Single Photon Detection Technology in Underwater Wireless Optical Communication:Modulation Modes and Error Correction Coding Analysis

This study explores the application of single photon detection(SPD)technology in underwater wireless optical communication(UWOC)and analyzes the influence of different modulation modes and error correction coding types on communication performance.The study investigates the impact of on-off keying(OOK)and 2-pulse-position modulation(2-PPM)on the bit error rate(BER)in single-channel intensity and polarization multiplexing.Furthermore,it compares the error correction performance of low-density parity check(LDPC)and Reed-Solomon(RS)codes across different error correction coding types.The effects of unscattered photon ratio and depolarization ratio on BER are also verified.Finally,a UWOC system based on SPD is constructed,achieving 14.58 Mbps with polarization OOK multiplexing modulation and 4.37 Mbps with polarization 2-PPM multiplexing modulation using LDPC code error correction.

A Study of Efficient Power Consumption Wireless Communication Techniques/ Modules for Internet of Things (IoT) Applications

A study of wireless technologies for IoT applications in terms of power consumption has been presented in this paper. The study focuses on the importance of using low power wireless techniques and modules in IoT applications by introducing a comparative between different low power wireless communication techniques such as ZigBee, Low Power Wi-Fi, 6LowPAN, LPWA and their modules to conserve power and longing the life for the IoT network sensors. The approach of the study is in term of protocol used and the particular module that achieve that protocol. The candidate protocols are classified according to the range of connectivity between sensor nodes. For short ranges connectivity the candidate protocols are ZigBee, 6LoWPAN and low power Wi-Fi. For long connectivity the candidate is LoRaWAN protocol. The results of the study demonstrate that the choice of module for each protocol plays a vital role in battery life due to the difference of power consumption for each module/protocol. So, the evaluation of protocols with each other depends on the module used.

Performance Analysis and Optimization of Energy Harvesting Modulation for Multi-User Integrated Data and Energy Transfer

Integrated data and energy transfer(IDET)enables the electromagnetic waves to transmit wireless energy at the same time of data delivery for lowpower devices.In this paper,an energy harvesting modulation(EHM)assisted multi-user IDET system is studied,where all the received signals at the users are exploited for energy harvesting without the degradation of wireless data transfer(WDT)performance.The joint IDET performance is then analysed theoretically by conceiving a practical time-dependent wireless channel.With the aid of the AO based algorithm,the average effective data rate among users are maximized by ensuring the BER and the wireless energy transfer(WET)performance.Simulation results validate and evaluate the IDET performance of the EHM assisted system,which also demonstrates that the optimal number of user clusters and IDET time slots should be allocated,in order to improve the WET and WDT performance.

Self-diagnosis method for faulty modules on wireless sensor node

In order to diagnose the working status of each module on sensor node and make sure the wireless sensor networks （WSN） work properly, the components of sensor node and their working characteristics are studied. An on-line fault self-diagnosis method for sensor node is proposed. First, a flexible fault sensing circuit is designed as a state detection module on sensor node. Second, a self- diagnosis algorithm is proposed based on the hardware design and the failure analysis on sensor node. Finally, in order to ensure the WSN reliability, the voltage changes of each module working statuses can be observed using the state detection module and the faulty module will be found out timely. The experimental results show that this self-diagnosis method is suitable to sensor nodes in WSN.

Research of the Wireless Management System for Solar Street Lamp Based on NanoLOC AVR Module

In order to improve the service life of solar street lamp, it is necessary to manage the lamp＇s battery in the form of on-line detection via wireless communanication. A wireless managonent systean for solar street lamp based on nanoLOC AVR nttlule is researched in this paper, the system can real-timely detect the solar street lamp＇s battery voltage, corrent, tonperature, internal resistance, residual capacity and so on. And the collected data is transmitted to computer＇ s management via wireless connnunication to achieve recording, storage, analysis and processing for various parameters.

Extending the Network Lifetime Using Optimized Energy Efficient Cross Layer Module (OEEXLM) in Wireless Sensor Networks

In wireless sensor network, the primary design is to save the energy consumption as much as possible while achieving the given task. Most of recent researches works have only focused on the individual layer issues and ignore the importance of inter working between different layers in a sensor network. In this paper, we use a cross-layer approach to propose an energy-efficient and extending the life time of the sensor network. This protocol which uses routing in the network layer, and the data scheduling in MAC layer. The main ob-jective of this paper is to provide a possible and flexible approach to solve the conflicts between the require-ments of large scale, long life-time, and multi-purpose wireless sensor networks. This OEEXLM module gives better performance compared to all other existing protocols. The performance of OEEXLM module compared with S-MAC and directed diffusion protocol.

