A LiDAR and IMU Integrated Indoor Navigation System for UAVs and Its Application in Real-Time Pipeline Classification.

G Kumar,Ashok Patil,Seong Park,Young Chai,Rekha Patil

doi:10.3390/s17061268

G Kumar, Ashok Patil + Show 3 more

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https://doi.org/10.3390/s17061268

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Journal: Sensors (Basel, Switzerland)	Publication Date: Jun 2, 2017
Citations: 113	License type: CC BY 4.0

Affiliation: Chung-Ang University

Abstract

Mapping the environment of a vehicle and localizing a vehicle within that unknown environment are complex issues. Although many approaches based on various types of sensory inputs and computational concepts have been successfully utilized for ground robot localization, there is difficulty in localizing an unmanned aerial vehicle (UAV) due to variation in altitude and motion dynamics. This paper proposes a robust and efficient indoor mapping and localization solution for a UAV integrated with low-cost Light Detection and Ranging (LiDAR) and Inertial Measurement Unit (IMU) sensors. Considering the advantage of the typical geometric structure of indoor environments, the planar position of UAVs can be efficiently calculated from a point-to-point scan matching algorithm using measurements from a horizontally scanning primary LiDAR. The altitude of the UAV with respect to the floor can be estimated accurately using a vertically scanning secondary LiDAR scanner, which is mounted orthogonally to the primary LiDAR. Furthermore, a Kalman filter is used to derive the 3D position by fusing primary and secondary LiDAR data. Additionally, this work presents a novel method for its application in the real-time classification of a pipeline in an indoor map by integrating the proposed navigation approach. Classification of the pipeline is based on the pipe radius estimation considering the region of interest (ROI) and the typical angle. The ROI is selected by finding the nearest neighbors of the selected seed point in the pipeline point cloud, and the typical angle is estimated with the directional histogram. Experimental results are provided to determine the feasibility of the proposed navigation system and its integration with real-time application in industrial plant engineering.

Highlights

There is a growing need for autonomous robots in applications such as rescue, disaster assessment, plant engineering, or other tasks that would be a risky or impossible for a human to perform that requires efficient localization techniques for robots
We propose a complete navigation solution for unmanned aerial vehicle (UAV) in an indoor environment by customizing and combining suitable existing algorithms
The scan matching algorithm was extended to use with UAVs by stabilizing the Light Detection and Ranging (LiDAR) measurement plane using an Inertial Measurement Unit (IMU) sensor

Summary

Introduction

There is a growing need for autonomous robots in applications such as rescue, disaster assessment, plant engineering, or other tasks that would be a risky or impossible for a human to perform that requires efficient localization techniques for robots. The problem of localizing autonomous robots in unknown environments is typically solved using a low-cost scanning laser or another type of range finder; this approach has seen successful for large- to medium-sized ground robots [1,2]. Localization of unmanned aerial vehicles (UAVs) in an indoor environment suffers from high computational costs and the need for a number of sensory inputs. Inertial navigation system (INS) measurements, GPS-based localization remains impractical in closed environments due to high attenuation of the GPS signal in an indoor environment. Sensors 2017, 17, 1268; doi:10.3390/s17061268 www.mdpi.com/journal/sensors remains impractical in closed environments due to high attenuation of the GPS signal in an indoor environment.

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