Your search keyword '"Ardian Jusufi"' showing total 33 results

1. Learning control for body caudal undulation with soft sensory feedback

Author

Fabian Schwab, Mohamed El Arayshi, Seyedreza Rezaei, Hadrien Sprumont, Federico Allione, Claudio Mucignat, Ivan Lunati, Cristiano Maria Verrelli, and Ardian Jusufi

Subjects

bio-mimicry, soft robotics, repetitive learning, robotic fish, locomotion, swimming, Biotechnology, TP248.13-248.65

Abstract

Soft bio-mimetic 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 this type 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 the bending angle envelope 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.

Published

2024

2. Modeling and Control of a Soft Robotic Fish with Integrated Soft Sensing

Author

Yu-Hsiang Lin, Robert Siddall, Fabian Schwab, Toshihiko Fukushima, Hritwick Banerjee, Youngjoon Baek, Daniel Vogt, Yong-Lae Park, and Ardian Jusufi

Subjects

actuators, bioinspired robots, locomotion, modeling, soft robots, soft sensors, Computer engineering. Computer hardware, TK7885-7895, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

Soft robotics can be used not only as a means of achieving novel, more lifelike forms of locomotion, but also as a tool to understand complex biomechanics through the use of robotic model animals. Herein, the control of the undulation mechanics of an entirely soft robotic subcarangiform fish is presented, using antagonistic fast‐PneuNet actuators and hyperelastic eutectic gallium–indium (eGaIn) embedded in silicone channels for strain sensing. To design a controller, a simple, data‐driven lumped parameter approach is developed, which allows accurate but lightweight simulation, tuned using experimental data and a genetic algorithm. The model accurately predicts the robot's behavior over a range of driving frequencies and a range of pressure amplitudes, including the effect of antagonistic co‐contraction of the soft actuators. An amplitude controller is prototyped using the model and deployed to the robot to reach the setpoint of a tail‐beat amplitude using fully soft and real‐time strain sensing.

Published

2023

3. Tails stabilize landing of gliding geckos crashing head-first into tree trunks

Author

Robert Siddall, Greg Byrnes, Robert J. Full, and Ardian Jusufi

Subjects

Biology (General), QH301-705.5

Abstract

Siddall, Byrnes, Full, and Jusufi observe the function of the Asian flat-tailed gecko tail in gliding and landing on tree trunks in the field, complemented with mathematical and robotic models made of soft active materials. Altogether, their models show how geckos use an active tail reflex to brace the impact and reduce the risk of falling from landings on tree trunks.

Published

2021

4. Morphologically Adaptive Crash Landing on a Wall: Soft‐Bodied Models of Gliding Geckos with Varying Material Stiffnesses

Author

Mrudul Chellapurath, Pranav Khandelwal, Tom Rottier, Fabian Schwab, and Ardian Jusufi

Subjects

bioinspired robot, biomimetic robot, gecko, landing, perching, soft robot, Computer engineering. Computer hardware, TK7885-7895, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

Landing on vertical surfaces in challenging environments is a critical ability for multimodal robots—it allows the robot to hold position above the ground without expending energy to hover. Asian flat‐tailed geckos (Hemidactylus platyurus) are observed to glide and perch on vertical surfaces by relying on their tail and body morphology, potentially reducing the control effort to perch. This novel perching mechanism using a bioinspired physical model is discussed and its tail and body parameters to determine their influence on perching success and the kinematics of the gecko's dynamic landing maneuver are adjusted. Perching performance is evaluated by changing the model's torso and tail stiffness. Combining a compliant torso and stiff tail enables the model to passively perch on a vertical substrate with a success rate >90%, compared with ≈10% without a tail attached. A compliant torso is necessary to absorb the in‐flight kinetic energy and accommodate the uncertainties in approach conditions. Similar to the gecko's perching strategy, the stiff tail pushes against the substrate, preventing the model from falling backward head over heels. These findings highlight the critical role of tail and material stiffness for perching and provide a simplified mechanism to impart perching capabilities in robots.

Published

2022

5. Undulatory Swimming Performance Explored With a Biorobotic Fish and Measured by Soft Sensors and Particle Image Velocimetry

Author

Fabian Schwab, Fabian Wiesemüller, Claudio Mucignat, Yong-Lae Park, Ivan Lunati, Mirko Kovac, and Ardian Jusufi

Subjects

fish, robot, tail, sensor, feedback, flow, Mechanical engineering and machinery, TJ1-1570, Electronic computers. Computer science, QA75.5-76.95

Abstract

Due to the difficulty of manipulating muscle activation in live, freely swimming fish, a thorough examination of the body kinematics, propulsive performance, and muscle activity patterns in fish during undulatory swimming motion has not been conducted. We propose to use soft robotic model animals as experimental platforms to address biomechanics questions and acquire understanding into subcarangiform fish swimming behavior. We extend previous research on a bio-inspired soft robotic fish equipped with two pneumatic actuators and soft strain sensors to investigate swimming performance in undulation frequencies between 0.3 and 0.7 Hz and flow rates ranging from 0 to 20 cms in a recirculating flow tank. We demonstrate the potential of eutectic gallium–indium (eGaIn) sensors to measure the lateral deflection of a robotic fish in real time, a controller that is able to keep a constant undulatory amplitude in varying flow conditions, as well as using Particle Image Velocimetry (PIV) to characterizing swimming performance across a range of flow speeds and give a qualitative measurement of thrust force exerted by the physical platform without the need of externally attached force sensors. A detailed wake structure was then analyzed with Dynamic Mode Decomposition (DMD) to highlight different wave modes present in the robot’s swimming motion and provide insights into the efficiency of the robotic swimmer. In the future, we anticipate 3D-PIV with DMD serving as a global framework for comparing the performance of diverse bio-inspired swimming robots against a variety of swimming animals.

