Atmospheric optical communications channel estimation employing superimposed training sequence under sand-dust weather conditions

Cao Minghua; Hu Qiu; Wang Huiqin; Kang Zhongjiang; Wu Xin; Wang Chanfei

doi:10.3788/IRLA201948.S218002

Volume 48 Issue S2

Oct. 2019

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Article Navigation > Infrared and Laser Engineering > 2019 > 48(S2): 109-116

Cao Minghua, Hu Qiu, Wang Huiqin, Kang Zhongjiang, Wu Xin, Wang Chanfei. Atmospheric optical communications channel estimation employing superimposed training sequence under sand-dust weather conditions[J]. Infrared and Laser Engineering, 2019, 48(S2): 109-116. doi: 10.3788/IRLA201948.S218002

Citation:

Cao Minghua, Hu Qiu, Wang Huiqin, Kang Zhongjiang, Wu Xin, Wang Chanfei. Atmospheric optical communications channel estimation employing superimposed training sequence under sand-dust weather conditions[J]. Infrared and Laser Engineering, 2019, 48(S2): 109-116. doi: 10.3788/IRLA201948.S218002

Atmospheric optical communications channel estimation employing superimposed training sequence under sand-dust weather conditions

doi: 10.3788/IRLA201948.S218002

1.
School of Computer and Communication,Lanzhou University of Technology,Lanzhou 730050,China

Received Date: 2019-04-10
Rev Recd Date: 2019-05-20
Publish Date: 2019-09-30

Abstract

The inherent advantages of superimposed training method are restricted by superposition data information, power allocation, and direct current bias in channel estimation of atmospheric optical communications under sand-dust weather. A novel scheme was proposed to perform these issues, especially for the channel with sand-dust particles. In the proposal, the data-dependent superimposed training algorithm was utilized to mitigate the influence of data information, the correlation matching algorithm was utilized for direct current bias elimination, and the maximum output signal-to-noise ratio was utilized to perform the optimal power allocation factor. The performance of mean square error, power allocation factor, bit error rate and algorithm complexity were numerically evaluated. The results demonstrate that the proposed method has a better performance than conventional methods with a slightly increased computational complexity.
- atmospheric optical communication,
- channel estimation,
- superimposed training sequence,
- sand-dust weather condition

