Your search keyword '"Kieft, Brian"' showing total 3 results

1. Dynamic robotic tracking of underwater targets using reinforcement learning

Author

European Commission, Ministerio de Ciencia, Innovación y Universidades (España), Ministerio de Economía y Competitividad (España), Agencia Estatal de Investigación (España), Masmitja, Ivan, Martin, Mario, O'Reilly, Tom, Kieft, Brian, Palomeras, Narcís, Navarro, Joan, Katija, Kakani, European Commission, Ministerio de Ciencia, Innovación y Universidades (España), Ministerio de Economía y Competitividad (España), Agencia Estatal de Investigación (España), Masmitja, Ivan, Martin, Mario, O'Reilly, Tom, Kieft, Brian, Palomeras, Narcís, Navarro, Joan, and Katija, Kakani

Abstract

To realize the potential of autonomous underwater robots that scale up our observational capacity in the ocean, new techniques are needed. Fleets of autonomous robots could be used to study complex marine systems and animals with either new imaging configurations or by tracking tagged animals to study their behavior. These activities can then inform and create new policies for community conservation. The role of animal connectivity via active movement of animals represents a major knowledge gap related to the distribution of deep ocean populations. Tracking underwater targets represents a major challenge for observing biological processes in situ, and methods to robustly respond to a changing environment during monitoring missions are needed. Analytical techniques for optimal sensor placement and path planning to locate underwater targets are not straightforward in such cases. The aim of this study was to investigate the use of reinforcement learning as a tool for range-only underwater target-tracking optimization, whose promising capabilities have been demonstrated in terrestrial scenarios. To evaluate its usefulness, a reinforcement learning method was implemented as a path planning system for an autonomous surface vehicle while tracking an underwater mobile target. A complete description of an open-source model, performance metrics in simulated environments, and evaluated algorithms based on more than 15 hours of at-sea field experiments are presented. These efforts demonstrate that deep reinforcement learning is a powerful approach that enhances the abilities of autonomous robots in the ocean and encourages the deployment of algorithms like these for monitoring marine biological systems in the future

Published

2023

2. Mobile robotic platforms for the acoustic tracking of deep-sea demersal fishery resources

Author

Ministerio de Ciencia, Innovación y Universidades (España), Generalitat de Catalunya, European Commission, Agencia Estatal de Investigación (España), Masmitja, Ivan, Navarro, Joan, Gomáriz, Spartacus, Aguzzi, Jacopo, Kieft, Brian, O'Reilly, Tom, Katija, Kakani, Bouvet, P.J., Fannjiang, Clara, Vigo Fernandez, María, Puig, Pere, Alcocer, A., Vallicrosa, Guillem, Palomeras, Narcís, Carreras, Marc, Río, Joaquín del, Company, Joan B., Ministerio de Ciencia, Innovación y Universidades (España), Generalitat de Catalunya, European Commission, Agencia Estatal de Investigación (España), Masmitja, Ivan, Navarro, Joan, Gomáriz, Spartacus, Aguzzi, Jacopo, Kieft, Brian, O'Reilly, Tom, Katija, Kakani, Bouvet, P.J., Fannjiang, Clara, Vigo Fernandez, María, Puig, Pere, Alcocer, A., Vallicrosa, Guillem, Palomeras, Narcís, Carreras, Marc, Río, Joaquín del, and Company, Joan B.

Abstract

Knowing the displacement capacity and mobility patterns of industrially exploited (i.e., fished) marine resources is key to establishing effective conservation management strategies in human-impacted marine ecosystems. Acquiring accurate behavioral information of deep-sea fished ecosystems is necessary to establish the sizes of marine protected areas within the framework of large international societal programs (e.g., European Community H2020, as part of the Blue Growth economic strategy). However, such information is currently scarce, and high-frequency and prolonged data collection is rarely available. Here, we report the implementation of autonomous underwater vehicles and remotely operated vehicles as an aid for acoustic long-baseline localization systems for autonomous tracking of Norway lobster (Nephrops norvegicus), one of the key living resources exploited in European waters. In combination with seafloor moored acoustic receivers, we detected and tracked the movements of 33 tagged lobsters at 400-m depth for more than 3 months. We also identified the best procedures to localize both the acoustic receivers and the tagged lobsters, based on algorithms designed for off-the-shelf acoustic tags identification. Autonomous mobile platforms that deliver data on animal behavior beyond traditional fixed platform capabilities represent an advance for prolonged, in situ monitoring of deep-sea benthic animal behavior at meter spatial scales

Published

2020

3. A system of coordinated autonomous robots for Lagrangian studies of microbes in the oceanic deep chlorophyll maximum.

Author

Zhang, Yanwu, Ryan, John P., Hobson, Brett W., Kieft, Brian, Romano, Anna, Barone, Benedetto, Preston, Christina M., Roman, Brent, Raanan, Ben-Yair, Pargett, Douglas, Dugenne, Mathilde, White, Angelicque E., Freitas, Fernanda Henderikx, Poulos, Steve, Wilson, Samuel T., DeLong, Edward F., Karl, David M., Birch, James M., Bellingham, James G., and Scholin, Christopher A.

Abstract

The deep chlorophyll maximum (DCM) layer is an ecologically important feature of the open ocean. The DCM cannot be observed using aerial or satellite remote sensing; thus, in situ observations are essential. Further, understanding the responses of microbes to the environmental processes driving their metabolism and interactions requires observing in a reference frame that moves with a plankton population drifting in ocean currents, i.e., Lagrangian. Here, we report the development and application of a system of coordinated robots for studying planktonic biological communities drifting within the ocean. The presented Lagrangian system uses three coordinated autonomous robotic platforms. The focal platform consists of an autonomous underwater vehicle (AUV) fitted with a robotic water sampler. This platform localizes and drifts within a DCM community, periodically acquiring samples while continuously monitoring the local environment. The second platform is an AUV equipped with environmental sensing and acoustic tracking capabilities. This platform characterizes environmental conditions by tracking the focal platform and vertically profiling in its vicinity. The third platform is an autonomous surface vehicle equipped with satellite communications and subsea acoustic tracking capabilities. While also acoustically tracking the focal platform, this vehicle serves as a communication relay that connects the subsea robot to human operators, thereby providing situational awareness and enabling intervention if needed. Deployed in the North Pacific Ocean within the core of a cyclonic eddy, this coordinated system autonomously captured fundamental characteristics of the in situ DCM microbial community in a manner not possible previously. [ABSTRACT FROM AUTHOR]

Published

2021