Visible Light Positioning: A Machine Learning Approach

计算机工程与设计 Pub Date : 2022-09-23 DOI:10.1109/SEEDA-CECNSM57760.2022.9932981

Vasileios P. Rekkas, S. Sotiroudis, D. Plets, W. Joseph, S. Goudos

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引用次数: 2

Abstract

Visible light positioning (VLP) systems have experienced substantial revolutionary progress over the past year because they can offer great positioning accuracy without needing any additional infrastructure, as conventional radio-frequency (RF)-based systems. Received signal strength (RSS)-based VLP systems are a promising approach to many indoor positioning estimation problems, but still suffer from difficulty in providing high accuracy and reliability. A potential solution to these challenges is to combine VLP systems, and machine learning (ML) approaches to enhance the position prediction accuracy in two-dimensional (2-D) spaces, or more complex problems. In this paper, we propose a ML approach to accurately predict the 2-D indoor position of a mobile receiver (eg. an automated guided vehicles-AGV), based on the measured RSS values of 4 photodiodes (PDs) forming a star architecture. We examine and evaluate the performance of different ML learners applied to the above-described problem. The proposed ML and Neural Network (NN) methods exhibit great accuracy results in predicting the 2-D coordinates of a PD-based receiver.

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可见光定位:一种机器学习方法

可见光定位(VLP)系统在过去一年中经历了重大的革命性进步，因为它们可以提供很高的定位精度，而不需要任何额外的基础设施，就像传统的射频(RF)系统一样。基于接收信号强度(RSS)的VLP系统是解决许多室内定位问题的一种很有前途的方法，但在提供高精度和可靠性方面仍然存在困难。应对这些挑战的一个潜在解决方案是将VLP系统和机器学习(ML)方法结合起来，以提高二维(2-D)空间或更复杂问题中的位置预测精度。在本文中，我们提出了一种机器学习方法来准确预测移动接收器的二维室内位置(例如。一种自动制导车辆(agv)，基于形成星形结构的4个光电二极管(pd)的测量RSS值。我们检查和评估应用于上述问题的不同ML学习器的性能。所提出的机器学习和神经网络(NN)方法在预测基于pd的接收器的二维坐标方面表现出很高的准确性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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计算机工程与设计

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20353

期刊介绍： Computer Engineering and Design is supervised by China Aerospace Science and Industry Corporation and sponsored by the 706th Institute of the Second Academy of China Aerospace Science and Industry Corporation. It was founded in 1980. The purpose of the journal is to disseminate new technologies and promote academic exchanges. Since its inception, it has adhered to the principle of combining depth and breadth, theory and application, and focused on reporting cutting-edge and hot computer technologies. The journal accepts academic papers with innovative and independent academic insights, including papers on fund projects, award-winning research papers, outstanding papers at academic conferences, doctoral and master's theses, etc.

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