The performance of an OFDM/OQAM system under phase noise is analyzed. The analysis helps to direct the design of low cost tuners through specifying the required phase noise characteristics. Discrete time formulation o...The performance of an OFDM/OQAM system under phase noise is analyzed. The analysis helps to direct the design of low cost tuners through specifying the required phase noise characteristics. Discrete time formulation of OFDM/OQAM is first derived with the square root raised cosine (SRRC) filter as the pulse-shaping filter. Then the effect of multiplicative phase noise is equivalently represented as additive white Gaussian noise (AWGN), the variance of which is given analytically. We can observe that the same result as OFDM/QAM system is derived. Lastly, all the analytical results are verified by the bit error rate (BER) degradation through Monte Carlo simulation.展开更多
部分传输序列(Partial Transmit Sequence,PTS)是降低正交频分复用(Orthogonal Frequency Division Multiplexing,OFDM)系统峰均比(Peak-to-Average Power Ratio,PAPR)的有效方法,但是PTS穷举法搜索最优解,使系统复杂度增加。针对这一...部分传输序列(Partial Transmit Sequence,PTS)是降低正交频分复用(Orthogonal Frequency Division Multiplexing,OFDM)系统峰均比(Peak-to-Average Power Ratio,PAPR)的有效方法,但是PTS穷举法搜索最优解,使系统复杂度增加。针对这一缺点进行改进,提出了基于离散粒子群优化的部分传输序列(Partial Transmit Sequence based on Discrete Particle Swarm Optimization,PTS-DPSO)方法,并将其应用到基于偏移正交幅度调制的滤波器组多载波系统(Filter Bank Multicarrier with Offset Quadrature Amplitude Modulation,FBMC/OQAM)中。PTS-DPSO利用离散粒子群优化搜寻最优解,避免了系统复杂度的增加。通过仿真验证,PTS-DPSO可以有效抑制FBMC/OQAM系统过高的PAPR且误码率低。展开更多
传统的正交频分复用/偏移正交幅度调制(OFDM/OQAM)系统波形自适应设计主要针对具有非指数型时延功率谱和非U型多普勒功率谱的信道模型对波形进行优化,而实际中,波形自适应设计会因不同的信道模型产生不同的信道匹配准则系数。结合地空...传统的正交频分复用/偏移正交幅度调制(OFDM/OQAM)系统波形自适应设计主要针对具有非指数型时延功率谱和非U型多普勒功率谱的信道模型对波形进行优化,而实际中,波形自适应设计会因不同的信道模型产生不同的信道匹配准则系数。结合地空信道模型和扩展高斯函数的特性,在传统基于信干噪比(SINR)优化的OFDM/OQAM系统波形自适应算法的基础上提出一种新的OFDM/OQAM系统波形自适应设计算法。该算法引入信道匹配系数β,通过信道匹配准则建立波形时频域间隔与信道最大多径时延、最大多普勒频移的关系,再结合传统SINR优化函数计算扩展因子参数,将参数反馈给发送端并调整发送端和接收端的滤波器达到波形自适应的目的。仿真结果表明,4QAM和16QAM调制下,信道匹配系数β的引入在系统误码性能上均有1. 0 d B以上的改善。展开更多
水声信道是一个时变的双扩散信道,不仅会引起传输信号的时频扩展,而且会造成严重的信息损失。由于滤波器组多载波/交错正交幅度调制(Filter Bank Based Multicarrier/Offset Quadrature Amplitude Modulation, FBMC/OQAM)系统可通过改...水声信道是一个时变的双扩散信道,不仅会引起传输信号的时频扩展,而且会造成严重的信息损失。由于滤波器组多载波/交错正交幅度调制(Filter Bank Based Multicarrier/Offset Quadrature Amplitude Modulation, FBMC/OQAM)系统可通过改变发送信号的成型脉冲来减小时频扩展带来的符号干扰和子载波干扰,因此更适合快速时变的水下声信道。为了降低现有成型脉冲设计算法的优化难度,提出了一种快速且易于实现的成型脉冲设计方法,该方法根据信道时频统计特性对扩展高斯函数(Extend Gaussian Function, EGF)进行了优化,实现了期望信号能量最大化,并在时域符号间加入适当的保护间隔,进一步增强了抗多途干扰的能力。仿真结果表明,无论在高频散信道还是在低频信道下,相比于其它成型脉冲算法,该算法在降低计算量的同时,改进了的FBMC/OQAM系统的传输性能,误码率降低了2~3 dB。展开更多
文摘The performance of an OFDM/OQAM system under phase noise is analyzed. The analysis helps to direct the design of low cost tuners through specifying the required phase noise characteristics. Discrete time formulation of OFDM/OQAM is first derived with the square root raised cosine (SRRC) filter as the pulse-shaping filter. Then the effect of multiplicative phase noise is equivalently represented as additive white Gaussian noise (AWGN), the variance of which is given analytically. We can observe that the same result as OFDM/QAM system is derived. Lastly, all the analytical results are verified by the bit error rate (BER) degradation through Monte Carlo simulation.
文摘部分传输序列(Partial Transmit Sequence,PTS)是降低正交频分复用(Orthogonal Frequency Division Multiplexing,OFDM)系统峰均比(Peak-to-Average Power Ratio,PAPR)的有效方法,但是PTS穷举法搜索最优解,使系统复杂度增加。针对这一缺点进行改进,提出了基于离散粒子群优化的部分传输序列(Partial Transmit Sequence based on Discrete Particle Swarm Optimization,PTS-DPSO)方法,并将其应用到基于偏移正交幅度调制的滤波器组多载波系统(Filter Bank Multicarrier with Offset Quadrature Amplitude Modulation,FBMC/OQAM)中。PTS-DPSO利用离散粒子群优化搜寻最优解,避免了系统复杂度的增加。通过仿真验证,PTS-DPSO可以有效抑制FBMC/OQAM系统过高的PAPR且误码率低。
文摘传统的正交频分复用/偏移正交幅度调制(OFDM/OQAM)系统波形自适应设计主要针对具有非指数型时延功率谱和非U型多普勒功率谱的信道模型对波形进行优化,而实际中,波形自适应设计会因不同的信道模型产生不同的信道匹配准则系数。结合地空信道模型和扩展高斯函数的特性,在传统基于信干噪比(SINR)优化的OFDM/OQAM系统波形自适应算法的基础上提出一种新的OFDM/OQAM系统波形自适应设计算法。该算法引入信道匹配系数β,通过信道匹配准则建立波形时频域间隔与信道最大多径时延、最大多普勒频移的关系,再结合传统SINR优化函数计算扩展因子参数,将参数反馈给发送端并调整发送端和接收端的滤波器达到波形自适应的目的。仿真结果表明,4QAM和16QAM调制下,信道匹配系数β的引入在系统误码性能上均有1. 0 d B以上的改善。
