A terrain-covering algorithm for an AUV

Hert, Susan; Tiwari, Sanjay; Lumelsky, V.

doi:10.1007/bf00141150

Cited by 138 publications

(52 citation statements)

References 14 publications

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“…Acar and Choset (2000) proposed two methods to sense these points using robot range sensors. Hert et al (1996) proposed an algorithm which does not use cellular decomposition, but incrementally explores the area and covers it using back and forth motions. Here the environment is represented as a combination of inlets and islands that are investigated during the exploration.…”

Section: Covering Algorithmsmentioning

confidence: 99%

Olfactory coordinated area coverage

et al. 2006

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This paper proposes an olfaction based methodology to automatically cover an unknown area enabling the decoupled cooperation of a group of floor cleaning mobile robots. This method is based on the utilisation of low cost chemical sensors in cleaning mobile robots, in order to differentiate clean from dirty areas. The experimental results show that the use of olfactory capabilities allows to efficiently cover and clean a certain area, and demonstrate the possibility of coordinating several mobile robots without the need of expensive sensing capabilities, map building or complex algorithms for task scheduling.

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Section: Covering Algorithmsmentioning

confidence: 99%

Olfactory coordinated area coverage

et al. 2006

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“…Hert's algorithm is based on a Seed Spreader technique [14] developed for the exploration of known area, and the validity of the method has been proved in terms of path length compared with the Seed Spreader technique. The total path length based on the worst situation using Hert's algorithm [12] can be described as in (15). …”

Section: Mathematical Verification and Comparisonmentioning

confidence: 99%

“…Completeness depends heavily on sea current disturbances, which can have a very large effect on the performance of a coverage algorithm. In this paper, we propose a new dynamic model of an AUV that includes exterior disturbances such as sea current, and we develop a new tool that enables us to eliminate missed areas by calculating efficient exploring widths for an AUV zigzagging with respect to disturbances Hert and Lumelsky [12] present a coverage algorithm that applies to a partially unknown of space where the widths of cells are fixed but the tops and bottoms can have any shape. Their planar terrain-covering algorithm can be applied to both simply and non-simply connected environments.…”

Section: Introductionmentioning

confidence: 99%

An efficient underwater coverage method for multi-AUV with sea current disturbances

Jung¹,

Lee

et al. 2009

Int. J. Control Autom. Syst.

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This paper presents an online coverage method for the exploration of unknown oceanic terrains using multiple autonomous underwater vehicles (AUVs). Working from the concept of planar algorithm developed by Hert, this study attempts to develop an improved method. Instead of theoretical research, it focuses on the practical aspects of exploration by considering the equations of motion for AUVs that are actually used in oceanic exploration as well as on the characteristics of complex oceanic topography and other realistic variables, such as sea current. These elements are used to calculate cross track error (CTE) and path width for AUV movement. The validity of the improved algorithm for terrain coverage is first verified mathematically and then by a simulation of the real underwater environment that analyzes the path length and time taken for the coverage as well as the missed areas, which is the key element of efficiency. In order to apply the improved method to the multi-AUV operation, each AUV was assigned a covering or a scanning role by means of a dynamic role-changing mechanism. The results showed that the multi-AUV operation has an advantage over a single-AUV operation in many ways. The method proposed in this study will be useful not only for commercial applications but also for mine counter-measures (MCMs) and rapid environmental assessments (REAs) as part of naval military operations as well. We also believe that it will be ideal for use in variable oceanic environment, particularly in shallow water terrains. For the purposes of this study, we assume that the communication between AUVs is problem-free.

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“…Considerable interest has been shown in recent years for using autonomous underwater vehicles (AUVs) to cover and locate specific targets of interest [1], [2]. Current military search doctrine for finding fields of discrete targets dictates that 100% of a searchable area is covered [3] and every target identified and located.…”

Section: Introductionmentioning

confidence: 99%

Towards tracking a row of discrete targets with AUVs using Markov Decision Processes and probabilistic techniques

Bays

Redfield

2008

2008 IEEE/OES Autonomous Underwater Vehicles

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While complete searches of an area are the standard method currently used by the U.S. Navy for detecting and determining the extent of a field of discrete underwater targets of interest, there are situations where time constraints or mission objectives prohibit a complete search. Furthermore, in many situations it is unnecessary to detect all targets within a field of targets of interest, but is sufficient to determine the area over which the field extends. In this paper we present a novel search procedure for determining the extent of a line of targets within an area for use with AUVs. This method uses a Markov Decision Process coupled with belief propagation. Monte Carlo simulations indicate that this algorithm out-performs the standard search techniques for determining the endpoints of a line of targets when the metric is time.

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A terrain-covering algorithm for an AUV

Cited by 138 publications

References 14 publications

Olfactory coordinated area coverage

Olfactory coordinated area coverage

An efficient underwater coverage method for multi-AUV with sea current disturbances

Towards tracking a row of discrete targets with AUVs using Markov Decision Processes and probabilistic techniques

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