Evaluation of Battery-free UHF-RFID Sensor Wireless Signals for In-pipe Robotic Applications

Gunatilake, Amal; Thiyagarajan, Karthick; Kodagoda, Sarath

doi:10.1109/sensors47087.2021.9639827

Cited by 5 publications

(1 citation statement)

References 19 publications

(8 reference statements)

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“…Other robots can employ wheel encoders, however, uneven terrain could cause the wheels to slip, resulting in erroneous odometry measurements. Researchers have been experimenting with RFID sensors in settings that demand precise 1D odometry [9], [10]. However, RFID sensors must be placed in advance to employ these approaches.…”

Section: Introductionmentioning

confidence: 99%

Deep Learned Ground Penetrating Radar Subsurface Features for Robot Localization

2022

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Sensors help robots perceive their environment and localize themselves. Determining a robot's location requires a range of sensing systems. Depending on accuracy criteria and navigation conditions, robot localization sensors can differ. Common sensors for robot localization include encoders, GPS, cameras, LIDARs, and IMUs. Traditional sensors are not capable enough in changing environments and uneven terrain. In this paper, we propose a method based on deep learning to use the subsurface features obtained through a Ground Penetrating Radar (GPR) to estimate the odometry of a robot. This proposed method does not rely on visual features or the distance gathered from wheel encoders. The proposed approach was evaluated on a publicly available dataset, and the evaluation results show that the proposed method can be used for robot localization without the need for odometry from wheel encoders.

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Section: Introductionmentioning

confidence: 99%

Deep Learned Ground Penetrating Radar Subsurface Features for Robot Localization

2022

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Battery-Free UHF-RFID Sensors-Based SLAM for In-Pipe Robot Perception

2022

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Water utilities across the globe are concerned with the inspection and replacement of buried metallic water pipes due to corrosion-related structural damages. Internal pipe linings are commonly used as a renewal method to improve structural strength as they are regarded to be a less expensive alternative to costly and time-consuming pipe replacements. However, linings are also prone to failure as well. Therefore, water authorities regularly monitor lining performance, where defect evolution over a long period of time is an important parameter to note. It requires an accurate in-pipe robot localization technology. In this article, we propose a novel method for in-pipe robot localization and tag mapping that uses battery-free UHF-RFID sensor wireless signals. It utilizes a signal mapping approach in combination with a tailored posegraph simultaneous localization and mapping algorithm. Evaluation results of a field-extracted pipe sample from Sydney Water's distribution network show the proposed approach is capable of localizing the robot within 2.5cm accuracy in a 50m equivalent pipe with an unknown UHF-RFID distribution. The proposed approach outperformed other reported similar work in the literature.

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A Novel UHF-RFID Dual Antenna Signals Combined With Gaussian Process and Particle Filter for In-Pipe Robot Localization

Gunatilake

Kodagoda

Thiyagarajan

2022

IEEE Robot. Autom. Lett.

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Evaluation of Battery-free UHF-RFID Sensor Wireless Signals for In-pipe Robotic Applications

Cited by 5 publications

References 19 publications

Deep Learned Ground Penetrating Radar Subsurface Features for Robot Localization

Deep Learned Ground Penetrating Radar Subsurface Features for Robot Localization

Battery-Free UHF-RFID Sensors-Based SLAM for In-Pipe Robot Perception

A Novel UHF-RFID Dual Antenna Signals Combined With Gaussian Process and Particle Filter for In-Pipe Robot Localization

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