Adaptive modulation in MIMO optical wireless communication systems

In the intensity modulation and direct detection （IM/DD） multiple-input multiple-output （MIMO） optical wireless communication systems, a direct-current-biased adaptive modulation scheme is proposed to guarantee the nonnegative property of transmitted signals, and the MIMO channel is converted to a parallel channel by using a singular value decomposition. Besides, a QR decomposition and successive interference cancellation based adaptive modulation scheme is proposed, and the MIMO channel can be simplified to a parallel channel under the bit error ratio （BER） target constraint. The power is optimally allocated to each sub-channel to maximize the data rate. Simulation results show that the proposed adaptive modulation schemes can effectively improve the transmission rate of the systems under the BER target and constant optical power constraints. The proposed adaptive modulation schemes make use of the multiplexing gain of the MIMO techniques, and can further improve the spectrum efficiency of optical wireless systems.

Feedback Stabilization over Wireless Network Using Adaptive Coded Modulation

In this paper,we apply adaptive coded modulation (ACM) schemes to a wireless networked control system (WNCS) to improve the energy efficiency and increase the data rate over a fading channel.To capture the characteristics of varying rate, interference,and routing in wireless transmission channels,the concepts of equivalent delay (ED) and networked condition index (NCI) are introduced.Also,the analytic lower and upper bounds of EDs are obtained.Furthermore,we model the WNCS as a multicontroller switched system (MSS) under consideration of EDs and loss index in the wireless transmission.Sufficient stability condition of the closed-loop WNCS and corresponding dynamic state feedback controllers are derived in terms of linear matrix inequality (LMI). Numerical results show the validity and advantage of our proposed control strategies.

Acoustic wireless communication based on parameter modulation and complex Lorenz chaotic systems with complex parameters and parametric attractors

As the competition for marine resources is increasingly fierce,the security of underwater acoustic communication has attracted a great deal of attention.The information and location of the communicating platform can be leaked during the traditional underwater acoustic communication technology.According to the unique advantages of chaos communication,we put forward a novel communication scheme using complex parameter modulation and the complex Lorenz system.Firstly,we design a feedback controller and parameter update laws in a complex-variable form with rigorous mathematical proofs(while many previous references on the real-variable form were only special cases in which the imaginary part was zero),which can be realized in practical engineering;then we design a new communication scheme employing parameter modulation.The main parameter spaces of the complex Lorenz system are discussed,then they are adopted in our communication scheme.We also find that there exist parametric attractors in the complex Lorenz system.We make numerical simulations in two channels for digital signals and the simulations verify our conclusions.

Simultaneous wireless information and power transfer with fixed and adaptive modulation

Activating Wireless Power Transfer (WPT) in Radio-Frequency (RF) to provide on-demand energy supply to widely deployed Internet of Everything devices is a key to the next-generation energy self-sustainable 6G network. However, Simultaneous Wireless Information and Power Transfer (SWIPT) in the same RF bands is challenging. The majority of previous studies compared SWIPT performance to Gaussian signaling with an infinite alphabet, which is impossible to implement in any realistic communication system. In contrast, we study the SWIPT system in a well-known Nakagami-m wireless fading channel using practical modulation techniques with finite alphabet. The attainable rate-energy-reliability tradeoff and the corresponding rationale are revealed for fixed modulation schemes. Furthermore, an adaptive modulation-based transceiver is provided for further expanding the attainable rate-energy-reliability region based on various SWIPT performances of different modulation schemes. The modulation switching thresholds and transmit power allocation at the SWIPT transmitter and the power splitting ratios at the SWIPT receiver are jointly optimized to maximize the attainable spectrum efficiency of wireless information transfer while satisfying the WPT requirement and the instantaneous and average BER constraints. Numerical results demonstrate the SWIPT performance of various fixed modulation schemes in different fading conditions. The advantage of the adaptive modulation-based SWIPT transceiver is validated.

