Nautical Research Platform for Water-Bound Experiments

Dillon J. Eyer; Monica Leibowitz; Amanda White; Zachariah Vandeventer; Heather Dyer; Andrew Byrd; Dustin Nguyen; Terek Zimmerman; Hugh Sheldon; Morgan Hill; Jeremy Bouchard; Jessica M. Mueller; Adam Torek; Kalynn Cotton; Jose Escobosa; Tyler Johnson; Nathan Sundquist; Zuly Lapa; Ryan Olson; Carolyn Murrey; David Maldonado; Aidan McConnehey; Keaton Poe; Libbie Luevanos; Andrew Handzel; Steve Swanson; Gus Engstrom; Megan Gambs; Gunes Uzer

Nautical Research Platform for Water-Bound Experiments

Dillon J. Eyer
, Monica Leibowitz
, Amanda White
, Zachariah Vandeventer
, Heather Dyer
, Andrew Byrd
, Dustin Nguyen
, Terek Zimmerman
, Hugh Sheldon
, Morgan Hill
, Jeremy Bouchard
, Jessica M. Mueller
, Adam Torek
, Kalynn Cotton
, Jose Escobosa
, Tyler Johnson
, Nathan Sundquist
, Zuly Lapa
, Ryan Olson
, Carolyn Murrey

David Maldonado, Aidan McConnehey, Keaton Poe, Libbie Luevanos, Andrew Handzel, Steve Swanson, Gus Engstrom, Megan Gambs, Gunes Uzer

Boise State University

Research output: Contribution to conference › Presentation

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Abstract

Conducting research in lakes and rivers requires large crews and heavy-duty equipment, making even simple tests more costly and time consuming. Newer research methods are evolving constantly as new technology enables more precise and accessible experiments to be conducted. The need for simple execution of water-bound experiments exists and must be addressed to aid our understanding of these environments. We at the Microgravity Undergraduate Research Team have taken our previous research in autonomous Unmanned Surface Vehicles (USVs) and applied our efforts to relieving this problem. Our current research aims to provide a universal platform for research and experiments to be conducted in lakes and rivers, where we can then expand our efforts to more broad applications. The design allows for remote-control navigation by one user and easy portability. To address precision in experimentation, we have integrated autonomous GPS waypoint navigation which removes user error in sensitive measurements. The most important factor in its design is modularity; the ability to accommodate a wide range of equipment for research. Our platform succeeds in making water-bound experiments more accessible and more precise for a multitude of potential applications.

Original language	American English
State	Published - 12 Apr 2020

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@conference{72acbed3be2b400cabdca66b0b5800fb,

title = "Nautical Research Platform for Water-Bound Experiments",

abstract = " Conducting research in lakes and rivers requires large crews and heavy-duty equipment, making even simple tests more costly and time consuming. Newer research methods are evolving constantly as new technology enables more precise and accessible experiments to be conducted. The need for simple execution of water-bound experiments exists and must be addressed to aid our understanding of these environments. We at the Microgravity Undergraduate Research Team have taken our previous research in autonomous Unmanned Surface Vehicles (USVs) and applied our efforts to relieving this problem. Our current research aims to provide a universal platform for research and experiments to be conducted in lakes and rivers, where we can then expand our efforts to more broad applications. The design allows for remote-control navigation by one user and easy portability. To address precision in experimentation, we have integrated autonomous GPS waypoint navigation which removes user error in sensitive measurements. The most important factor in its design is modularity; the ability to accommodate a wide range of equipment for research. Our platform succeeds in making water-bound experiments more accessible and more precise for a multitude of potential applications.",

author = "Eyer, \{Dillon J.\} and Monica Leibowitz and Amanda White and Zachariah Vandeventer and Heather Dyer and Andrew Byrd and Dustin Nguyen and Terek Zimmerman and Hugh Sheldon and Morgan Hill and Jeremy Bouchard and Mueller, \{Jessica M.\} and Adam Torek and Kalynn Cotton and Jose Escobosa and Tyler Johnson and Nathan Sundquist and Zuly Lapa and Ryan Olson and Carolyn Murrey and David Maldonado and Aidan McConnehey and Keaton Poe and Libbie Luevanos and Andrew Handzel and Steve Swanson and Gus Engstrom and Megan Gambs and Gunes Uzer",

