Continuation methods with the trusty time-stepping scheme for linearly constrained optimization with noisy data

The nonlinear optimization problem with linear constraints has many applications in engineering fields such as the visual-inertial navigation and localization of an unmanned aerial vehicle maintaining the horizontal flight. In order to solve this practical problem efficiently, this paper constructs...

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Veröffentlicht in:	Optimization and engineering 2022-03, Vol.23 (1), p.329-360
Hauptverfasser:	Luo, Xin-long, Lv, Jia-hui, Sun, Geng
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Sprache:	eng
Schlagworte:	Computing time Constraints Continuation methods Control Engineering Environmental Management Financial Engineering Horizontal flight Inertial navigation Iterative methods Linear equations Mathematics Mathematics and Statistics Operations Research/Decision Theory Optimization Quadratic programming Research Article Subroutines Systems Theory Unmanned aerial vehicles
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container_title	Optimization and engineering
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creator	Luo, Xin-long Lv, Jia-hui Sun, Geng
description	The nonlinear optimization problem with linear constraints has many applications in engineering fields such as the visual-inertial navigation and localization of an unmanned aerial vehicle maintaining the horizontal flight. In order to solve this practical problem efficiently, this paper constructs a continuation method with the trusty time-stepping scheme for the linearly equality-constrained optimization problem at every sampling time. At every iteration, the new method only solves a system of linear equations other than the traditional optimization method such as the sequential quadratic programming (SQP) method, which needs to solve a quadratic programming subproblem. Consequently, the new method can save much more computational time than SQP. Numerical results show that the new method works well for this problem and its consumed time is about one fifth of that of SQP (the built-in subroutine fmincon.m of the MATLAB2018a environment) or that of the traditional dynamical method (the built-in subroutine ode15s.m of the MATLAB2018a environment). Furthermore, we also give the global convergence analysis of the new method.
doi_str_mv	10.1007/s11081-020-09590-z
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subjects	Computing time Constraints Continuation methods Control Engineering Environmental Management Financial Engineering Horizontal flight Inertial navigation Iterative methods Linear equations Mathematics Mathematics and Statistics Operations Research/Decision Theory Optimization Quadratic programming Research Article Subroutines Systems Theory Unmanned aerial vehicles
title	Continuation methods with the trusty time-stepping scheme for linearly constrained optimization with noisy data
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