Development and analysis of a bio-inspired wire-driven variable stiffness double spring based tapered multi-section flexible robot | Emerald Insight
Novel bio-inspired variable stiffness soft actuator via fiber-reinforced dielectric elastomer, inspired by Octopus bimaculoides | SpringerLink
Soft robotics - Wikipedia
Tunable stiffness enables fast and efficient swimming in fish-like robots – ZHONG LAB
Architecture of bio-inspired legged robot with parallel waist. (A)... | Download Scientific Diagram
overview of soft robotic systems. a, Conception of a future soft... | Download Scientific Diagram
Frontiers | Hardware Methods for Onboard Control of Fluidically Actuated Soft Robots
Robotics-inspired biology
Untethered and ultrafast soft-bodied robots | Communications Materials
Soft robotics: Technologies and systems pushing the boundaries of robot abilities | Science Robotics
A variable-stiffness tendril-like soft robot based on reversible osmotic actuation | Nature Communications
Frontiers | A Bio-inspired Grasp Stiffness Control for Robotic Hands
A resonant squid-inspired robot unlocks biological propulsive efficiency | Science Robotics
Development and analysis of a bio-inspired wire-driven variable stiffness double spring based tapered multi-section flexible robot | Emerald Insight
Robotics | Free Full-Text | Topological Analysis of a Novel Compact Omnidirectional Three-Legged Robot with Parallel Hip Structures Regarding Locomotion Capability and Load Distribution
A jump for soft-bodied robots
Bio-inspired finger concept: (a) anatomic sketch of the human index... | Download Scientific Diagram
Antagonistic actuation and stiffness control in soft inflatable robots | Nature Reviews Materials
Sensors | Free Full-Text | Insect-Inspired Robots: Bridging Biological and Artificial Systems
Frontiers | A Bio-inspired Grasp Stiffness Control for Robotic Hands
Segmentations in fins enable large morphing amplitudes combined with high flexural stiffness for fish-inspired robotic materials | Science Robotics
A Light Touch May Help Animals and Robots Move on Sand and Snow | News Center
Animal-inspired robot legs | Dynamic Locomotion - Max Planck Institute for Intelligent Systems
Bioinspired dual-stiffness origami | Science Robotics
