气候变化领域集成服务门户(CCPortal): Underwater Orbital Angular Momentum Optical Communications

CCPortal

DOI	10.3788/AOS231614
	Underwater Orbital Angular Momentum Optical Communications
	Wang Jian; Wang Zhongyang
发表日期	2024
ISSN	0253-2239
起始页码	44
结束页码	4
卷号	44 期号:4
英文摘要	Significance The ocean occupies more than 70% of the earth's surface, which has vast area and rich resources. Research and exploration of the ocean have never ended. Due to the complexity and variability of the underwater environment, the ocean has not yet been fully explored and utilized. Further exploration of the underwater environment plays an important role in climate change, oil and gas detection, disaster early-warning, biological research, and other fields. Underwater wireless communication ensures information transmission and interconnection between unmanned devices in the underwater environment during ocean exploration. As the demand for underwater data transmission increases, high-bandwidth and low-latency underwater communication has become a key technology for exploring and utilizing the ocean at a deeper level. Commonly used carriers for underwater wireless communications include sound waves, electromagnetic waves (e. g. radio frequencies), and light waves. Each of the three carriers has its own characteristics. Although sound waves, as a traditional underwater communication method, have the advantage of a wide transmission range and have been widely used, the problems of relatively narrow bandwidth and longer delay in the medium limit their applications. Electromagnetic waves are difficult to be widely used in underwater environments as they require complicated equipment and short transmission distances. As a new type of underwater communication technology, underwater wireless optical communication has gained widespread attention due to its advantages such as larger transmission bandwidth, better anti-interference ability, lower latency, and lower costs. Underwater wireless optical communication refers to an underwater communication system that uses light waves as the transmission carrier. In recent years, underwater wireless optical communication has made considerable progress in the transmission capacity through the expansion and utilization of multiple physical dimensions of light waves, such as wavelength, time, amplitude, phase, and polarization. However, there are challenges in further improving the transmission capacity. The exploration of the spatial dimension of light waves has become a feasible way for capacity scaling. Structured light refers to a special light field that exploits the spatial dimension by tailoring the spatial amplitude, phase, and polarization distribution of light waves to obtain the required characteristics. Especially, structured light with a spiral phase front carrying orbital angular momentum (OAM) has attracted interest in many applications such as optical manipulation, tweezers, sensors, metrology, microscopy, imaging, and quantum science. OAM-carrying structured light appears spatially as an annular intensity distribution due to phase singularity at the beam center. Since OAM-carrying structured light can accommodate multiple orthogonal spatial modes, it has important advantages in expanding the capacity of underwater wireless optical communication. We comprehensively reviewed the advances in underwater OAM optical communications. Progress We first introduced the development history of three types of underwater wireless communication technology, including underwater acoustic communication, underwater electromagnetic (radio frequency) communication, and underwater optical communication, and summarized their respective advantages and disadvantages. Then, we focused on underwater wireless optical communication using OAM modes, with their basic principle, generation, and measurement methods introduced. The research progress of underwater OAM mode wireless optical communication was comprehensively reviewed, including underwater OAM mode encoding and decoding communication, underwater OAM mode multiplexing communication, and underwater OAM mode broadcasting communication. Moreover, OAM mode optical communications involving air-water interface (water-air-water crossing air-water medium, total reflection by air-water interface) and fast auto-alignment assisted OAM mode optical communications were presented. In addition to the OAM mode, other underwater structured light (e.g. Bessel beam and Ince-Gaussian beam) communications were also introduced. Additionally, complex medium optical communications using OAM modes assisted by adaptive turbulence compensation and fast auto-alignment were presented. Conclusions and Prospects OAM mode exploits the spatial dimension of light waves, providing a new way for the sustainable capacity expansion of underwater wireless optical communication. The future development trend of underwater wireless optical communication is as follows. From the spatial mode point of view, more flexible and powerful spatial light manipulation, a large number of OAM modes, more general structured light accessing the full spatial dimension (spatial amplitude, spatial phase, and spatial polarization), and full use of multiple dimensions are highly desired. From the underwater communication point of view, complex channel modeling, high capacity, long distance, and high robustness are highly expected. Key devices [lasers, modulators, detectors, converters, and (de)multiplexers] and techniques (high speed, high power, high sensitivity, high efficiency, high scalability, and high integration) are of great importance. Meanwhile, from the perspective of future underwater wireless optical communication, on the one hand, it is expected to be combined with electromagnetic (e. g. RF) communication and acoustic communication. According to different application scenarios and different capacity and distance requirements, one or more suitable communication methods and their combinations can be selected. On the other hand, the integration of underwater wireless optical communication technology and underwater perception technology (i. e. integrated communication and perception) is also an important research direction in the future, which is of great significance for improving the development capacity of marine resources, developing the marine economy, protecting the marine ecological environment, and serving the strategy of becoming a powerful marine country.
英文关键词	optical communications; underwater wireless optical communications; orbital angular momentum; structured light; spatial dimension; light field manipulation
语种	英语
WOS研究方向	Optics
WOS类目	Optics
WOS记录号	WOS:001205291100001
来源期刊	ACTA OPTICA SINICA
文献类型	期刊论文
条目标识符	http://gcip.llas.ac.cn/handle/2XKMVOVA/306892
作者单位	Huazhong University of Science & Technology
推荐引用方式 GB/T 7714	Wang Jian,Wang Zhongyang. Underwater Orbital Angular Momentum Optical Communications[J],2024,44(4).
APA	Wang Jian,&Wang Zhongyang.(2024).Underwater Orbital Angular Momentum Optical Communications.ACTA OPTICA SINICA,44(4).
MLA	Wang Jian,et al."Underwater Orbital Angular Momentum Optical Communications".ACTA OPTICA SINICA 44.4(2024).