References

[1]	Yin Junyan, Yin Fuchang, Chen Ming, et al. Impact on laser transmission in atmosphere[J]. Infrared and Laser Engineering, 2008, 37(S):399-402. (in Chinese)阴俊燕, 尹福昌, 陈明, 等. 影响激光大气传输因素分析[J]. 红外与激光工程, 2008, 37(S):399-402.
[2]	Zheng Xiaojing, Zhang Jinghong. Characteristics of near-surface turbulence during a dust storm passing Minqin on March 19, 2010[J]. Chinese Sci Bull, 2010, 55(22):2235-2240. (in Chinese)郑晓静, 张静红. 2010年3月19日沙尘暴期间甘肃民勤地区近地表的湍流性质[J]. 科学通报, 2010, 55(22):2235-2240.
[3]	Yuksel H, Milner S, Davis C C. Aperture averaging for optimizing receiver design and system performance on free-space optical communication links[J]. Journal of Optical Networking, 2005, 4(8):462-475.
[4]	Tyson R K. Bit-error rate for free-space adaptive optics laser communications[J]. Journal of the Optical Society of America A Optics Image Science Vision, 2002, 19(4):753-758.
[5]	Li Fei, Lu Houbing. Optimization method for detection threshold of atmospheric optical communication under weak turbulence condition[J]. Infrared and Laser Engineering, 2016, 45(12):1211004. (in Chinese)李菲, 路后兵. 弱湍流条件下大气光通信的阈值优化方法[J]. 红外与激光工程, 2016, 45(12):1211004.
[6]	Niu Chaojun, Yu Shijie, Han Xiang'e. Analysis about effect of wavefront sensorless adaptive optics on optical communication[J]. Laser Optoelectronics Progress, 2015, 52(8):080102. (in Chinese)牛超君, 于诗杰, 韩香娥. 无波前探测自适应光学对光通信性能影响分析[J]. 激光与光电子学进展, 2015, 52(8):080102.
[7]	Zhou Jianguo, Hao Shiqi, Liu Jialin, et al. Interleaver design based on genetic algorithm in atmospheric optical communication[J]. Chinese Journal of Lasers, 2013, 40(6):0605004. (in Chinese)周建国, 郝士琦, 刘加林,等. 大气激光通信中基于遗传算法的交织器设计[J]. 中国激光, 2013, 40(6):0605004.
[8]	Wang J B, Jiao Y, Song X, et al. Optimal training sequences for indoor atmospheric optical communications[J]. Journal of Optics, 2012, 14(1):015401.
[9]	Zhou Chao. Research on optical communication adaptive digital equalization based on LMS algorithm[D]. Chengdu:University of Electronic Science and Technology of China, 2018. (in Chinese)周超. 基于LMS算法的光通信自适应数字均衡技术研究[D]. 成都:电子科技大学, 2018.
[10]	Kaushal H, Kumar V, Dutta A, et al. Experimental study on beam wander under varying atmospheric turbulence conditions[J]. IEEE Photonics Technology Letters, 2011, 23(22):1691-1693.
[11]	Mishra N, Sriram K D, Jha P K. Performance analysis of dual-hop optical wireless communication systems over k-distribution turbulence channel with pointing error[C]//AIP Conference Proceedings, 2017, 1849(1):1-8.
[12]	Gorshtein A, Levy O, Katz G, et al. Coherent compensation for 100G DP-QPSK with one sample per symbol based on antialiasing filtering and blind equalization MLSE[J]. IEEE Photonics Technology Letters, 2010, 22(16):1208-1210.
[13]	Gorshtein A, Levy O, Katz G, et al. Blind channel estimation for MLSE receiver in high speed optical communications:theory and ASIC implementation[J]. Optics Express, 2013, 21(19):21766-21789.
[14]	Zamani M, Chen C, Li C, et al. A blind channel estimation for 100+Gb/s optical IM-DD DMT over 100-km SMF in 1550nm[J]. IEEE Photonics Technology Letters, 2014, 26(19):1928-1931.
[15]	Wang J B, Jiao Y, Xie X X, et al. Complementary sequences-based channel estimation for diffuse atmospheric optical communications[J]. Optical Engineering, 2011, 50(7):075003.
[16]	Omomukuyo O, Chang D, Dobre O, et al. Ngatched, Robust frame and frequency synchronization based on alamouti coding for RGI-CO-OFDM[J]. IEEE Photonics Technology Letters, 2016, 28(24):2783-2786.
[17]	Wu D, Wang Z, Wang R, et al. Channel estimation for asymmetrically clipped optical orthogonal frequency division multiplexing optical atmospheric communications[J]. Iet Communications, 2012, 6(5):532-540.
[18]	Zhao H, Li M, Wang R, et al. Compressed sensing theory-based channel estimation for optical orthogonal frequency division multiplexing communication system[J]. Optics Communications, 2014, 326(5):94-99.
[19]	Zhu C, Pittal F, Finkenbusch M, et al. Overhead-free channel estimation using implicit training for polarization-multiplexed coherent optical systems[C]//Optical Fiber Communication Conference and Exposition and the National Fiber Optic Engineers Conference IEEE, 2013:1-3.
[20]	Chan K C, Huang W C, Li C P, et al. Elimination of data identification problem for data-dependent superimposed training[J]. IEEE Transactions on Signal Processing, 2015, 63(6):1595-1604.
[21]	Fan S, Li Y, Wang L, et al. Comparison of implicit training and implicit pilot in coherent optical transmission[C]//International Conference on Optical Internet IEEE, 2014:1-2.
[22]	Zhu Y J, Sun Z G, Zhang J, et al. Training receivers for repetition coded MISO outdoor visible light communications[J]. IEEE Transactions on Vehicular Technology, 2017, 66(1):529-540.
[23]	Dissanayake S D, Armstrong J. Novel techniques for combating DC offset in diversity combined ACO-OFDM[J]. IEEE Communications Letters, 2011, 15(11):1237-1239.
[24]	Liu T. A novel method for demodulation of ACO-OFDM in the presence of DC offset[J]. Journal of the Franklin Institute, 2015, 352(3):802-812.
[25]	Alameda-Hernandez E, Mclernon D C, Orozcolugo A G, et al. Frame/training sequence synchronization and DC-offset removal for(data-dependent) superimposed training based channel estimation[J]. IEEE Transactions on Signal Processing, 2007, 55(6):2557-2569.
[26]	Wang Huiqin, Wang Yangang, Cao Minghua, et al. Impact of atmospheric visibility on laser intensity in sandy and dust weather[J]. Acta Photonica Sinica, 2015, 44(2):0229001. (in Chinese)王惠琴, 王彦刚, 曹明华, 等. 沙尘天气下大气能见度对激光光强的影响[J]. 光子学报, 2015, 44(2):0229001.

