A review of linkage mechanisms in animal joints and related bioinspired designs

Burgess, SC

doi:10.1088/1748-3190/abf744

Cited by 27 publications

(21 citation statements)

References 57 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For example, a bird uses its legs and feet for locomotion, manipulation, perching, and grasping. [63][64][65][66] Looking ahead to other functions, perching is analogous to dynamic aerial grasping (to catch an object on the wing) in that the bird needs to absorb a significant controlled aerial collision with their legs while closing their feet and claws around an object. 10 This illustrates how birds use a single biomechanical structure for a wide range of tasks that have no engineering analog.…”

Section: Biological Context For the Robot Vignettesmentioning

confidence: 99%

Bird-inspired robotics principles as a framework for developing smart aerospace materials

Hoffmann

Chen

Cutkosky

et al. 2023

Journal of Composite Materials

View full text Add to dashboard Cite

Birds are notable for their ability to seamlessly transition between different locomotory functions by dynamically leveraging their shape-shifting morphology. In contrast, the performance of aerial vehicles is constrained to a narrow flight envelope. To understand which functional morphological principles enable birds to successfully adapt to complex environments on the wing, engineers have started to develop biomimetic models of bird morphing flight, perching, aerial grasping and dynamic pursuit. These studies show how avian morphological capabilities are enabled by the biomaterial properties that make up their multifunctional biomechanical structures. The hierarchical structural design includes concepts like lightweight skeletons actuated by distributed muscles that shapeshift the body, informed by embedded sensing, combined with a soft streamlined external surface composed of thousands of overlapping feathers. In aerospace engineering, these functions are best replicated by smart materials, including composites, that incorporate sensing, actuation, communication, and computation. Here we provide a review of recently developed biohybrid, biomimetic, and bioinspired robot structural design principles. To inspire integrative smart material design, we first synthesize the new principles into an aerial robot concept to translate it into its aircraft equivalent. Promising aerospace applications include multifunctional morphing wing structures composed out of smart composites with embedded sensing, artificial muscles for robotic actuation, and fast actuating compliant structures with integrated sensors. The potential benefits of developing and mass-manufacturing these materials for future aerial robots and aircraft include improving flight performance, mission scope, and environmental resilience.

show abstract

Section: Biological Context For the Robot Vignettesmentioning

confidence: 99%

Bird-inspired robotics principles as a framework for developing smart aerospace materials

Hoffmann

Chen

Cutkosky

et al. 2023

Journal of Composite Materials

View full text Add to dashboard Cite

show abstract

“…Rotation of any given unfixed link results in a known rotation of all other links. A number of biomechanical systems in organismal design function as a four‐bar linkage, such as fish jaws (Westneat, 1994), mantis shrimp claws (Hu et al, 2017), bird wings, and the human knee (Burgess, 2021). Four‐bar linkages are defined as having an input link (force is applied, such as through a muscle or tendon), an output link (rotates as a result of the input link), a fixed link (usually representing connection to the relatively immobile body), and a coupler link (which helps to transmit motion between the input and output).…”

Section: Introductionmentioning

confidence: 99%

Organismal form constrains the evolution of complex lever systems in Neotropical cichlid four‐bar linkages

Arbour

Rumpp

López‐Fernández

2023

The Anatomical Record

View full text Add to dashboard Cite

The diversification of functional traits may be limited by the intrinsic constraints of organismal form (i.e., constructional constraints), owing to the differential investment in different anatomical structures. In this study, we test whether overall organismal form impacts the evolution of shape and function in complex lever systems. We examined the relationship between four‐bar shape and overall head shape in two four‐bar linkage systems: the oral‐jaw and hyoid‐neurocranium systems in Neotropical cichlids. We also investigated the strength of form‐function mapping in these four‐bar linkages and the impact of constraining head shape on these correlations. We quantified the shape of the head and two four‐bar linkages using geometric morphometrics and compared these with the kinematic transmission coefficient of each linkage system. The shapes of both linkages were strongly correlated with their mechanical properties, and head shape appears to constrain the shape of both four‐bar linkages. Head shape induced greater integration between the two linkages, was associated with stronger form‐function correlations and higher rates of evolution in biomechanically important features. Head shape constraints may also contribute to a weak but significant trade‐off in linkage kinematics. Elongation of the head and body, in particular, appears to minimize the impact of this trade‐off, possibly through maximizing anterior–posterior space availability. However, the strength of relationships between shape and function, and the impact of head shape differed between the two linkages, with the hyoid four‐bar in general showing stronger form‐function relationships despite being more independent from head shape constraints.

show abstract

“…Engineering companies should also implement biomimetic design processes into their procedures by changing organizational structures that, in the end, may combine the fields of engineering and biology together [ 5 ]. Biomimetic robots are robots that imitate not only humans but also animals that will eventually adapt to the environment so that they can learn and react faster, while, at the same time, may have novel mechanisms and manipulator structures according to their needs [ 6 , 7 ]. Over the past decade, many robotic devices, whose designs are based upon certain biological species in terms of user functionality in practical applications, have been developed, such as: humanoid robots [ 8 , 9 ] snake-like robots [ 10 , 11 ], swimming robots [ 12 , 13 , 14 ], flying robots [ 15 , 16 ], and even plants [ 17 ].…”

Section: Introductionmentioning

confidence: 99%

Utilization of Function Generation Synthesis on Biomimetics: A Case Study on Moray Eel Double Jaw Design

et al. 2022

View full text Add to dashboard Cite

Throughout history, humans have observed living or non-living things in nature and then imitated them in relation to these observations. This is due to the fact that the energy found in nature is generally consumed at an optimal level in order for it to endure. Biomimetic inspiration in many designs and applications is widely displayed, including within the field of engineering. In this paper, we were inspired by the double set of jaws found in the moray eel, which gives this fish a huge advantage while hunting, with a mobile pharyngeal jaw that works together with its oral jaw in order to overcome ineffective suction capabilities. A procedure that mimics the hunting motion of the moray eel was utilized by considering the overall movement as a single degree of freedom with multiple outputs on account of the repeating motion that is required during hunting. This procedure includes structural and dimensioning synthesis, wherein the latter was utilized with analytic kinematic synthesis for each linkage transfer. The flexibilities in parameters were taken into account with a novel multiple iterative kinematic synthesis algorithm that resulted in various mechanisms with the same purpose. Among the excessive number of resultant mechanisms, the optimization was carried out by considering the highest torque transmission ratio at critical timings that were specified as bio-constraints. In the end, the kinematic movement validation was utilized.

show abstract

A review of linkage mechanisms in animal joints and related bioinspired designs

Cited by 27 publications

References 57 publications

Bird-inspired robotics principles as a framework for developing smart aerospace materials

Bird-inspired robotics principles as a framework for developing smart aerospace materials

Organismal form constrains the evolution of complex lever systems in Neotropical cichlid four‐bar linkages

Utilization of Function Generation Synthesis on Biomimetics: A Case Study on Moray Eel Double Jaw Design

Contact Info

Product

Resources

About