These 3D Printed Millirobots Can Sense and React to Their Surroundings – Singularity Hub

The millirobot looked like an adorable cartoon vehicle as it expertly navigated a complex maze. Its a strange creature: the bottom resembles a collapsed fence; the top, a colander-like basket. The size of a penny, it seems fragile and utterly unassuming.

But at its core is a potential paradigm shift for building autonomous robots that can sense and respond to its local environment. Unlike classic robots, which are assembled with multiple components, the millirobot is 3D printed with a milky-looking metamaterial that can flexibly change its properties with a few electrical zaps.

Metamaterials sound like something out of a comic book, but the concept is simple. Unlike wood, glass, or other static materials we readily rely on to hold their structure, the metamaterials used in the studypiezoelectric materialseasily change their structure when blasted with an electromagnetic field. This allows the material to twist, contort, shrink, or expand. Map out each movement, and its possible to build and steer a robot.

To build the bot, the team designed a 3D printing setup to print out robotic structures using piezoelectric materials. As an additional add-on, the team gave the bots an ultrasound glowup, embedding components into the material, which helped the bots turn vibrations into electricity to sense their environment.

The millibots learned to autonomously walk, jump, and escape from potential obstacles in real time. They could even take a mini-beach hike in the lab, easily navigating through a rough, sandy terrain partially covered with greenery.

The bots, though still rudimentary, could one day help deliver drugs in confined spaces in our bodies if shrunken down. They may also act as cheap, tiny, but powerful scouts to explore new or hazardous environments.

To Dr. Ahmad Rafsanjani at the Center for Soft Robotics, University of Southern Denmark, who was not involved in the study, the millibots bring metamaterials into the limelight as a new way to construct autonomous robots. The study highlights a broader view of robotic materials in which the boundary between materials and machines becomes indiscernible, he wrote in a related commentary. Additive manufacturing of piezoelectric metamaterials may lead to materializing fully integrated robots that might eventually walk straight out of a 3D printer.

Metamaterials are weird. But thanks to their exotic properties, scientists have readily explored potential uses for these strange ducks. A classic one is optics. Metamaterials are often made of components that flexibly interact with electromagnetic waves, including light. In a way, theyre similar to camera lenses or mirrors, but with the superpower to rapidly change how they direct every light wave. In theory, a carefully created structure from metamaterials could overhaul all types of glassesfrom microscope lenses to those on our faces.

More recently, scientists began exploring other uses. One major effort is incorporating piezoelectric materials into neuromorphic chips, which roughly simulate how the brain computes and stores information. By changing the properties of these materials with electrical fields, scientists can approximate how synapses work with ultra-low energy. Other studies tapped into metamaterials acrobatic ability to morph their shape, creating structures that convert linear motionsay, a crab walkinto rotations and mechanical gears. Its as if your legs suddenly turn into rotating wheels.

Yeah, metamaterials are weird. How do they work?

It helps to imagine them as old-school boxed TVs with antennae. To adjust the channelthat is, the materials behavioryou move the antennae around until their structure interacts strongly with radio waves, and voil, youve nailed the materials state. It can then be blended with conventional materials to build intricate, lattice-like structures while preserving their metamorphosis properties. This flexibility makes them an especially intriguing canvas for designing robots. Because theyre a near-single structure, in the long run, they could help build intelligent prosthetics less prone to failure, as they dont have mechanical moving parts. Rather than soldering, they can now be 3D printed. (This gives me all the Westworld vibesmechanical Dolores versus milky-liquid printed version, anyone?).

The new millibots look like a hybrid between Wall-E and TARS, a ridged, folding, chopsticks-esque robot in Interstellar. Fully 3D printed, they shattered the conventional dogma for building robots. Normally, a robot needs several independent components: sensors to navigate the environment, microprocessors for the brain, actuators for movement, and a power supply to drive the whole system. Each link is prone to failure.

Here, the team integrated each component into one design. The first key ingredient is piezoelectric materials, which convert electrical fields into mechanical tension and vice versa. Theyre the muscles that guide the robots movement. But they do triple duty. Depending on the state of the metamaterial, it can form a ceramic-like backbone to help the millibot maintain its shape. In its conductive phase, it acts like nerve cells, capturing electromagnetic signals to control the muscles. Further bumping up the bots prowess is an ultrasonic element, melded onto the bot, that helps it sense its surroundings.

Altogether, the simple millibot essentially has multiple systems mixed into one glaring white goo: a nervous system capable of sensing and actuation, a muscle component, and a skeletal structure. Dropping the goo into a 3D printer, the team built sophisticated lattices as the robots backbone, each carefully decorated with conductive metals and piezoelectric properties onto specific regions.

The result? A tiny robot that taps into electrical fields to sense and navigate its environment. Even more impressive is its ability to understand its own bodily movements and place in spacea trick called proprioception thats been dubbed the sixth sense of human perception and rarely implemented in robots.

With a few challenges, the authors next showcased the bots prowess. One robot expertly navigated around roadblocks in real time as a human sequentially dropped down barriers based on ultrasound feedback. In another test, the robot hopped long distances and expertly navigated sharp turns. With just milliseconds of delay, the robot frog hopped several rough surfaces without a sweata motor task thats previously bewildered other bots.

The millibots also made great pack mules. Even with 500 percent weight in payloadsuch as an onboard power source, a driver, and a microcontrollerthey were able to move easily with just a 20 percent decline in speed. In practice, the superpower makes these bots great scaffolds as drug delivery machines that may one day roam our bloodstream.

A single piece of piezoelectric material can be extremely flexible, with six degrees of freedomthe ability to extend linearly in three axes (like bending your arm forward, sideways, and back) and twist rotationally. Thanks to the studys additive manufacturing, its easy to design different robotic architectures guided by creative algorithms.

The team artfully interweaved actuation and perception in a lightweight miniature

composite 3D lattice that moves around and senses its surroundings, said Rafsanjani.

The robots may come off as an incongruous conundrum: a flexible creature thats made of hard ceramic-like backbone with one metamaterial. But so are we humanswere made of cells with vastly different shapes, sizes, and capabilities. Adapting ideas used to design piezoelectric robots gives soft robotics a new outlook, potentially leading to completely artificial materials that jive with our bodies.

The study brings robotic metamaterials closer to biological systems, one function at a time, said Rafsanjani.

Image Credit: Rayne Research Group

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These 3D Printed Millirobots Can Sense and React to Their Surroundings - Singularity Hub