Zhuoyuan Song scite author profile

Zhuoyuan Song

5Publications

57Citation Statements Received

66Citation Statements Given

How they've been cited

123

How they cite others

186

Affiliations

University of Hawaiʻi at Mānoa, University of Florida, University of Hawaii System

Publications

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Long-Term Inertial Navigation Aided by Dynamics of Flow Field Features

Song

Mohseni

2018

IEEE J. Oceanic Eng.

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A current-aided inertial navigation framework is proposed for small autonomous underwater vehicles in longduration operations (> 1 hour), where neither frequent surfacing nor consistent bottom-tracking are available. We instantiate this concept through mid-depth, underwater navigation. This strategy mitigates dead-reckoning uncertainty of a traditional inertial navigation system by comparing the estimate of local, ambient flow velocity with preloaded ocean current maps. The proposed navigation system is implemented through a marginalized particle filter where the vehicle's states are sequentially tracked along with sensor bias and local turbulence that is not resolved by general flow prediction. The performance of the proposed approach is first analyzed through Monte Carlo simulations in two artificial background flow fields, resembling real-world ocean circulation patterns, superposed with smaller-scale, turbulent components with Kolmogorov energy spectrum. The current-aided navigation scheme significantly improves the dead-reckoning performance of the vehicle even when unresolved, small-scale flow perturbations are present. For a 6-hour navigation with an automotive-grade inertial navigation system, the currentaided navigation scheme results in positioning estimates with under 3% uncertainty per distance traveled (UDT) in a turbulent, double-gyre flow field, and under 7.3% UDT in a turbulent, meandering jet flow field. Further evaluation with field test data and actual ocean simulation analysis demonstrates consistent performance for a 6-hour mission, positioning result with under 25% UDT for a 24-hour navigation when provided direct heading measurements, and terminal positioning estimate with 16% UDT at the cost of increased uncertainty at an early stage of the navigation.

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Wear-life analysis of deep groove ball bearings based on Archard wear theory

Xia

Song

et al. 2018

J Mech Sci Technol

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Multi-vehicle cooperation and nearly fuel-optimal flock guidance in strong background flows

2017

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A Compact Autonomous Underwater Vehicle With Cephalopod-Inspired Propulsion

Song¹,

Mazzola²,

Schwartz³

et al. 2016

mar technol soc j

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In this paper, a bioinspired, compact, cost-effective autonomous underwater vehicle system is presented. Designed to operate in a heterogeneous, multivehicle collaboration hierarchy, the presented vehicle design features 3D printing technology to enable fast fabrication with a complex internal structure. Similar to a previous vehicle prototype, this system generates propulsive forces by expelling unsteady, pulsed jets, inspired by the locomotion of cephalopods and jellyfish. The novel thrusters enable the vehicle to be fully actuated in horizontal plane motions, without sacrificing the low-forward-drag, slender vehicle profile. By successively ingesting water and expelling finite water jets, periodic actuation forces are generated at all possible vehicle velocities, eliminating the need for control surfaces used in many conventional underwater vehicle designs. A semiactive buoyancy control system, inspired by the nautilus, adjusts the vehicle depth by passively allowing water flowing into and actively expelling water out of an internal bladder. A compact embedded system is developed to achieve the control and sensing capabilities necessary for multiagent interactions with the minimum required processing power and at a low energy cost. The new vehicle design also showcases an underwater optical communication system for short-range, high-speed data transmission, supplementing the conventional acoustic communication system. Experimental results show that, with the thruster motors powered at a 60% duty-cycle, the new vehicle is able to achieve a 1/4 zero-radius turn in 3.5 s and one-body-width sway translation in 2.5 s.

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Coordinated Coverage and Fault Tolerance using Fixed-wing Unmanned Aerial Vehicles

Shriwastav

Song

2020

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Zhuoyuan Song

Long-Term Inertial Navigation Aided by Dynamics of Flow Field Features

Wear-life analysis of deep groove ball bearings based on Archard wear theory

Multi-vehicle cooperation and nearly fuel-optimal flock guidance in strong background flows

A Compact Autonomous Underwater Vehicle With Cephalopod-Inspired Propulsion

Coordinated Coverage and Fault Tolerance using Fixed-wing Unmanned Aerial Vehicles

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