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通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

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Atmospheric optical communications channel estimation employing superimposed training sequence under sand-dust weather conditions

1. School of Computer and Communication,Lanzhou University of Technology,Lanzhou 730050,China

Received Date: 2019-04-10

Rev Recd Date: 2019-05-20

Publish Date: 2019-09-30

Key words:

Abstract: The inherent advantages of superimposed training method are restricted by superposition data information, power allocation, and direct current bias in channel estimation of atmospheric optical communications under sand-dust weather. A novel scheme was proposed to perform these issues, especially for the channel with sand-dust particles. In the proposal, the data-dependent superimposed training algorithm was utilized to mitigate the influence of data information, the correlation matching algorithm was utilized for direct current bias elimination, and the maximum output signal-to-noise ratio was utilized to perform the optimal power allocation factor. The performance of mean square error, power allocation factor, bit error rate and algorithm complexity were numerically evaluated. The results demonstrate that the proposed method has a better performance than conventional methods with a slightly increased computational complexity.

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Reference (26)

[1]	Yin Junyan, Yin Fuchang, Chen Ming, et al. Impact on laser transmission in atmosphere[J]. Infrared and Laser Engineering, 2008, 37(S):399-402. (in Chinese)阴俊燕, 尹福昌, 陈明, 等. 影响激光大气传输因素分析[J]. 红外与激光工程, 2008, 37(S):399-402.
[2]	Zheng Xiaojing, Zhang Jinghong. Characteristics of near-surface turbulence during a dust storm passing Minqin on March 19, 2010[J]. Chinese Sci Bull, 2010, 55(22):2235-2240. (in Chinese)郑晓静, 张静红. 2010年3月19日沙尘暴期间甘肃民勤地区近地表的湍流性质[J]. 科学通报, 2010, 55(22):2235-2240.
[3]	Yuksel H, Milner S, Davis C C. Aperture averaging for optimizing receiver design and system performance on free-space optical communication links[J]. Journal of Optical Networking, 2005, 4(8):462-475.
[4]	Tyson R K. Bit-error rate for free-space adaptive optics laser communications[J]. Journal of the Optical Society of America A Optics Image Science Vision, 2002, 19(4):753-758.
[5]	Li Fei, Lu Houbing. Optimization method for detection threshold of atmospheric optical communication under weak turbulence condition[J]. Infrared and Laser Engineering, 2016, 45(12):1211004. (in Chinese)李菲, 路后兵. 弱湍流条件下大气光通信的阈值优化方法[J]. 红外与激光工程, 2016, 45(12):1211004.
[6]	Niu Chaojun, Yu Shijie, Han Xiang'e. Analysis about effect of wavefront sensorless adaptive optics on optical communication[J]. Laser Optoelectronics Progress, 2015, 52(8):080102. (in Chinese)牛超君, 于诗杰, 韩香娥. 无波前探测自适应光学对光通信性能影响分析[J]. 激光与光电子学进展, 2015, 52(8):080102.
[7]	Zhou Jianguo, Hao Shiqi, Liu Jialin, et al. Interleaver design based on genetic algorithm in atmospheric optical communication[J]. Chinese Journal of Lasers, 2013, 40(6):0605004. (in Chinese)周建国, 郝士琦, 刘加林,等. 大气激光通信中基于遗传算法的交织器设计[J]. 中国激光, 2013, 40(6):0605004.
[8]	Wang J B, Jiao Y, Song X, et al. Optimal training sequences for indoor atmospheric optical communications[J]. Journal of Optics, 2012, 14(1):015401.
[9]	Zhou Chao. Research on optical communication adaptive digital equalization based on LMS algorithm[D]. Chengdu:University of Electronic Science and Technology of China, 2018. (in Chinese)周超. 基于LMS算法的光通信自适应数字均衡技术研究[D]. 成都:电子科技大学, 2018.
