I. Introduction

Autonomous Underwater Vehicles (AUV) have been successfully used in various applications, such as oceanographic surveys [3], [7], [8], [15], bathymetric measurements [4], [8], [15], [17] and underwater maintenance activities [6]. Hence, deriving accurate dynamic models for these vehicles is of prime importance for their maneuvering prediction and control, that is a difficult task due to the nonlinear cross-coupled hydrodynamics forces affecting the various body elements and possible mechanical interaction with surrounding structures. The most common are six-degree-of-fredoom (6 DoF) models based on Newtonian-Lagrange mechanics first principles [13]. In some maneuvers, such as diving or motion in waves, the AUV may be described by a linear time invariant (LTI) model [9], [12]. Therefore, LTI time-domain and frequency-domain system identification algorithms have been proposed to estimate these models. Due to the complexity of the 6 DoF models, most system identification approaches do not estimate the full model. In [1], the authors split the 6 DoF model into several simplified sub-models such as the longitudinal dynamic model or the surge dynamic model. Gibson and Stilwell estimate damping models only by assuming that the other parameters are known [5]. Ross et al. split the AUV into longitudinal and lateral subsystems and identify each of these models using tests in a pool with the AUV attached with four springs, and the vehicle positions measured by a camera. The velocities and accelerations were determined by FIR derivative filters and the model parameters were found by a Least-Squares estimator [10]. Feng et al. estimate the AUV model in a zig-zag diving motion using a Least-Squares Support Vector Machine (LSVM) with a Linear Kernel [16], where the linear and rotational velocities are assumed to be known. Pepijn et al propose a method to identify the hydrodynamic damping with neural networks [14]. In [11] the damping viscous coefficients are included in the state vector of the 6 DoF model and estimated using either the Extended Kalman Filter or the Unscented Kalman filter.