Published

2022

6. Wearable and Stretchable Strain Sensors: Materials, Sensing Mechanisms, and Applications

Author

Hamid Souri, Hritwick Banerjee, Ardian Jusufi, Norbert Radacsi, Adam A. Stokes, Inkyu Park, Metin Sitti, and Morteza Amjadi

Subjects

composites, nanomaterials, polymers, soft robotics, wearable strain sensors, Computer engineering. Computer hardware, TK7885-7895, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

Recent advances in the design and implementation of wearable resistive, capacitive, and optical strain sensors are summarized herein. Wearable and stretchable strain sensors have received extensive research interest due to their applications in personalized healthcare, human motion detection, human–machine interfaces, soft robotics, and beyond. The disconnection of overlapped nanomaterials, reversible opening/closing of microcracks in sensing films, and alteration of the tunneling resistance have been successfully adopted to develop high‐performance resistive‐type sensors. On the other hand, the sensing behavior of capacitive‐type and optical strain sensors is largely governed by their geometrical changes under stretching/releasing cycles. The sensor design parameters, including stretchability, sensitivity, linearity, hysteresis, and dynamic durability, are comprehensively discussed. Finally, the promising applications of wearable strain sensors are highlighted in detail. Although considerable progress has been made so far, wearable strain sensors are still in their prototype stage, and several challenges in the manufacturing of integrated and multifunctional strain sensors should be yet tackled.

Published

2020

7. Rapid inversion: running animals and robots swing like a pendulum under ledges.

Author

Jean-Michel Mongeau, Brian McRae, Ardian Jusufi, Paul Birkmeyer, Aaron M Hoover, Ronald Fearing, and Robert J Full

Subjects

Medicine, Science

Abstract

Escaping from predators often demands that animals rapidly negotiate complex environments. The smallest animals attain relatively fast speeds with high frequency leg cycling, wing flapping or body undulations, but absolute speeds are slow compared to larger animals. Instead, small animals benefit from the advantages of enhanced maneuverability in part due to scaling. Here, we report a novel behavior in small, legged runners that may facilitate their escape by disappearance from predators. We video recorded cockroaches and geckos rapidly running up an incline toward a ledge, digitized their motion and created a simple model to generalize the behavior. Both species ran rapidly at 12-15 body lengths-per-second toward the ledge without braking, dove off the ledge, attached their feet by claws like a grappling hook, and used a pendulum-like motion that can exceed one meter-per-second to swing around to an inverted position under the ledge, out of sight. We discovered geckos in Southeast Asia can execute this escape behavior in the field. Quantification of these acrobatic behaviors provides biological inspiration toward the design of small, highly mobile search-and-rescue robots that can assist us during natural and human-made disasters. We report the first steps toward this new capability in a small, hexapedal robot.

Published

2012

8. Soft Sensors for Curvature Estimation under Water in a Soft Robotic Fish.

Author

Brian Wright, Daniel M. Vogt, Robert J. Wood, and Ardian Jusufi

Published

2019

9. Heads or Tails? Cranio-Caudal Mass Distribution for Robust Locomotion with Biorobotic Appendages Composed of 3D-Printed Soft Materials.

Author

Robert Siddall, Fabian Schwab, Jenny Michel, James Weaver, and Ardian Jusufi

Published

2019

10. Strong, Ultrastretchable Hydrogel‐Based Multilayered Soft Actuator Composites Enhancing Biologically Inspired Pumping Systems

Author

Hritwick Banerjee, Manivannan Sivaperuman Kalairaj, Hongliang Ren, and Ardian Jusufi

Subjects

General Materials Science, Condensed Matter Physics

Published

2023

11. Tail wags the dogis unsupported by biomechanical Modeling of Canidae Tails Use during Terrestrial Motion

Author

Tom Rottier, Andrew K. Schulz, Katja Söhnel, Kathryn Mccarthy, Martin S. Fischer, and Ardian Jusufi

Abstract

Dogs and other members of Canidae utilize their tail for different purposes including agile movement such as running and jumping. One of the unique aspects of the Canidae species is they have a very small size differential as a clade with all of the extant canid species are below 35 kg, except large dog breeds. In this study, we utilize morphological geometries of the animals to test differences in tail use in 24 extant Canidae. We propose evolutionary trade-offs of larger and more massive tails through varying simulations. This work could alleviate unknown biomechanical use of the tails to understand the behavioral biomechanics of lesser-known species in their ability to use their tail for rapid and taxing behaviors including sprinting or climbing. We analyze the phylogenetics between the kinematics of tail use to predicatively hypothesize differences of function for variable center of mass benefits.

Published

2022

12. Tails stabilize landing of gliding geckos crashing head-first into tree trunks

Author

Greg Byrnes, Robert J. Full, Ardian Jusufi, and Robert Siddall

Subjects

Rainforest, QH301-705.5, Medicine (miscellaneous), Southeast asian, Article, General Biochemistry, Genetics and Molecular Biology, Trees, Vertical surfaces, medicine, Animals, Biomechanics, Gecko, Biology (General), Singapore, Head First, biology, Herpetology, Lizards, Torso, Geodesy, biology.organism_classification, Biomechanical Phenomena, body regions, Tree (data structure), medicine.anatomical_structure, Reflex, General Agricultural and Biological Sciences, Falling (sensation), Locomotion, Geology

Abstract

Animals use diverse solutions to land on vertical surfaces. Here we show the unique landing of the gliding gecko, Hemidactylus platyurus. Our high-speed video footage in the Southeast Asian rainforest capturing the first recorded, subcritical, short-range glides revealed that geckos did not markedly decrease velocity prior to impact. Unlike specialized gliders, geckos crashed head-first with the tree trunk at 6.0 ± 0.9 m/s (~140 body lengths per second) followed by an enormous pitchback of their head and torso 103 ± 34° away from the tree trunk anchored by only their hind limbs and tail. A dynamic mathematical model pointed to the utility of tails for the fall arresting response (FAR) upon landing. We tested predictions by measuring foot forces during landing of a soft, robotic physical model with an active tail reflex triggered by forefoot contact. As in wild animals, greater landing success was found for tailed robots. Experiments showed that longer tails with an active tail reflex resulted in the lower adhesive foot forces necessary for stabilizing successful landings, with a tail shortened to 25% requiring over twice the adhesive foot force., Siddall, Byrnes, Full, and Jusufi observe the function of the Asian flat-tailed gecko tail in gliding and landing on tree trunks in the field, complemented with mathematical and robotic models made of soft active materials. Altogether, their models show how geckos use an active tail reflex to brace the impact and reduce the risk of falling from landings on tree trunks.

