In-flight positional and energy use data set of a DJI Matrice 100 quadcopter for small package delivery
Abstract
We autonomously directed a small quadcopter package delivery Uncrewed Aerial Vehicle (UAV) or “drone” to take off, fly a specified route, and land for a total of 209 flights while varying a set of operational parameters. The vehicle was equipped with onboard sensors, including GPS, IMU, voltage and current sensors, and an ultrasonic anemometer, to collect high-resolution data on the inertial states, wind speed, and power consumption. Operational parameters, such as commanded ground speed, payload, and cruise altitude, were varied for each flight. This large data set has a total flight time of 10 hours and 45 minutes and was collected from April to October of 2019 covering a total distance of approximately 65 kilometers. The data collected were validated by comparing flights with similar operational parameters. We believe these data will be of great interest to the research and industrial communities, who can use the data to improve UAV designs, safety, and energy efficiency, as well as advance the physical understanding of in-flight operations for package delivery drones.
This work was supported by the U.S. Department of Energy’s Vehicle Technologies Office, Award Number DE-EE0008463. This material is also based upon work supported by the National Science Foundation Graduate Research Fellowship under Grant No. DGE1745016. The work was also supported in part by LORD MicroStrain Sensing Systems.
BibTeX
@article{Rodrigues-2021-127867,author = {Thiago A. Rodrigues and Jay Patrikar and Arnav Choudhry and Jacob Feldgoise and Vaibhav Arcot and Aradhana Gahlaut and Sophia Lau and Brady Moon and Bastian Wagner and H. Scott Matthews and Sebastian Scherer and Constantine Samaras},
title = {In-flight positional and energy use data set of a DJI Matrice 100 quadcopter for small package delivery},
journal = {Scientific Data},
year = {2021},
month = {June},
volume = {8},
}