Autonomous Close Formation Flight Control with Fixed Wing and Quadrotor Test Beds

Caleb Rice; Yu Gu; Haiyang Chao; Trenton Larrabee; Srikanth Gururajan; Marcello Napolitano; Tanmay Mandal; Matthew Rhudy

doi:10.1155/2016/9517654

Autonomous Close Formation Flight Control with Fixed Wing and Quadrotor Test Beds

Caleb Rice, Yu Gu, Haiyang Chao, Trenton Larrabee, Srikanth Gururajan, Marcello Napolitano, Tanmay Mandal, Matthew Rhudy

Division of Engineering, Business & Computing (Berks)

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Autonomous formation flight is a key approach for reducing energy cost and managing traffic in future high density airspace. The use of Unmanned Aerial Vehicles (UAVs) has allowed low-budget and low-risk validation of autonomous formation flight concepts. This paper discusses the implementation and flight testing of nonlinear dynamic inversion (NLDI) controllers for close formation flight (CFF) using two distinct UAV platforms: a set of fixed wing aircraft named "Phastball" and a set of quadrotors named "NEO." Experimental results show that autonomous CFF with approximately 5-wingspan separation is achievable with a pair of low-cost unmanned Phastball research aircraft. Simulations of the quadrotor flight also validate the design of the NLDI controller for the NEO quadrotors.

Original language	English (US)
Article number	9517654
Journal	International Journal of Aerospace Engineering
Volume	2016
DOIs	https://doi.org/10.1155/2016/9517654
State	Published - 2016

All Science Journal Classification (ASJC) codes

Aerospace Engineering

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10.1155/2016/9517654

Cite this

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title = "Autonomous Close Formation Flight Control with Fixed Wing and Quadrotor Test Beds",

abstract = "Autonomous formation flight is a key approach for reducing energy cost and managing traffic in future high density airspace. The use of Unmanned Aerial Vehicles (UAVs) has allowed low-budget and low-risk validation of autonomous formation flight concepts. This paper discusses the implementation and flight testing of nonlinear dynamic inversion (NLDI) controllers for close formation flight (CFF) using two distinct UAV platforms: a set of fixed wing aircraft named {"}Phastball{"} and a set of quadrotors named {"}NEO.{"} Experimental results show that autonomous CFF with approximately 5-wingspan separation is achievable with a pair of low-cost unmanned Phastball research aircraft. Simulations of the quadrotor flight also validate the design of the NLDI controller for the NEO quadrotors.",

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AU - Gu, Yu

AU - Chao, Haiyang

AU - Larrabee, Trenton

AU - Gururajan, Srikanth

AU - Napolitano, Marcello

AU - Mandal, Tanmay

AU - Rhudy, Matthew

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AB - Autonomous formation flight is a key approach for reducing energy cost and managing traffic in future high density airspace. The use of Unmanned Aerial Vehicles (UAVs) has allowed low-budget and low-risk validation of autonomous formation flight concepts. This paper discusses the implementation and flight testing of nonlinear dynamic inversion (NLDI) controllers for close formation flight (CFF) using two distinct UAV platforms: a set of fixed wing aircraft named "Phastball" and a set of quadrotors named "NEO." Experimental results show that autonomous CFF with approximately 5-wingspan separation is achievable with a pair of low-cost unmanned Phastball research aircraft. Simulations of the quadrotor flight also validate the design of the NLDI controller for the NEO quadrotors.

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Autonomous Close Formation Flight Control with Fixed Wing and Quadrotor Test Beds

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