Published

2021

13. Tails, Flails, and Sails: How Appendages Improve Terrestrial Maneuverability by Improving Stability

Author

Ardian Jusufi, Stacey Shield, Amir Patel, and Ricardo Jericevich

Subjects

Tail, 0106 biological sciences, 0301 basic medicine, Inertial frame of reference, Computer science, media_common.quotation_subject, Plant Science, Inertia, Models, Biological, 010603 evolutionary biology, 01 natural sciences, Motion capture, 03 medical and health sciences, Acceleration, Gait (human), Control theory, Animals, Gait, media_common, Appendage, Symposium, business.industry, Robotics, Trajectory optimization, Biomechanical Phenomena, 030104 developmental biology, AcademicSubjects/SCI00960, Animal Science and Zoology, Artificial intelligence, business, Locomotion

Abstract

Trade-offs in maneuverability and stability are essential in ecologically relevant situations with respect to robustness of locomotion, with multiple strategies apparent in animal model systems depending on their habitat and ecology. Free appendages such as tails and ungrounded limbs may assist in navigating this trade-off by assisting with balance, thereby increasing the acceleration that can be achieved without destabilizing the body. This comparative analysis explores the inertial mechanisms and, in some cases, fluid dynamic mechanisms by which appendages contribute to the stabilization of gait and perturbation response behaviors in a wide variety of animals. Following a broad review of examples from nature and bio-inspired robotics that illustrate the importance of appendages to the control of body orientation, two specific cases are examined through preliminary experiments: the role of arm motion in bipedal gait termination is explored using trajectory optimization, and the role of the cheetah’s tail during a deceleration maneuver is analyzed based on motion capture data. In both these examples, forward rotation of the appendage in question is found to counteract the unwanted forward pitch caused by the braking forces. It is theorized that this stabilizing action may facilitate more rapid deceleration by allowing larger or longer-acting braking forces to be applied safely.

Published

2021

14. Inertial Tail Effects during Righting of Squirrels in Unexpected Falls: From Behavior to Robotics

Author

Séverine Toussaint, John A. Nyakatura, Greg Byrnes, Fabian Schwab, Robert Siddall, Toshihiko Fukushima, and Ardian Jusufi

Subjects

Tail, Arboreal locomotion, Symposium, Inertial frame of reference, Computer science, business.industry, media_common.quotation_subject, Sciuridae, Robotics, Plant Science, Inertia, Rotation, Models, Biological, Trees, Control theory, AcademicSubjects/SCI00960, Animals, Accidental Falls, Animal Science and Zoology, Artificial intelligence, business, media_common

Abstract

Arboreal mammals navigate a highly three dimensional and discontinuous habitat. Among arboreal mammals, squirrels demonstrate impressive agility. In a recent “viral” YouTube video, unsuspecting squirrels were mechanically catapulted off of a track, inducing an initially uncontrolled rotation of the body. Interestingly, they skillfully stabilized themselves using tail motion, which ultimately allowed the squirrels to land successfully. Here we analyze the mechanism by which the squirrels recover from large body angular rates. We analyzed from the video that squirrels first use their tail to help stabilizing their head to visually fix a landing site. Then the tail starts to rotate to help stabilizing the body, preparing themselves for landing. To analyze further the mechanism of this tail use during mid-air, we built a multibody squirrel model and showed the righting strategy based on body inertia moment changes and active angular momentum transfer between axes. To validate the hypothesized strategy, we made a squirrel-like robot and demonstrated a fall-stabilizing experiment. Our results demonstrate that a squirrel’s long tail, despite comprising just 3% of body mass, can inertially stabilize a rapidly rotating body. This research contributes to better understanding the importance of long tails for righting mechanisms in animals living in complex environments such as trees.

Published

2021

15. Compliance, mass distribution and contact forces in cursorial and scansorial locomotion with biorobotic physical models

Author

Era Hasimja, Lina Martin, Drilon Bardhi, Toshihiko Fukushima, Albulena Morina, Yll Dujaka, Robert Siddall, Ardian Jusufi, Gezim Haziri, Buna Perteshoni, and Hritwick Banerjee

Subjects

0209 industrial biotechnology, Physical model, Mass distribution, business.industry, Computer science, Robotics, 02 engineering and technology, Cursorial, Computer Science Applications, Contact force, Human-Computer Interaction, 020901 industrial engineering & automation, Hardware and Architecture, Control and Systems Engineering, Climbing, Obstacle, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Artificial intelligence, Aerospace engineering, business, Software

Abstract

Locomotion in unstructured and irregular environments is an enduring challenge in robotics. This is particularly true at the small scale, where relative obstacle size increases, often to the point ...

Published

2021

16. Undulatory Swimming Performance Explored With a Biorobotic Fish Measured by Soft Sensors and Particle Image Velocimetry

Author

Fabian Schwab, Fabian Wiesemüller, Claudio Mucignat, Yong-Lae Park, Ivan Lunati, Mirko Kovac, and Ardian Jusufi

Subjects

Robotics and AI, fish, robot, feedback, QA75.5-76.95, Computer Science Applications, PIV, tail, Artificial Intelligence, sensor, flow, Electronic computers. Computer science, DMD, TJ1-1570, Mechanical engineering and machinery, Original Research

Abstract

Due to the difficulty of manipulating muscle activation in live, freely swimming fish, a thorough examination of the body kinematics, propulsive performance, and muscle activity patterns in fish during undulatory swimming motion has not been conducted. We propose to use soft robotic model animals as experimental platforms to address biomechanics questions and acquire understanding into subcarangiform fish swimming behavior. We extend previous research on a bio-inspired soft robotic fish equipped with two pneumatic actuators and soft strain sensors to investigate swimming performance in undulation frequencies between 0.3 and 0.7 Hz and flow rates ranging from 0 to 20 cms in a recirculating flow tank. We demonstrate the potential of eutectic gallium–indium (eGaIn) sensors to measure the lateral deflection of a robotic fish in real time, a controller that is able to keep a constant undulatory amplitude in varying flow conditions, as well as using Particle Image Velocimetry (PIV) to characterizing swimming performance across a range of flow speeds and give a qualitative measurement of thrust force exerted by the physical platform without the need of externally attached force sensors. A detailed wake structure was then analyzed with Dynamic Mode Decomposition (DMD) to highlight different wave modes present in the robot’s swimming motion and provide insights into the efficiency of the robotic swimmer. In the future, we anticipate 3D-PIV with DMD serving as a global framework for comparing the performance of diverse bio-inspired swimming robots against a variety of swimming animals.

