Folding robots based on origami have emerged as an exciting new frontier of robotic design. However, they generally require onboard batteries or a wired connection to a power source, making them bulkier and clunkier than their paper inspiration and limiting their functionality. A team of researchers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) and the Wyss Institute for Biologically Inspired Engineering has created battery-free folding robots that are capable of complex, repeatable movements powered and controlled through a wireless magnetic field.

A magnetic folding robot arm can grasp and bend thanks to its pattern of origami-inspired folds and a wireless electromagnetic field. (Credit: Wyss Institute at Harvard University)

“Like origami, one of the main points of our design is simplicity,” says Dr. Je-sung Koh, who conducted the research as a Postdoctoral Fellow at the Wyss Institute and SEAS, and is now an Assistant Professor at Ajou University in South Korea. “This system requires only basic, passive electronic components on the robot to deliver an electric current — the structure of the robot itself takes care of the rest.”

Resembling the paper on which they're based, the research team's robots are flat and thin plastic tetrahedrons, with the three outer triangles connected to the central triangle by hinges, and a small circuit on the central triangle. Attached to the hinges are coils made of a type of metal called shape-memory alloy (SMA) that can recover its original shape after deformation by being heated to a certain temperature.

When the robot's hinges lie flat, the SMA coils are stretched out in their “deformed” state; when an electric current is passed through the circuit and the coils heat up, they spring back to their original, relaxed state, contracting like tiny muscles and folding the robots’ outer triangles in toward the center. When the current stops, the SMA coils are stretched back out due to the stiffness of the flexure hinge, thus lowering the outer triangles back down.

The power that creates the electrical current needed for the robots’ movement is delivered wirelessly using electromagnetic power transmission, the same technology inside wireless charging pads that recharge the batteries in cell phones and other small electronics. An external coil with its own power source generates a magnetic field, which induces a current in the circuits in the robot, thus heating the SMA coils to induce folding.

In order to control which coils contract, the team built a resonator into each coil unit and tuned it to respond only to a very specific electromagnetic frequency. By changing the frequency of the external magnetic field, they were able to induce each SMA coil to contract independently from the others.

Small and large folding robots in their relaxed state, with a U.S. quarter for scale. (Credit: Wyss Institute at Harvard University)

“Not only are our robots’ folding motions repeatable, we can control when and where they happen, which enables more complex movements,” explains Dr. Mustafa Boyvat, a Postdoctoral Fellow at the Wyss Institute and SEAS.

Just like the muscles in the human body, the SMA coils can only contract and relax. It's the structure of the body of the robot — the origami “joints” — that translates those contractions into specific movements. To demonstrate this capability, the team built a small robotic arm capable of bending to the left and right, as well as opening and closing a gripper around an object. The arm is constructed with a special origami-like pattern to permit it to bend when force is applied, and two SMA coils deliver that force when activated while a third coil pulls the gripper open. By changing the frequency of the magnetic field generated by the external coil, the team was able to control the robot's bending and gripping motions independently.

There are many applications for this kind of minimalist robotic technology. For example, rather than having an uncomfortable endoscope put down their throat to assist a doctor with surgery, a patient could just swallow a micro-robot that could move around and perform simple tasks, like holding tissue or filming, powered by a coil outside their body. Using a much larger source coil (on the order of yards in diameter) could enable wireless, battery-free communication between multiple “smart” objects in an entire home.

The team built a variety of robots, from a quarter-sized flat tetrahedral robot to a hand-sized ship robot made of folded paper, to show that their technology can accommodate a variety of circuit designs and successfully scale for devices large and small. “There is still room for miniaturization. We don't think we went to the limit of how small these can be, and we're excited to further develop our designs for biomedical applications,” Boyvat says.

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