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This code replicates the numerical simulations reported in the research paper entitled "Optimal time-invariant distributed formation tracking for second-order multi-agent systems"

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distributed-oift

This code replicates the numerical simulations reported in the research paper entitled "Optimal time-invariant distributed formation tracking for second-order multi-agent systems"


Authors: Marco Fabris*, Giulio Fattore, Angelo Cenedese

All the authors are with the University of Padua, Italy

* M. Fabris is the algorithm and software developer. E-mail: marco.fabris.1@unipd.it

Special thanks to John Hauser** for his assistance while using PRONTO.

** John Hauser is with the University of Colorado-Boulder, USA

Published on the European Journal of Control. Paper available at https://doi.org/10.1016/j.ejcon.2024.100985

Publication history:

  • Received 23 June 2023
  • Revised 31 December 2023
  • Accepted 27 March 2024
  • Available online 4 April 2024
  • Version of Record 8 April 2024

Abstract: This paper addresses the optimal time-invariant formation tracking problem with the aim of providing a distributed solution for multi-agent systems with second-order integrator dynamics. In the literature, most of the results related to multi-agent formation tracking do not consider energy issues while investigating distributed feedback control laws. In order to account for this crucial design aspect, we contribute by formalizing and proposing a solution to an optimization problem that encapsulates trajectory tracking, distance-based formation control and input energy minimization, through a specific and key choice of potential functions in the optimization cost. To this end, we show how to compute the inverse dynamics in a centralized fashion by means of the Projector-Operator-based Newton’s method for Trajectory Optimization (PRONTO) and, more importantly, we exploit such an offline solution as a general reference to devise a stabilizing online distributed control law. Finally, numerical examples involving a cubic formation following a chicane-like path in the 3D space are provided to validate the proposed control strategies.


Instructions:

  1. install a GCC compiler on your PC (see also https://it.mathworks.com/help/matlab/call-mex-files-1.html?s_tid=CRUX_lftnav) and configure it by running mex_newt_files.m in MatLab (make sure to indicate the correct path in the command setenv)
  2. set the kind of simulation you wish to replicate by assigning the variable simul_choice in MAIN.m (or create a new simulation)
  3. run MAIN.m and wait for its termination

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This code replicates the numerical simulations reported in the research paper entitled "Optimal time-invariant distributed formation tracking for second-order multi-agent systems"

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