Published

2022

17. Mechanisms for Mid-Air Reorientation Using Tail Rotation in Gliding Geckos

Author

Ardian Jusufi, Greg Byrnes, Robert J. Full, Robert Siddall, and Victor Ibanez

Subjects

Tail, Arboreal locomotion, Inertial frame of reference, media_common.quotation_subject, Posture, Lizards, Plant Science, Invited Paper, Rotation, Inertia, Biomechanical Phenomena, Aerodynamic force, Gliding flight, Flight, Animal, Orientation (geometry), AcademicSubjects/SCI00960, Animals, Animal Science and Zoology, Descent (aeronautics), Biological system, Geology, media_common

Abstract

Arboreal animals face numerous challenges when negotiating complex three-dimensional terrain. Directed aerial descent or gliding flight allows for rapid traversal of arboreal environments, but presents control challenges. Some animals, such as birds or gliding squirrels, have specialized structures to modulate aerodynamic forces while airborne. However, many arboreal animals do not possess these specializations but still control posture and orientation in mid-air. One of the largest inertial segments in lizards is their tail. Inertial reorientation can be used to attain postures appropriate for controlled aerial descent. Here, we discuss the role of tail inertia in a range of mid-air reorientation behaviors using experimental data from geckos in combination with mathematical and robotic models. Geckos can self-right in mid-air by tail rotation alone. Equilibrium glide behavior of geckos in a vertical wind tunnel show that they can steer toward a visual stimulus by using rapid, circular tail rotations to control pitch and yaw. Multiple coordinated tail responses appear to be required for the most effective terminal velocity gliding. A mathematical model allows us to explore the relationship between morphology and the capacity for inertial reorientation by conducting sensitivity analyses, and testing control approaches. Robotic models further define the limits of performance and generate new control hypotheses. Such comparative analysis allows predictions about the diversity of performance across lizard morphologies, relative limb proportions, and provides insights into the evolution of aerial behaviors.

Published

2021

18. Future Tail Tales: A Forward-Looking, Integrative Perspective on Tail Research

Author

Ardian Jusufi, Craig P. McGowan, Brandon E. Jackson, C B Campos, Billie J. Swalla, Frank E. Fish, M J Schwaner, S Bradley, Brooke E. Flammang, I Braasch, S T Hsieh, P J Mekdara, Matthew K. Vickaryous, Amir Patel, Clint E. Collins, O E Fitch, and Cassandra M. Donatelli

Subjects

0106 biological sciences, 0301 basic medicine, Appendage, Cognitive science, Tail, Symposium, Computer science, media_common.quotation_subject, Perspective (graphical), Plant Science, 010603 evolutionary biology, 01 natural sciences, Sensorimotor control, 03 medical and health sciences, 030104 developmental biology, Functional morphology, Forward looking, Animals, Animal Science and Zoology, Function (engineering), media_common

Abstract

Synopsis Tails are a defining characteristic of chordates and show enormous diversity in function and shape. Although chordate tails share a common evolutionary and genetic-developmental origin, tails are extremely versatile in morphology and function. For example, tails can be short or long, thin or thick, and feathered or spiked, and they can be used for propulsion, communication, or balancing, and they mediate in predator–prey outcomes. Depending on the species of animal the tail is attached to, it can have extraordinarily multi-functional purposes. Despite its morphological diversity and broad functional roles, tails have not received similar scientific attention as, for example, the paired appendages such as legs or fins. This forward-looking review article is a first step toward interdisciplinary scientific synthesis in tail research. We discuss the importance of tail research in relation to five topics: (1) evolution and development, (2) regeneration, (3) functional morphology, (4) sensorimotor control, and (5) computational and physical models. Within each of these areas, we highlight areas of research and combinations of long-standing and new experimental approaches to move the field of tail research forward. To best advance a holistic understanding of tail evolution and function, it is imperative to embrace an interdisciplinary approach, re-integrating traditionally siloed fields around discussions on tail-related research.

Published

2021

19. Modeling and Control of a Soft Robotic Fish with Integrated Soft Sensing

Author

Daniel M. Vogt, Fabian Schwab, Hritwick Banerjee, Youngjoon Baek, Yong-Lae Park, Ardian Jusufi, Robert Siddall, Toshihiko Fukushima, and Yu-Hsiang Lin

Subjects

Computer science, Soft sensing, Real-time computing, Soft robotics, %22">Fish , General Economics, Econometrics and Finance

Published

2021

20. Body Caudal Undulation Measured by Soft Sensors and Emulated by Soft Artificial Muscles

Author

Taehwa Hong, Yong-Lae Park, Ardian Jusufi, Elias T. Lunsford, Fabian Schwab, Fabian Wiesemuller, James C. Liao, M. Kovac, and Otar Akanyeti

Subjects

Computer science, Soft robotics, 02 engineering and technology, Plant Science, Models, Biological, 03 medical and health sciences, Undulatory locomotion, Animals, 030304 developmental biology, 0303 health sciences, Symposium, Physical model, business.industry, Animal locomotion, Muscles, Fishes, Control engineering, Robotics, Bio-inspired robotics, 021001 nanoscience & nanotechnology, Soft sensor, AcademicSubjects/SCI00960, Animal Science and Zoology, Artificial muscle, Artificial intelligence, 0210 nano-technology, business, Locomotion

Abstract

We propose the use of bio-inspired robotics equipped with soft sensor technologies to gain a better understanding of the mechanics and control of animal movement. Soft robotic systems can be used to generate new hypotheses and uncover fundamental principles underlying animal locomotion and sensory capabilities, which could subsequently be validated using living organisms. Physical models increasingly include lateral body movements, notably back and tail bending, which are necessary for horizontal plane undulation in model systems ranging from fish to amphibians and reptiles. We present a comparative study of the use of physical modeling in conjunction with soft robotics and integrated soft and hyperelastic sensors to monitor local pressures, enabling local feedback control, and discuss issues related to understanding the mechanics and control of undulatory locomotion. A parallel approach combining live animal data with biorobotic physical modeling promises to be beneficial for gaining a better understanding of systems in motion.

