Abstract
In most autonomous underwater vehicles (AUVs), the navigation system is based on an inertial navigation system (INS) aided by a Doppler velocity log (DVL). In several INSs, only the velocity vector, provided by the DVL, can be used as input for assistance, thus limiting the integration approach to a loosely coupled one. In situations of partial DVL measurements (such as failure to maintain bottom lock) the DVL cannot provide the AUV velocity vector, and as a result, the navigation solution is based only on the standalone INS solution and will drift in time. To circumvent that problem, the extended loosely coupled (ELC) approach was recently proposed. ELC combines the partial DVL measurements and additional information, such as the pervious navigation solution, to form a calculated velocity measurement to aid the INS. When doing so, the assumption made in the extended Kalman filter (EKF) derivation of zero correlated process and measurement noise covariance does not hold. In this paper, we elaborate the ELC approach by taking into account the cross-covariance matrix of the correlated process (INS) and measurement (Partial DVL) noises. At first, this covariance matrix is evaluated based on the specific assumption used in the ELC approach and then implemented in the EKF algorithm. Using a 6DOF AUV simulation, results show that the proposed methodology improves the performance of the ELC integration approach.
Highlights
Most autonomous underwater vehicles (AUVs) are equipped with an inertial navigation system (INS) as their main navigation sensor [1,2]
Using a 6DOF AUV simulation, the results show that the proposed methodology improves the performance of the extended loosely coupled (ELC) integration approach
The velocity vector of the platform cannot be calculated by the Doppler velocity log (DVL), and no velocity assistance can be provided to the INS
Summary
Most autonomous underwater vehicles (AUVs) are equipped with an inertial navigation system (INS) as their main navigation sensor [1,2]. In the LC approach, the DVL raw data (relative velocity in each beam direction) is used to calculate the vehicle velocity, which in turn is used to aid the INS via a navigation filter The advantage of this method is the simplicity of integration and the ability to combine any off-the-shelf INS with any DVL. The INS navigation solution will drift in time To circumvent this problem, the extended loosely coupled (ELC) approach for calculating platform velocity with partial DVL measurements was recently proposed [8]. There, the basic idea was to use the partial measured raw data from the DVL combined with additional information to derive the platform velocity vector This calculated vehicle velocity is used for aiding the INS, as in the regular LC approach. Using a 6DOF AUV simulation, the results show that the proposed methodology improves the performance of the ELC integration approach
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