Propulsive Performance And Maneuver Control Of Undulatory Ribbon Fin Propulsion Using Bio Inspired Robotic Systems

Propulsive Performance and Maneuver Control of Undulatory Ribbon Fin Propulsion Using Bio-inspired Robotic Systems

Author : Hanlin Liu

Publisher :

Page : 125 pages

File Size : 12,45 MB

Release : 2017

Category : Marine engineering

ISBN :

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Book Description

Undulatory ribbon-fin-based propulsion is an appealing propulsion mechanism due to its rich locomotor capabilities that can improve the propulsive performance and maneuverability of underwater vehicles. For instance, the swimming mechanics of weakly electric black ghost knifesh (Apteronotus albifrons) is of great interest to study because of their high swimming efficiency at low speeds and extraordinary agility such as rapid reversal swimming, hovering in presence of water disturbance, rolling and vertical swimming. In this thesis work, to facilitate our understanding on the flexible undulatory ribbon fin propulsion, we have four research motivations. The first objective is to study how the use of flexible rays and different fin morphology can influence the propulsive performance of ribbon-fin propulsion. It is possible that natural swimmers using this locomotion method could take advantage of passive fin motion based on the coupling of fluid-structure interaction and the elasto-mechanical responses of the undulating fin. Therefore, the second objective is to understand how an under-actuated undulating fin can take advantage of natural dynamics of the fluid-structure interaction for the propulsive force generation. In addition to the impressive propulsive performance of the undulatory fin propulsion, the exceptional maneuverability of knifesh is also a key motivation that drives this thesis work. Thus, we dedicate to investigate how traveling wave shapes and actuation parameters (frequency, wavelength) can manipulate the maneuvering behaviors of a swimmer propelled by an undulating ribbon fin. Lastly, we aim to uncover the varying traveling wave amplitudes and pectoral fins on its maneuvering performances. Two robotic devices were developed to study the propulsive performance of both fully actuated and under-actuated ribbon fin propulsion and investigate the maneuver control of a free-swimming underwater robot propelled by an undulatory fin. For the first research aim, we study the effect of flexible rays and different fin morphology on the propulsive performance of ribbon-fin propulsion. A physical model composed of fifteen rays interconnected with an elastic membrane was used to test four different ray flexural stiffness and four aspect ratios. Our results show that flexible rays can improve the propulsive effciency compared to a rigid counterpart. In addition, the morphology of the ribbon fin affects its propulsive performance as well, and there could exist an optimal fin morphology. To understand how an underactuated undulating fin can modify its active and passive fin motion to effectively control the hydrodynamic force and propulsive effciency. We did a series of experiments using the same robotic fin model but with some structural modications and we measured fin kinematics, net surge force and power consumption. We found that the under-actuated fin can keep the equivalent propulsive effciency as the fully-actuated counterpart within our experimental parameter range. Moreover, our results demonstrate that the thrust force and power consumption of an under-actuated fin follow the same scaling laws as the fully-actuated fin. To conduct the free-swimming maneuver study, we developed a self-contained, free-swimming robot propelled by an undulatory fin, which is able to perform the following maneuvers: forward, reversed swimming and hovering motion. We also performed V3V PIV experiments to capture the flow structures generated by the robotic device. Our results show that the robot can reach higher swimming effciency at low frequencies. As the number of traveling waves increases, the robot swims more stably in roll, pitch and yaw motions. For cases with varying wave amplitudes, traveling wave with incremental wave amplitude can achieve free-swimming velocity higher than that of decremental wave amplitude. However, the latter case can generate higher pitch angles. For the robot with slightly negative-pitched pectoral fins, it can perform slow diving maneuvers. These findings demonstrate that we can take advantage of the undulating ribbon fin propulsion to achieve high maneuverability for the future underwater vehicles in complex environment.



