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可见光通信中正交频分复用调制技术

徐宪莹,岳殿武

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徐宪莹, 岳殿武. 可见光通信中正交频分复用调制技术[J]. , 2021, 14(3): 516-527. doi: 10.37188/CO.2020-0051
引用本文: 徐宪莹, 岳殿武. 可见光通信中正交频分复用调制技术[J]. , 2021, 14(3): 516-527.doi:10.37188/CO.2020-0051
XU Xian-ying, YUE Dian-wu. Orthogonal frequency division multiplexing modulation techniques in visible light communication[J]. Chinese Optics, 2021, 14(3): 516-527. doi: 10.37188/CO.2020-0051
Citation: XU Xian-ying, YUE Dian-wu. Orthogonal frequency division multiplexing modulation techniques in visible light communication[J].Chinese Optics, 2021, 14(3): 516-527.doi:10.37188/CO.2020-0051

可见光通信中正交频分复用调制技术

doi:10.37188/CO.2020-0051
基金项目:国家自然科学基金(No. 61371091);大连海事大学研究生教育教学改革研究项目(No. YJG2019205)
详细信息
    作者简介:

    徐宪莹(1988—),女,山东莒县人,讲师,大连海事大学博士研究生,2011年、2014年于大连海事大学分别获得学士、硕士学位,主要从事可见光通信研究。E-mail:xuxianying@dlmu.edu.cn

    岳殿武(1966—),男,吉林四平人,博士,教授,博士生导师,1986年,1989年于南开大学分别获得学士、硕士学位,1996年于北京邮电大学获得博士学位,主要从事无线通信方面的研究。E-mail:dwyue@dlmu.edu.cn

  • 中图分类号:TN929.12

Orthogonal frequency division multiplexing modulation techniques in visible light communication

Funds:Supported by National Natural Science Foundation of China (No. 61371091); Research Project on Postgraduate Education and Teaching Reform of Dalian Maritime University (No. YJG2019205)
More Information
  • 摘要:可见光通信(VLC)由于可以弥补射频通信的不足而成为研究热点,正交频分复用(OFDM)技术因其高数据速率和抗频率选择性衰落被广泛应用在VLC中。本文从能量效率、频谱效率、误码率、计算复杂度等方面对可见光通信系统中OFDM调制技术进行研究和比较,主要包括基于离散傅立叶变换的单极性方案、改进或增强型方案和混合型方案,基于哈特莱变换的光OFDM,以及基于LED索引调制的光OFDM。文中介绍了多种光OFDM调制技术的工作原理综合对比了频谱效率等性能;研究了光OFDM系统接收机改进方案;总结了可见光OFDM系统存在的问题和未来研究方向。本文对可见光OFDM系统进行归纳和总结,为提出更加高效的单极化调制技术、进一步提高系统频谱效率及可靠性提供了参考。

  • 图 1基于离散傅立叶变换的光OFDM系统框图

    Figure 1.Block diagram of an optical OFDM system based on discrete Fourier transformation

    图 2光OFDM系统BER=10−3时光功耗与频带利用率的关系

    Figure 2.The relationship between optical power and spectral efficiency in the optical OFDM system underBER=10−3

    表 1典型单极性光OFDM调制原理对比

    Table 1.Comparison of modulation principles of typical optical OFDM

    典型单极性光OFDM 频域子载波设置 时域信号极性 单极化处理
    DCO-OFDM[10] $ {X}_{k}={X}_{N-k}^{\ast },0 双极性实数 添加直流偏置
    ACO-OFDM[11] ${{X} }=\left(0,{X}_{1},0,{X}_{3},\cdots,{X}_{\frac{N}{2}-1},0,{X}_{\frac{N}{2}-1}^{\ast },\cdots,{X}_{3}^{\ast },0,{X}_{1}^{\ast }\right)$ 双极性实数,具有特殊对称性:${x}_{n}=-{x}_{n+\frac{N}{2} }\left(0{\text{≤} } n < N/2\right)$ 负值限幅
    U-OFDM[12] $ {X}_{k}={X}_{N-k}^{\ast },0 双极性实数 极性编码
    Flip-OFDM[13] $ {X}_{k}={X}_{N-k}^{\ast },0 双极性实数 “正”、“负”模块分别传输
    PAM-DMT[14] $\begin{array}{l}{{X} }=(0,{\rm{j} }{X}_{\rm{PAM},1},{\rm{j} }{X}_{\rm{PAM,2} },\cdots,{\rm{j} }{X}_{ { {\rm{PAM} } },\frac{N}{2}-1},0,\\-{\rm{j} }{X}_{ {\rm{PAM} },\frac{N}{2}-1},\cdots,-{\rm{j} }{X}_{\rm{PAM},2},-{\rm{j} }{X}_{\rm{PAM},1})\end{array}$ 双极性实数,具有特殊对称性:${x}_{N-n}=-{x}_{n},1{\text{≤} } n{\text{≤} } \dfrac{N}{2}-1$ 负值限幅
    MACO-OFDM[15] ${{X} }=\left(0,{X}_{1},0,{X}_{3},\cdots,{X}_{\frac{N}{2}-1},0,{X}_{\frac{N}{2}-1 }^{\ast },\cdots,{X}_{3}^{\ast },0,{X}_{1}^{\ast }\right)$ 双极性实数具有特殊对称性:${x}_{n}=-{x}_{n+\frac{N}{2} }\left(0{\text{≤} } n < \dfrac{N}{2}\right)$ 极性编码
    下载: 导出CSV