year = "2020",

month = apr,

day = "12",

language = "American English",

}

Eyer, DJ, Leibowitz, M, White, A, Vandeventer, Z, Dyer, H, Byrd, A, Nguyen, D, Zimmerman, T, Sheldon, H, Hill, M, Bouchard, J, Mueller, JM, Torek, A, Cotton, K, Escobosa, J, Johnson, T, Sundquist, N, Lapa, Z, Olson, R, Murrey, C, Maldonado, D, McConnehey, A, Poe, K, Luevanos, L, Handzel, A, Swanson, S, Engstrom, G, Gambs, M & Uzer, G 2020, 'Nautical Research Platform for Water-Bound Experiments'.

TY - CONF

T1 - Nautical Research Platform for Water-Bound Experiments

AU - Eyer, Dillon J.

AU - Leibowitz, Monica

AU - White, Amanda

AU - Vandeventer, Zachariah

AU - Dyer, Heather

AU - Byrd, Andrew

AU - Nguyen, Dustin

AU - Zimmerman, Terek

AU - Sheldon, Hugh

AU - Hill, Morgan

AU - Bouchard, Jeremy

AU - Mueller, Jessica M.

AU - Torek, Adam

AU - Cotton, Kalynn

AU - Escobosa, Jose

AU - Johnson, Tyler

AU - Sundquist, Nathan

AU - Lapa, Zuly

AU - Olson, Ryan

AU - Murrey, Carolyn

AU - Maldonado, David

AU - McConnehey, Aidan

AU - Poe, Keaton

AU - Luevanos, Libbie

AU - Handzel, Andrew

AU - Swanson, Steve

AU - Engstrom, Gus

AU - Gambs, Megan

AU - Uzer, Gunes

PY - 2020/4/12

Y1 - 2020/4/12

N2 - Conducting research in lakes and rivers requires large crews and heavy-duty equipment, making even simple tests more costly and time consuming. Newer research methods are evolving constantly as new technology enables more precise and accessible experiments to be conducted. The need for simple execution of water-bound experiments exists and must be addressed to aid our understanding of these environments. We at the Microgravity Undergraduate Research Team have taken our previous research in autonomous Unmanned Surface Vehicles (USVs) and applied our efforts to relieving this problem. Our current research aims to provide a universal platform for research and experiments to be conducted in lakes and rivers, where we can then expand our efforts to more broad applications. The design allows for remote-control navigation by one user and easy portability. To address precision in experimentation, we have integrated autonomous GPS waypoint navigation which removes user error in sensitive measurements. The most important factor in its design is modularity; the ability to accommodate a wide range of equipment for research. Our platform succeeds in making water-bound experiments more accessible and more precise for a multitude of potential applications.

AB - Conducting research in lakes and rivers requires large crews and heavy-duty equipment, making even simple tests more costly and time consuming. Newer research methods are evolving constantly as new technology enables more precise and accessible experiments to be conducted. The need for simple execution of water-bound experiments exists and must be addressed to aid our understanding of these environments. We at the Microgravity Undergraduate Research Team have taken our previous research in autonomous Unmanned Surface Vehicles (USVs) and applied our efforts to relieving this problem. Our current research aims to provide a universal platform for research and experiments to be conducted in lakes and rivers, where we can then expand our efforts to more broad applications. The design allows for remote-control navigation by one user and easy portability. To address precision in experimentation, we have integrated autonomous GPS waypoint navigation which removes user error in sensitive measurements. The most important factor in its design is modularity; the ability to accommodate a wide range of equipment for research. Our platform succeeds in making water-bound experiments more accessible and more precise for a multitude of potential applications.

UR - https://scholarworks.boisestate.edu/under_showcase_2020/52

M3 - Presentation

ER -

Nautical Research Platform for Water-Bound Experiments

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