Project description
Flapping-wing robots to monitor aquatic environments
Robotics can play an important role in monitoring Earth's aquatic environments, vastly improving our understanding of climate changes. To collect samples and data in rivers, lakes and oceans, robots need to be resilient, light and affordable. Aerial-aquatic robots could be a solution: they can cover large distances in the air and are able to physically interact with our waters to take measurements and samples. The EU-funded FAAV project will model, design, and develop a small-scale flapping wing approach. Taking inspiration from animals, the project's Flapping wing, Aerial-Aquatic Vehicle – the first of its kind – will seamlessly transition between air and water, in addition to carrying relevant sensory payloads. The project will test these new devices in realistic outdoor conditions.
Objective
As our world is experiencing climate changes, we need better monitoring technologies. Since most of our planet is covered in water, sample and data collection in rivers, lakes and oceans plays a leading role in our world’s understanding. While robotics shows huge promises in this task, aquatic environments remain challenging to operate in. There is thus a strong need for light, affordable and resilient mobile robots that can operate and rapidly collect multiple measurements in these environments.
Aerial-aquatic robots are promising to combine the capability to cover large distance in air, overcoming obstacles with the ability to physically interact, measure, and sample our lakes, rivers and oceans. For that, we need to study new locomotion methods and platforms that (1) can effectively move from water to air and transition in-between (2) can cope with the highly complex and dynamic nature of our environment i.e. wind, waves (3) possess a high level of autonomy and reliability to reliably operate with climate scientists.
For this, I propose a small-scale flapping wing approach. Animals have readily shown aerial-aquatic locomotion and therefore are a tremendous source for inspiration, already demonstrating the capabilities of flapping-wing. These devices are inherently safe thanks to their low velocities, also preventing breakage, and promise to efficiently move both in air and in water.
This project will result in the first Flapping wing, Aerial-Aquatic Vehicle - or FAAV capable of carrying relevant sensory payload. This will build upon a theoretical model of this locomotion strategy and successive tests both in air and underwater, leading to an efficient, reliable device capable of sub-surface and air motion. The resulting designs will be field-tested in realistic outdoor conditions and equipped with navigation and data-collection capabilities for environmental research.
Fields of science
Programme(s)
Funding Scheme
MSCA-IF - Marie Skłodowska-Curie Individual Fellowships (IF)Coordinator
1015 Lausanne
Switzerland