Coordinators Coordinators

The coordinator of this Topic Group is Florian Röhrbein, leader of the Neurorobotik department at the TU Chemnitz, former managing director for neurorobotics in the Human Brain Project and chief editor of "Frontiers in Neurorobotics".

 

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Introduction Introduction

Do you know why ants are capable of showcasing swarm intelligence, navigation skills, self-organization, and colony efficiency, often surpassing many of our own human abilities?

The interdisciplinary field of Bio-inspired robotics utilizes concepts from biology to develop robotic systems that mimic the mechanisms, functions, and behaviours of living organisms. By emulating natural phenomena ranging from the swift flight of birds, the cooperative behaviour of ants, to the fluid locomotion of fish. This Topic enhances the capabilities of robots, improving their adaptability, efficiency, and resilience in diverse environments.
As we uncover more of nature's secrets, we can develop a new generation of machines that combine the best of nature and AI.

 

Bio-inspired robotics is a rapidly growing field of research that draws its theoretical and practical underpinnings from principles observed in biological systems. The fundamental aim is to transcend traditional engineering boundaries and attain advanced performance, robustness, and versatility in robotic systems, as seen in nature.
The process of bio-inspired robotics typically involves three stages: observation, abstraction, and implementation. Initially, detailed observation of natural entities is undertaken, studying the mechanisms they employ for survival, adaptation, and interaction with their environment. This information is then abstracted into a set of principles or a theoretical model. Lastly, these principles are implemented into a bio-inspired robot, creating a practical realization of the biological phenomenon.
Applications are wide-ranging. In exploration, bio-inspired robots can endure harsh conditions in deep-sea research or space missions. In healthcare, robots inspired by the precision of biological systems can contribute to microsurgeries. In disaster management, swarm robots, inspired by the behaviour of ants or bees, can work together in large groups, self-organising and cooperating to solve complex tasks such as efficiently coordinating search and rescue operations.
In the realm of localisation, the technology is inspired by the echolocation of bats or the event-based visual pathway of living creatures, which has led to a fundamental change in the mechanics and technology of these sensors.
The interplay between biology and robotics is reciprocal. While biology offers a trove of inspirations for robotics, these robots can also act as physical models to test biological hypotheses, advancing our understanding of living organisms.
Bio-inspired robotics signifies a paradigm shift in robotics, fusing the adaptability of biological systems with the precision of artificial mechanisms. This symbiotic fusion is progressively pushing the boundaries of what robotic systems can achieve, heralding an exciting future in robotics.

 

 

 

botics is a broad topic and an ongoing expanding field.

 

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