Intelligent networking for autonomous internet of underwater things: from smart cities to a smart world

自主水下物联网的智能网络：从智慧城市到智能世界

• 批准号: RGPIN-2019-04558
• 负责人: Kaddoum, Georges
• 金额: $ 2.84万
• 依托单位: École de technologie supérieure
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=714981
• 关键词: Intelligent; networking; autonomous; internet; underwater

Underwater wireless communications (UWC) is attracting considerable attention due to the increased interaction of humans with the underwater world. This technology has a wide range of scientific, environmental, civil, and military applications, such as marine exploration, detection of man-made and natural environmental disasters, and submarine communications. With the recent industrial advancements in the internet of things (IoT) and its new branch, the internet of underwater things (IoUT), UWC has promising potentials and unprecedented applications. The extreme underwater conditions impose challenges on UWC. The technologies used for UWC include radio frequency (RF), optical, and acoustic. However, RF suffers from severe attenuation. Optical technology enjoys a wide bandwidth but operates in short range. Acoustic transmission can cover long range but with a limited bandwidth. With the increasing demand for UWC, many efforts have been made to address those limitations. In 2017, the NATO Centre of Maritime Research and Exploration has published the first standard for UWC. This protocol, JANUS, paves the way for a standardized IoUT. However, the latter is still in its early stages, with many venues for improvements. Our long-term objective is to design robust, autonomous, secured, and self-sustaining IoUT networks. The proposed network can accommodate numerous UWC devices of various applications and connection requirements. The developed network will be robust by providing reliable connections, even in turbulent underwater conditions. Novel learning algorithms will be designed, enabling self-organization and self-reconfiguration to maintain network autonomy. Additionally, security algorithms will be developed to immunize the network and make it resilient to the underwater conditions. Lastly, sustainability will be achieved through innovative energy harvesting solutions. To achieve the longer-term objectives, the program will undergo three parallel and integrated phases; each one has its own short-term objectives that tackle specific challenges of the UWC. The first phase will address network coverage and reliability. The second will focus on security. The last phase will ensure sustainability. The three bordering oceans and the 7% of the world's freshwater have a significant influence on Canada's people, flora, and fauna in many aspects, especially under the climate change. Designing efficient IoUT network will significantly facilitate the science, strategic planning, and the security of Canada. Additionally, this research is the first of its kind and will open new research directions for environmental, civil, and military applications. Several patents and high-impact journal and conference articles will be published. Moreover, the success of this program will enable innovation in industrial sectors, such as fish farming, IoUT prototyping and manufacturing of specialized autonomous underwater vehicles (UAV) equipped with UWC capabilities.

由于人类与水下世界互动的增加，水下无线通信（UWC）引起了广泛的关注。该技术具有广泛的科学、环境、民用和军事应用，例如海洋勘探、人为和自然环境灾害的探测以及海底通信。随着物联网 (IoT) 及其新分支水下物联网 (IoUT) 的最新工业进步，UWC 具有广阔的潜力和前所未有的应用。 极端的水下条件给UWC带来了挑战。 UWC 使用的技术包括射频 (RF)、光学和声学。然而，射频衰减严重。光学技术具有较宽的带宽，但工作范围较短。声波传输可以覆盖很远的距离，但带宽有限。随着对 UWC 的需求不断增加，人们做出了许多努力来解决这些限制。 2017年，北约海事研究与探索中心发布了首个UWC标准。这个协议 JANUS 为标准化 IoUT 铺平了道路。然而，后者仍处于早期阶段，还有许多需要改进的地方。 我们的长期目标是设计强大、自主、安全和自我维持的 IoUT 网络。所提出的网络可以容纳各种应用和连接要求的众多 UWC 设备。即使在湍急的水下条件下，开发的网络也将通过提供可靠的连接而变得强大。将设计新颖的学习算法，实现自组织和自重新配置，以保持网络自治。此外，还将开发安全算法来使网络免疫并使其适应水下条件。最后，可持续发展将通过创新的能量收集解决方案来实现。为了实现长期目标，该计划将经历三个并行且综合的阶段；每个项目都有自己的短期目标来应对 UWC 的具体挑战。第一阶段将解决网络覆盖范围和可靠性问题。第二个重点是安全。最后阶段将确保可持续性。 三个毗邻的海洋和占世界7%的淡水在许多方面对加拿大的人民、动植物产生了重大影响，特别是在气候变化的情况下。设计高效的物联网网络将极大地促进加拿大的科学、战略规划和安全。此外，这项研究在同类研究中尚属首次，将为环境、民用和军事应用开辟新的研究方向。将发表多项专利以及高影响力的期刊和会议文章。此外，该计划的成功将促进工业领域的创新，例如养鱼、物联网原型设计以及配备 UWC 功能的专用自主水下航行器 (UAV) 的制造。