Published

2021

21. Fish-like aquatic propulsion studied using a pneumatically-actuated soft-robotic model

Author

Zena T. Wolf, Ardian Jusufi, Daniel M. Vogt, and George V. Lauder

Subjects

0209 industrial biotechnology, genetic structures, Biophysics, Soft robotics, Thrust, 02 engineering and technology, Bending, Kinematics, Propulsion, Biochemistry, 020901 industrial engineering & automation, Biomimetic Materials, Fish locomotion, medicine, Torque, Animals, Engineering (miscellaneous), Swimming, Physics, musculoskeletal, neural, and ocular physiology, Fishes, Stiffness, Mechanics, Robotics, 021001 nanoscience & nanotechnology, Biomechanical Phenomena, Hydrodynamics, Linear Models, Molecular Medicine, medicine.symptom, 0210 nano-technology, human activities, Biotechnology

Abstract

Fish locomotion is characterized by waves of muscle electrical activity that proceed from head to tail, and result in an undulatory pattern of body bending that generates thrust during locomotion. Isolating the effects of parameters like body stiffness, co-activation between the right and left sides of the body, and frequency on thrust generation has proven to be difficult in live fishes. We use a pneumatically-actuated fish-like model to investigate how these parameters affect locomotor force generation. We measure thrust as well as side forces and torques generated during propulsion. Using a statistical linear model we examine the effects of input parameter combinations on thrust generation. We show that both stiffness and frequency substantially affect swimming kinematics, and that there are complex interactive effects of these two parameters on thrust. The stiffer the backbone the more impact that increasing frequency has on thrust production. For stiffer models, increasing frequency resulted in higher values for both thrust and lateral forces. Large side forces reduce swimming efficiency but this effect could be mitigated by decreasing undulatory wavelength and allowing appropriate phasing of left and right body movements to reduce amplitudes of side force.

Published

2020

22. Geckos race across the water's surface using multiple mechanisms

Author

Jasmine A. Nirody, Timothy J. Lee, Ardian Jusufi, Robert J. Full, Thomas Libby, David Hu, and Judy Jinn

Subjects

Male, 0106 biological sciences, Hemidactylus platyurus, Air water interface, Zoology, 02 engineering and technology, 010603 evolutionary biology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Running, Gait (human), House gecko, Animals, Gecko, Gait, Appendage, biology, Animal locomotion, Water, Lizards, 021001 nanoscience & nanotechnology, biology.organism_classification, Biomechanical Phenomena, %22">Fish , Female, 0210 nano-technology, General Agricultural and Biological Sciences

Abstract

Summary Acrobatic geckos can sprint at high speeds over challenging terrain [ 1 ], scamper up the smoothest surfaces [ 2 ], rapidly swing underneath leaves [ 3 ], and right themselves in midair by swinging only their tails [ 4 , 5 ]. From our field observations, we can add racing on the water’s surface to the gecko’s list of agile feats. Locomotion at the air-water interface evolved in over a thousand species, including insects, fish, reptiles, and mammals [ 6 ]. To support their weight, some larger-legged vertebrates use forces generated by vigorous slapping of the fluid’s surface followed by a stroke of their appendage [ 7 , 8 , 9 , 10 , 11 , 12 ], whereas smaller animals, like arthropods, rely on surface tension to walk on water [ 6 , 13 ]. Intermediate-sized geckos (Hemidactylus platyurus) fall squarely between these two regimes. Here, we report the unique ability of geckos to exceed the speed limits of conventional surface swimming. Several mechanisms likely contribute in this intermediate regime. In contrast to bipedal basilisk lizards [ 7 , 8 , 9 , 10 ], geckos used a stereotypic trotting gait with all four limbs, creating air cavities during slapping to raise their head and anterior trunk above water. Adding surfactant to the water decreased velocity by half, confirming surface tension’s role. The superhydrophobic skin could reduce drag during semi-planing. Geckos laterally undulated their bodies, including their submerged posterior trunk and tail, generating thrust for forward propulsion, much like water dragons [ 14 ] and alligators [ 15 ]. Geckos again remind us of the advantages of multi-functional morphologies providing the opportunity for multiple mechanisms for motion.

Published

2020

23. Strong, Ultrastretchable Hydrogel‐Based Multilayered Soft Actuator Composites Enhancing Biologically Inspired Pumping Systems

Author

Hritwick Banerjee, Manivannan Sivaperuman Kalairaj, Ardian Jusufi, and Hongliang Ren

Subjects

Dielectric elastomers, Materials science, Self-healing hydrogels, Soft actuator, General Materials Science, Composite material, Condensed Matter Physics

Published

2021

24. Soft Sensors for Curvature Estimation under Water in a Soft Robotic Fish

Author

Daniel M. Vogt, Robert J. Wood, Ardian Jusufi, and Brian Wright

Subjects

Undulatory locomotion, Fin, Materials science, Pneumatic actuator, Acoustics, Soft robotics, medicine, Stiffness, Bending, medicine.symptom, Curvature, Actuator

