共查询到19条相似文献,搜索用时 359 毫秒
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提出了将具有比声学高达几倍的数据通信速率,良好的安全性和隐蔽性的光学无线通信技术应用于海军、海洋科学研究和水下工程等领域,实现高速率的水下无线通信技术实现海量数据的信息交换.基于生物光学特性的水下光学信道模型,建立了水下光学通信系统性能分析方法.并对基于发光二极管(LED)的水下光学无线通信系统进行了仿真,其结果表明所建立的方法可以进行各种海域水质环境的模拟,便于时水下光学无线通信系统性能进行预测评估,为水下光学无线通信系统的设计方案的评估提供了依据. 相似文献
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水声通信及组网的现状和展望 总被引:1,自引:0,他引:1
水声通信是海洋中无线信息传输的主要技术手段。水声通信技术在海洋环境监测、水下航行器/载人潜水器作业等方面有着广泛应用。同时,水声信道传输状态多变、海洋作业环境恶劣,对通信算法和设备可靠性有较高要求,水声通信及组网成为目前的研究热点。文中面向海洋环境监测领域,从水声通信物理层技术、网络技术及组网应用等方面进行介绍,并对未来技术趋势进行展望。 相似文献
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水下光通信具有高数据速率、低链路延迟等优势,但水体浑浊、对准困难等原因限制了其应用, 声通信则因具有互补性可被用于组成声、光混合通信系统。但考虑到声、光信号不同传播特性,常规上此类声、光混合通信系统均采用声、光用独立调制、解调的方式实现,造成较高的硬件系统开销。因此,提出了近程水下声光一体化高速通信方案,该方案采用 PPM 调制方式,基于同一套调制、解调模块以一体化的方式支持声、光 2 种通信链路,通过声、光 2 种通信模式的一体化实现,以更低的系统硬件实现复杂度提供具有更好的指向特性、水质、环境噪声适应性的近距高速链路。经水池实验验证:该系统在近程通信时,声、光通信链路均可实现 1 Mbps 数据速率的无误码通信。 相似文献
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面向海洋立体信息感知中长期环境监测、目标探测、区域预警、跨介质信息中继等领域对极浅海域空海信息链路的需求,考虑极浅海域信道恶劣、潮流复杂、环境噪声严重等困难,采用直接序列扩频结合差分二进制相移键控(DS-DBPSK)的水声调制解调技术,以波浪滑翔器为平台进行水声通信、无线系统设计与整合,构建面向极浅海域水下信息支持的波浪滑翔机跨介质通信链路,并在平均深度 12 m 的厦门港海域开展极浅海域跨介质通信实验,验证了所设计技术方案及系统的有效性。 相似文献
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介绍了一种DS/DBPSK调制解调技术方案,该方案采用了具有较强抗干扰、抗衰落和抗多径性能的扩频技术,并结合与信道适应性较好、不需载波恢复的差分相位调制技术,对浅海水声信道造成的干扰进行抑制.在此方法上,基于Visual C(VC)及PC平台设计了一个通用性好的软件水声调制解调系统,利用双缓冲邋和多线程技术机制实现算法实时处理,同时可通过串口通信提供上层应用接口.实验系统验证了扩频和差分调制技术在浅海水声通信中的性能,为水声组网提供了底层支持.海试实验结果表明了系统的有效性. 相似文献
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由于水下无线光通信(Underwater Wireless Optical Communication,UWOC)具有高速率、低延迟和高保密性等优势,成为了水下无线通信的潜在应用。针对 UWOC 系统的模型及研究现状进行了简要的总结,重点阐述了 UWOC 系统所用到的关键技术,包括光源的选择、调制编码、探测、信道建模等关键技术, 并介绍了一种 UWOC 系统的设计方案。最后针对实现水下长距离通信和高速率传输等问题,总结了 UWOC 未来的发展趋势及所面临的挑战,为 UWOC 将来的发展方向及实用化提供了参考。 相似文献
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《中国海洋大学学报(自然科学版)》2016,(2)
水下量子密钥分配可以为水下通信提供绝对安全的保密手段。本文采用蒙特卡洛方法,结合海水信道的光学性质和光子的量子特性模拟了光子在海水中的传输过程,研究其衰减和偏振特性,计算了接收到的光子数随接收端口径、视场角和传输距离的变化,从保真度的角度分析散射光的偏振变化情况,并结合背景光的影响分析了水下量子通信误码率。结果表明,水下量子通信理论上可以实现百米量级的安全通信。 相似文献
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随着世界各国海洋开发步伐的加快,对水下传感器网络、水下监视系统、水声预警网络的需求愈来愈迫切,海洋水声通信网络的研究成了世界范围内的研究热点.水声通信网研究面临的主要困难是:海洋声信道的长延时、可用频带有限、严重的时变多途影响、功耗限制、网络安全性等.在分析水下无线通信的特殊环境后,针对水声通信网的多址接入技术进行了研究,选择适合的传输方式及相关协议构建基于OFDM与CDMA技术结合的水下通信网多载波CDMA系统;在matlab上实现多载波CDMA技术的水声通信网络节点对节点的数据传送,并得出了该系统的仿真结果:在帧长一定的情况下,随着信噪比的增大,系统的误码率会减小.在信噪比一定的情况下,子载波数目的进一步增大不会带来系统误码率的改善反而会使系统复杂性增加,降低系统的平均吞吐量,因此子载波数的选择应该在系统复杂性和效率之间折衷考虑.当水声信道上的信噪比一定时,可以通过控制数据帧的长度和子载波的个数来实现较高的网络平均吞吐量. 相似文献
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Underwater acoustic communications (UAC) at the reverberation-limited range results in severely distorted information signals. Wide-band signals are subject to both intermodal and intramodal-type of dispersions. The underwater acoustic channel impulse response and the sidelobes strongly depend on the waveguide structure and the source and receiver positions. The motion and displacement from this position, as well as other environmental variabilities impose a real-time adaptivity for the receiver operation to keep track of the fluctuations. To increase the system's reliability and data rate, there is a need to employ adaptive equalizers and diversity techniques to improve the margins against noise, and intersymbol interference (ISI). Blind adaptive equalization (BAE) is the ideal adaptive compensation when operating point-to-multipoint networks, and centralized communication systems in general. Inherent optimum multiple resonant modes within the ocean acoustic waveguide can be exploited judiciously via a new proposed parallel data multicarrier modulation (MCM) scheme by sending data over the multiple subcarriers. MCM might eventually obviate equalization which introduces higher-order computational complexity to the receiver. The above modulation eliminates multipaths and allows operation at multiples of the single-carrier transmission rate. The system's immunity to distortions such as ISI, fast fades, and impulsive noises, is increased due to incorporation of symbol guard space. Direct comparisons with single carrier schemes (such as higher-order statistics (HOS)-based equalization) are of great interest, since the proposed new receiver configuration has low-complexity to provide a compact, portable and low-power practical acoustic modem. Finally, network topology issues are considered to determine optimum network architectures for underwater acoustic LANs. A central topology (CT) supported by BAE and MCM transmission is proposed 相似文献