    表 2光OFDM性能比较

    Table 2.Performance comparison of optical OFDM schemes

    光OFDM 频谱效率(bits·s−1·Hz−1 功率效率 接收机复杂度
    DCO-OFDM[10] $\displaystyle \frac{N-2}{2N}{\rm{log} }_{2}\; M$ $ O\left(N{\rm{log}}_{2}\; N\right)$
    ACO-OFDM[11] $\displaystyle \frac{1}{4}{\rm{log} }_{2}\; M$ $ O\left(N{\rm{log}}_{2}\; N\right)$
    U-OFDM[12] $\displaystyle \frac{N-2}{4N}{\rm{log} }_{2}\; M$ $ O\left(N{\rm{log}}_{2}\; N\right)$
    Flip-OFDM[13] $\displaystyle \frac{N-2}{4N}{\rm{log} }_{2}\; M$ $ O\left(N{\rm{log}}_{2}\; N\right)$
    PAM-DMT[14] $\displaystyle\frac{N-2}{2N}{\rm{log} }_{2}\; M$ $ O\left(N{\rm{log}}_{2}\; N\right)$
    MACO-OFDM[15] $\displaystyle\frac{1}{8}{\rm{log} }_{2}\; M$ $ O\left(N{\rm{log}}_{2}\; N\right)$
    eU-OFDM[16] $\left(1-\displaystyle\frac{1}{ {2}^{D} }\right)\displaystyle\frac{N-2}{2N}{\rm{log} }_{2}\; M$ $ {O}\left[\left(2D-1\right)\left(N{\rm{log}}_{2}\; N\right)\right]$
    GREENER-OFDM[32] $\displaystyle\frac{N-2}{4N}{\displaystyle \sum _{d=1}^{D}\displaystyle\frac{ {\rm{log} }_{2}\; {M}_{d} }{ {2}^{d-1} } }$ $ {O}\left[\left(2D-1\right)\left(N{\rm{log}}_{2}\; N\right)\right]$
    ePAM-DMT[33] $ {\displaystyle \sum _{d=1}^{D}\frac{\left(N-2d\right){\rm{log}}_{2}{M}_{d}}{{2}^{d}N}}$ ${O}\left({2\displaystyle \sum _{d=1}^{D}{N}_{d}{\rm{log} }_{2}{N}_{d} }-{N}_{D}{\rm{log} }_{2}{N}_{D}\right)$
    eACO-OFDM[34] $ {\displaystyle \sum _{d=1}^{D}\frac{{\rm{log}}_{2}{M}_{d}}{{2}^{d+1}}}$ ${ O }\left({\displaystyle \sum _{l=1}^{L}\displaystyle\frac{N}{ {2}^{l-2} } }{\rm{log} }_{2}\left(\displaystyle\frac{N}{ {2}^{l-1} }\right)-\displaystyle\frac{N}{ {2}^{L-1} }{\rm{log} }_{2}\left(\displaystyle\frac{N}{ {2}^{L-1} }\right)\right)$
    LACO-OFDM[17] $\left(\displaystyle\frac{1}{2}-\displaystyle\frac{1}{ {2}^{L+1} }\right){\rm{log} }_{2}\; M$ ${O}\left({\displaystyle \sum _{l=1}^{L}\displaystyle\frac{N}{ {2}^{l-2} } }{\rm{log} }_{2}\left(\displaystyle\frac{N}{ {2}^{l-1} }\right)-\displaystyle\frac{N}{ {2}^{L-1} }{\rm{log} }_{2}\left(\displaystyle\frac{N}{ {2}^{L-1} }\right)\right)$
    THO-OFDM[35] $\displaystyle\frac{1}{4}{\rm{log} }_{2}\; {M}_{\rm{ACO} }^{1}+\frac{1}{8}{\rm{log} }_{2}\; {M}_{\rm{ACO} }^{2}+\left(\frac{1}{8}-\frac{1}{N}\right){\rm{log} }_{2}\; {M}_{\rm{PAM} }$ $\begin{array}{l}{\rm{TD} }:{O}\left[N\left({\rm{log} }_{2}N+{\rm{log} }_{2}\left(\displaystyle\frac{N}{2}\right)\right)\right]\\ {\rm{FD} }:{O}\left[N\left(3{\rm{log} }_{2}N+{\rm{log} }_{2}\left(\displaystyle\frac{N}{2}\right)\right)\right]\end{array}$
    ADO-OFDM[18] $\displaystyle \frac{1}{4}{\rm{log} }_{2}\; {M}_{\rm{ACO} }+\left(\frac{1}{4}-\frac{1}{N}\right){\rm{log} }_{2}\; {M}_{\rm{DCO} }$ $ {O}\left(4N{\rm{log}}_{2}\; N\right)$
    HACO-OFDM[19] $\displaystyle \frac{1}{4}{\rm{log} }_{2}\; {M}_{\rm{ACO} }+\left(\frac{1}{4}-\frac{1}{N}\right){\rm{log} }_{2}\; {M}_{\rm{PAM} }$ $ {O}\left(3N{\rm{log}}_{2}\; N\right)$
    EHACO-OFDM[20] $\displaystyle\frac{1}{4}{\rm{log} }_{2}\; {M}_{\rm{ACO} }+\left(\frac{1}{4}-\frac{1}{N}\right)\left({\rm{log} }_{2}\; {M}_{\rm{DCO} }+{\rm{log} }_{2}\; {M}_{\rm{PAM} }\right)$ $ {O}\left(5N{\rm{log}}_{2}\; N\right)$
    AAO-OFDM[21] $\displaystyle\frac{1}{4}\left({\rm{log} }_{2}\; {M}_{\rm{AVO} }+{\rm{log} }_{2}\; {M}_{\rm{ACO} }\right)-\frac{1}{N}{\rm{log} }_{2}\; {M}_{\rm{AVO} }-\frac{1}{2}$ $ {O}\left(4N{\rm{log}}_{2}\; N\right)$
    PM-OFDM[22] $\displaystyle\frac{1}{4}{\rm{log} }_{2}\; M$ $ \begin{array}{l}{\rm{PM}}-1:{O}\left(N{\rm{log}}_{2}\; N\right)\\ {\rm{PM}}-2:{O}\left(9N{\rm{log}}_{2}\; N\right)\end{array}$
    P-OFDM[23] $\displaystyle \frac{1}{2}{\rm{log} }_{2}\; M$ $ O\left(N{\rm{log}}_{2}\; N\right)$
    下载: 导出CSV

