Design and Control of Soft Robots Using Differentiable Simulation

Completely soft and flexible robots offer to revolutionize fields ranging from search and rescue to endoscopic surgery. One of the outstanding challenges in this burgeoning field is the chicken-and-egg problem of body-brain design: Development of locomotion requires the preexistence of a locomotion-capable body, and development of a location-capable body requires the preexistence of a locomotive gait. This problem is compounded by the high degree of coupling between the material properties of a soft body (such as stiffness or damping coefficients) and the effectiveness of a gait. This article synthesizes four years of research into soft robotics, in particular describing three approaches to the co-discovery of soft robot morphology and control. In the first, muscle placement and firing patterns are coevolved for a fixed body shape with fixed material properties. In the second, the material properties of a simulated soft body coevolve alongside locomotive gaits, with body shape and muscle placement fixed. In the third, a developmental encoding is used to scalably grow elaborate soft body shapes from a small seed structure. Considerations of the simulation time and the challenges of physically implementing soft robots in the real world are discussed.

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FROM OCTOPUS VULGARIS TO UNDERWATER HOPPING ROBOTS: BIO-INSPIRED PATH TOWARD DESIGN AND CONTROL OF SOFT ROBOTS

Advances in Cooperative Robotics ◽

10.1142/9789813149137_0088 ◽

2016 ◽

pp. 765-770

Author(s):

MARCELLO CALISTI ◽

CECILIA LASCHI

Keyword(s):

Octopus Vulgaris ◽

Soft Robots ◽

Hopping Robots ◽

And Control

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Software toolkit for modeling, simulation, and control of soft robots

Advanced Robotics ◽

10.1080/01691864.2017.1395362 ◽

2017 ◽

Vol 31 (22) ◽

pp. 1208-1224 ◽

Cited By ~ 32

Author(s):

E. Coevoet ◽

T. Morales-Bieze ◽

F. Largilliere ◽

Z. Zhang ◽

M. Thieffry ◽

...

Keyword(s):

Soft Robots ◽

Software Toolkit ◽

Modeling Simulation ◽

Simulation And Control ◽

And Control

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Soft Robotics: Biological Inspiration, State of the Art, and Future Research

Applied Bionics and Biomechanics ◽

10.1155/2008/520417 ◽

2008 ◽

Vol 5 (3) ◽

pp. 99-117 ◽

Cited By ~ 688

Author(s):

Deepak Trivedi ◽

Christopher D. Rahn ◽

William M. Kier ◽

Ian D. Walker

Keyword(s):

Degrees Of Freedom ◽

State Of The Art ◽

Future Research ◽

Robot Design ◽

The Novel ◽

Soft Robots ◽

Biological Inspiration ◽

End Effectors ◽

And Control ◽

Complex Movement

Traditional robots have rigid underlying structures that limit their ability to interact with their environment. For example, conventional robot manipulators have rigid links and can manipulate objects using only their specialised end effectors. These robots often encounter difficulties operating in unstructured and highly congested environments. A variety of animals and plants exhibit complex movement with soft structures devoid of rigid components. Muscular hydrostats (e.g. octopus arms and elephant trunks) are almost entirely composed of muscle and connective tissue and plant cells can change shape when pressurised by osmosis. Researchers have been inspired by biology to design and build soft robots. With a soft structure and redundant degrees of freedom, these robots can be used for delicate tasks in cluttered and/or unstructured environments. This paper discusses the novel capabilities of soft robots, describes examples from nature that provide biological inspiration, surveys the state of the art and outlines existing challenges in soft robot design, modelling, fabrication and control.

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Soft Robots for Healthcare Applications: Design, modelling, and control

10.1049/pbhe014e ◽

2017 ◽

Cited By ~ 1

Author(s):

S. Xie ◽

M. Zhang ◽

W. Meng

Keyword(s):

Healthcare Applications ◽

Soft Robots ◽

And Control

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Review on generic methods for mechanical modeling, simulation and control of soft robots

PLoS ONE ◽

10.1371/journal.pone.0251059 ◽

2022 ◽

Vol 17 (1) ◽

pp. e0251059

Author(s):

Pierre Schegg ◽

Christian Duriez

Keyword(s):

Dynamic Control ◽

Material Behavior ◽

Sensor Data ◽

Control Algorithms ◽

Mechanical Modeling ◽

Soft Robots ◽

Mechanical Compliance ◽

Mechanical Models ◽

Simulation And Control ◽

And Control

In this review paper, we are interested in the models and algorithms that allow generic simulation and control of a soft robot. First, we start with a quick overview of modeling approaches for soft robots and available methods for calculating the mechanical compliance, and in particular numerical methods, like real-time Finite Element Method (FEM). We also show how these models can be updated based on sensor data. Then, we are interested in the problem of inverse kinematics, under constraints, with generic solutions without assumption on the robot shape, the type, the placement or the redundancy of the actuators, the material behavior… We are also interested by the use of these models and algorithms in case of contact with the environment. Moreover, we refer to dynamic control algorithms based on mechanical models, allowing for robust control of the positioning of the robot. For each of these aspects, this paper gives a quick overview of the existing methods and a focus on the use of FEM. Finally, we discuss the implementation and our contribution in the field for an open soft robotics research.