Bioinspired Sensing, Actuation, and Control in Underwater Soft Robotic Systems

Author : Derek A. Paley

Publisher : Springer Nature

Page : 301 pages

File Size : 40,32 MB

Release : 2020-11-06

Category : Technology & Engineering

ISBN : 303050476X

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Book Description

This book includes representative research from the state‐of‐the‐art in the emerging field of soft robotics, with a special focus on bioinspired soft robotics for underwater applications. Topics include novel materials, sensors, actuators, and system design for distributed estimation and control of soft robotic appendages inspired by the octopus and seastar. It summarizes the latest findings in an emerging field of bioinspired soft robotics for the underwater domain, primarily drawing from (but not limited to) an ongoing research program in bioinspired autonomous systems sponsored by the Office of Naval Research. The program has stimulated cross‐disciplinary research in biology, material science, computational mechanics, and systems and control for the purpose of creating novel robotic appendages for maritime applications. The book collects recent results in this area.



Analyzing the Effect of Fin Morphology on the Propulsive Performance of an Oscillating Caudal Fin Using a Robotic Model

Author : Tyler M. Fischer

Publisher :

Page : 61 pages

File Size : 44,97 MB

Release : 2017

Category : Artificial intelligence

ISBN :

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Book Description

A bio-inspired robotic underwater vessel was developed to test the effect of fin morphology on the propulsive performance of caudal fin. The robotic vessel, called The Bullet Fish, features a cylindrical body with a hemisphere at the forward section and a conical body at the stern. The vessel uses an oscillating caudal fin for thrust generation. The robotic vessel was tested in a recirculating flume for seven different caudal fins that range different bio-inspired forms and aspect ratios. The experiments were performed at four different flow velocities and two flapping frequencies: 0.5 and 1.0 Hz. We found that for 1 Hz flapping frequency that in general as the aspect-ratio decreases both thrust production tends and power decrease resulting in a better propulsive efficiency for aspect ratios between 0.9 and 1.0. A less uniform trend was found for 0.5 Hz, where our data suggest multiple efficiency peaks. Additional experiments on the robotic model could help understand the propulsion aquatic locomotion and help the design of bio-inspired underwater vehicles.



Robot Fish

Author : Ruxu Du

Publisher : Springer

Page : 380 pages

File Size : 23,75 MB

Release : 2015-05-06

Category : Technology & Engineering

ISBN : 3662468700

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Book Description

This book provides a comprehensive coverage on robot fish including design, modeling and optimization, control, autonomous control and applications. It gathers contributions by the leading researchers in the area. Readers will find the book very useful for designing and building robot fish, not only in theory but also in practice. Moreover, the book discusses various important issues for future research and development, including design methodology, control methodology, and autonomous control strategy. This book is intended for researchers and graduate students in the fields of robotics, ocean engineering and related areas.



Design and Characterization of Sectored (patterned) Ionic Polymer-metal Composite Actuators for Propulsion and Maneuvering in Bio-inspired Underwater Systems

Author : Joel Jackson Ures Hubbard

Publisher :

Page : 180 pages

File Size : 38,99 MB

Release : 2011

Category : Thesis

ISBN :

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Book Description

The goal of this thesis is to characterize the performance of ionic polymer-metal composite (IPMCs) propulsors for underwater applications, namely for propelling and maneuvering small bio-inspired autonomous systems. Specifically, this work examines the capabilities of IPMCs with sectored (patterned) electrodes. The electrode pattern on the surface of the ion exchange membrane is created, for example, using a straightforward surface-machining process. These IPMCs have recently been fabricated for realizing bending and twisting motion, where the main application is for creating next-generation artificial fish-like propulsors that can mimic the undulatory, flapping, and complex motions of real fish fins. Not only can the sectored IPMCs be used for actuation, but sections of the composite material can be employed as a sensor, for sensing fin deformation and responses to external stimulation. The result is a compact monolithic control surface with integrated sensing for multifunctional applications. Herein, a thorough experimental study is performed on IPMCs with sectored electrodes to characterize their performance. In particular, results are presented to show (1) the achievable twisting response; (2) blocking force and torque; (3) propulsion characteristics; (4) power consumption and effectiveness. These results can be utilized to guide the design of practical marine systems driven by IPMC propulsors. For example, a bio-inspired robotic system capable of ostraciiform locomotion with the potential to control pitch, roll, and yaw through complex twisting of the pectoral and tail fins is developed. The maximum speed for the initial prototype is measured at 2.8 cm/s. It is noted that significant improvements in swimming speed can be made, for example, by optimizing the IPMC-caudal fin geometry.



