Abstract
Recently, ocean exploration has increased considerably through the use of autonomous underwater vehicles (AUV). A key enabling technology is the precision of the AUV navigation capability. In this paper, we focus on understanding the limitation of the AUV navigation system. That is, what are the observable error-states for different maneuvering types of the AUV? Since analyzing the performance of an underwater navigation system is highly complex, to answer the above question, current approaches use simulations. This, of course, limits the conclusions to the emulated type of vehicle used and to the simulation setup. For this reason, we take a different approach and analyze the system observability for different types of vehicle dynamics by finding the set of observable and unobservable states. To that end, we apply the observability Gramian approach, previously used only for terrestrial applications. We demonstrate our analysis for an underwater inertial navigation system aided by a Doppler velocity logger or by a pressure sensor. The result is a first prediction of the performance of an AUV standing, rotating at a position and turning at a constant speed. Our conclusions of the observable and unobservable navigation error states for different dynamics are supported by extensive numerical simulation.
Highlights
The use of Autonomous Underwater Vehicles (AUVs) for ocean applications has increased considerably
We focused on the problem of predicting the observable and unobservable error states of the AUV navigation system for several maneuvering types
This is important for understanding the limits of the Inertial Navigation Systems (INS) AUV navigation system, as well as to improve path planning for AUVs
Summary
The use of Autonomous Underwater Vehicles (AUVs) for ocean applications has increased considerably. These applications include gathering of scientific data, pollution control, climate monitoring, transmission of images from remote places, seafloor mapping, oceanographic surveys and maintenance of off-shore facilities, to name just a few [1,2]. A typical mission of an AUV involves submerging for a few hours while following a specific route and gathering measurements with respect to the AUV’s location and dynamics. The AUV must navigate while being submerged. The vehicle is assumed to be on the surface and location is determined, commonly, using one of the Global Navigation Satellite Systems (GNSS). When the vehicle is below the water surface, GNSS is no longer available and the vehicle must use its inertial system
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