Abstract

This platform provides a biorobotic model for exploring body stiffness modulation and swimming performance experimentally. Fishes, amphibians and reptiles utilize undulatory motion of the body in the lateral plane as their predominant mode of locomotion. Here, soft bending actuators facilitate shape changes on the body to gain insight into undulatory locomotion, and allow exploration of mechanisms for body stiffness control with soft sensors. Soft pneumatic actuators were attached on each side of a flexible panel with stiffness comparable to that of a fish body. Hyper-elastic soft sensors were embedded at two locations of the undulating soft robotic fish body for curvature estimation in order to close the control feedback loop. Microchannels within the soft sensors are filled with a liquid metal, eutectic Gallium Indium (eGaIn). This marks the first study in which resistive eGaIn soft sensors have been tested under water. Results indicate that the sensor allows for measurement of changes of body curvature. As fin curvature changes, bending of the soft pneumatic actuator causes dimensional changes in the enclosed liquid metal which correspond to changes in electrical conductivity: Resistance increased proportionally with bending. The resistance measurement enabled by the sensor correlates with tail fin curvature. This fin displacement information opens the door to provide feedback for swimming with closed-loop control. The sensing of body-caudal fin shape changes-facilitated by soft sensors injected with liquid metal-could enhance maneuverability in rapid turning responses in future biologically inspired swimming robots.

Published

2019

25. Heads or Tails? Cranio-Caudal Mass Distribution for Robust Locomotion with Biorobotic Appendages Composed of 3D-Printed Soft Materials

Author

Ardian Jusufi, James C. Weaver, Robert Siddall, Jenny Michel, and Fabian Schwab

Subjects

030110 physiology, 0301 basic medicine, Appendage, Physics, 0209 industrial biotechnology, Chassis, Biorobotics, Mass distribution, Acoustics, Dynamics (mechanics), Soft robotics, 02 engineering and technology, Moment of inertia, 03 medical and health sciences, 020901 industrial engineering & automation, Head (vessel)

Abstract

The addition of external mass onto an organism can be used to examine the salient features of inherent locomotion dynamics. In this biorobotics study general principles of systems in motion are explored experimentally to gain insight on observed biodiversity in body plans and prevalent cranio-caudal mass distributions. Head and tail mass can make up approximately 20% of total body mass in lizards. To focus on the effect of differential loading of the ‘head’ and the ‘tail’ we designed an experiment using weights of 10% total body mass connected to the front and rear at varying distances to simulate biological mass distribution. Additive manufacturing techniques with compliant materials were utilized to make the biomimetic limbs. Obstacle traversal performance was evaluated over 126 trials in a variety of Moment of Inertia (MOI) configurations, recording pitch angles. Results showed that a forward-biased MOI appears useful for regaining contact in the front wheels during obstacle negotiation, while large passive tails can have a destabilising effect in some configurations. In our robophysical model, we explore both wheeled and legged locomotion (‘whegs’), and additionally examine damping the motion of the chassis by utilizing soft non-pneumatic tires (‘tweels’) which reduce body oscillations that arise from locomotion on irregular terrain.

Published

2019

26. Wearable and Stretchable Strain Sensors: Materials, Sensing Mechanisms, and Applications

Author

Morteza Amjadi, Norbert Radacsi, Hamid Souri, Inkyu Park, Hritwick Banerjee, Adam A. Stokes, Metin Sitti, and Ardian Jusufi

Subjects

soft robotics, lcsh:Computer engineering. Computer hardware, Materials science, lcsh:Control engineering systems. Automatic machinery (General), Soft robotics, Wearable computer, lcsh:TK7885-7895, Nanotechnology, Human motion, composites, wearable strain sensors, lcsh:TJ212-225, General Economics, Econometrics and Finance, nanomaterials, polymers

Abstract

Recent advances in the design and implementation of wearable resistive, capacitive, and optical strain sensors are summarized herein. Wearable and stretchable strain sensors have received extensive research interest due to their applications in personalized healthcare, human motion detection, human–machine interfaces, soft robotics, and beyond. The disconnection of overlapped nanomaterials, reversible opening/closing of microcracks in sensing films, and alteration of the tunneling resistance have been successfully adopted to develop high‐performance resistive‐type sensors. On the other hand, the sensing behavior of capacitive‐type and optical strain sensors is largely governed by their geometrical changes under stretching/releasing cycles. The sensor design parameters, including stretchability, sensitivity, linearity, hysteresis, and dynamic durability, are comprehensively discussed. Finally, the promising applications of wearable strain sensors are highlighted in detail. Although considerable progress has been made so far, wearable strain sensors are still in their prototype stage, and several challenges in the manufacturing of integrated and multifunctional strain sensors should be yet tackled.

Published

2020

27. Undulatory Swimming Performance and Body Stiffness Modulation in a Soft Robotic Fish-Inspired Physical Model

Author

Daniel M. Vogt, George V. Lauder, Ardian Jusufi, and Robert J. Wood

Subjects

0209 industrial biotechnology, Water flow, Polymers, Acoustics, Biophysics, Soft robotics, Thrust, 02 engineering and technology, Kinematics, Propulsion, Models, Biological, 020901 industrial engineering & automation, Undulatory locomotion, Artificial Intelligence, Animals, Simulation, Swimming, Physics, Pneumatic actuator, Fishes, Robotics, 021001 nanoscience & nanotechnology, Biomechanical Phenomena, Elastomers, Control and Systems Engineering, Hydrodynamics, 0210 nano-technology, Actuator

Abstract

Undulatory motion of the body is the dominant mode of locomotion in fishes, and numerous studies of body kinematics and muscle activity patterns have provided insights into the mechanics of swimming. However, it has not been possible to investigate how key parameters such as the extent of bilateral muscle activation affect propulsive performance due to the inability to manipulate muscle activation in live, freely swimming fishes. In this article we extend previous work on passive flexible mechanical models of undulatory propulsion by using actively controlled pneumatic actuators attached to a flexible foil to gain insight into undulatory locomotion and mechanisms for body stiffness control. Two soft actuators were attached on each side of a flexible panel with stiffness comparable to that of a fish body. To study how bilateral contraction can be used to modify axial body stiffness during swimming, we ran a parameter sweep of actuator contraction phasing and frequency. Thrust production by the soft pneumatic actuators was tested at cyclic undulation frequencies ranging from 0.3 to 1.2 Hz in a recirculating flow tank at flow speeds up to 28 cm/s. Overall, this system generated more thrust at higher tail beat frequencies, with a plateau in thrust above 0.8 Hz. Self-propelled speed was found to be 0.8 foil lengths per second or ∼13 cm/s when actuated at 0.55 Hz. This active pneumatic model is capable of producing substantial trailing edge amplitudes with a maximum excursion equivalent to 1.4 foil lengths, and of generating considerable thrust. Altering the extent of bilateral co-contraction in a range from -22% to 17% of the cycle period showed that thrust was maximized with some amount of simultaneous left-right actuation of ∼3% to 6% of the cycle period. When the system is exposed to water flow, thrust was substantially reduced for conditions of greatest antagonistic overlap in left-right actuation, and also for the largest latencies introduced. This experimental platform provides a soft robotic testbed for studying aquatic propulsion with active control of undulatory kinematics.

