同信道干扰下RIS辅助FSO-RF混构系统性能分析

针对自由空间光（FSO）通信无法进行视距传输的问题,在FSO链路中引入可重构智能表面（RIS）技术,并考虑射频（RF）链路中的同信道干扰（CCI）信号,提出一种CCI下RIS辅助FSO-RF混构系统研究方案。其中FSO链路和RF链路分别服从Gamma-Gamma分布和Rayleigh分布,在光电转换中继节点处采用译码转发协议,以减少噪声对信号的干扰。基于系统端到端瞬时信噪比的概率密度函数,推导了系统中断概率和平均误码率的闭合表达式,采用蒙特卡罗仿真验证了结果的准确性。研究结果表明,相较于传统的混合FSO/RF系统,RIS能明显提升系统的性能。另外,根据系统的分集顺序,得出系统的性能主要与FSO链路的衰落参数、光检测方式和指向误差有关。     

2x2中继混合射频/自由空间光航空通信系统性能分析

基于解码转发中继方式,研究了2×2中继条件下混合射频/自由空间光(RF/FSO)航空通信系统的性能。建立了2×2中继混合RF/FSO通信系统模型,利用Meijer’s G函数推导出该系统信噪比的概率分布函数及累积分布函数,并推导了该系统平均误码率(BER)和中断概率的闭合表达式。仿真分析了大气湍流强度、孔径尺寸和调制方式对平均BER和中断概率的影响。结果表明,孔径平均效应可有效改善混合RF/FSO航空通信系统的性能,2×2中继通信系统性能明显优于1×1中继通信系统。     

采用QPSK调制的50 Gbit/s高速大气激光通信传输特性研究

高级多电平调制格式在海上高速和高光谱效率的光通信中已经显示出巨大的潜力。将正交相移键控(QPSK)调制格式引入自由空间光(FSO)通信,实验证明可实现高达50 Gbit/s的高速FSO传输链路,能够清楚地观察到所发送的QPSK信号的眼图和星座图。通过比较传输之前和之后的误码率曲线,可以发现接收灵敏度都小于-36.7 dBm。当误码率为3.8×10-3时,它们的功率损失都小于4.2 dB。     

基于空间分集的高空平台光链路性能研究

针对高空平台不稳定性以及大气湍流对平台光通信性能的影响,提出利用空间分集技术改善高空平台光通信链路性能。在系统采用开关键控(OOK)调制条件下,利用矩母函数特性分别得到采用协作分集技术和多输入多输出(MIMO)技术的高空平台光链路误码率表达式,并求解协作通信系统中继平台的最优位置。仿真结果表明:协作分集技术与光MIMO技术对高空平台光链路性能的改善效果受到跟瞄误差的限制。采用发射选择分集的光MIMO技术对光链路的误码率性能最好。与采用重复码的MIMO方法相比,协作分集技术更适用于跟瞄误差大的通信系统。中继平台的最优位置与中继策略以及跟瞄误差无关。在中继平台最优位置附近,采用协作分集的光链路性能优于采用重复码MIMO光通信链路。     

月地光通信的链路设计(英文)

光通信技术可以满足未来深空探测对较大带宽的需求,因此光通信技术具有很好的应用前景.本文主要对月地光通信的链路进行了设计,从而实现月地通信链路中数据的大容量传输.首先,文中对月地光通信系统链路中主要参数设计进行仿真分析,主要包括信号光的接收功率、链路容量,以及收发天线增益和信息空间损耗的近似计算.另外还对脉冲位置调制下的信息传输效率和带宽利用率进行了仿真分析.结果表明,收发天线的直径和信息帧的时隙数对通信的影响较大,在通信的过程中需要对其进行优化设计,并且光源波长的选择也要合理.因此,本文的研究对实际的月地光通信链路设计具有一定的理论指导意义.     

无线激光通信协议的设计

研究了无线激光通信（FSO）与传统激光通信的区别,编制了一套FSO物理层收发协议。采用现场可编程门阵列（FPGA）完成收发机与外部电路的数据通信,利用先入先出（FIFO）存储器完成收发协议与外部系统的接口。设计的物理层收发协议主要完成发送数据的编码、串行化以及接收数据的解串行化和解码。仿真实验结果表明：设计的收发协议可实现在40 Mbps通信速率下的稳定工作,证明了该收发协议设计的可行性。     

无线激光通信协议的设计(英文)

研究了无线激光通信(FSO)与传统激光通信的区别,编制了一套FSO物理层收发协议。采用现场可编程门阵列(FPGA)完成收发机与外部电路的数据通信,利用先入先出(FIFO)存储器完成收发协议与外部系统的接口。设计的物理层收发协议主要完成发送数据的编码、串行化以及接收数据的解串行化和解码。仿真实验结果表明:设计的收发协议可实现在40 Mbps通信速率下的稳定工作,证明了该收发协议设计的可行性。     

