Cross-Track Formation Control of Underactuated Autonomous Underwater Vehicles

Abstract: Summary. The problem of 3D cross-track control for underactuated 5-degrees-of-freedom (5-DOF) autonomous underwater vehicles (AUV) is considered. The proposed decentralized controllers make the AUVs asymptotically constitute a desired formation that follows a given straight-line path with a given forward speed profile. The proposed controllers consist of two blocks. The first block, which is based on a Line of Sight guidance law, makes every AUV asymptotically follow straight line paths corresponding to the de… Show more

“…For fully actuated marine vehicles the formation control problem has been considered in [9], [10] and [11]. For underactuated marine vehicle this problem has been considered in [12] for the case of two vehicles with planar motion, in This [13] for an arbitrary number of surface vessels and in [14], [15] for the 3D case of autonomous underwater vehicles.…”

Straight line path following for formations of underactuated underwater vehicles

“…For fully actuated marine vehicles the formation control problem has been considered in [9], [10] and [11]. For underactuated marine vehicle this problem has been considered in [12] for the case of two vehicles with planar motion, in This [13] for an arbitrary number of surface vessels and in [14], [15] for the 3D case of autonomous underwater vehicles.…”

Straight line path following for formations of underactuated underwater vehicles

“…The sway dynamics (7b) is assumed to be inherently stable, with its boundedness properties captured by an assumption in the next section. The terms w ⊤ * (ψ)ρ are the corresponding components of the vector M −1 Dν c , with ν c given in (3). In what follows we will use the reformulated model (6)- (7) with (τ u , τ r ) as control inputs and with the current vector ρ = [ρ x ρ y ] ⊤ ∈ R 2 as unknown parameters.…”

“…Yet for marine vessels, especially in the underactuated case, one cannot simply put together general results on formation control (which are usually formulated on the kinematics level) and results on the path following problem for a single vehicle (studied both on the kinematics and dynamics level). Such a combination requires careful overall analysis due to the highly nonlinear dynamics of the systems involved, as pointed out in [3]. In [15] this analysis is done for the case of two cooperating vessels, and in [1], [4] it is performed for an arbitrary number of surface vessels.…”

Straight line path following for formations of underactuated surface vessels under influence of constant ocean currents

“…The problem of path following control of formations of marine vehicles is studied in [16]- [21]. In [19] path following of two underwater vehicles is investigated.…”

“…In [16]- [18] straight-line path following for formations of marine vehicles is considered. In particular, in [16]- [18] LOS guidance is used to make each vehicle in the formation follow a desired path, whilst a formation control term is added to the velocity control to achieve a desired inter-agent distance and formation. However, in all the formation control approaches discussed above the effects of ocean currents are not taken into account.…”

Path following for formations of underactuated marine vessels under influence of constant ocean currents