The latest in weird and potentially useful robots from German automation giant Festo
We love Festo because every year they invest an entirely appropriate amount of time and money into bio-inspired robots that are totally cool and very functional but have limited usefulness. More often than not, it seems like Festo is able to take some of what it learns from designing and constructing these things and create practical new revenue-generating products. Which is good for them, and means they’ll keep making cool stuff. Over the last few years, we’ve met ants, butterflies, flying jellyfish and penguins, kangaroos, seagulls, and much more.
Festo has just announced its two newest bionic learning network robots—one is a very convincing flying fox, and the other is a walking, tumbling robot inspired by a Saharan spider.
Festo calls their BionicFlyingFox an “ultra-lightweight flying object with intelligent kinematics.” It’s 87 centimeters long with a 228-cm wingspan, but it weighs only 580 grams. Flying foxes are the largest bats in the world, and as such, their wings consist of membranes of skin rather than feathers. Mimicking that required some creativity on Festo’s part:
The model’s flying membrane is wafer-thin and ultralight whilst also robust. It consists of two airtight films and a knitted elastane fabric, which are welded together at approximately 45,000 points. Due to its elasticity, it stays almost uncreased, even when the wings are retracted. The fabric’s honeycomb structure prevents small cracks in the flying membrane from getting bigger. This means that the BionicFlyingFox can continue flying even if the fabric sustains minor damage.
Diagram of Festo’s bionic flying fox, a type of megabat.
The wing is separated into primary and secondary control surfaces which are mechanically coupled together—on the upstroke, the primary folds in toward the secondary and extends back out again on the downstroke. Small motors in the body can adjust each wing separately, while a larger brushless dc motor does the flapping.
The robot is autonomous, sort of, in that it flies by itself but relies on a ground station for camera-based localization, and all of the computing is off-board. Festo uses machine learning to optimize the BionicFlyingFox’s flight behavior, such that every time it performs a maneuver, it gets just a little bit better. I’m not sure it’ll ever get good enough to stick an upside-down landing, though.
This crazy thing is BionicWheelBot. The design is a little more creatively bio-inspired than the flying fox; it’s based on the flic-flac spider, which lives in the Sahara and can move very quickly with a unique combination of cartwheel flips when it feels threatened:
The guy in that video who both discovered the spider and invented the original robot (Ingo Rechenberg, a bionics professor at TU Berlin) was also involved in the design of Festo’s version. As with the flying fox, the behavior of this robot is based very closely on the real thing:
Like its biological model, the BionicWheelBot has eight legs, which help it to both walk and roll. They are controlled by a total of 15 small motors, which fit in the knee joints and body. There are also 14 automatic-locking worm gear units that ensure that the spider only has to use energy when moving its legs—not, however, to keep its body upright when standing still.
In rolling mode, the BionicWheelBot does a somersault with its whole body, just like the real flic-flac spider. Thanks to the integrated inertial sensor, it always knows what position it is in and when it has to push off again. It, too, is therefore much faster when rolling than walking and can even overcome inclines of up to five per cent uphill.
Festo also made some more practical (if a bit less flashy) robotics announcements. The first is the BionicWorkplace, which integrates robots and a host of control devices and displays to help human users operate the system more effectively:
In the BionicWorkplace, the bionic robot arm works together with numerous assistance systems and peripheral devices, which are networked and communicate with each other. At the same time, artificial intelligence and machine learning methods turn the BionicWorkplace into a learning and anticipative system that continuously optimises itself.
The whole workplace is ergonomically designed and can be adapted to people individually down to the lighting. At the centre of the worker’s field of vision is a large projection screen. It supplies the worker with all the relevant information and reacts dynamically with its contents to the relevant requirements. All around the projection screen, various sensors and camera systems are fitted, which constantly record the positions of the worker, components and tools. In this way, a human can directly interact with the BionicCobot and control it using movement, touch or speech.
The second is an educational “bionics training kit” designed for kids age 14 to 18, to be available in the United States and Germany:
See full details: News from Journal World – www.journalgazett.com