Skip to main content

Harvard’s insect-inspired HAMR robot scuttles like a cockroach on meth

The Power and Control Autonomous Harvard Ambulatory MicroRobot (HAMR-F)

For many folks, the word “hammer” summons up distinctly 1990s images of baggy hip-hop pants and rapper-dancers going broke. There is nothing retro about Harvard University’s HAMR robot, however. An acronym derived from “Harvard Ambulatory MicroRobot,” it’s a cutting-edge, insect-inspired robot that can scamper along the ground at an impressive speed of a little under four times its own body lengths every second.

Unlike previous versions of the robot that Harvard has built, its latest iteration — the HAMR-F — no longer has to be tethered to a power source in order to function. While that makes it a little slower than its predecessor, it also opens up new possibilities in terms of freedom of movement.

“The Harvard Ambulatory MicroRobot is a quadrupedal robot that is inspired by cockroaches, having a similar size, mass, and body morphology to them,” Benjamin Goldberg, a researcher on the project, told Digital Trends. “Tethered versions of HAMR have previously been shown to run at speeds exceeding 10 body lengths per second and can perform agile turning and dynamic jumping maneuvers. The most exciting development with HAMR-F is that we are now able to take the robot outside of the lab with an onboard battery an electronics, while still maintaining high speeds and maneuverability.”

The ready-to-run robot weighs just 2.8 grams and is powered by an 8-mAh lithium-polymer battery. Eventually, the hope is that it will be able to move autonomously but, right now, it still has to be controlled via a human operator, although this can be carried out wirelessly.

Harvard University
Harvard University

“The application for HAMR-F that we are most excited about is confined environment exploration,” Goldberg continued. “For example, HAMR-F could be used to search for defects within an engine cavity, within a pipe, or behind a wall. Our current version demonstrates really robust tether-free locomotion capabilities — however, many applications would still require sensors such as a camera or other specialized sensing modalities. HAMR-F has a substantial payload carrying capacity of around 50 percent of its own body weight and the circuit boards are compatible with many of these sensors, so hopefully, these types of applications are not far off.”

Goldberg said that the next step for HAMR’s development is to add more exteroceptive sensors, capable of wirelessly transmitting data back to a host machine. “This is a technology that we are very excited about commercializing because we see great potential for cost reduction and automation of some inspection tasks by opening up new pathways in challenging environments and tight spaces,” Goldberg said.

A paper describing the work has been submitted to the journal IEEE Robotics and Automation Letters.

Luke Dormehl
I'm a UK-based tech writer covering Cool Tech at Digital Trends. I've also written for Fast Company, Wired, the Guardian…
Insect-inspired repair robot clings to giant turbine blades with suction legs
BladeBug robot

Have you heard of “wing walkers,” the daredevil stuntmen and women who walk along the wings of planes in flight? Well, BladeBUG is cut from the same cloth -- only instead of airborne planes, it performs “blade walks” along the blades of operational offshore wind turbines. And instead of being a death-defying human daredevil, it’s a suction cup-equipped robot insect. (But other than that, it’s totally the same.)

“This opens the door to autonomous inspection and repair of wind turbines, improving the efficiency of the blades and reducing risk for rope access technicians,” Chris Cieslak, founder and director of BladeBUG, told Digital Trends. “[Our robot] uses a patent-pending six-legged design with suction cup feet, which means each of the legs can move and bend independently. This is significant because it enables the robot to walk on the blade’s changing curved surface, as well as inside the blade, tower, or hub of the turbine.”

Read more
Tiny robot can be made to ‘walk’ using pulsed laser beams
Laser microbot

Computer chips morph into tiny robots with medical applications

A breakthrough robot can be made to walk by charging up its legs with pulsed laser beams, allowing it to move without the need for an onboard battery. Unfortunately, you’ll probably never get to see it with your own eyes.

Read more
This speedy, tiny soft robot was inspired by the way a cheetah runs
north carolina state cheetah robot

video combined

Researchers at North Carolina State University have built a cheetah-inspired robot. But it doesn’t look quite like what you’re probably expecting. While we’re used to robots like Boston Dynamics’ canine-inspired, full-sized dog robots, North Carolina State’s cheetah robot is just 7 centimeters long (2.75 inches) and weighs only 45 grams (just over 1.5 ounces). For those who don’t qualify as wildlife experts, that’s considerably smaller than a real-life adult cheetah, which can measure around 4.5 feet in length, and weigh between 75 and 150 pounds.

Read more