[10]	Kaushal H, Kumar V, Dutta A, et al. Experimental study on beam wander under varying atmospheric turbulence conditions[J]. IEEE Photonics Technology Letters, 2011, 23(22):1691-1693.
[11]	Mishra N, Sriram K D, Jha P K. Performance analysis of dual-hop optical wireless communication systems over k-distribution turbulence channel with pointing error[C]//AIP Conference Proceedings, 2017, 1849(1):1-8.
[12]	Gorshtein A, Levy O, Katz G, et al. Coherent compensation for 100G DP-QPSK with one sample per symbol based on antialiasing filtering and blind equalization MLSE[J]. IEEE Photonics Technology Letters, 2010, 22(16):1208-1210.
[13]	Gorshtein A, Levy O, Katz G, et al. Blind channel estimation for MLSE receiver in high speed optical communications:theory and ASIC implementation[J]. Optics Express, 2013, 21(19):21766-21789.
[14]	Zamani M, Chen C, Li C, et al. A blind channel estimation for 100+Gb/s optical IM-DD DMT over 100-km SMF in 1550nm[J]. IEEE Photonics Technology Letters, 2014, 26(19):1928-1931.
[15]	Wang J B, Jiao Y, Xie X X, et al. Complementary sequences-based channel estimation for diffuse atmospheric optical communications[J]. Optical Engineering, 2011, 50(7):075003.
[16]	Omomukuyo O, Chang D, Dobre O, et al. Ngatched, Robust frame and frequency synchronization based on alamouti coding for RGI-CO-OFDM[J]. IEEE Photonics Technology Letters, 2016, 28(24):2783-2786.
[17]	Wu D, Wang Z, Wang R, et al. Channel estimation for asymmetrically clipped optical orthogonal frequency division multiplexing optical atmospheric communications[J]. Iet Communications, 2012, 6(5):532-540.
[18]	Zhao H, Li M, Wang R, et al. Compressed sensing theory-based channel estimation for optical orthogonal frequency division multiplexing communication system[J]. Optics Communications, 2014, 326(5):94-99.
[19]	Zhu C, Pittal F, Finkenbusch M, et al. Overhead-free channel estimation using implicit training for polarization-multiplexed coherent optical systems[C]//Optical Fiber Communication Conference and Exposition and the National Fiber Optic Engineers Conference IEEE, 2013:1-3.
[20]	Chan K C, Huang W C, Li C P, et al. Elimination of data identification problem for data-dependent superimposed training[J]. IEEE Transactions on Signal Processing, 2015, 63(6):1595-1604.
[21]	Fan S, Li Y, Wang L, et al. Comparison of implicit training and implicit pilot in coherent optical transmission[C]//International Conference on Optical Internet IEEE, 2014:1-2.
[22]	Zhu Y J, Sun Z G, Zhang J, et al. Training receivers for repetition coded MISO outdoor visible light communications[J]. IEEE Transactions on Vehicular Technology, 2017, 66(1):529-540.
[23]	Dissanayake S D, Armstrong J. Novel techniques for combating DC offset in diversity combined ACO-OFDM[J]. IEEE Communications Letters, 2011, 15(11):1237-1239.
[24]	Liu T. A novel method for demodulation of ACO-OFDM in the presence of DC offset[J]. Journal of the Franklin Institute, 2015, 352(3):802-812.
[25]	Alameda-Hernandez E, Mclernon D C, Orozcolugo A G, et al. Frame/training sequence synchronization and DC-offset removal for(data-dependent) superimposed training based channel estimation[J]. IEEE Transactions on Signal Processing, 2007, 55(6):2557-2569.
[26]	Wang Huiqin, Wang Yangang, Cao Minghua, et al. Impact of atmospheric visibility on laser intensity in sandy and dust weather[J]. Acta Photonica Sinica, 2015, 44(2):0229001. (in Chinese)王惠琴, 王彦刚, 曹明华, 等. 沙尘天气下大气能见度对激光光强的影响[J]. 光子学报, 2015, 44(2):0229001.

Atmospheric optical communications channel estimation employing superimposed training sequence under sand-dust weather conditions

doi: 10.3788/IRLA201948.S218002

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