A Robotic System for Localization of Passive UHF-RFID Tagged Objects on Shelves

A Robotic System for Localization of Passive UHF-RFID Tagged Objects on Shelves

This paper faces the problem of a robot that patrols a warehouse and localizes objects on shelves using RFID technology. A two-step localization system has been developed. First, the robot localizes itself by means of a Kalman-based algorithm that fuses robot odometry with the information coming fro...

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Bibliographic Details
Published in:IEEE sensors journal Vol. 18; no. 20; pp. 8558 - 8568
Main Authors: DiGiampaolo, Emidio, Martinelli, Francesco
Format: Journal Article
Language:English
Published: New York IEEE 15-10-2018
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Algorithms
Antennas
Cartons
electromagnetic modeling
Estimating techniques
Fuses
Kalman filtering
Localization
Mathematical models
Mobile robots
Noise measurement
Numerical analysis
Odometers
Radio frequency identification
Radiofrequency identification
Robot kinematics
Robot sensing systems
Robotic localization
Robots
Shelves
UHF-RFID
Very high frequencies
Warehouses
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Summary:This paper faces the problem of a robot that patrols a warehouse and localizes objects on shelves using RFID technology. A two-step localization system has been developed. First, the robot localizes itself by means of a Kalman-based algorithm that fuses robot odometry with the information coming from the phase of the signals of few reference RFID tags deployed along the shelves. Then, the objects on the shelves are localized using an algorithm that matches the phase of the signals from tagged objects collected along specific paths (suitably devised to decouple the estimation problem of the different tag coordinates) with a parametric electromagnetic model. A numerical analysis has been reported to show that the estimation error in the tag coordinates remains in the order of a few centimeters under several operating conditions of the system (e.g., for different values of the standard deviation of the measurement noise or under several parameter perturbations). Experimental tests in real scenarios assess the effectiveness of the system: the average position estimation error of the objects is about 10 cm in the case of cluttered metallic shelves but decreases up to a few centimeters in the case of stacked cartons.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2018.2865339