Besides Pokémon, there might have been no greater media franchise for a child of the 90s than the Transformers, mysterious robots fighting an intergalactic war but which can inexplicably change into various Earth-based object, like trucks and airplanes. It led to a number of toys which can also change shapes from fighting robots into various ordinary objects as well. And, perhaps in a way of life imitating art, plenty of real-life robots have features one might think were inspired by this franchise like this transforming quadruped robot.
Called the CYOBot, the robot has four articulating arms with a wheel at the end of each. The arms can be placed in a wide array of positions for different operating characteristics, allowing the robot to move in an incredibly diverse way. It’s based on a previous version called the CYOCrawler, using similar articulating arms but with no wheels. The build centers around an ESP32-S3 microcontroller, giving it plenty of compute power for things like machine learning, as well as wireless capabilities for control or access to more computing power.
Both robots are open source and modular as well, allowing a range of people to use and add on to the platform. Another perk here is that most parts are common or 3d printed, making it a fairly low barrier to entry for a platform with so many different configurations and options for expansion and development. If you prefer robots without wheels, though, we’d always recommend looking at Strandbeests for inspiration.
Even in the advanced world of 2024, robots are still better in science fiction than in reality. Star Trek gave us the erudite and refined Data, Rogue One gave us the fierce yet funny K-2SO, and Big Hero 6 gave us the caring charmer named Baymax. All these robots had smarts, capability, and agency. More than that, though—they were faithful(ish) companions to humans, fulfilling what that role entails.
The thing is, we’re not gonna get robots like that unless somebody builds them. [Angela Sheehan] is a artist and an educator, and a maker—and she’s trying to create exactly that. She came down to the 2023 Hackaday Supercon to tell us all about her efforts to create cuddly companion bots for real.
Beep Boop
You might remember Angela from her 2019 Supercon costume—she showed up dressed as a color-changing fairy. In fact, she has dabbled in all kinds of fields, which has given her a broad skillset applicable to creating companion bots. She’s done lots of costuming and cosplay over the years, she’s worked in product design, and she brands herself a bit of a fashion hacker. These skills might not be particularly relevant to building a high-speed industrial robot arm to perform 2000 welds an hour. However, they come in absolute clutch when you’re trying to build a robot that acts as a soft, cuddly companion. She notes that she was inspired to create her own companion bots by the work of others formerly showcased by Hackaday—you might remember work in this field from Alex Glow and Jorvon Moss.
Angela’s talk soon tackles the elephant in the room—from the drop, you’ve probably been wondering about the cute critter perched on her shoulder. The long-tailed creature is named Nova, and she’s remarkably friendly and soothing once you get to know her.
Development took some time, with Angela doing lots of research and development to create the Nova we see today. “I actually did a lot of the prototyping and field testing for this bot in the library makerspace that I work at,” she explains. “It was great to see people who don’t know the inside and out of technology interact with [Nova] and I could pinpoint the moment that she became alive to people.” The bot got quite a response, transcending the level of basic machine to something a little more. “People wanted to come in and visit her and pet her,” says Angela. “That was such a powerful moment… that happened as soon as I started putting a face on her.” Angela doesn’t just tell the tale—during the talk, she passes Nova to the audience so they can interact with her up close. She explains that this is something that she does regularly—and we get to see photos of the lovely interactions Nova has had with dozens of smiling, happy people.
Nova leverages Angela’s skills in sewing, 3D modelling, and 3D printing. She explains how components like Nova’s wings were first drafted in Adobe Illustrator. From there, the structure was refined into actual models in Fusion 360, while a PCB was developed in Eagle for the lighting electronics.
The face, though, was perhaps most crucial—as is the case for any anthropomorphic character. She took inspiration from Toothless from How To Train Your Dragon, using a stuffed toy as reference. Initial attempts weren’t particularly satisfying though, so she learned 3D sculpting for a further attempt in clay. Feedback from Twitter helped her develop the face further into the Nova we see today. The eyes were sourced from an Etsy supplier specializing in doll eyes. Angela notes there’s some magic there—when backlit with LEDs, switching them on and off can create a really believable blink pattern that feels super realistic. “What are those elements that make it feel alive?” Angela muses. “There are just little pieces of the psychology of it that you can dial into and you can make something that feels very alive.”
The talk then covers the rest of the design that helps create the “illusion of life.” Angela explains using servos and a robot gripper mechanism to flap the wings, and dialing in the motion so it felt as authentic as possible. She also covers robustness, designing “cuddle-worthy” bodies, and the value of designing for modularity. There’s also a useful discussion about how to make these builds more accessible, including useful starting points like which microcontroller and code platforms are good to use.
Even better, we get a look into the companion bot community, and we learn about the emotional impact these robots can have. Sometimes that’s intentional, other times, it’s down to a happy accident. “There is an unintended effect with [Nova’s] servos, that it feels like a purr,” says Angela. “It’s very comforting right on your shoulder, and I was thinking maybe I should try and insulate it a little bit, but actually people love it.”