Subcarrier Intensity Modulated Optical Wireless Communications:A Survey from Communication Theory Perspective

Subcarrier intensity modulation with direet detection is a modulatiou/detection technique tbr optical wireless communication systems, where a pre-modulated and properly biased radio frequency signal is modulated on the intensity of the optical carrier. The most important benefits of subcarrier intensity modulation are as follows： 1） it does not provide irreducible error floor like the conventional on-off keying intensity modulation with a fixed detection threshold; 2） it provides improved spectral efficiency and supports higher order modulation schemes; and 3） it has much less implementation complexity compared to coherent optical wireless communications with heterodyne or homodyne detection. In this paper, we present an up-to-date review of subcarrier intensity modulated optical wireless communication systems. We survey the error rate and outage performance of subcarrier intensity modulations in the atmospheric turbulence channels considering different modulation and coding schemes. We also explore different contemporary atmospheric turbulence fading mitigation solutions that can be employed for subcarrier intensity modulation. These solutions include diversity combining, adaptive transmission, relay assisted transmission, multiple-subcarrier intensity modulations, and optical orthogonal frequency division multiplexing. Moreover, we review the performance of subcarrier intensity modulations due to the pointing error and synchronization error.

通信激光器及其调制技术研究进展

在光通信领域,激光器及其调制带宽、调制速率对无线光通信至关重要。对半导体激光器信号的调制方式主要有内调制和外调制两种。这两种调制技术具有各自的特点,适用于光纤通信中的不同领域,都是当前重要的研究热点。内调制激光器又称为直接调制激光器,因其具有高速传输以及低成本的特点,成为目前应用在第五代移动通信技术(5G)前传和数据中心中的高性价比光源。而外调制激光器不存在光源附加的Chirp,所以可以有效地克服光纤色散造成的复合二次差拍(CSB)失真。文章在回顾通信激光器及其调制技术发展历程的基础上,介绍了西安理工大学在该领域所做的工作以及取得的主要进展。针对半导体激光器发生非线性失真的内外因素进行讨论,仿真响应特性各参数、线性化补偿方法以及功率控制系统对光发射器件输出光源的作用,并分析了温度的起伏对激光器和调制器件输出功率产生的影响。采用折射率椭球基本理论和数值分析,分别在纵向和横向调制下,讨论出射光强随温度的变化趋势。结果表明,纵向调制下出射光光强随温度的变化趋势只与铌酸锂(LN)晶体折射率的变化有关;横向调制下出射光光强随温度的变化趋势不仅要受到晶体折射率的影响,还要受到晶体尺寸及其膨胀系数的影响,因此可以利用特殊尺寸的晶体来提高电光调制器的温度稳定性。

基于LoRa通信的无线发射台信号智能监测技术研究

为实现大面积无线发射台信号覆盖监测,有效地抵御监测过程中多径干扰和频率选择性衰减等干扰因素的影响,研究基于LoRa通信的无线发射台信号智能监测技术。在无线发射台发出信号后,转换成数字信号进行对比,识别出有效发射台信号后,通过级联型LoRa组网方式以及LoRa通信技术,将数据发送到服务器中存储,实现无线发射台信号的传输。利用循环位移因子对基带产生的Chirp信号完成调频扩频调制,扩展信号频谱,增强信号抗干扰能力以及传输可靠性,增强信号监测的效果。实验结果表明:该方法能够在距离LoRa终端设备2.5 km处依旧接收到发射台信号,丢包率为12%,能够准确地监测到无线发射台是否存在发射信号。

串联补偿无线电能传输变换器载波通信研究

无线电能传输(WPT)负载电压、电流等状态信息需送到原边进行闭环控制和监控处理,副边到原边的通信至关重要。首先介绍了电容调制的WPT系统拓扑和工作原理,电容调制与否使得系统拓扑发生变化,未调制时原、副边拓扑为串/串(S/S)结构;调制时原、副边拓扑为串/串并(S/SP)结构。调制电容的投切形成两种状态来传递通信信息,且该状态变化可以反映到原边电流上。其次采用幅移键控(ASK)解调电路对原边电流处理即可还原通信信号,为提高解调精度和抗干扰能力,对ASK解调电路进行改进。最后通过仿真和实验验证了方案的有效性,实验结果表明,该系统在100 W的运行功率、2~5 kHz的通信频率下,可以精准完成副边到原边的通信。