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High-throughout multiple-access communication networks are being considered for use in underwater acoustic channels. Bandwidth limitations of underwater acoustic channels require receivers to process broad-band communications signals in the presence of several active users. To deal with the resulting multiple-access interference in addition to high intersymbol interference, the spatial variability of ocean multipath is exploited in a multichannel multiuser receiver. Two configurations of such a receiver, a centralized and a decentralized one, are presented in fully adaptive modes of operations. While greatly reducing intersymbol and multiple-access interference, spatial diversity implies high increase in adaptive multiuser receiver complexity. To reduce the complexity of the optimal multichannel combiner, spatial structure of multipath is exploited. The complexity of resulting adaptive decentralized multichannel multiuser receiver is reduced at almost no cost in performance. Comparison of proposed multichannel receivers in an experimental shallow water channel demonstrates superior performance of spatial signal combining. The use of multiple input channels is shown to provide high level of tolerance for the near-far effect in both centralized and decentralized receivers. Decentralized receiver with reduced-complexity combining is found to satisfy the performance/complexity trade-off required for practical receiver realization in shallow water networks 相似文献
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In this paper, we investigate the performance of adaptive modulation (AM) orthogonal frequency division multiplexing (OFDM) system in underwater acoustic (UWA) communications. The aim is to solve the problem of large feedback overhead for channel state information (CSI) in every subcarrier. A novel CSI feedback scheme is proposed based on the theory of compressed sensing (CS). We propose a feedback from the receiver that only feedback the sparse channel parameters. Additionally, prediction of the channel state is proposed every several symbols to realize the AM in practice. We describe a linear channel prediction algorithm which is used in adaptive transmission. This system has been tested in the real underwater acoustic channel. The linear channel prediction makes the AM transmission techniques more feasible for acoustic channel communications. The simulation and experiment show that significant improvements can be obtained both in bit error rate (BER) and throughput in the AM scheme compared with the fixed Quadrature Phase Shift Keying (QPSK) modulation scheme. Moreover, the performance with standard CS outperforms the Discrete Cosine Transform (DCT) method. 相似文献
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Milica Stojanovic Lee Freitag 《Oceanic Engineering, IEEE Journal of》2006,31(3):685-695
Direct-sequence (DS) code-division multiple access (CDMA) is considered for future wideband mobile underwater acoustic networks, where a typical configuration may include several autonomous underwater vehicles (AUVs) operating within a few kilometers of a central receiver. Two receivers that utilize multichannel (array) processing of asynchronous multiuser signals are proposed: the symbol decision feedback (SDF) receiver and the chip hypothesis feedback (CHF) receiver. Both receivers use a chip-resolution adaptive front end consisting of a many-to-few combiner and a bank of fractionally-spaced feedforward equalizers. In the SDF receiver, feedback equalization is implemented at symbol resolution, and receiver filters, including a decision-directed phase-locked loop, are adapted at the symbol rate. This limits its applicability to the channels whose time variation is slow compared to the symbol rate. In a wideband acoustic system, which transmits at maximal chip rate, the symbol rate is down-scaled by the spreading factor, and an inverse effect may occur by which increasing the spreading factor results in performance degradation. To eliminate this effect, feedback equalization, which is necessary for the majority of acoustic channels, is performed in the CHF receiver at chip resolution and receiver parameters are adjusted at the chip rate. At the price of increased computational complexity (there are as many adaptive filters as there are symbol values), this receiver provides improved performance for systems where time variation cannot be neglected with respect to the symbol rate [e.g., low probability of detection (LPD) acoustic systems]. Performance of the two receivers was demonstrated in a four-user scenario, using experimental data obtained over a 2-km shallow-water channel. At the chip rate of 19.2 kilochips per second (kc/s) with quaternary phase-shift keying (QPSK) modulation, excellent results were achieved at an aggregate data rate of up to 10 kb/s 相似文献
