 2006.
[25] A. Abraham and L. Jain, “Evolutionary multiobjective optimization,” in Evolutionary
Multiobjective Optimization, pp. 1–6, Springer, 2005.
[26] J. Branke, K. Deb, H. Dierolf, and M. Osswald, “Finding knees in multi-objective
optimization,” in Parallel problem solving from nature-PPSN VIII, pp. 722–731,
Springer, 2004.
[27] K. Deb and M.-o. O. U. E. Algorithms, “vol. 16,” 2001.
[28] Y. S. Cho, J. Kim, W. Y. Yang, and C. G. Kang, MIMO-OFDM wireless communications
with MATLAB. John Wiley & Sons, 2010.
[29] S. Boyd, L. El Ghaoui, E. Feron, and V. Balakrishnan, Linear matrix inequalities
in system and control theory. SIAM, 1994.
[30] C. F. Wu, B.-S. Chen, and W. Zhang, “Multiobjective investment policy for nonlinear
stochastic financial system: Fuzzy approach,” IEEE Transactions on Fuzzy
Systems, 2016.
[31] K. B. Petersen, M. S. Pedersen, et al., “The matrix cookbook,” Technical University
of Denmark, vol. 7, p. 15, 2008.
[32] Y. Sun, D. W. K. Ng, J. Zhu, and R. Schober, “Multi-objective optimization for
robust power efficient and secure full-duplex wireless communication systems,”
IEEE Transactions on Wireless Communications, vol. 15, no. 8, pp. 5511–5526,
2016.