轻载工况下基于效率优化的双向无线电能传输系统半桥调制策略

针对基于全桥拓扑的双向双LCC无线充电系统调制策略在轻载工况下功率因数和效率下降严重的问题,该文在不改变全桥结构的基础上,提出一种半桥调制策略。首先对双向双LCC补偿电路进行通态效率建模,并定量分析影响效率的关键变量及其约束条件,从而为调制策略的优化提供理论依据;在此基础上,对所提双边半桥调制策略的工作原理、正导通角优化关系及软开关实现条件进行详细分析,证明该策略在保证开关器件零电压导通的同时,可显著减小外移相角,从而有效提高系统的功率因数和运行效率;最后,搭建3.3 kW的双向无线电能传输系统样机进行对比实验,实验结果表明,所提半桥调制策略在1/4满载及以下的轻载工况下效率最高可达95.6%,且在输出电压宽范围变化时都能够取得明显的优化效果。

基于部分能量耦合线圈的无线能量与信号同步传输方法研究

针对无线电能传输系统中能量发送端与接收端进行全双工通信的需求,提出一种基于部分能量耦合线圈的无线能量与信号同步传输方法。利用能量耦合线圈的内侧和外侧部分线圈分别作为信号正反向传输耦合机构,并在信号接收回路中采用LC并联支路抑制同侧信号载波的串扰。通过构建系统模型,分析能量传输与信号传输的增益以及系统传输干扰,得到系统参数对传输特性影响规律。为提高信号传输增益以及减小信号正反向传输之间的串扰,优化了耦合机构线圈布置方案。最后,搭建了传输功率为20 W的无线能量与信号全双工同步传输平台,实验结果表明,在电能传输不受影响的同时,实现了正向传输速率200 kbps、反向传输速率400 kbps的信号全双工同步传输,验证了所提方法的可靠性和有效性。

多路无线温度检测系统设计与实现

无线温度检测系统在民用市场、工业场景等具有很强的实用价值。文章设计并实现基于单片机的多路无线温度检测系统,该系统包含上位机系统和下位机系统,两者的主控芯片都选用STC51单片机,无线通信采用ZigBee模块进行无线数据传送和接收。其中上位机系统主要包含有最小系统、ZigBee模块、LCD显示模块、LED超温报警模块和USB模块。下位机系统有多个节点,每个节点主要包含最小系统、ZigBee模块和DS18B20温度模块。通过硬件软件设计并实现平台的搭建,进行温度系统检测与调试。经测试,该系统能够通过无线形式实时采集并显示多路温度数据,具有超温报警功能,稳定性较好。

基于490 nm垂直外腔面发射激光器的长距离水下激光通信系统

水下无线光通信技术为深海勘探和海洋资源开发利用带来了一种效率高且可靠性强的通信新方案.本文采用490 nm垂直外腔面发射激光器作为光源,基于声光外调制技术,采用脉冲位置调制方式(pulseposition modulation,PPM)搭建了长距离水下无线光通信系统.结合光源的优势并经过软判决算法优化PPM解调来提升水下通信性能,采用64 PPM调制,成功实现了96 m的水下传输距离,在50 MHz时隙频率下得到传输的误码率为1.9×10^(-5).同时测量到采用软判决解调相较于硬判决解调在性能增益上有着大约2 dB的提升,验证了软判决算法在提升水下通信性能方面相比硬判决算法的显著优势.

面向6G的高速太赫兹无线通信系统与关键技术验证

太赫兹通信以其可提供更高速、更大容量和更安全的数据传输的独特优势,在未来6G中成为重要的关键技术之一。基于固态电子的太赫兹通信系统存在带宽受限、频谱响应不平坦等问题,需要先进的信号形式结合灵活高效的处理方法来提升系统性能。搭建了基于固态电子的G波段太赫兹无线通信系统,通过采用比特-功率加载的离散多音(Bit and Power Loading-Discrete Multitone, BPL-DM)调制技术,实现了对系统频谱资源的有效利用;通过对通信速率的灵活调整、自适应削波和基于三阶多项式的后均衡技术,解决了峰值功率约束带来的挑战,提升了整体传输性能,实现了在195 GHz中心频率下,单通道130 Gbit/s的通信线路速率。基于以上技术,为进一步提升系统容量,搭建了4×4的多输入多输出(Multiple-Input Multiple-Output, MIMO)太赫兹通信系统,总线路速率超过399 Gbit/s。