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A modulation technique for increasing the reliable data rate achievable by an underwater acoustic communication system is presented and demonstrated. The technique, termed spatial modulation, seeks to control the spatial distribution of signal energy such that the single physical ocean channel supports multiple parallel communication channels. Given a signal energy constraint, a communication architecture with access to parallel channels will have increased capacity and reliability as compared to one with access to a single channel. Results from two experiments demonstrate higher obtainable data rates and power throughput for a system employing spatial modulation than for one that does not. The demonstrated benefits were characterized by an equivalent SNR gain of over 5 dB in the first experiment. In the second experiment, using two element source and receiver arrays with apertures of 0.9 m, a coherently modulated signal was shown to offer nearly 50% greater capacity by using spatial modulation than by using temporal modulation alone. 相似文献
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High-speed phase coherent communications in the ocean channel are made difficult by the combined effects of large Doppler fluctuations and extended, time-varying multipath. In order to account for these effects, we consider a receiver which performs optimal phase synchronization and channel equalization jointly. Since the intersymbol interference in some underwater acoustic channels spans several tens of symbol intervals, making the optimal maximum-likelihood receiver unacceptably complex, we use a suboptimal, but low complexity, decision feedback equalizer. The mean squared error multiparameter optimization results in an adaptive algorithm which is a combination of recursive least squares and second-order digital phase and delay-locked loops. The use of a fractionally spaced equalizer eliminates the need for explicit symbol delay tracking. The proposed algorithm is applied to experimental data from three types of underwater acoustic channels: long-range deep water, long-range shallow water, and short-range shallow water channels. The modulation techniques used are 4- and 8-PSK. The results indicate the feasibility of achieving power-efficient communications in these channels and demonstrate the ability to coherently combine multiple arrivals, thus exploiting the diversity inherent in multipath propagation 相似文献
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《Oceanic Engineering, IEEE Journal of》2009,34(4):624-633
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Freitag L. Stojanovic M. Singh S. Johnson M. 《Oceanic Engineering, IEEE Journal of》2001,26(4):586-593
Multiuser underwater acoustic communication is one of the enabling technologies for the autonomous ocean-sampling network (AOSN). Multiuser communication allows vehicles, moorings, and bottom instruments to interact without human intervention to perform adaptive sampling tasks. In addition, multiuser communication may be used to send data from many autonomous users to one buoy with RF communications capability, which will then forward the information to shore. The two major signaling techniques for multiuser acoustic communication are phase-shift keying (PSK) direct-sequence spread-spectrum (DSSS) and frequency-shift keying (FSK) frequency-hopped spread-spectrum (FHSS). Selecting between these two techniques requires not only a study of their performance under multiuser conditions, but also an analysis of the impact of the underwater acoustic channel. In the case of DSSS, limitations in temporal coherence of the channel affect the maximum spreading factor, leading to situations that may be better suited to FHSS signals. Conversely, the multipath resolving properties of DSSS minimize the effects of frequency-selective fading that degrade the performance of FSK modulation. Two direct-sequence receivers potentially suitable for the underwater channel are presented. The first utilizes standard despreading followed by decision-directed gain and phase tracking. The second uses chip-rate adaptive filtering and phase tracking prior to despreading. Results from shallow water testing in two different scenarios are presented to illustrate the techniques and their performance 相似文献