Design Optimization of Folding Solar Powered Autonomous Underwater Vehicles Using Origami Architecture

Hur, Doe Young; Hernandez, Edwin A. Peraza; Galván, Edgar; Hartl, Darren J.; Malak, Richard J.

doi:10.1115/detc2017-67848

Cited by 3 publications

(1 citation statement)

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“…Such a simplification cannot capture the influence of compliant creases or thickness in an origami pattern, which can be significant in studying the mechanical behaviours of origami, such as bistability in a four-crease vertex [35]. The smooth fold model proposed by Hernandez and coworkers [36][37][38][39] captures the influence of compliant creases on an origami by explicitly including crease width into the model and solving for the corresponding crease curvature and crease stretching at equilibrium. Zhu & Filipov [40] recently proposed a bar and hinge implementation with compliant creases, which provides a faster simulation technique when only the global behaviour of origami is of interest.…”

Section: (A) Origami Simulation Techniquesmentioning

confidence: 99%

An efficient numerical approach for simulating contact in origami assemblages

Filipov

2019

Proc. R. Soc. A.

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Origami-inspired structures provide novel solutions to many engineering applications. The presence of self-contact within origami patterns has been difficult to simulate, yet it has significant implications for the foldability, kinematics and resulting mechanical properties of the final origami system. To open up the full potential of origami engineering, this paper presents an efficient numerical approach that simulates the panel contact in a generalized origami framework. The proposed panel contact model is based on the principle of stationary potential energy and assumes that the contact forces are conserved. The contact potential is formulated such that both the internal force vector and the stiffness matrix approach infinity as the distance between the contacting panel and node approaches zero. We use benchmark simulations to show that the model can correctly capture the kinematics and mechanics induced by contact. By tuning the model parameters accordingly, this methodology can simulate the thickness in origami. Practical examples are used to demonstrate the validity, efficiency and the broad applicability of the proposed model.

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Section: (A) Origami Simulation Techniquesmentioning

confidence: 99%

An efficient numerical approach for simulating contact in origami assemblages

Filipov

2019

Proc. R. Soc. A.

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Tuck-Folding Method for the Design of Origami Structures with Smooth Folds

Hernandez¹,

Hartl²,

Lagoudas³

2019

Active Origami

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Energy Optimization Techniques in Underwater Internet of Things: Issues, State-of-the-Art, and Future Directions

Yoon

et al. 2022

Water

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The underwater internet of things (UIoT) has emerged as a booming technology in today’s digital world due to the enhancement of a wide range of underwater applications concerning ocean exploration, deep-sea monitoring, underwater surveillance, diver network monitoring, location and object tracking, etc. Generally, acoustic, infrared (IR), visible light (VL), radiofrequency (RF), and magnet induction (MI) are used as the medium of communication in order to transfer information among digitally linked underwater devices. However, each communication medium has its advantages and limitations: for example, the acoustic communication medium is suitable for long-range data transmission but has challenges such as narrow bandwidth, long delay, and high cost, etc., and the optical medium is suitable for short-range data transmission but has challenges such as high attenuation, and optical scattering due to water particles, etc. Furthermore, UIoT devices are operated using batteries with limited capacity and high energy consumption; hence, energy consumption is considered as one of the most significant challenges in UIoT networks. Therefore, to support reliable and energy-efficient communication in UIoT networks, it is necessary to adopt robust energy optimization techniques for UIoT networks. Hence, this paper focuses on identifying the various issues concerning energy optimization in the underwater internet of things and state-of-the-art contributions relevant to inducement techniques of energy optimization in the underwater internet of things; that provides a systematic literature review (SLR) on various power-saving and optimization techniques of UIoT networks since 2010, along with core applications, and research gaps. Finally, future directions are proposed based on the analysis of various energy optimization issues and techniques of UIoT networks. This research contributes much to the profit of researchers and developers to build smart, energy-efficient, auto-rechargeable, and battery-less communication systems for UIoT networks.

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Design Optimization of Folding Solar Powered Autonomous Underwater Vehicles Using Origami Architecture

Cited by 3 publications

References 0 publications

An efficient numerical approach for simulating contact in origami assemblages

An efficient numerical approach for simulating contact in origami assemblages

Tuck-Folding Method for the Design of Origami Structures with Smooth Folds

Energy Optimization Techniques in Underwater Internet of Things: Issues, State-of-the-Art, and Future Directions

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