Nonlinear Control of Robotic Fish

Author : Maria L. Castano

Publisher :

Page : 169 pages

File Size : 45,89 MB

Release : 2021

Category : Electronic dissertations

ISBN :

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Book Description

In the past few decades, robots that propel and maneuver themselves like fish, known as robotic fish, have received substantial attention due to their efficiency, maneuverability, and lifelike features. Their agile locomotion can be partially attributed to their bio-inspired propulsion methods, which range from tail (caudal) and dorsal to paired pectoral fins. While these characteristics make robotic fish an attractive choice for a myriad of aquatic applications, their highly nonlinear, often under-actuated dynamics and actuator constraints present significant challenges in control design. The goal of this dissertation is to develop systematic model-based control approaches that guarantee closed-loop system stability, accommodate input constraints, and are computationally viable for robotic fish. We first propose a nonlinear model predictive control (NMPC) approach for path-following of a tail-actuated robotic fish, where the control design is based on an averaged dynamic model. The bias and the amplitude of the tail oscillation are treated as physical variables to be manipulated and are related to the control inputs via a nonlinear map. A control projection method is introduced to accommodate the inputs constraints while minimizing the optimization complexity in solving the NMPC problem. Both simulation and experimental results on a tail-actuated robotic fish support the efficacy of the proposed approach and its advantages over alternative approaches. Although NMPC is a promising candidate for tracking control, its computational complexity poses significant challenges in its implementation on resource-constrained robotic fish. We thus propose a backstepping-based trajectory tracking control scheme that is computationally inexpensive and guarantees closed-loop stability. We demonstrate how the control scheme can be synthesized to handle input constraints and establish via singular perturbation analysis the ultimate boundedness of three tracking errors (2D-position and orientation) despite the under-actuated nature of the robot. The effectiveness of this approach is supported by both simulation and experimental results on a tail-actuated robotic fish. We then turn our attention to pectoral fin-actuated robotic fish. Despite its benefits in achieving agile maneuvering at low swimming speeds, the range constraint of pectoral fin movement presents challenges in control. To overcome these challenges, we propose two different backstepping-based control approaches to achieve trajectory tracking and quick-maneuvering control, respectively. We first propose a scaling-based approach to develop a control-affine nonlinear dynamic average model for a pectoral fin-actuated robotic fish, which is validated via both simulation and experiments. The utility of the developed average dynamic model is then demonstrated via the synthesis of a dual-loop backstepping-based trajectory tracking controller. Cyclic actuation can often limit precise manipulation of the fin movements and the full exploitation of the maneuverability of pectoral fin-actuated robotic fish. To achieve quick velocity maneuvering control, we propose a dual-loop control approach composed of a backstepping-based controller in the outer loop and a fin movement-planning algorithm in the inner loop. Simulation results are presented to demonstrate the performance of the proposed scheme via comparison with a nonlinear model predictive controller.