航空超短波通信链路余量分析系统设计

为分析飞行器位置、姿态和工作频率对航空超短波通信链路性能的影响,构建了航空超短波通信链路模型,利用FEKO7.0电磁仿真软件计算了机载天线与飞行器一体化电磁辐射特性,基于MATLAB软件设计了系统的主程序,系统主程序通过调用天线的辐射特性数据,结合飞行器的位置、速度和姿态变化,可计算出通信双方之间的天线极化衰减和空间衰减等数据,分析了飞行器在相应状态下航空超短波通信链路性能的数值变化,具有较强的实用性。     

激光星间链路终端技术发展与展望北大核心CSCD

激光星间链路主要用于卫星之间高速数传,是构建天基信息网络的关键技术。目前国外通信、遥感、导航和中继等卫星系统都已计划部署激光通信终端,激光星间链路技术已从在轨演示验证向大规模组网应用阶段发展。简要梳理了国际上现有组网卫星系统的激光星间链路终端技术发展情况,对激光星间链路的技术体制和终端分类进行了总结;侧重分析了我国激光星间链路终端技术发展现状及大规模应用面临的主要问题,针对重难点技术的解决途径进行了思考;对激光星间链路终端未来的发展趋势做了展望,尤其是轻小型化设计与实现、宽带化、一对多光学天线和网络化等技术发展趋势进行了分析。     

星地微波光传输链路分析

根据星地大容量通信发展需求,研究了基于微波空间光传输技术的星地激光通信链路。在建立星地微波光传输链路模型的基础上,分析了链路光功率衰减、输出微波信号、噪声功率以及在大气湍流信道下系统的误码率。仿真分析了调制器直流偏置电压大小对链路输出信噪比和误码率的影响,结果表明,相对于通常的正交偏置工作点,通过优化控制直流偏置点的位置,可以提高链路输出信噪比和误码率,这种改善程度随着调制系数的减小而增大。该研究为建立星地微波光传输系统提供了有益参考。     

A cost effective 100 Gbps hybrid MDM–OCDMA–FSO transmission system under atmospheric turbulences

FSO or free space optics is a familiar name used in a wide array of applications in the area of telecommunications. Due to its features of low maintenance cost and deployment time, most of the applications consider FSO as the alternative solution for appropriately replacing fiber optics. In this work, we have designed 100 Gbps FSO system by combining mode division multiplexing (MDM) and optical code multiple access scheme (OCDMA). Ten channels, each carrying 10 Gbps data, are transported over 8 km FSO link by using MDM of two Laguerre Gaussian modes and random diagonal codes. Moreover, the performance of proposed MDM–OCDMA–FSO system is also investigated under atmospheric turbulences.     

Enhancement of free space optical link in heavy rain attenuation using multiple beam concept

Free space optics (FSO) has attracted a lot of attention for a variety of applications in telecommunications area, and it is dream of every researcher and telecommunication society to make it a real alternative solution for the last mile problem, to replace fiber optics. FSO is much preferred because of its low maintenance cost and deployment time. FSO with single-beam system is vulnerable to atmospheric attenuation, so to overcome this, a multiple-beam FSO transceiver system has become prominent and is usually used. In this paper, average rain attenuation is evaluated from the collected rain intensity data which are collected for a period of seven months, and implemented in the study concerning results relating link distance, and received optical power of using multiple-beam FSO system in tropical rainy weather. Comparison is made in terms of received optical power, geometrical losses, atmospheric losses, and bit error rate (BER) on using different number of optical beams, based on simulation at data rate of 1 Gb/s. From the results it is clear that the quality of received power is improved by using up to four beams, along with link distance up to 1141.2 m as compared to one-beam, two-beam, and three-beam, with link distances 833.3 m, 991.0 m, 1075.4 m, respectively.     

Performance analysis of an 80 (8 × 10) Gbps RZ-DPSK based WDM-FSO system under combined effects of various weather conditions and atmospheric turbulence induced fading employing Gamma–Gamma fading model

Free space optics (FSO) has the capacity to be a vital element for the design of ubiquitous and reliable systems for next-generation networks owing to its large bandwidth and high data rate support. The last-mile issue finds an efficient solution in FSO in scenarios where fiber deployment is not feasible. However the FSO link is prone to fluctuations in optical signal strength due to various weather conditions and atmospheric turbulence. In this paper, an 80 (8 × 10) Gbps RZ-DPSK based WDM-FSO system is analyzed based on its performance on weather conditions viz. very clear, drizzle, haze, thin fog, moderate fog and thick fog. Link-margin analysis is also done. The turbulence model employed is the Gamma–Gamma fading model. The system is simulated on OptiSystem 14.0.     