Published

2017

28. A Study of Rapid Tetrapod Running and Turning Dynamics Utilizing Inertial Measurement Units in Greyhound Sprinting

Author

David Eager, Terry Brown, H Hayati, and Ardian Jusufi

Subjects

Units of measurement, Plasma arc welding, Engineering, Inertial frame of reference, business.industry, Dynamics (mechanics), Biomechanics, Tetrapod (structure), Mechanical engineering, Biomimetics, business, Accelerometer

Abstract

Understanding the biomechanics of rapid running locomotion plays an important role in comparative biomechanics and bio-inspired engineering and is an integral part of animal welfare. However, this is not easily achieved using conventional methods of gait analysis: measuring ground reaction forces using a force plate, mainly on irregular granular terrain i.e. greyhounds in racing conditions or in animal’s natural habitats i.e. cheetahs in natural terrain. An alternative to measuring forces externally via force platforms embedded in track ways, we can attach inertial measurement units to agile quadrupeds to measure the effects of rapid running and turning. Here we deployed an IMU equipped with a tri-axial accelerometer on sprinting greyhounds to analyze rapid locomotion behaviors like dynamic banking and turning in conditions equivalent to racing. High speed videography and paw print analysis of the entire race were used for calibration. The results are beneficial in locomotion analysis and welfare of greyhounds.

Published

2017

29. Aerial Righting Reflexes in Flightless Animals

Author

Yu Zeng, Robert Dudley, Robert J. Full, and Ardian Jusufi

Subjects

Tail, Evolutionary Biology, Arboreal locomotion, Behavior, Animal, Rotation, biology, Ecology, Posture, Torsion, Mechanical, Computational Biology, Zoology, Lizards, Plant Science, biology.organism_classification, Anolis, Biomechanical Phenomena, Reflex, Righting, Flight, Animal, Orientation, Animals, Biomechanics, Animal Science and Zoology, Extatosoma tiaratum, Gecko, Righting reflex

Abstract

Synopsis Animals that fall upside down typically engage in an aerial righting response so as to reorient dorsoventrally. This behavior can be preparatory to gliding or other controlled aerial behaviors and is ultimately necessary for a successful landing. Aerial righting reflexes have been described historically in various mammals such as cats, guinea pigs, rabbits, rats, and primates. The mechanisms whereby such righting can be accomplished depend on the size of the animal and on anatomical features associated with motion of the limbs and body. Here we apply a comparative approach to the study of aerial righting to explore the diverse strategies used for reorientation in midair. We discuss data for two species of lizards, the gecko Hemidactylus platyurus and the anole Anolis carolinensis, as well as for the first instar of the stick insect Extatosoma tiaratum, to illustrate size-dependence of this phenomenon and its relevance to subsequent aerial performance in parachuting and gliding animals. Geckos can use rotation of their large tails to reorient their bodies via conservation of angular momentum. Lizards with tails well exceeding snout-vent length, and correspondingly large tail inertia to body inertia ratios, are more effective at creating midair reorientation maneuvers. Moreover, experiments with stick insects, weighing an order of magnitude less than the lizards, suggest that aerodynamic torques acting on the limbs and body may play a dominant role in the righting process for small invertebrates. Both inertial and aerodynamic effects, therefore, can play a role in the control of aerial righting. We propose that aerial righting reflexes are widespread among arboreal vertebrates and arthropods and that they represent an important initial adaptation in the evolution of controlled aerial behavior.

Published

2011

30. Rapid Inversion: Running Animals and Robots Swing like a Pendulum under Ledges

Author

Aaron M. Hoover, Jean Michel Mongeau, Brian McRae, Ardian Jusufi, Paul M. Birkmeyer, Robert J. Full, Ronald S. Fearing, and Bongard, Josh

Subjects

0106 biological sciences, Anatomy and Physiology, 030310 physiology, Population Dynamics, Video Recording, lcsh:Medicine, Cockroaches, 01 natural sciences, Behavioral Ecology, Predator-Prey Dynamics, Engineering, Biomimetics, Escape Reaction, Body Size, Biomechanics, lcsh:Science, Musculoskeletal System, Physics, 0303 health sciences, Multidisciplinary, Ecology, Animal Behavior, Pendulum, Robotics, Lizards, Swing, Biomechanical Phenomena, Sight, Community Ecology, Flapping, Locomotion, Research Article, Hook, General Science & Technology, Bioengineering, 010603 evolutionary biology, 03 medical and health sciences, Animals, Biology, Simulation, Evolutionary Biology, Wing, Population Biology, business.industry, lcsh:R, Species Interactions, Robot, lcsh:Q, Artificial intelligence, business, Zoology

Abstract

Escaping from predators often demands that animals rapidly negotiate complex environments. The smallest animals attain relatively fast speeds with high frequency leg cycling, wing flapping or body undulations, but absolute speeds are slow compared to larger animals. Instead, small animals benefit from the advantages of enhanced maneuverability in part due to scaling. Here, we report a novel behavior in small, legged runners that may facilitate their escape by disappearance from predators. We video recorded cockroaches and geckos rapidly running up an incline toward a ledge, digitized their motion and created a simple model to generalize the behavior. Both species ran rapidly at 12–15 body lengths-per-second toward the ledge without braking, dove off the ledge, attached their feet by claws like a grappling hook, and used a pendulum-like motion that can exceed one meter-per-second to swing around to an inverted position under the ledge, out of sight. We discovered geckos in Southeast Asia can execute this escape behavior in the field. Quantification of these acrobatic behaviors provides biological inspiration toward the design of small, highly mobile search-and-rescue robots that can assist us during natural and human-made disasters. We report the first steps toward this new capability in a small, hexapedal robot.