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Modeling and Control of Soft Robots Using the Koopman Operator and Model Predictive Control

Robotics: Science and Systems XV ◽

10.15607/rss.2019.xv.060 ◽

2019 ◽

Cited By ~ 8

Author(s):

Daniel Bruder ◽

Brent Gillespie ◽

C. David Remy ◽

Ram Vasudevan

Keyword(s):

Model Predictive Control ◽

Predictive Control ◽

Soft Robots ◽

Modeling And Control ◽

Koopman Operator ◽

And Control

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Editorial: Soft Robotic Modeling and Control: Bringing Together Articulated Soft Robots and Soft-Bodied Robots

The International Journal of Robotics Research ◽

10.1177/0278364921998088 ◽

2021 ◽

Vol 40 (1) ◽

pp. 3-6

Author(s):

Cosimo Della Santina ◽

Robert K. Katzschmann ◽

Antonio Bicchi ◽

Daniela Rus

Keyword(s):

Soft Robots ◽

Modeling And Control ◽

And Control

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Design and Control of Foam Hands for Dexterous Manipulation

International Journal of Humanoid Robotics ◽

10.1142/s0219843619500336 ◽

2020 ◽

Vol 17 (01) ◽

pp. 1950033

Author(s):

Dominik Bauer ◽

Cornelia Bauer ◽

Jonathan P. King ◽

Daniele Moro ◽

Kai-Hung Chang ◽

...

Keyword(s):

Design Optimization ◽

Robot Design ◽

Soft Robot ◽

Dexterous Manipulation ◽

Soft Robots ◽

Manufacturing Control ◽

Great Progress ◽

Robot Hands ◽

High Competence ◽

And Control

There has been great progress in soft robot design, manufacture, and control in recent years, and soft robots are a tool of choice for safe and robust handling of objects in conditions of uncertainty. Still, dexterous in-hand manipulation using soft robots remains a challenge. This paper introduces foam robot hands actuated by tendons sewn through a fabric glove. The flexibility of tendon actuation allows for high competence in utilizing deformation for robust in-hand manipulation. We discuss manufacturing, control, and design optimization for foam robots and demonstrate robust grasping and in-hand manipulation on a variety of different physical hand prototypes.

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Capability by Stacking: The Current Design Heuristic for Soft Robots

Biomimetics ◽

10.3390/biomimetics3030016 ◽

2018 ◽

Vol 3 (3) ◽

pp. 16 ◽

Cited By ~ 6

Author(s):

Stephen Mahon ◽

Jamie Roberts ◽

Mohammed Sayed ◽

Derek Chun ◽

Simona Aracri ◽

...

Keyword(s):

Soft Robots ◽

Soft Systems ◽

Diverse Range ◽

Current State ◽

Current Design ◽

Practical Limit ◽

Functional Blocks ◽

One To One ◽

And Control ◽

Design Heuristic

Soft robots are a new class of systems being developed and studied by robotics scientists. These systems have a diverse range of applications including sub-sea manipulation and rehabilitative robotics. In their current state of development, the prevalent paradigm for the control architecture in these systems is a one-to-one mapping of controller outputs to actuators. In this work, we define functional blocks as the physical implementation of some discrete behaviors, which are presented as a decomposition of the behavior of the soft robot. We also use the term ‘stacking’ as the ability to combine functional blocks to create a system that is more complex and has greater capability than the sum of its parts. By stacking functional blocks a system designer can increase the range of behaviors and the overall capability of the system. As the community continues to increase the capabilities of soft systems—by stacking more and more functional blocks—we will encounter a practical limit with the number of parallelized control lines. In this paper, we review 20 soft systems reported in the literature and we observe this trend of one-to-one mapping of control outputs to functional blocks. We also observe that stacking functional blocks results in systems that are increasingly capable of a diverse range of complex motions and behaviors, leading ultimately to systems that are capable of performing useful tasks. The design heuristic that we observe is one of increased capability by stacking simple units—a classic engineering approach. As we move towards more capability in soft robotic systems, and begin to reach practical limits in control, we predict that we will require increased amounts of autonomy in the system. The field of soft robotics is in its infancy, and as we move towards realizing the potential of this technology, we will need to develop design tools and control paradigms that allow us to handle the complexity in these stacked, non-linear systems.

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