AirBurr

Electronics sit within a cage of triangular and oval frame pieces.
AirBurr's cage protects it from collisions. Photo: EPFL Laboratory of Intelligent Systems

AirBurr is a flying robot designed for constrained, cluttered spaces. Its spring-based cage protects it from damage. Even after crashing on walls and other things, it just picks itself up and takes off.

Creator

École Polytechnique Fédérale de Lausanne

Year
2010
Country
Switzerland 🇨🇭
Categories
Features
Overview of AirBurr. Video: EPFL News

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Did you know?

Researchers have created about a dozen AirBurr versions, which have names like V1-Hovermouse, V4-Crashy, and V6-Sticky.

A blue drone is composited into four spots of a building whose walls are torn apart.
A photo composite of AirBurr navigating a disaster site. Image: EPFL Laboratory of Intelligent Systems
Colored yellow and red lines indicate where a drone was flying.
Long-exposure shot shows AirBurr flying and crashing. Photo: EPFL Laboratory of Intelligent Systems

History

The AirBurr project was born when researchers at the Laboratory of Intelligent Systems at the Ecole Polytechnique Federale de Lausanne (EPFL) began observing how animals fly. Birds and insects often collide with windows and other obstacles, but they are built to survive and recover from such crashes, unlike most existing flying robots. The first AirBurr was a 25-gram wing-based platform, and it has since gone through more than 10 major revisions. In its evolution, AirBurr has been able to crash, stand up, stick to walls, follow light sources, and, perhaps most important, generally entertain its makers. The final goal is building a version capable of navigating even more complex and constrained environments, such as caves or collapsed buildings.

Circuit boards
The BurrMove and BurrSens systems keep AirBurr running. Photo: EPFL Laboratory of Intelligent Systems
Four circular framed pieces with propellers and electronics inside.
The first prototype, nicknamed HoverMouse. Photo: EPFL Laboratory of Intelligent Systems

Specs

Overview

Equipped with retractable arms for self-righting after crashes. Able to navigate by bumping into the environment or following a light source.

Status

Ongoing

Year

2010

Website
Width
35 cm
Height
70 cm
Length
35 cm
Weight
0.35 kg
Sensors

Standard: three-axis accelerometer and gyroscope (for inertial stabilization), ultrasonic sensor (altitude detection), four photodiodes (to detect leg position and external light sources). Optional: three-axis high-g accelerometer (collision force detection), miniature optic flow sensors (anti-drift), Hall-effect-based contact sensor embedded within protective cage.

Actuators

Coaxial dual brushless DC motor (thrust), two servos (control surfaces), and four brushed DC motors with custom gearbox (legs).

Materials

Carbon fiber and aramid inner frame; carbon fiber rods and laser-sintered plastic for protective structure.

Compute

Two 16-bit microcontrollers. Custom wireless communication for telemetry and data logging.

Software

Custom software written in C for embedded microcontrollers.

Power

1350-mAh lithium-polymer battery, 10 minutes of flight.