Exploiting natural dynamics for gait generation in undulatory locomotion

Ludeke, Taylor; Iwasaki, Tetsuya

doi:10.1080/00207179.2019.1569763

Cited by 6 publications

(7 citation statements)

References 35 publications

(39 reference statements)

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“…Contrarily, in [ 24 ] for dry frictional environment, it is found that at resonance, the speed of undulatory locomotion decreases and the power increases. More recently, in [ 37 ], for viscous friction, the resonance frequency is defined as the frequency at which the speed of a system is maximized with minimum actuation effort for undulatory locomotion. In this section we study the correlation between the input frequency and the resulting speed.…”

Section: Resultsmentioning

confidence: 99%

Towards the optimization of passive undulatory locomotion on land: mathematical and physical models

Yaqoob

Dottore

Mondini

et al. 2023

J. R. Soc. Interface.

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The current study investigates the body–environment interaction and exploits the passive viscoelastic properties of the body to perform undulatory locomotion. The investigations are carried out using a mathematical model based on a dry frictional environment, and the results are compared with the performance obtained using a physical model. The physical robot is a wheel-based modular system with flexible joints moving on different substrates. The influence of the spatial distribution of body stiffness on speed performance is also investigated. Our results suggest that the environment affects the performance of undulatory locomotion based on the distribution of body stiffness. While stiffness may vary with the environment, we have established a qualitative constitutive law that holds across environments. Specifically, we expect the stiffness distribution to exhibit either an ascending–descending or an ascending–plateau pattern along the length of the object, from head to tail. Furthermore, undulatory locomotion showed sensitivity to contact mechanics: solid–solid or solid–viscoelastic contact produced different locomotion kinematics. Our results elucidate how terrestrial limbless animals achieve undulatory locomotion performance by exploiting the passive properties of the environment and the body. Application of the results obtained may lead to better performing long-segmented robots that exploit the suitability of passive body dynamics and the properties of the environment in which they need to move.

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Section: Resultsmentioning

confidence: 99%

Towards the optimization of passive undulatory locomotion on land: mathematical and physical models

Yaqoob

Dottore

Mondini

et al. 2023

J. R. Soc. Interface.

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“…The author emphasizes that the analytical fluid force model ( 4) is greatly simplified and cannot, for example, describe the pressure or shear force variation across the wings or body obeying the Bernoulli's principle as shown in figures 14(a) and (b) in [16] or other hydrodynamic characteristics of the swimming. It is only used in our study as well as other studies [21,23,[32][33][34][35]37] to give an approximation of the fluid force acting on the wing or body in the study of wing-or body-fluid interaction which allows us to study the response of wing kinematics to the tension and fluid force, to investigate the influence of resonance exploitation of wing natural modes on wing oscillation amplitude, the total thrust and the muscle power consumption, and to derive the analytical relationships of swimming kinematics and kinetics (the results in sections 4.1 and 4.2). For example, simulation showed that when the actuation frequency of the wing was 0.5 Hz, off the resonance frequency 0.29 Hz, the peak power of the middle tensegrity fin rays increased by more than 70%, but both the wing peak-to-peak oscillation .…”

Section: Determination Of Added Mass Coefficientmentioning

confidence: 99%

Flexible tensegrity wing design and insights in principles of swimming kinematics of batoid rays

Chen¹

2021

Bioinspir. Biomim.

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A novel tensegrity wing design is first proposed which can emulate the kinematic waves of the pectoral fin of batoid rays and has a simple structure for manufacture. The attitude control and the regulation of wing natural frequency are realized by wing morphing. Then analytical insights in batoid ray swimming are gained by analyzing the analytical wing (cable)–fluid interaction model, whose parameters are determined based on the biological data. The stride length (traveled distance per cycle normalized by the body length (BL)) is shown to be almost invariant among different-sized rays if the phase and amplitude of wing flexion angles remain unchanged. This result is supported by biological data, 1.5 and 1.47 respectively for the manta ray and cownose ray, though their flapping frequencies (0.15–0.45 Hz and 0.64–1.25 Hz respectively) and body sizes (1.25 m and 0.15 m respectively) are very different, and similar to the expression for the carangiform fish swimming. In other words, the swimming kinematics of two different swimming forms are described by a similar analytical equation when the body resonance is exploited. The fluid force and cable tension are both found to be proportional to the fourth power of the body size and the square of the wing flapping frequency, which may tell that the flapping frequency of the manta ray (BL = 1.25 m) is much smaller than that of the cownose ray (BL = 0.15 m) is to avoid both the large actuation tension and fluid force density due to the size increase.

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“…By synchronizing body undulation frequency with the flow, fish swim efficiently, harnessing energy from the fluid and converting it into propulsion (Beal et al, 2006; Akanyeti et al, 2016; Liao and Akanyeti, 2017). The oscillation of the caudal fin emerges as one of the most efficient propulsion modes in terms of transport costs (Rayner, 1986; Ludeke and Iwasaki, 2019), and underwater speeds are enhanced significantly (Block et al, 1992), resulting in passive propulsion even in deceased fish specimens (Liao et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

Repetitive Learning Control for Body Caudal Undulation with Soft Sensory Feedback

Schwab,

El Arayshi,

Rezaei

et al. 2024

Preprint

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Soft bio-inspired robotics is a growing field of research that seeks to close the gap with animal robustness and adaptability where conventional robots fall short. The embedding of sensors with the capability to discriminate between different body deformation modes is a key technological challenge in soft robotics to enhance robot control — a difficult task for such kinds of systems with high degrees of freedom. The recently conceived Linear Repetitive Learning Estimation Scheme (LRLES) — to be included in the traditional Proportional Integral Derivative (PID) control — is proposed here as a way to compensate for uncertain dynamics on a soft swimming robot, which is actuated with soft pneumatic actuators and equipped with soft sensors providing proprioceptive information pertaining to lateral body caudal bending akin to a goniometer. The proposed controller is derived in detail and experimentally validated, with the experiment consisting of tracking a desired trajectory for bending angle while continuously oscillating with a constant frequency. The results are compared vis a vis those achieved with the traditional PID controller, finding that the PID endowed with the LRLES outperforms the PID controller (though the latter has been separately tuned) and experimentally validating the novel controller's effectiveness, accuracy, and matching speed.

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Exploiting natural dynamics for gait generation in undulatory locomotion

Cited by 6 publications

References 35 publications

Towards the optimization of passive undulatory locomotion on land: mathematical and physical models

Towards the optimization of passive undulatory locomotion on land: mathematical and physical models

Flexible tensegrity wing design and insights in principles of swimming kinematics of batoid rays

Repetitive Learning Control for Body Caudal Undulation with Soft Sensory Feedback

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