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借助群体自主海洋船舶上的传感器网络和分布式账本技术实现可靠的环境监测。

Trustable Environmental Monitoring by Means of Sensors Networks on Swarming Autonomous Marine Vessels and Distributed Ledger Technology.

作者信息

Berman Ivan, Zereik Enrica, Kapitonov Aleksandr, Bonsignorio Fabio, Khassanov Alisher, Oripova Aziza, Lonshakov Sergei, Bulatov Vitaly

机构信息

Faculty of Control Systems and Robotics, ITMO University, Saint Petersburg, Russia.

Institute of Marine Engineering, Italian National Research Council, Genova, Italy.

出版信息

Front Robot AI. 2020 May 28;7:70. doi: 10.3389/frobt.2020.00070. eCollection 2020.

DOI:10.3389/frobt.2020.00070
PMID:33501237
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7805745/
Abstract

The article describes a highly trustable environmental monitoring system employing a small scalable swarm of small-sized marine vessels equipped with compact sensors and intended for the monitoring of water resources and infrastructures. The technological foundation of the process which guarantees that any third party can not alter the samples taken by the robot swarm is based on the Robonomics platform. This platform provides encrypted decentralized technologies based on distributed ledger tools, and market mechanisms for organizing the work of heterogeneous multi-vendor cyber-physical systems when automated economical transactions are needed. A small swarm of robots follows the autonomous ship, which is in charge of maintaining the secure transactions. The swarm implements a version of Reynolds' Boids model based on the Belief Space Planning approach. The main contributions of our work consist of: (1) the deployment of a secure sample certification and logging platform based on the blockchain with a small-sized swarm of autonomous vessels performing maneuvers to measure chemical parameters of water in automatic mode; (2) the coordination of a leader-follower framework for the small platoon of robots by means of a Reynolds' Boids model based on a Belief Space Planning approach. In addition, the article describes the process of measuring the chemical parameters of water by using sensors located on the vessels. Both technology testing on experimental vessel and environmental measurements are detailed. The results have been obtained through real world experiments of an autonomous vessel, which was integrated as the "leader" into a mixed reality simulation of a swarm of simulated smaller vessels.The design of the experimental vessel physically deployed in the Volga river to demonstrate the practical viability of the proposed methods is shortly described.

摘要

本文介绍了一种高度可靠的环境监测系统,该系统采用一小群小型海洋船只,这些船只配备了紧凑型传感器,用于监测水资源和基础设施。该过程的技术基础基于Robonomics平台,可确保任何第三方都无法更改机器人集群采集的样本。该平台提供基于分布式账本工具的加密去中心化技术,以及在需要自动经济交易时组织异构多供应商网络物理系统工作的市场机制。一小群机器人跟随自主船舶,自主船舶负责维护安全交易。该集群基于信念空间规划方法实现了雷诺兹的Boids模型的一个版本。我们工作的主要贡献包括:(1)基于区块链部署一个安全的样本认证和记录平台,由一小群自主船只以自动模式执行测量水化学参数的操作;(2)通过基于信念空间规划方法的雷诺兹Boids模型协调一小队机器人的领导者-跟随者框架。此外,本文还描述了利用船上传感器测量水化学参数的过程。详细介绍了在实验船上进行的技术测试和环境测量。这些结果是通过一艘自主船舶的实际实验获得的,该自主船舶作为“领导者”被集成到一群模拟较小船只的混合现实模拟中。简要描述了实际部署在伏尔加河上以证明所提方法实际可行性的实验船的设计。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dc3d/7805745/709f8d2e4eee/frobt-07-00070-g0014.jpg
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