Performance comparison of various modulation schemes over free space optical (FSO) link employing Gamma–Gamma fading model

Free Space Optics (FSO) is an emerging line-of-sight technology intending to provide last-mile solution to the network problem where fiber technology is not feasible. The use of Wavelength Division Multiplexing (WDM) technology for FSO is inspired due to the demand for broadband communication. This technique has brought a revolution because the system data capacity is enhanced by simply adding more number of channels and reducing the channel spacing without having the need of more than one FSO link. By reducing the channel spacing to an appropriate level, Dense Wavelength Division Multiplexing (DWDM) based FSO systems are also be attained and are reported by various research works. FSO finds applications in vast areas like backhaul networks for cellular communication, disaster recovery, LAN–LAN connectivity, high-definition TV, MAN-extension, video transmission, medicine industry and surveillance. However, its usage is limited due to the serious challenges of link vulnerability to weather and atmospheric turbulence-induced fading. This paper is based on a WDM-FSO system. An 8-channel WDM based FSO system is proposed and performance is evaluated on widely accepted modulation schemes under weak, moderate and strong turbulence conditions. Gamma–Gamma fading model is employed for atmospheric turbulence modelling. The system is simulated on OptiSystem 14.0.     

Analysis of free space optical link in turbulent atmosphere

Free space optical (FSO) communication is an upgraded supplement to the existing wireless technologies. FSO technology provides vast modulation bandwidth, unlicensed spectrum, cost effective deployment, low power consumption and less mass requirement. Today, researchers are preliminary focused to use the free space communication systems for inter satellites links. In this paper, the performance analysis of FSO communication link in weak atmospheric turbulence has been analyzed for different atmospheric transmission windows using OOK modulation. The analysis has been done using bit error rate as the performance metric. The effect of attenuation on the link performance has been investigated by varying distance between transmitter and receiver for a given power and data rate. Further, BER performance analysis has been carried out for varying data rate and transmitted power. Also, the effect of attenuation on received optical power has been studied. The work has been performed in OptSim environment.     

Modeling of 2.5 Gbps-intersatellite link (ISL) in inter-satellite optical wireless communication (IsOWC) system

Free-space optics (FSO) has the combined features of most dominated telecommunication technologies: wireless and fiber optics. Many of the aspects of FSO are related to fiber optics with an important difference of transmission medium which is air/free space rather than the glass of the fiber-optic cable. Inter-satellite optical wireless communication systems (IsOWC), one of the important applications of FSO/WSO technology, will be deployed in space in the near future as such systems provide a high bandwidth, small size, light weight, low power and low cost alternative to present microwave satellite systems. In this paper, we have designed a model of IsOWC system using OPTI-SYSTEM™ simulator to establish an inter-satellite link (ISL) between two satellites estranged by a distance of 1000 km at data rate of 2.5 Gbps which is not reported in previous investigated works.     

High speed,long reach OFDM-FSO transmission link incorporating OSSB and OTSB schemes

Free Space Optics (FSO) link is extremely responsive to the diverse climate state of affairs that bound the FSO range. A demonstration of fading resistant FSO system using a simulated test-bed employing OFDM scheme is reported in this work to realize the prolonged FSO link with acceptable SNR and BER with the highest stream rate of 5 Gb ps under the impact of diverse weather conditions. Simulations point toward that the proposed hybrid OFDM-FSO transmission system incorporating OTSB- and OSSB-schemes promises significantly enhanced FSO link compared to conventional FSO systems.     

BER analysis of DPSK–SIM over MIMO free space optical links with misalignment

Free-space optics (FSO) is a safe, license-free, high speed and high-bandwidth cordless technique for broadcasting signals at the same speed as fiber optics. But the main drawback of FSO is the dissolution of the signals due to atmospheric turbulence and thus degrading the link performance. So, to enhance the bit error rate (BER) performance, spatial diversity is employed over the FSO links for single-input multiple-output FSO (SIMO-FSO) systems. In this paper, we analyze the BER performance of SIMO-FSO links with spatial diversity and multiple-input multiple-output FSO (MIMO-FSO) systems over gamma–gamma atmospheric turbulence fading channel with misalignment (pointing errors). The closed form expressions are derived for the same with various combining schemes in terms of the Meijer G function and also evaluate the results with 2D and 3D graphs.     

Millimeter-wave enabled PAM-4 data transmission over hybrid FSO-MMPOF link for access networks

Optical Review - In this paper, we propose a full duplex architecture based on a hybrid link composed of free space optics (FSO) and multimode plastic optical fiber (MMPOF) for short-range wireless...     

Optimization of free space optics parameters: An optimum solution for bad weather conditions

Free Space Optics Systems (FSO) is one of the most effective solutions, especially for atmospheric turbulence due to the weather and environment structure. Free space optics system suffers from various limitations. A well-known disadvantage of FSO is its sensitivity on local weather conditions-primarily to haze and rain, resulting in substantial loss of optical signal power over the communication path. The main objective of this article is to evaluate the quality of data transmission using Wavelength Division Multiplexing (WDM) with highlighting several factors that will affect the quality of data transmission. The results of these analyses are to develop a system of quality-free space optics for a high data rate transmission. From the result analysis, FSO wavelength with 1550 nm produces less effect in atmospheric attenuation. Short link range between the transmitter and receiver can optimize the FSO system transmission parameters or components. Based on the analysis, it is recommended to develop an FSO system of 2.5 Gbps with 1550 nm wavelength and link range up to 150 km at the clear weather condition of bit-error-rate (BER) 10⁻⁹.