This paper presents a novel way to approach the problem of how to adaptively sample the ocean using fleets of underwater gliders. The technique is particularly suited for those situations where the covariance of the field to sample is unknown or unreliable but some information on the variance is known. The proposed algorithm, which is a variant of the well-known fuzzy C-means clustering algorithm, is able to exploit the presence of non-maneuverable assets, such as fixed buoys. We modified the fuzzy C-means optimization problem statement by including additional constraints. Then we provided an algorithmic solution to the new, constrained problem
Ocean processes are dynamic, complex, and occur on multiple spatial and temporal scales. To obtain a...
Abstract The use of robots for scientific mapping and exploration can result in large, rapidly growi...
This paper presents a tool recently developed at the Centre for Maritime Research and Experimentat...
This paper presents a novel way to approach the problem of how to adaptively sample the ocean using...
Using fleets of underwater gliders to sample the ocean has been proved to be an appealing alternativ...
In the last decade the use of fleets of gliders has proven to be an effective way for sampling the o...
Underwater Gliders are a cost-effective technological solution to sample the ocean. In highly dynami...
This paper describes an optimal sampling approach to support glider fleet operators and marine scien...
This paper describes an optimal sampling approach to support glider fleet operators and marine scien...
This paper presents an optimal sampling approach to plan the optimum paths for a glider fleet. Optim...
This paper focuses on coverage sampling over a given region by a fleet of underwater gliders. The co...
Maintaining a healthy ocean is of the utmost importance. Having only a limited set of resources avai...
A full-scale adaptive ocean sampling network was deployed throughout the month-long 2006 Adaptive Sa...
The Autonomous Ocean Sampling Network-II (AOSN-II) and Adaptive Sampling and Prediction (ASAP) proje...
Digital Object Identifier: 10.1002/rob.20366A full-scale adaptive ocean sampling network was deploye...
Ocean processes are dynamic, complex, and occur on multiple spatial and temporal scales. To obtain a...
Abstract The use of robots for scientific mapping and exploration can result in large, rapidly growi...
This paper presents a tool recently developed at the Centre for Maritime Research and Experimentat...
This paper presents a novel way to approach the problem of how to adaptively sample the ocean using...
Using fleets of underwater gliders to sample the ocean has been proved to be an appealing alternativ...
In the last decade the use of fleets of gliders has proven to be an effective way for sampling the o...
Underwater Gliders are a cost-effective technological solution to sample the ocean. In highly dynami...
This paper describes an optimal sampling approach to support glider fleet operators and marine scien...
This paper describes an optimal sampling approach to support glider fleet operators and marine scien...
This paper presents an optimal sampling approach to plan the optimum paths for a glider fleet. Optim...
This paper focuses on coverage sampling over a given region by a fleet of underwater gliders. The co...
Maintaining a healthy ocean is of the utmost importance. Having only a limited set of resources avai...
A full-scale adaptive ocean sampling network was deployed throughout the month-long 2006 Adaptive Sa...
The Autonomous Ocean Sampling Network-II (AOSN-II) and Adaptive Sampling and Prediction (ASAP) proje...
Digital Object Identifier: 10.1002/rob.20366A full-scale adaptive ocean sampling network was deploye...
Ocean processes are dynamic, complex, and occur on multiple spatial and temporal scales. To obtain a...
Abstract The use of robots for scientific mapping and exploration can result in large, rapidly growi...
This paper presents a tool recently developed at the Centre for Maritime Research and Experimentat...