    表 3基于FFT与FHT的光OFDM对比

    Table 3.Comparison of optical OFDM with FFT and FHT

    FFT-OFDM FHT-OFDM
    定义式 $\begin{array}{l}{\rm{FFT} }: X(k)={\displaystyle \sum _{n=0}^{N-1}x(n){\rm{exp} }\;\left(-{\rm{j} }\frac{2{\text{π} } nk}{N}\right)},0{\text{≤} } k{\text{≤} } N-1\\ {\rm{IFFT} }: x(n)={\displaystyle \sum _{k=0}^{N-1}X(k){\rm{exp} }\;\left({\rm{j} }\frac{2{\text{π} }nk}{N}\right)},0{\text{≤} } n{\text{≤} } N-1\end{array}$ $\begin{array}{l}{\rm{FHT} }: X(k)={\displaystyle \sum _{n=0}^{N-1}x(n)}{\rm{cas} }\;(2{\text{π} } kn/N),0{\text{≤} } k{\text{≤} } N-1\\ {\rm{IFHT} }:x(n)={\displaystyle \sum _{k=0}^{N-1}X(k)}{\rm{cas} }(2{\text{π} } kn/N),0{\text{≤} } n{\text{≤} } N-1\\{\rm{cas} }(2{\text{π} }kn/N)={\rm{cos} }(2{\text{π} }kn/N)+{\rm{sin} }(2{\text{π} }kn/N)\end{array}$
    调制方式 复星座(m-QAM) 实星座(BPSK,M-PAM)
    星座尺寸 m $ M=\sqrt{m}$
    厄米特对称 需要 不需要
    计算复杂度 有复数计算附加共轭运算 无复数计算无附加共轭运算
    有用载波 N/2 N
    下载: 导出CSV
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出版历程
  • 收稿日期:2020-03-30
  • 修回日期:2020-05-26
  • 网络出版日期:2021-04-17
  • 刊出日期:2021-05-01

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