Fundamentally, companion bots are a bit like virtual reality. We’ve seen a ton of products make big promises over the years, but we’ve never seen a killer app. However, as [Angela] demonstrates, it’s very possible to create something very real and very lovable if you pay attention to the right things. Perhaps it’s the personal touch that makes DIY companion bots so seemingly lifelike in a way that Furby never was.
In any case, if you’ve ever wanted a robot companion of your very own, there’s no reason you can’t start building your own. With maker skills, enthusiasm, and the will to succeed, you can create a fun and cuddly robot critter that has that magical spark of life.
Venus hasn’t received nearly the same attention from space programs as Mars, largely due to its exceedingly hostile environment. Most electronics wouldn’t survive the 462 °C heat, never mind the intense atmospheric pressure and sulfuric acid clouds. With this in mind, NASA has been experimenting with the concept of a completely mechanical rover. The [Beardy Penguin] and a team of fellow students from the University of Southampton decided to try their hand at the concept—video after the break.
The project was divided into four subsystems: obstacle detection, mechanical computer, locomotion (tracks), and the drivetrain. The obstacle detection system consists of three (left, center, right) triple-rollers in front of the rover, which trigger inputs on the mechanical computer when it encounters an obstacle over a certain size. The inputs indicate the position of each roller (up/down) and the combination of inputs determines the appropriate maneuver to clear the obstacle. [Beardy Penguin] used Simulink to design the logic circuit, consisting of AND, OR, and NOT gates. The resulting 5-layer mechanical computer quickly ran into the limits of tolerances and friction, and the team eventually had trouble getting their design to work with the available input forces.
Due to the high-pressure atmosphere, an on-board wind turbine has long been proposed as a viable power source for a Venus rover. It wasn’t part of this project, so it was replaced with a comparable 40 W electric motor. The output from a logic circuit goes through a timing mechanism and into a planetary gearbox system. It changes output rotation direction by driving the planet gear carrier with the sun gear or locking it in a stationary position.
As with many undergraduate engineering projects, the physical results were mixed, but the educational value was immense. They got individual subsystems working, but not the fully integrated prototype. Even so, they received several awards for their project and even came third in an international Simulink challenge. It also allowed another team to continue their work and refine the subsystems.
As natural as walking is to us tail-less bipedal mammals, the fact of the matter is that it took many evolutionary adaptations to make this act of controlled falling forward work (somewhat) reliably. It’s therefore little wonder that replicating bipedal walking (and running) in robotics is taking a while. Recently a Chinese humanoid robot managed to bump up the maximum running speed to 3.6 m/s (12.96 km/h), during a match between two of Robot Era’s STAR1 humanoid robots in the Gobi desert.
For comparison, the footspeed of humans during a marathon is around 20 km/h and significantly higher with a sprint. These humanoid robots did a 34 minute run, with an interesting difference being that one was equipped with running shoes, which helped it reach these faster speeds. Clearly the same reasons which has led humans to start adopting footwear since humankind’s hunter-gatherer days – including increased grip and traction – also apply to humanoid robots.
That said, it looks like the era when humans can no longer outrun humanoid robots is still a long time off.
Automating tasks with a robot sounds appealing, but not everyone has the budget for an Aismo or Kuka. [FABRI Creator] has a great tutorial on how to build your own mini robotic arm for small, repeatable tasks.
Walking us through the entire build, step-by-step, [FABRI Creator] shows us how to populate the custom-designed PCB and where to put every servo motor and potentiometer to bring the creation to life. This seems like a great project to start with if you haven’t branched out into motion systems before since it’s a useful build without anything too complicated to trip up the beginner.
Beyond the usual ability to use the arm to perform tasks, this particular device uses an Arduino Nano to allow you to record a set of positions as you move the arm and to replay it over and over. The video shows the arm putting rings on a stand, but we can think of all kinds of small tasks that it could accomplish for us, letting us get back to writing or hacking.
As things get smaller, we can fit more processing power into devices like robots to allow them to do more things or interact with their environment in new ways. If not, we can at least build them for less cost. But the design process can get exponentially more complicated when miniaturizing things. [Carl] wanted to build the smallest 9-axis robotic microcontroller with as many features as possible, and went through a number of design iterations to finally get to this extremely small robotics platform.
Although there are smaller wireless-enabled microcontrollers, [Carl] based this project around the popular ESP32 platform to allow it to be usable by a wider range of people. With that module taking up most of the top side of the PCB, he turned to the bottom to add the rest of the components for the platform. The first thing to add was a power management circuit, and after one iteration he settled on a circuit which can provide the board power from a battery or a USB cable, while also managing the battery’s charge. As for sensors, it has a light sensor and an optional 9-axis motion sensor, allowing for gesture sensing, proximity detection, and motion tracking.
Of course there were some compromises in this design to minimize the footprint, like placing the antenna near the USB-C charger and sacrificing some processing power compared to other development boards like the STM-32. But for the size and cost of components it’s hard to get so many features in such a small package. [Carl] is using it to build some pretty tiny robots so it suits his needs perfectly. In fact, it’s hard to find anything smaller that isn’t a bristlebot.