Wireless 'RoboFly' Looks Like an Insect, Gets Its Power from Lasers

A new type of flying robot is so tiny and lightweight — it weighs about as much as a toothpick — it can perch on your finger. The little flitter is also capable of untethered flight and is powered by lasers.

This is a big leap forward in the design of diminutive airborne bots, which are usually too small to support a power source and must trail a lifeline to a distant battery in order to fly, engineers who built the new robot announced in a statement.

Their insect-inspired creation is dubbed RoboFly, and like its animal namesake, it sports a pair of delicate, transparent wings that carry it into the air. But unlike its robot precursors, RoboFly ain't got no strings to hold it down. Instead, the miniature bot uses a lightweight onboard circuit to convert laser light into enough electrical power to send it soaring. [New Flying Robots Take Cues From Airborne Animals]

A new type of flying robot is so tiny and lightweight — it weighs about as much as a toothpick — it can perch on your finger. The little flitter is also capable of untethered flight and is powered by lasers.

This is a big leap forward in the design of diminutive airborne bots, which are usually too small to support a power source and must trail a lifeline to a distant battery in order to fly, engineers who built the new robot announced in a statement.

Their insect-inspired creation is dubbed RoboFly, and like its animal namesake, it sports a pair of delicate, transparent wings that carry it into the air. But unlike its robot precursors, RoboFly ain't got no strings to hold it down. Instead, the miniature bot uses a lightweight onboard circuit to convert laser light into enough electrical power to send it soaring. [New Flying Robots Take Cues From Airborne Animals]

However, the cell doesn't store energy; the circuit must be within range of the fixed laser to generate power for the robot to take off, and once its cell moves beyond the laser's reach, RoboFly's flight is over. 

Tiny, highly maneuverable robots like RoboFly could quickly flutter into crevasses where bigger aerial drones simply wouldn't fit. One possible task for future versions of RoboFly could draw even more inspiration from flies — particularly, their talent for tracking down "smelly things," study co-author Sawyer Fuller, an assistant professor in the Department of Mechanical Engineering at the University of Washington, said in the statement.

"I'd really like to make one that finds methane leaks," he said. "You could buy a suitcase full of them, open it up, and they would fly around your building looking for plumes of gas coming out of leaky pipes. If these robots can make it easy to find leaks, they will be much more likely to be patched up, which will reduce greenhouse [gas] emissions."

NASA Tests Origami-Inspired Robot

NASA Tests Origami-Inspired Robot That May One Day Explore Mars

This small, nimble robot can fold and unfold itself

It costs a stupendous amount of money to send something from the surface of Earth to the surface of Mars, and there are severe limits on the volume and mass that you can send at any one time. In order to stuff the maximum amount of science into the minimum amount of space, NASA has had to get creative, with landers and rovers designed to be lightweight and foldable.

At NASA’s Jet Propulsion Laboratory, in Pasadena, Calif., engineers have long been trying to cram as much robot as possible into the absolute minimum amount of space, and a team of roboticists there recently showed us their latest creation: PUFFER, the Pop-Up Flat Folding Explorer Robot. It’s designed to pack down nearly flat for transport, and then re-expand on site to investigate all the places a bigger rover can’t quite reach.

The overall idea with PUFFER is that you’d pack a bunch of them along with the next Mars rover, and send them out whenever you want to go somewhere that it would be either risky or impossible for the larger rover to go. Maybe this is crawling along dunes of deep sand, taking a trip down the steep sides of a crater, or exploring little nooks and crannies where a larger rover simply can’t fit.

PUFFER’s small size and weight also open up some interesting possibilities when you think about sending more than one of them on a mission at once. Potentially, a lot more than one of them. Having access to a small swarm of PUFFERs means that you could set up robots to cooperate with each other, perhaps even to the extent of robots providing physical assistance to one another to do more comprehensive science.

One of the most exciting things about PUFFER is how it’s helping to bring some of the coolest robotics research we’ve seen over the last several years into the realm of practical applications. Most of the time, when we write about things like origami robots, the best that we can say is that in the abstract they might, at some point, be good for disaster relief or exploration or something like that. With PUFFER, JPL is taking the next step, saying, “Okay, how can we make these technologies actually do something useful in a real world environment, even if that real world is some world other than Earth?”

Delivery Drone Protects Your Package With an Origami Cage

EPFL's Collapsable Delivery Drone Protects Your Package With an Origami Cage

By Jogi Jose

Of the many, many (many many many) challenges that are inherent to urban drone delivery, safety is one of the most important. Nobody has a reliable, cost-effective solution for this, although we’ve seen some unreliable ones (dangling packages on strings) and cumbersome ones (dedicated, protected landing pads), so we’ve been missing an elegant way of protecting end users from robots that fly with spinning blades of death.

EPFL in Switzerland has had a solution for this for years—drones surrounded by protective cages that allow them to bounce off of obstacles. As far as the drones are concerned, humans are obstacles as well, so a protective cage does pretty well at protecting them from us (and vice versa). The annoying thing about these cages has always been that they’re all kinds of bulky, especially if they’re protecting a quadrotor beefy enough to be useful.

At IROS in Vancouver, researchers from Dario Floreano’s lab at EPFL will present a clever origami protective cage that can quickly expand to 92 percent of its original size to safely(ish) deliver 0.5 kilogram of whatever you want, locked up inside.

The specific folding pattern used here (similar to a Chinese lantern) was designed to result in a rigid structure—many origami enclosures are squeezable, but this one isn’t. The pattern also has vertices that are modular, allowing the density of the cage to be adjusted. You might think that the system overall would work better with the quadrotor on the inside top of the cage instead of the inside bottom, which would allow the entire cage to act as an impact absorber for hard landings and make it safer to grab, but simulations showed that having the package beneath the rotors would have a significant impact on efficiency. 

In its current form, the quadrotor (which is sorely lacking a catchy name like “Cagey McDroneface”) weighs 1 kg. The carbon fiber cage is 65 x 65 x 43 centimeters when deployed, and folds down to a size of 31 x 38 x 12 cm when stowed. To attach the package to the cage, a high-tech system comprising either “a round shape lightweight net and ropes” or a glorified plastic box is used. While the drone is technically autonomous in that it has an autopilot on board, without any sense-and-avoid system, it’s limited to navigating between GPS waypoints.

The abstract on this paper says that the cage “ensures the safety of people,” but especially since this is being presented as a delivery drone, what they really should be saying is something more like “enhances the safety of trained users.” With the drone hovering above me, my first instinct (and I think this is a common one) would be to grasp it by sticking my fingers through the cage, rather than by holding my hands flat against the cage. You can see the researchers doing the former in the video, and it puts their fingers very close to the propellers. This version of the drone will probably not sever anything, but I bet it’s very painful, and this particular design seems not ideal for generalized public deliveries. 

Looking at this thing, it seems like the cage should mess with the aerodynamics to the point where there’d be a serious impact on efficiency. As it turns out, any drone carrying a package takes a big efficiency hit, and that hit essentially overwhelms the impact that the cage has on the quadrotor. This design can also be scaled up for larger payloads (it scales linearly, cage and all), and the researchers estimate that their “proposed design could scale up to fly 2 kg cargo over 15 km, which would cover 86 percent of the deliveries made by Amazon.”

Besides just scaling the drone up, the EPFL researchers also plan to investigate other cage styles to be able to accommodate packages of different shapes and sizes (like documents). They also want to add cameras on the outside of the cage for precision landings, as well as an emergency parachute system just in case things goes wrong, which (since this is a robot) at some point it almost certainly will.