2015
DOI: 10.1007/s11071-015-2248-1
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Nonlinear adaptive trajectory tracking control for a stratospheric airship with parametric uncertainty

Abstract: A nonlinear adaptive trajectory tracking control strategy is proposed for a fully actuated stratospheric airship subject to uncertain mass and inertia parameters. Based on the stratospheric airship trajectory tracking model, a non-certainty equivalence adaptive control approach is adopted to estimate the uncertain parameters since its excellently attractive property of the immersion and invariance manifold condition.The key idea involves a new filter construction for the regressor terms in the airship dynamics… Show more

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Cited by 44 publications
(27 citation statements)
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“…where B u (•) is a continuously bounded function on a compact set on a compact set (24) y u ∈ R 22 It should be noted that the first equation in 7 can be rewritten as ν = R T (ψ)η; thus, the function f u (ν) can be restated as a continuous function f u (ζ ), where ζ = [η T ,η T ] T . Since the nonlinear f u (ζ ) is indefinite, we use the RBF NNs to model the nonlinear functions f u (ζ ) as (13)…”
Section: Position Controlmentioning
confidence: 99%
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“…where B u (•) is a continuously bounded function on a compact set on a compact set (24) y u ∈ R 22 It should be noted that the first equation in 7 can be rewritten as ν = R T (ψ)η; thus, the function f u (ν) can be restated as a continuous function f u (ζ ), where ζ = [η T ,η T ] T . Since the nonlinear f u (ζ ) is indefinite, we use the RBF NNs to model the nonlinear functions f u (ζ ) as (13)…”
Section: Position Controlmentioning
confidence: 99%
“…In Ref. (22), a non-certainty equivalence adaptive trajectory tracking control structure was formulated for a fully actuated airship subject to parametric uncertainties. By adopting a time-varying tan-type barrier Lyapunov function, Zheng et al (37,38,40) presented outputconstrained control schemes that could effectively implement error-constrained trajectory tracking or path-following, and constructed radial basis function (RBF) NNs to approximate the uncertain dynamics and disturbances of an airship.…”
Section: Introductionmentioning
confidence: 99%
“…To generate the desired attitude ξ d (t), a Frenet frame [41] of the desired trajectory p d (t) at arbitrary time t is defined as follows: (21) where e t , e b and e n represent the tangent vector, the binormal vector and the normal vector, respectively. Then, the desired reference frame can be established by {e t , sgn(e b3 )e n , sgn(e b3 )e b }, and the rotation matrix from the desired reference frame to ERF can be written as R e d = e t , sgn(e b3 )e n , sgn(e b3 )e b where e b3 is the third element of e b [4], [11]. Since the objective of attitude tracking is to render the BRF coinciding the desired reference frame, comparing R e d = r ij (i = j = 1, 2, 3) with R e b results in the desired attitude ξ…”
Section: A Trajectory Tracking Modelmentioning
confidence: 99%
“…Similar to the balloon [3], stratospheric airship gains the lift force through the use of a buoyant gas rather than aerodynamic force, which makes the airship possess longer endurance than the conventional aircraft. Unlike the balloon, the stratospheric airship is capable of cruising along the predetermined path, also known as trajectory tracking [4], [5], to accomplish relatively complicated missions, such as typhoon tracking and maritime rescue. However, the tracking control is quite difficult since stratospheric airship is a complex, highly nonlinear and…”
Section: Introductionmentioning
confidence: 99%
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