Summary: RoboBees could some day assist in reconnaissance missions, aid in remote communications and even act as artificial pollinators, researchers hope.
Source: National Science Foundation.
Long-term NSF support for Harvard University researchers helps develop unique flying micro-robots.
Increasingly, researchers are designing robots with forms and functions that defy our expectation of what a machine can be or do.
One of the more unexpected robotics applications in recent years comes from the National Science Foundation (NSF)-supported “RoboBees” project, which aims to create autonomous robotic insects capable of sustained, independent flight.
Such robots could one day assist in reconnaissance, aid in remote communication, or even act as artificial pollinators.
Led by Robert Wood, professor of Engineering and Applied Sciences at Harvard University and principal investigator of the RoboBee project, and working with collaborators at Harvard and Northeastern University, the researchers have designed increasingly sophisticated — and tiny — robots with a range of features that will one day soon enable autonomous flying.
To do so required the team to advance basic research in a number of areas where they saw obstacles to realizing their vision: from micro-manufacturing methods and materials for actuation, to small-scale energy storage and algorithms to effectively control individuals and coordinated swarms of robots.
The group’s research led to breakthroughs in each of these areas.
Highlights include new methods for manufacturing millimeter-scale devices based on lamination and folding; new sensors applicable to low-power and mobile computing applications; architectures for ultra-low power computing; and coordination algorithms for collections of hundreds or even thousands of robots to work together.
Bioinspired robotics
The team was inspired by nature — specifically the incredible ability of small insects to self-launch, navigate and perform agile actions despite their small bodies.
“Bees and other social insects provide a fascinating model for engineered systems that can maneuver in unstructured environments, sense their surroundings, communicate and perform complex tasks as a collective full of relatively simple individuals,” Wood said. “The RoboBees project grew out of this inspiration and has developed solutions to numerous fundamental challenges — challenges that are motivated by the small scale of the individual and large scale of the collective.”
Today’s RoboBee weighs only 84 milligrams — roughly the same size and even lighter than a real bee — and represents a model of successful interdisciplinary collaboration. Experts from neurobiology, evolutionary biology, materials science, computer science, electrical engineering, mechanical engineering, and bioengineering all worked together towards a common vision, with results that would be difficult to achieve with a smaller group.
While they were at it, the team created some eye-catching demonstrations, including, in 2012, the first controlled flight of an insect-scale robot.
Along the way, they have added new capabilities. The latest generation is able to swim, and they are working on RoboBees that can sense their environments using lasers.
In April 2016, the team presented work in Science that demonstrated that the RoboBee can perch during flight to save energy, as bats, birds or butterflies do.
“The use of adhesives that are controllable without complex physical mechanisms, are low power, and can adhere to a large array of surfaces is perfect for robots that are agile yet have limited payload — like the RoboBee,” Wood added. “When making robots the size of insects, simplicity and low power are always key constraints.”
The researchers used an electrode patch that takes advantage of electrostatic adhesion to allow the RoboBees to stick to almost any surface, from glass to wood to a leaf. The patch requires about 1,000 times less power to perch than it does to hover, offering to dramatically extend the operational life of the robot.
“Aerial microrobots have enormous potential for large-scale sensor deployment to inaccessible, expansive and dangerous locations. However, flight is energy-intensive, and the limitations of current energy storage technologies severely curtail in-air operations,” said Jordan Berg, an NSF program director familiar with the project. “Because the capabilities of flying insects far exceed those of similarly sized machines, many researchers seek design inspiration from nature. NSF-funded projects such as this one show that innovative solutions can arise from exploiting a synergy between biological ends and engineered means.”
The team has also generalized their insights for a range of projects beyond their core project.
“We have had some nice successes with translation of some of the technologies that emerged from the RoboBees project,” Wood said. “For example, several of the RoboBees principal investigators are now participating in a DARPA-sponsored project making new surgical tools based on the popup microfabrication technologies developed in the RoboBees project.”
Sustained support leads to big dividends
The initial project was supported by an NSF 2009 Expeditions in Computing grant, which provided $10 million over five years to the interdisciplinary, multi-investigator research teams to fund transformative computing and information technology research.
In 2012, Wood received the Alan T. Waterman Award, which recognizes one outstanding young science or engineering researcher each year.
And in 2015, Wood and his collaborators received an NSF grant to work with Intel Corporation and develop aspects of the brain-inspired computing chips their team had developed for a range of other small, autonomous systems. The award is one of a handful made as part of the InTrans program, which allows researchers to mature and deploy successful research results in industries and to transition innovations into new technologies.
Meanwhile, research on the RoboBee continues. The team is currently working to make the perching mechanism omnidirectional, enabling the robot to land anywhere, and developing onboard power sources that could allow RoboBees to fly untethered.
Wood estimates it will take another five to 10 years before the RoboBee might be ready for use in the real world.
This type of research requires a high level of sustained, long-term investment — something at which NSF excels and which helped spur technologies like the Internet, Wi-Fi and magnetic resonance imaging (MRI).
“The RoboBees project is a great example of the value of sustained support for basic research,” Wood added. “Long-term investment in high-impact research pays tremendous dividends in terms of the technology fallout. We have experienced this time and time again with this project. NSF support is essential for projects like these and in general to keep the U.S. at the forefront of technology innovation.”
Funding: The study was supported financially by the National Science Foundation.
Source: Aaron Dubrow – National Science Foundation
Image Source: This NeuroscienceNews.com image is credited to Kevin Ma and Pakpong Chirarattananon.
Original Research: AbstractNational Science Foundation for “Perching and takeoff of a robotic insect on overhangs using switchable electrostatic adhesion” by M. A. Graule, P. Chirarattananon, S. B. Fuller, N. T. Jafferis, K. Y. Ma, M. Spenko, R. Kornbluh, and R. J. Wood in Science. Published online May 20 2016 doi:10.1126/science.aaf1092
[cbtabs][cbtab title=”MLA”]National Science Foundation. “Flight of the RoboBee.” NeuroscienceNews. NeuroscienceNews, 7 June 2016.
<https://neurosciencenews.com/robobee-neuroscience-4393/>.[/cbtab][cbtab title=”APA”]National Science Foundation. (2016, June 7). Flight of the RoboBee. NeuroscienceNews. Retrieved June 7, 2016 from https://neurosciencenews.com/robobee-neuroscience-4393/[/cbtab][cbtab title=”Chicago”]National Science Foundation. “Flight of the RoboBee.” https://neurosciencenews.com/robobee-neuroscience-4393/ (accessed June 7, 2016).[/cbtab][/cbtabs]
Abstract
Perching and takeoff of a robotic insect on overhangs using switchable electrostatic adhesion
For aerial robots, maintaining a high vantage point for an extended time is crucial in many applications. However, available on-board power and mechanical fatigue constrain their flight time, especially for smaller, battery-powered aircraft. Perching on elevated structures is a biologically inspired approach to overcome these limitations. Previous perching robots have required specific material properties for the landing sites, such as surface asperities for spines, or ferromagnetism. We describe a switchable electroadhesive that enables controlled perching and detachment on nearly any material while requiring approximately three orders of magnitude less power than required to sustain flight. These electroadhesives are designed, characterized, and used to demonstrate a flying robotic insect able to robustly perch on a wide range of materials, including glass, wood, and a natural leaf.
“Perching and takeoff of a robotic insect on overhangs using switchable electrostatic adhesion” by M. A. Graule, P. Chirarattananon, S. B. Fuller, N. T. Jafferis, K. Y. Ma, M. Spenko, R. Kornbluh, and R. J. Wood in Science. Published online May 20 2016 doi:10.1126/science.aaf1092