Rakshak:用于监视和后勤操作的模块化无人地面车辆

Abhijit Gadekar , Sakshi Fulsundar , Prathamesh Deshmukh , Jaideep Aher , Kaajal Kataria , Dr. Vibha Patel , Dr. Shivprakash Barve
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引用次数: 1

摘要

在过去的十年里,移动机器人在商业和国防工业中的应用迅速增加。这些机器人是专门为执行特定任务而设计的,已被证明在人类存在可能存在问题的危险环境中特别有价值。然而,在灾难期间识别工人、士兵和紧急情况的危险区域并提供实时监控数据仍然是一项重大挑战。传统方法,如手动监视和绘制未知区域地图,耗时且容易出现人为错误。UGV能够实现防区外作战,从而降低或消除在苛刻和危险条件下的这些问题。本文讨论了Rakshak的设计和开发:一种模块化无人值守地面车辆,通过绘制未知区域和基于小有效载荷的后勤行动,作为360°实时监视的第一响应机制。UGV的远程操作是通过无线电传输的,这是一种可靠有效的通信方法。UGV的模块化设计允许灵活适应各种应用。数据采集和传输到移动应用程序是通过Wi-Fi通信实现的。
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Rakshak: A modular unmanned ground vehicle for surveillance and logistics operations

Over the past decade, the utilization of mobile robots in commercial and defense industries has rapidly increased. These robots are purpose-built to perform specific tasks and have proven to be particularly valuable in dangerous environments where human presence may be problematic. However, identifying hazardous areas for workers, soldiers, and emergen- cies during disasters and providing real-time surveillance data remain significant challenges. Conventional approaches, such as manual surveillance and mapping uncharted territories are time-consuming and susceptible to human error. UGVs enable standoff operations, which lowers or eliminates these problems in demanding, and hazardous conditions. This paper discusses the design and development of Rakshak: a modular UGV as a first response mechanism for 360° of real-time surveillance by mapping unknown areas and small- payload-based logistics operations. Teleoperation of the UGV is via radio transmission, a reliable and efficient method of communication. The modular design of the UGV allows for flexibility in adapting to various applications. Data acquisition and transfer to the mobile application are accomplished through Wi-Fi communication.

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