Indoor mobile robot localization using KNN

2016 6th IEEE International Conference on Control System, Computing and Engineering (ICCSCE) Pub Date : 2016-01-01 DOI:10.1109/ICCSCE.2016.7893573

B. Ilias, S. Shukor, A. H. Adom, N. Rahim, Mohd Firdaus Ibrahim, S. Yaacob

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引用次数: 3

Abstract

This paper describes the usage of sixteen piece 40 kHz ultrasonic sensors, known as Ultrasonic Sensor Bank (USB-16) mounted on a mobile robot platform. The Homogeneous Transformation Matrix (HTM) and trigonometric algorithm is utilized in this research as a wall mapping algorithm. The walls were designed with four types of basic shapes such as rectangle, triangle, curved and square, which are rarely tested by researchers in real time. Mapping and localization within real laboratory environment was also conducted. In this research, the USB-16 sensor bank transmitted ultrasonic signals in frequency waveform to the wall; the reflected signal was then filtered by a Nominal Wall Angle (NWA) algorithm to optimize the accuracy of the measured data. The purpose of this research is to determine the capability of USB-16 in not only providing an accurate map, but also its capability to recognize shapes and localization during mapping based on the size of walls. Next, NWA and KNN algorithm were applied in this experiment to study the accuracy of localization algorithm. This experiment had been carried out with two types of data sets, distance and coordinates. With the combination of these algorithms, the system can improve the accuracy of localization from 80% to 90% for basic wall shape and 78% for real laboratory environment. Basic Stamp, Basic Atom, LabVIEW and MATLAB software were fully utilized in the Self Localization and Mapping problem.

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基于KNN的室内移动机器人定位

本文介绍了安装在移动机器人平台上的16片40 kHz超声波传感器的使用方法，称为超声波传感器组(USB-16)。本文采用齐次变换矩阵(HTM)和三角算法作为墙体映射算法。墙体设计有矩形、三角形、弧形和方形四种基本形状，研究人员很少对这些基本形状进行实时测试。在真实的实验室环境中进行了绘图和定位。在本研究中，USB-16传感器组将超声信号以频率波形的形式传输到墙体;然后通过标称壁角(NWA)算法对反射信号进行滤波，以优化测量数据的精度。本研究的目的是确定USB-16不仅能够提供准确的地图，而且能够在基于墙壁尺寸的测绘过程中识别形状和定位。接下来，本实验将NWA和KNN算法应用于定位算法的精度研究。这个实验是用两种类型的数据集进行的:距离和坐标。结合这些算法，系统对基本墙体形状的定位精度可提高80% ~ 90%，对真实实验室环境的定位精度可提高78%。在自定位与映射问题中充分利用了Basic Stamp、Basic Atom、LabVIEW和MATLAB软件。

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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来源期刊

2016 6th IEEE International Conference on Control System, Computing and Engineering (ICCSCE)

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