2021
DOI: 10.1088/1748-3190/abd044
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Learning hydrodynamic signatures through proprioceptive sensing by bioinspired swimmers

Abstract: Objects moving in water or stationary objects in streams create a vortex wake. Such vortex wakes encode information about the objects and the flow conditions. Underwater robots that often function with constrained sensing capabilities can benefit from extracting this information from vortex wakes. Many species of fish do exactly this, by sensing flow features using their lateral lines as part of their multimodal sensing. To replicate such capabilities in robots, significant research has been devoted to develop… Show more

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Cited by 17 publications
(8 citation statements)
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“…The results in this paper as well as in [44] are valid under the assumption that the the sensing body is directly behind the forced one in the flow. Some lateral displacement (offset) of the trailing body from the center line of the reverse Kármán vortex wake created by the leading body, occurs naturally in the experiments due to the short tether with which the trailing foil is connected to the water tunnel.…”
Section: Discussionsupporting
confidence: 52%
See 3 more Smart Citations
“…The results in this paper as well as in [44] are valid under the assumption that the the sensing body is directly behind the forced one in the flow. Some lateral displacement (offset) of the trailing body from the center line of the reverse Kármán vortex wake created by the leading body, occurs naturally in the experiments due to the short tether with which the trailing foil is connected to the water tunnel.…”
Section: Discussionsupporting
confidence: 52%
“…Though multiple minutes of data are available for every wake, our objective is to develop a classifier that can determine changes in the wake in near real time, requiring high performance on only a portion of the available data. Previous work [44] with a different network architecture found that, for a rigid hydrofoil, windows of input exceeding 5 s in length do not show significant increases in classification accuracy, so we adopt a 5 s time series, or 150 points at 30 Hz, as the input. We will denote the set of all 5 s windows of time series extracted from the experimental measurements as X.…”
Section: Wake Classification and Neural Network Architecturementioning
confidence: 99%
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“…Recently, the increasing interest in proprioceptive sensing provides a new direction for underwater perception, which utilizes the kinematics or parts of the body to extract useful information inflow. 142 Since related research studies are just beginning, future directions might include determining the type of proprioceptive signal perceived and clarifying the neurotransmission mechanisms between proprioceptive and motor control. 143 From a long-term perspective, it is exciting to combine proprioceptive sensing with an ALL to realize powerful underwater perception.…”
Section: Challenges and Future Directionsmentioning
confidence: 99%