Chen’s group has been building robotic
insects for more than five years. Credit: MIT Soft and Micro Robotics Laboratory
In the future, tiny flying robots could be deployed to aid in
the search for survivors trapped beneath the rubble after a devastating
earthquake. Like real insects, these robots could flit through tight spaces
larger robots can't reach, while simultaneously dodging stationary obstacles
and pieces of falling rubble.
So
far, aerial microrobots have only been able to fly slowly along smooth
trajectories, far from the swift, agile flight of real insects—until now.
MIT researchers have demonstrated aerial
microrobots that can fly with speed and agility that is comparable to their
biological counterparts. A collaborative team designed a new AI-based
controller for
the robotic bug that enabled it to follow gymnastic flight paths, such as
executing continuous body flips.
With a two-part control scheme that
combines high performance with computational efficiency, the robot's speed and
acceleration increased by about 450% and 250%, respectively, compared to the
researchers' best previous demonstrations.
The speedy robot was agile enough to complete 10 consecutive somersaults in 11 seconds, even when wind disturbances threatened to push it off course.
Credit: Science Advances (2025). DOI:
10.1126/sciadv.aea8716
"We want to be able to use
these robots in scenarios that more traditional quad copter robots would have
trouble flying into, but that insects could navigate. Now, with our bioinspired control
framework, the flight
performance of our robot is comparable to insects in terms of speed,
acceleration, and the pitching angle. This is quite an exciting step toward
that future goal," says Kevin Chen, an associate professor in the
Department of Electrical Engineering and Computer Science (EECS), head of the
Soft and Micro Robotics Laboratory within the Research Laboratory of
Electronics (RLE), and co-senior author of a paper on the robot.
The study is published in the journal Science Advances.
Chen is joined on the paper by
co-lead authors Yi-Hsuan Hsiao, an EECS MIT graduate student; Andrea Tagliabue,
Ph.D.; and Owen Matteson, a graduate student in the Department of Aeronautics
and Astronautics (AeroAstro); as well as EECS graduate student Suhan Kim; Tong
Zhao; and co-senior author Jonathan P. How, the Ford Professor of Engineering
in the Department of Aeronautics and Astronautics and a principal investigator
in the Laboratory for Information and Decision Systems (LIDS).
An AI controller
Chen's group has been building
robotic insects for more than five years.
They recently developed a more durable version
of their tiny robot, a microcassette-sized device that weighs less than a paperclip. The new
version utilizes larger, flapping wings that enable more agile movements. They
are powered by a set of squishy artificial muscles that flap the wings at an
extremely fast rate.
But the controller—the "brain" of the robot that determines its position and tells it where to fly—was hand-tuned by a human, limiting the robot's performance.
A time-lapse photo shows a flying
microrobot performing a flip. Credit: MIT Soft and Micro Robotics Laboratory
For
the robot to fly quickly and aggressively like a real insect, it needed a more
robust controller that could account for uncertainty and perform complex
optimizations quickly.
Such a controller would be too
computationally intensive to be deployed in real time, especially with the
complicated aerodynamics of the lightweight robot.
To overcome this challenge, Chen's group
joined forces with How's team, and together, they crafted a two-step, AI-driven
control scheme that provides the robustness necessary for complex, rapid
maneuvers, and the computational efficiency needed for real-time deployment.
"The hardware advances pushed the
controller so there was more we could do on the software side, but at the same
time, as the controller developed, there was more they could do with the
hardware. As Kevin's team demonstrates new capabilities, we demonstrate that we
can utilize them," How says.
For the first step, the team built what is known as a model-predictive controller. This type of powerful controller uses a dynamic, mathematical model to predict the behavior of the robot and plan the optimal series of actions to safely follow a trajectory.
Credit: MIT Soft and Micro Robotics
Laboratory
While
computationally intensive, it can plan challenging maneuvers like aerial
somersaults, rapid turns, and aggressive body tilting. This high-performance
planner is also designed to consider constraints on the force and torque the
robot could apply, which is essential for avoiding collisions.
For instance, to perform multiple flips
in a row, the robot would need to decelerate in such a way that its initial
conditions are exactly right for doing the flip again.
"If small errors creep in, and you
try to repeat that flip 10 times with those small errors, the robot will just
crash. We need to have robust flight control," How says.
They use this expert planner to train a
"policy" based on a deep-learning model, to control the robot in real
time, through a process called imitation learning. A policy is the robot's
decision-making engine, which tells the robot where and how to fly.
Essentially, the imitation-learning
process compresses the powerful controller into a computationally efficient AI
model that can run very fast.
The key was having a smart way to create
just enough training data, which would teach the policy everything it needs to
know for aggressive maneuvers.
"The robust training method is the
secret sauce of this technique," How explains.
The AI-driven policy takes robot
positions as inputs and outputs control commands in real time, such as thrust
force and torques.
Insect-like performance
In their experiments, this two-step
approach enabled the insect-scale robot to fly 447% faster while exhibiting a
255% increase in acceleration. The robot was able to complete 10 somersaults in
11 seconds, and the tiny robot never strayed more than 4 or 5 centimeters off
its planned trajectory.
"This work demonstrates that
soft and microrobots, traditionally limited in speed, can now leverage advanced control
algorithms to achieve agility approaching that of natural insects and larger
robots, opening up new opportunities for multimodal locomotion," says
Hsiao.
The researchers were also able to
demonstrate saccade movement, which occurs when insects pitch very
aggressively, fly rapidly to a certain position, and then pitch the other way
to stop. This rapid acceleration and deceleration help insects localize themselves
and see clearly.
"This bio-mimicking flight
behavior could help us in the future when we start putting cameras and sensors
on board the robot," Chen says.
Adding sensors and cameras so the
microrobots can fly outdoors, without being attached to a complex motion
capture system, will be a major area of future work.
The researchers also want to study
how onboard sensors could help the robots avoid colliding with one another or
coordinate navigation.
"For the micro-robotics community, I hope this paper signals a paradigm shift by showing that we can develop a new control architecture that is high-performing and efficient at the same time," says Chen.
Even when wind disturbances threatened
to push it off course, a speedy robot was agile enough to complete 10
consecutive somersaults in 11 seconds. Credit: MIT Soft and Micro Robotics
Laboratory
"This
work is especially impressive because these robots still perform precise flips
and fast turns despite the large uncertainties that come from relatively large
fabrication tolerances in small-scale manufacturing, wind gusts of more than 1
meter per second, and even its power tether wrapping around the robot as it
performs repeated flips," says Sarah Bergbreiter, a professor of
mechanical engineering at Carnegie Mellon University, who was not involved with
this work.
"Although the controller currently runs on an external computer rather than onboard the robot, the authors demonstrate that similar, but less precise, control policies may be feasible even with the more limited computation available on an insect-scale robot. This is exciting because it points toward future insect-scale robots with agility approaching that of their biological counterparts," she adds.
Provided by Massachusetts Institute of Technology
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