There are robots that will vacuum your house, mow your lawn, and keep their unblinking electronic eyes on you at all times while hovering hundreds of feet in the air. How about a robot that plays a violin? That’s what [Seth Goldstein] built. He calls it a ‘kinetic sculpture’, but there more than enough electronics and mechatronics to keep even the most discerning tinkerer interested.
There are three main parts of [Seth]’s violin-playing kinetic sculpture. The first is a bow carriage that draws the bow across the strings using an electromagnet to press the bow against the strings. The individual strings are fingered with four rubber disks, and a tilting mechanism rotates the violin so the desired string is always underneath the bow and mechanical fingers.
As far as software goes, the Ro-Bow transforms MIDI files into robotic mechanization that make the violin sing. From what we can tell, it’s not quite as good as a human player; only one string at a time can be played. It is, however, great at what it does and is an amazing mechanical sculpture.
Continue reading “Ro-Bow, The Violin Playing Robot”
Yale University brings us quite a treat with their Openhand Project.
If you’ve ever operated a robotic arm, you know that one of the most cumbersome parts is always the end effector. It will quickly make you realize what an amazing work of engineering the human hand really is, and what a poor intimation a simple open-close gripper ends up being.
[Yale] is working to bring tendon-driven robotic hands to the masses with an interesting technique of combining 3D printing and resin/urethane casting. Known as Hybrid Deposition Manufacturing (HDM), it allows the team to 3D print robotic fingers that also contain the mold for finger pads and joints, all built right into the 3D part. The tendon-driven fingers allow for a very simple design that are not only easy to make, but have a low parts count as well. Because of the human-like tendons, the fingers naturally curl around the object, distributing it’s force much more evenly and naturally, much like a human hand would. In the videos after the break, you can see the building process, as well as the hand in action.
Best news is that it’s all open source. They also include some python libraries so you can customize the CAD files fit your needs.
Continue reading “Openhand Combines 3D Printing with Urethane Casting”
[Maurice] recently built a clock that draws the time (Google Doc) on a white board. We’ve seen plenty of clock hacks in the past, and even a very similar one. It’s always fun to see the different creative solutions people can come up with to solve the same problem.
This device runs on a PIC16F1454 microcontroller. The code for the project is available on GitHub. The micro is also connected to a 433MHz receiver. This allows a PC to keep track of the time, instead of having to include a real-time clock in the circuit. The USB connector is only used for power. All of the mounting pieces were designed in OpenSCAD and printed on a 3D printer. Two servos control the drawing arms. A third servo can raise and lower the marker to the whiteboard. This also has the added benefit of being able to place the marker tip inside of an eraser head. That way the same two servos can also erase the writing.
The communication protocol for this systems is interesting. The transmitter shows up on [Maurice’s] PC as a modem. All he needs to do to update the time is “echo 12:00 > /dev/whiteboard”. In this case, the command is run by a cron job every 5 minutes. This makes it easy to tweak the rate at which the time updates on the whiteboard. All communication is done one-way. The drawing circuit will verify the checksum each time it receives a message. If the check fails, the circuit simply waits for another message. The computer transmits the message multiple times, just in case there is a problem during transmission.
Week 1 of Hackaday’s Caption CERN Contest is complete. We have to say that the Hackaday.io users outdid themselves with funny captions but we also helped CERN add meaning to one of their orphan images. First a few of our favorite captions:
If you adjust that scope again, when I haven’t touched the controls, I’m donating you to a city college. – [Johnny B. Goode]
SAFTEY FIRST – The proper way to test a 6kv power supply for ripple on the output. – [milestogoh]
Dr. Otto Gunther Octavius – R&D some years before the accident. – [jlbrian7]
The prize though, goes to Hackaday commenting superstar [DainBramage], who proved he knows us all too well with his Portal inspired caption:
Here we see Doug Rattmann, one of Aperture’s best and brightest, perfecting our neurotoxin prior to delivery.
Congrats [DainBramage], enjoy your shirt from The Hackaday Store!
