Festo, inventor of sophisticated and elegant robotic birds, as well as robot jellyfish and penguins, has done it again. The company's latest robotic achievement is a dragonfly, the BionicOpter, which can independently move each of its wings to fly in any direction.
Introduced at the Hannover Trade Fair in Germany this week, the BionicOpter is one of many projects the company has pursued under the aegis of its Bionic Learning Network. The network's purpose is to use the energy-efficient principles already found in nature and adapt them to automation technology.
Modeled after a dragonfly, Festo's latest sophisticated robot is the BionicOpter, which can independently move each of its wings to fly in any direction, as well as hover and glide.
The robotic dragonfly can speed up or slow down quickly, or even fly backwards, because of its ability to independently move each of its four wings. It can also float like a glider while holding its wings steady. Since it doesn't need to generate forward thrust by tilting forward, the BionicOpter can also fly horizontally. It's extremely lightweight at 175 gm (6.17 oz). Its body, made of flexible polyamide and terpolymer, is 44 cm (17.3 inches) long, and houses an ARM microcontroller, eight servo motors for wing actuation, a brushless motor, two 7.6V lithium polymer batteries, 2.4 GHz wireless modules, and inertia, acceleration, and position sensors. The head and body are actuated by four flexible muscles made of nitinol, a shape memory alloy (SMA) that expands when cooled and contracts when heated. An electrical current passing through these "muscles" makes them move the tail up and down and the head from side to side.
Each of the BionicOpter's carbon fiber-framed wings are covered with a thin foil material, and total wingspan is 63 cm (24.8 inches). Direction and intensity of each wing can be individually adjusted: The direction of each wing's thrust is determined by its swiveling motions, and its amplitude controller regulates the intensity of that thrust. Each wing's flapping frequency and twisting motions are also independently controlled, and data on wing position and twisting is recorded and evaluated while the dragonfly is in flight. Remote-controlled with a smartphone, the robot only needs its operator for steering and speed control. Software and electronics coordinate the robot's motions.
Before attempting the complexities of engineering the robot dragonfly, Festo developed its SmartBird, which can take off, and fly and land autonomously, rising by means of its flapping wings alone. Inspired by a herring gull, the robotic bird flies, glides, and sails. A complex flight control system in its torso and tail section, combined with its articulated torsional drive unit, lets SmartBird's wings twist at specific angles, as well as beat up and down to optimize airflow use without the requirement for additional devices to assist lift. The bird's wing position and torsion are monitored by ZigBee-based two-way radio communication, which conveys operating data such as battery charge and power consumption, as well as pilot input.
Although Festo's press release claims that the BionicOpter dragonfly robot is the first system that can perform all the flight maneuvers of a plane, a helicopter, and a glider, two of these abilities have previously been demonstrated in one machine by Japan's Ministry of Defense. The Japanese remote-controlled flying spherical robot can move in any direction, fly down narrow passageways or up and down stairways, and take off and land vertically anywhere, on surfaces of nearly any shape. Like a helicopter, it can hover for eight minutes continuously, but the orb also has wings that let it fly forward horizontally at up to 60 km/hour.
Clinton, thanks for your feedback, especially the point about the focus on ROI above all else. And I completely agree about the sense of wonder. That's one of my husband's favorite phrases: he uses it to describe what he likes about great science fiction, like Dune, or Star Trek when it was new, or Simmons' Endymion series.
Yes, you're probably right, but I did see a story about someone who created this whole art piece by using a robotic arm...I can't remember if I did a story on it or not. I'll dig up the link. Or maybe you covered it? It was quite cool!
Rob, from the comments Festo makes in that brochure, I think the application is quite clear in their minds and the minds of their customers: independent autonomous robots whizzing around the plant, making their own decisions and networked via wireless comms technology. But who knows what else this little guy could do?
AnandY, you're welcome. I've seen photos and videos of hundreds of robots that were designed using biomimicry, and most of them are pretty clunky. Festo's machines don't even look or move like machines, if you ask me.
Yes, Greg, you're right, industrial robots certainly aren't very sexy. But they seem to be heading in a more attractive direction as well. I'm thinking of Baxter from Rethink Robots, which may not exactly look like a work of art, but is certainly easier on the eyes than traditional industrial robots.
I agree Liz, There is a perception that robots need to be intelligent and glamorous. Of course there is a big difference between industrial robots and humanlike robots. When they start looking and talking like Ginger from Gilligans Island, then I will want to get one. Industrial robots have less intelligence and looks than an automatic tranmission (unless you spend a fortune on software, sensors, barcode readers, and vision systems) and they will perform the same repetetive task millions of times without failure - but you will still have to look at all those wires...
According to a study by the National Institute of Standards and Technology, one of the factors in the collapse of the original World Trade Center towers on Sept. 11, 2001, was the reduction in the yield strength of the steel reinforcement as a result of the high temperatures of the fire and the loss of thermal insulation.
Robots are getting more agile and automation systems are becoming more complex. Yet the most impressive development in robotics and automation is increased intelligence. Machines in automation are increasingly able to analyze huge amounts of data. They are often able to see, speak, even imitate patterns of human thinking. Researchers at European Automation
call this deep learning.
The promise of the Internet of Things (IoT) is that devices, gadgets, and appliances we use every day will be able to communicate with one another. This potential is not limited to household items or smartphones, but also things we find in our yard and garden, as evidenced by a recent challenge from the element14 design community.
Focus on Fundamentals consists of 45-minute on-line classes that cover a host of technologies. You learn without leaving the comfort of your desk. All classes are taught by subject-matter experts and all are archived. So if you can't attend live, attend at your convenience.