Principles of Animal Locomotion

Author : R. McNeill Alexander

Publisher : Princeton University Press

Page : 384 pages

File Size : 36,87 MB

Release : 2006-03-19

Category : Science

ISBN : 0691126348

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Book Description

How can geckoes walk on the ceiling and basilisk lizards run over water? What are the aerodynamic effects that enable small insects to fly? What are the relative merits of squids' jet-propelled swimming and fishes' tail-powered swimming? Why do horses change gait as they increase speed? What determines our own vertical leap? Recent technical advances have greatly increased researchers' ability to answer these questions with certainty and in detail. This text provides an up-to-date overview of how animals run, walk, jump, crawl, swim, soar, hover, and fly. Excluding only the tiny creatures that use cilia, it covers all animals that power their movements with muscle--from roundworms to whales, clams to elephants, and gnats to albatrosses. The introduction sets out the general rules governing all modes of animal locomotion and considers the performance criteria--such as speed, endurance, and economy--that have shaped their selection. It introduces energetics and optimality as basic principles. The text then tackles each of the major modes by which animals move on land, in water, and through air. It explains the mechanisms involved and the physical and biological forces shaping those mechanisms, paying particular attention to energy costs. Focusing on general principles but extensively discussing a wide variety of individual cases, this is a superb synthesis of current knowledge about animal locomotion. It will be enormously useful to advanced undergraduates, graduate students, and a range of professional biologists, physicists, and engineers.



Legged Robots that Balance

Author : Marc H. Raibert

Publisher : MIT Press

Page : 254 pages

File Size : 18,66 MB

Release : 1986

Category : Computers

ISBN : 9780262181174

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Book Description

This book, by a leading authority on legged locomotion, presents exciting engineering and science, along with fascinating implications for theories of human motor control. It lays fundamental groundwork in legged locomotion, one of the least developed areas of robotics, addressing the possibility of building useful legged robots that run and balance. The book describes the study of physical machines that run and balance on just one leg, including analysis, computer simulation, and laboratory experiments. Contrary to expectations, it reveals that control of such machines is not particularly difficult. It describes how the principles of locomotion discovered with one leg can be extended to systems with several legs and reports preliminary experiments with a quadruped machine that runs using these principles. Raibert's work is unique in its emphasis on dynamics and active balance, aspects of the problem that have played a minor role in most previous work. His studies focus on the central issues of balance and dynamic control, while avoiding several problems that have dominated previous research on legged machines. Marc Raibert is Associate Professor of Computer Science and Robotics at Carnegie-Mellon University and on the editorial board of The MIT Press journal, Robotics Research. Legged Robots That Balanceis fifteenth in the Artificial Intelligence Series, edited by Patrick Winston and Michael Brady.



Biological Materials of Marine Origin

Author : Hermann Ehrlich

Publisher : Springer

Page : 439 pages

File Size : 42,9 MB

Release : 2014-12-01

Category : Technology & Engineering

ISBN : 9400757301

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Book Description

This is the second monograph by the author on biological materials of marine origin. The initial book is dedicated to the biological materials of marine invertebrates. This work is a source of modern knowledge on biomineralization, biomimetics and materials science with respect to marine vertebrates. For the first time in scientific literature the author gives the most coherent analysis of the nature, origin and evolution of biocomposites and biopolymers isolated from and observed in the broad variety of marine vertebrate organisms (fish, reptilian, birds and mammals) and within their unique hierarchically organized structural formations. There is a wealth of new and newly synthesized information, including dozens of previously unpublished images of unique marine creatures including extinct, extant and living taxa and their biocomposite-based structures from nano- to micro – and macroscale. This monograph reviews the most relevant advances in the marine biological materials research field, pointing out several approaches being introduced and explored by distinct modern laboratories.



Anagram Solver

Author : Bloomsbury Publishing

Publisher : Bloomsbury Publishing

Page : 719 pages

File Size : 27,72 MB

Release : 2009-01-01

Category : Games & Activities

ISBN : 1408102579

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Book Description

Anagram Solver is the essential guide to cracking all types of quiz and crossword featuring anagrams. Containing over 200,000 words and phrases, Anagram Solver includes plural noun forms, palindromes, idioms, first names and all parts of speech. Anagrams are grouped by the number of letters they contain with the letters set out in alphabetical order so that once the letters of an anagram are arranged alphabetically, finding the solution is as easy as locating the word in a dictionary.