The M3-Neony and M3-Synchy were developed as baby bots aimed at testing machine learning software, and specifically to take a look at fine motor skill development. The hardware on this adorable little bot are some typical cameras, a microphone, gyro, accelerometer, and tactile sensors.

I heard about the M3–neony and M3-synchy through this Engadget article but I was disappointed the coverage was so scant. When I began blogging for GoRobotics, I mentioned briefly my loved for HCI, and in particular human-robot interaction – naturally, this article inspired me enough for a second article today. But, as I was excited reading about it, it looks like the article only mentions briefly the research goals of the bots. There is, however, a lot of information about what was used to make them for you gearheads out there. I’m going to comb to find the Japanese lab site if I can, in the meantime here is what’s available so far:

This article at Plastic Pals seems to have more detailed specs on these two robots. The article is long, but features more detailed specs on the bot:

[...] it is 50cm (19.6″) tall, weighs about 3.5kg (7.7 lbs) – about the size of a newborn.  A pair of CMOS cameras for sight and microphones for hearing, as well as gyro and accelerometer sensors, and tactile sensors provide various feedback. The robot has a total of 22 degrees of freedom, powered by high torque (41kg/cm) servo motors sold by Osaka-based robotics company Vstone.

The main focus is on facial expressions and arm gestures, so it is an upper body robot only, with 17 DOF (2 eyes x3, neck x3, waist x2, 2 arms x3), measuring 30cm (12″) tall and weighing 2.5kg (5.5 lbs). The head is equipped with a single wide-angle lens CCD camera, two microphones, a speaker, and 15 LEDs which cause the robot to blush bright red.  Combined with object recognition, speech recognition, and speech synthesis, the robot will be able to communicate in a variety of ways.  The chest and arms appear to be based on Vstone’s Robovie-X hobby robot kit.

If anyone finds out more about what kind of tactile sensors are involved, I’d love to hear about it. Tactile sensors aren’t something I hear about a lot and I’d love to put together an article on what’s out there.

You can catch a video here, and do check out the Plastic Pals article – they have a great gallery of these baby bots.

This little gem came to me courtesy of my friend Greg Baker, who is a lecturer in Computer Science at Simon Fraser University. Thanks Greg! This one was too cool to pass up.

Gåågle - It’s not as weird to pronounce as you’d think. It’s actually pronounced like Google and you’ll begin to see why soon enough. Gåågle Bot is a modified remote-control Roomba that bears a webcam, fueled by real-time AJAX calls that zips around taking pictures and indexing the real world as it sees it. Vacuum, index. I love efficiency!

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The name GåågleBot is a play on the words gÃ¥ and google bot. The Swedish word for go is gåå. Googlebot, is the name of Google’s web indexer. If you don’t know what Google is, you are either lying or out of luck. Hence GåågleBot is a “going” indexer, indexing the real world around us while vacuuming your home at the same time! Can’t find that library book that is due tomorrow? Relax, just Gåågle it!

Excited about this bot? Head over here and give it a try. There is also a pretty nifty video as well showing the bot in action. The main site has all of the components listed, the source code, and other tidbits to get you started building your own remote-control crawler.

Today I have an interesting tidbit for those of you on LinkedIn ! There is now a LinkedIn group for hobby roboteers! Now I have even more of a reason to finally get on LinkedIn – we’ll see how much the temptation drives me.

The meat of today’s article is MIT’s MeBot.

MIT's MeBot

MIT has a pretty established humanoid robotics lab, meaning they’re at the forefront of our latent dreams to one day have cyborgs and robots walk the streets with our fellow man. (Call it whimsy, call it crazy, but I’m looking forward to an increasing number of robots in society. ) Anybody interested in robotics already knows of the legacy that MIT has for it’s robotics development, including Kismet – a rather impressive early attempt at robot-human social interaction (you can find more about Kismet here), and Cog – another human-robot interaction experiment that followed the reasoning that Cog should be able to learn from interacting with humans (more information about Cog here). MeBot comes to us from the Personal Robotics Lab.

Telerobotics is the area of robotics development concerned with – you probably guessed it – remote-control robots. The overarching idea of the field is that work needs to be done at a distance in some situations in life, and telerobotics is here to aim to answer those challenges.

The robot was presented at the Human-Robot Interaction conference in Osaka, Japan. Putting an OQO atop for a head plus some gesturing arms into the mix, it adds depth to the notion that you could really be there, and with a decent range of motion, rolling down the halls of MIT. Remotely. Via a robot.

The proposal here is that this mode allows the user to be more engaged through the movement of the head and arms. The head tracks  the face of of the user so that it can ‘look around’. The arms are moved by a set of hand-operated controls.