Published

2012

31. Tail-assisted pitch control in lizards, robots and dinosaurs

Author

Talia Y. Moore, Robert J. Full, Daniel J. Cohen, Deborah Li, Ardian Jusufi, Evan Chang-Siu, and Thomas Libby

Subjects

Tail, Agama agama, Rotation, General Science & Technology, media_common.quotation_subject, Posture, Inertia, Models, Biological, Dinosaurs, Control theory, Feedback, Sensory, biology.animal, Animals, Biomechanics, Computer Simulation, Balance (ability), media_common, Physics, Appendage, Multidisciplinary, biology, Lizard, Dynamics (mechanics), Lizards, Anatomy, Robotics, biology.organism_classification, Biological Evolution, Biomechanical Phenomena, body regions, Climbing

Abstract

In 1969, a palaeontologist proposed that theropod dinosaurs used their tails as dynamic stabilizers during rapid or irregular movements, contributing to their depiction as active and agile predators. Since then the inertia of swinging appendages has been implicated in stabilizing human walking, aiding acrobatic manoeuvres by primates and rodents, and enabling cats to balance on branches. Recent studies on geckos suggest that active tail stabilization occurs during climbing, righting and gliding. By contrast, studies on the effect of lizard tail loss show evidence of a decrease, an increase or no change in performance. Application of a control-theoretic framework could advance our general understanding of inertial appendage use in locomotion. Here we report that lizards control the swing of their tails in a measured manner to redirect angular momentum from their bodies to their tails, stabilizing body attitude in the sagittal plane. We video-recorded Red-Headed Agama lizards (Agama agama) leaping towards a vertical surface by first vaulting onto an obstacle with variable traction to induce a range of perturbations in body angular momentum. To examine a known controlled tail response, we built a lizard-sized robot with an active tail that used sensory feedback to stabilize pitch as it drove off a ramp. Our dynamics model revealed that a body swinging its tail experienced less rotation than a body with a rigid tail, a passively compliant tail or no tail. To compare a range of tails, we calculated tail effectiveness as the amount of tailless body rotation a tail could stabilize. A model Velociraptor mongoliensis supported the initial tail stabilization hypothesis, showing as it did a greater tail effectiveness than the Agama lizards. Leaping lizards show that inertial control of body attitude can advance our understanding of appendage evolution and provide biological inspiration for the next generation of manoeuvrable search-and-rescue robots.

Published

2011

32. Active tails enhance arboreal acrobatics in geckos

Author

Shai Revzen, Ardian Jusufi, Robert J. Full, and Daniel I. Goldman

Subjects

Appendage, Tail, Arboreal locomotion, Multidisciplinary, biology, musculoskeletal, neural, and ocular physiology, Lizards, Anatomy, Mechanics, Biological Sciences, Motor Activity, biology.organism_classification, Trees, body regions, Climbing, Climbing robots, Animals, Gecko, Descent (aeronautics), Falling (sensation), Slipping, human activities, Geology

Abstract

Geckos are nature's elite climbers. Their remarkable climbing feats have been attributed to specialized feet with hairy toes that uncurl and peel in milliseconds. Here, we report that the secret to the gecko's arboreal acrobatics includes an active tail. We examine the tail's role during rapid climbing, aerial descent, and gliding. We show that a gecko's tail functions as an emergency fifth leg to prevent falling during rapid climbing. A response initiated by slipping causes the tail tip to push against the vertical surface, thereby preventing pitch-back of the head and upper body. When pitch-back cannot be prevented, geckos avoid falling by placing their tail in a posture similar to a bicycle's kickstand. Should a gecko fall with its back to the ground, a swing of its tail induces the most rapid, zero-angular momentum air-righting response yet measured. Once righted to a sprawled gliding posture, circular tail movements control yaw and pitch as the gecko descends. Our results suggest that large, active tails can function as effective control appendages. These results have provided biological inspiration for the design of an active tail on a climbing robot, and we anticipate their use in small, unmanned gliding vehicles and multisegment spacecraft.

Published

2008

33. Righting and turning in mid-air using appendage inertia: reptile tails, analytical models and bio-inspired robots

Author

Robert J. Full, Ardian Jusufi, Thomas Libby, and Daniel T. Kawano

Subjects

Tail, Engineering, Inertial frame of reference, Aircraft, Physiology, media_common.quotation_subject, Biophysics, Rotation, Inertia, Models, Biological, Biochemistry, Body roll, Attitude control, Biomimetic Materials, Biomimetics, Animals, Computer Simulation, Engineering (miscellaneous), media_common, Appendage, business.industry, Lizards, Equipment Design, Robotics, Structural engineering, Mechanics, Swing, Flight, Animal, Computer-Aided Design, Molecular Medicine, Falling (sensation), business, Biotechnology

Abstract

Unlike the falling cat, lizards can right themselves in mid-air by a swing of their large tails in one direction causing the body to rotate in the other. Here, we developed a new three-dimensional analytical model to investigate the effectiveness of tails as inertial appendages that change body orientation. We anchored our model using the morphological parameters of the flat-tailed house gecko Hemidactylus platyurus. The degree of roll in air righting and the amount of yaw in mid-air turning directly measured in house geckos matched the model’s results. Our model predicted an increase in body roll and turning as tails increase in length relative to the body. Tails that swung from a near orthogonal plane relative to the body (i.e. 0‐30 ◦ from vertical) were the most effective at generating body roll, whereas tails operating at steeper angles (i.e. 45‐60 ◦ ) produced only half the rotation. To further test our analytical model’s predictions, we built a bio-inspired robot prototype. The robot reinforced how effective attitude control can be attained with simple movements of an inertial appendage.

Published

2010