The Meaning of the Image:
Funny captions weren’t the only thing in the comments though – the image tickled [jlbrian7’s] memory and led to a link for CERN Love. A four-year old blog entry about robots at CERN turned out to be the key to unraveling the mystery of this captionless photo. The image depicts [Robert Horne] working with a prototype of the MANTIS system. MANTIS was a teleoperation manipulator system created to work in sections of the CERN facility which were unsafe for humans due to high levels of radioactivity. The MANTIS story is an epic hack itself, so keep your eyes peeled for a future article covering it! We’ve submitted the information to CERN, and we’re giving [jlbrian7] a T-shirt as well for his contribution to finding the actual caption for this image.
Get Started on Next Week:
The image for week 2 is already up, so head over and see for yourself. We’re eager for your clever captions. Ideally we can also figure out the backstory for each week’s randomly chosen image.
One day while at our poor, poor Radio Shack, [davidhend] purchased a little 6-legged walking robot. It came with an infrared remote that allowed a user to control its movements from afar. After a few minutes of making the robot walk around [davidhend] got bored and decided it would be a great toy to hack.
His plan was to make the robot autonomous and able to avoid obstacles. To start off, the robot was taken apart enough to expose the circuit board. There he found a ST1155A bi-directional motor driver that was controlled by an on-board microcontroller. After checking out the ST1155A data sheet, [davidhend] thought he would be able to drive it with an Arduino. So, out came the soldering iron and all the unnecessary components were removed from the original circuit board.
An off the shelf PING))) sensor was mounted on the front of the robot and is responsible for detecting obstacles. That information is then sent back to the Arduino Nano which controls the motor driver to make the robot back up, turn and then start walking straight again until another obstacle is detected. [davidhend] made his Arduino Code (.zip file) available to anyone who wants to make a similar project. Check out the video after the break!
Oh, and if you plan to run down to the Shack to pick up a robot of your own you better do it like right now.
Continue reading “Cute Tiny Robot Gets a Pair of Hacked Eyes”
[Matt], [Andrew], [Noah], and [Tim] have a pretty interesting build for their capstone project at Ohio Northern University. They’re using a Microsoft Kinect, and a Leap Motion to create a natural user interface for controlling humanoid robots.
The robot the team is using for this project is a tracked humanoid robot they’ve affectionately come to call Johnny Five. Johnny takes commands from a computer, Kinect, and Leap motion to move the chassis, arm, and gripper around in a way that’s somewhat natural, and surely a lot easier than controlling a humanoid robot with a keyboard.
The team has also released all their software onto Github under an open source license. You can grab that over on the Gits, or take a look at some of the pics and videos from the Columbus Mini Maker Faire.
Listening tests reveal significant sound quality differences between various digital music storage technologies. Finally the audiophile press is tackling the important questions. This listening test looks at the difference between two four-bay NAS boxes, with one making the piano on Scherzo and Trio from Penguin Café Orchestra’s Union Cafe sound more Steinway-like, while another NAS makes it sound more like a Bosendörfer. Yes, your choice of digital storage medium can change the timbre of a piano. Another gem: “Additionally, the two units also had different processor architectures, which might also affect perceived audible differences.” There must be a corollary to Poe’s Law when it comes to audiophiles…
[10p6] has begun a project that can play every old Atari cartridge. Right now it’s just a few bits of plastic that fits every non-Jaguar Atari cartridge, but it’s a start.
The Android IMSI-Catcher Detector. You’ve heard about Stingrays, devices used by law enforcement that are basically fake cell towers. These Stingrays downgrade or disable the encryption present in all cellphones, allowing anyone, with or without a warrant, to listen in on any cell phone conversation. Now there’s an effort to detect these Stingrays. It’s open source, and they’re looking for volunteers.
[Rob] sent in something that’s the perfect application of projection mapping. It’s called Face Hacking, and it’s pretty much just a motion capture systems, a few projectors, a whole lot of CG work, and just a tiny bit of dubstep. It look cool, but we’re wondering what the applications would be. Theatre or some sort of performance art is the best I can come up with.
A while ago, [4ndreas] saw a 3D printed industrial robot arm. He contacted the guy for the files, but nothing came of that. [4ndreas] did what anyone should do – made his own 3D printable industrial robot arm. The main motors are NEMA 17, and printing this will take a long time. Still, it looks really, really cool.