This work aims to analyze the torque effects produced by the hull-wake
interaction on the maneuverability of a flatfish-shaped AUV, by 3-D
realistic scale computational simulations. On account of the inertia,
the AUV provides a self-averaging mechanism that erases the high
frequency components. Following this line, we processed a high frequency
filter on the torques time series. We concluded that the flatfish shape
has an excellent capacity of maneuverability under low velocities,
showed by its tiny torque variations over time as the inlet speed
decreases. We also observe that the pitch component has high torque
oscillations over time with drift (also called yaw) angles, showing a
significant increment of amplitudes when this angle becomes 10 degrees.
This represents an important concern about flatfish maneuverability
while, on the other hand, the roll component has shown the lowest
oscillations among the three rotational degrees of freedom. The yaw
component increases moderately with an increase in attack yaw angles.
The description above, especially for low speeds, indicates that the
flatfish-shaped AUV presents suitable conditions for missions executing
scanning and filming tasks that require good stability and controllable
maneuverability.
%0 Journal Article
%1 WOS:000483638400014
%A da Silva Costa, G
%A Almeide, M P
%A de Melo Filho V, A R
%A da Cunha Lima, A T
%A da Cunha Lima, I C
%C THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, OXON, ENGLAND
%D 2019
%I ELSEVIER SCI LTD
%J APPLIED OCEAN RESEARCH
%K Maneuverability; Numerical OpenFOAM} simulation; {AUV;
%R 10.1016/j.apor.2019.06.006
%T 3-D realistic simulations over a Flatfish shaped AUV submitted to ocean
currents
%V 90
%X This work aims to analyze the torque effects produced by the hull-wake
interaction on the maneuverability of a flatfish-shaped AUV, by 3-D
realistic scale computational simulations. On account of the inertia,
the AUV provides a self-averaging mechanism that erases the high
frequency components. Following this line, we processed a high frequency
filter on the torques time series. We concluded that the flatfish shape
has an excellent capacity of maneuverability under low velocities,
showed by its tiny torque variations over time as the inlet speed
decreases. We also observe that the pitch component has high torque
oscillations over time with drift (also called yaw) angles, showing a
significant increment of amplitudes when this angle becomes 10 degrees.
This represents an important concern about flatfish maneuverability
while, on the other hand, the roll component has shown the lowest
oscillations among the three rotational degrees of freedom. The yaw
component increases moderately with an increase in attack yaw angles.
The description above, especially for low speeds, indicates that the
flatfish-shaped AUV presents suitable conditions for missions executing
scanning and filming tasks that require good stability and controllable
maneuverability.
@article{WOS:000483638400014,
abstract = {This work aims to analyze the torque effects produced by the hull-wake
interaction on the maneuverability of a flatfish-shaped AUV, by 3-D
realistic scale computational simulations. On account of the inertia,
the AUV provides a self-averaging mechanism that erases the high
frequency components. Following this line, we processed a high frequency
filter on the torques time series. We concluded that the flatfish shape
has an excellent capacity of maneuverability under low velocities,
showed by its tiny torque variations over time as the inlet speed
decreases. We also observe that the pitch component has high torque
oscillations over time with drift (also called yaw) angles, showing a
significant increment of amplitudes when this angle becomes 10 degrees.
This represents an important concern about flatfish maneuverability
while, on the other hand, the roll component has shown the lowest
oscillations among the three rotational degrees of freedom. The yaw
component increases moderately with an increase in attack yaw angles.
The description above, especially for low speeds, indicates that the
flatfish-shaped AUV presents suitable conditions for missions executing
scanning and filming tasks that require good stability and controllable
maneuverability.},
added-at = {2022-05-23T20:00:14.000+0200},
address = {THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, OXON, ENGLAND},
author = {da Silva Costa, G and Almeide, M P and de Melo Filho V, A R and da Cunha Lima, A T and da Cunha Lima, I C},
biburl = {https://www.bibsonomy.org/bibtex/26297d52496880d76700a299ddddc0cd3/ppgfis_ufc_br},
doi = {10.1016/j.apor.2019.06.006},
interhash = {03f585bf6859c1a8fb13e55ea212d335},
intrahash = {6297d52496880d76700a299ddddc0cd3},
issn = {0141-1187},
journal = {APPLIED OCEAN RESEARCH},
keywords = {Maneuverability; Numerical OpenFOAM} simulation; {AUV;},
publisher = {ELSEVIER SCI LTD},
pubstate = {published},
timestamp = {2022-05-23T20:00:14.000+0200},
title = {3-D realistic simulations over a Flatfish shaped AUV submitted to ocean
currents},
tppubtype = {article},
volume = 90,
year = 2019
}