Scripting languages are for large computers, right? “Real” embedded device work is a hellish, never-ending cycle of code, compile, and re-flash. Well, I used to think so too, but with the proliferation of scripting and other interactive languages to microcontrollers over the last few years, the hurdle to interactive development on the small chips has gotten a lot lower.
On the ESP8266 platform, I’ve tried out NodeMCU’s Lua and ESP8266 BASIC. (For the last half-year, I’ve been using the awesome Mecrisp-Stellaris almost exclusively on the STM32F1xx and F4xx chips, but haven’t dipped into ESP8266 Forth yet.)
NodeMCU is great because it’s got everything you could want built in, and through cloud services it’s easy to get a tailored build made that maximizes free flash memory for your projects. I just don’t dig the asynchronous Lua thing (you might, try it!). ESP BASIC has a different set of libraries, and is missing MQTT for my purposes. Still it’s pretty slick, and worth a look.
So when the MicroPython folks announced that they were releasing the binary builds for the ESP, I thought it was time to give it a spin. I’ve used Python for nearly twelve years now, so it’s like a comfortable shoe for me. Would MicroPython be the same on the ESP8266? The short answer is yes and no.
Continue reading “MicroPython on the ESP8266: Kicking the Tires”
The 2016 Hackaday SuperConference is coming. Now is the time to submit your proposal for a talk or a workshop at the world’s greatest conference about hardware creation. The SuperCon is an unparalleled opportunity to present on a deeply technical level where you can be certain everyone in the audience is following. All of those details, the war stories of production, the out-of-stock problems and board respins, the moments when you’ve bent physics to your will, these stories will be met with awe and cheers as the audience of your peers takes the ride along with you.
SuperCon will take place in Pasadena, California on November 5th and 6th, 2016. It is a gathering of hackers, designers, and engineers passionate about learning, teaching, and celebrating what goes into making new and exciting creations. The atmosphere will be that of a hacker village, with several venues in close proximity playing host to talks, workshops, and other activities. This breaks out of the beige prison that usually accompanies hotel-based conferences and opens the weekend up for you to meet and interact with a cadre of interesting people. SuperCon is the place to share your hard-won knowledge and experience, and to add to your own arsenal of skills.
Accepted talks will be scheduled for 20-40 minutes, and workshops will be booked for 1-4 hours. In both cases, topics may include themes like techniques for rapid prototyping, new and interesting uses of technology, creativity in technical design, and stories of product development and manufacturing.
Last year’s SuperConference was incredibly successful. If you weren’t able to attend you can still work your way through all of the talks which were recorded and posted shortly after the event. That success is a credit to all of the talented presenters in the Hackaday community who put together their stories to share for the benefit of all. Thank you!
To all of you reading this now and wondering if you should propose a talk, you should! We thank you in advance for taking time out of your life to make this year’s SuperConference even more amazing by submitting your own proposal. It won’t happen without you because this is a conference of active involvement and not one of passive consumption. Be the hardware movement; this is your chance.
Do you dream of opening a hackerspace, makerspace, or co-working space? Maybe it’s in the works and you’re already scoping out locations, intoxicated by visions of all the projects that will emerge from it. Here’s a sobering thought: makerspaces are a great big pile of risk. If the doors of your ‘space are already open, perhaps you’ve come to realize that the initial insurance policy you signed doesn’t really fit the needs of your particular creative paradise. Even if it does, the protection you need will change as you acquire new toys.
So why should you even get insurance? For one thing, your landlord will probably require it. If you own the building, you should insure it to protect yourself and anyone who uses the space. Do it for the same reason you’d insure a car, your house, or your collection of vintage pinball machines: to mitigate risk. It takes a lot of hard work to open a makerspace, perform the day-to-day operations, and keep it growing and getting better. Whenever the unthinkable happens, insurance will protect your investment as well as the people who make it a great place to be.
In researching this article, I contacted several well-established makerspaces in the United States as well as most of the major insurance providers to get both sides of the story. My intent was not to make a how-to guide, but to simply explore the topic and provide a view of the process and the struggle.
Continue reading “Hackerspaces are Hard: Insurance”
3D Printering: the final frontier. These are the voyages of another 3D printer hack. Its mission: to explore strange new ways of leveling a print bed.
So far, we’ve had servo probes, Allen key probes, Z-sled probes, inductive and capacitive contactless switches, just to name a few. All of them allow a 3D printer to probe its print bed, calculate a correction plane or mesh, and compensate for its own inherent, time variant, inaccuracies.
Continue reading “Sonic 3D Printer Auto Bed Leveling Makes a Swoosh”
How does one go about measuring the mass of an object? Mass is defined as the amount of matter an object contains. This is very different from weight, of course, as the mass of our object would remain the same despite the presence or size of a gravitational field. It is safe to say, however, that most laboratory measurement systems are here on Earth, and we can use the Earth’s gravity to aid in our mass measurement. One way is to use a balance and a known amount of mass. Simply place our object on one side of the balance, and keep adding known amounts of mass to the other side until the balance is balanced.
But what if our object is very small…too small to see and too light to measure with gravity? How does one measure the mass of single atom? Furthermore, how does one determine how much of an object consists of a particular type of atom? There are two commonly used tools just for this purpose. Chances are you’ve heard of one of these but not the other. These tools used to measure substances on the atomic level is the focus of today’s article.
Continue reading “How to Measure the Extremely Small: Atomic Mass”
Like many people, going through university followed an intense career building period was a dry spell in terms of making things. Of course things settled down and I finally broke that dry spell to work on what I called “non-conventional propulsion”.
I wanted to stay away from the term “anti-gravity” because I was enough of a science nut to know that such a thing was dubious. But I also suspected that there might be science principles yet to be discovered. I was willing to give it a try anyway, and did for a few years. It was also my introduction to the world of high voltage… DC. Everything came out null though, meaning that any effects could be accounted for by some form of ionization or Coulomb force. At no time did I get anything to actually fly, though there was a lot of spinning things on rotors or weight changes on scales and balances due to ion propulsion.
So when a video appeared in 2001 from a small company called Transdimensional Technologies of a triangle shaped, aluminum foil and wire thing called a lifter that actually propelled itself off the table, I immediately had to make one. I’d had enough background by then to be confident that it was flying using ion propulsion. And in fact, given my background I was able to put an enhancement in my first version that others came up with only later.
For those who’ve never seen a lifter, it’s extremely simple. Think of it as a very leaky capacitor. One electrode is an aluminum foil skirt, in the shape of a triangle. Spaced apart from that around an inch or so away, usually using 1/6″ balsa wood sticks, is a very thin bare wire (think 30AWG) also shaped as a triangle. High voltage is applied between the foil skirt and the wire. The result is that a downward jet of air is created around and through the middle of the triangle and the lifter flies up off the table. But that is just the barest explanation of how it works. We must go deeper!
Continue reading “Expanding Horizons With The Ion Propelled Lifter”
The history of capacitors starts in the pioneering days of electricity. I liken it to the pioneering days of aviation when you made your own planes out of wood and canvas and struggled to leap into the air, not understanding enough about aerodynamics to know how to stay there. Electricity had a similar period. At the time of the discovery of the capacitor our understanding was so primitive that electricity was thought to be a fluid and that it came in two forms, vitreous electricity and resinous electricity. As you’ll see below, it was during the capacitor’s early years that all this changed.
The history starts in 1745. At the time, one way of generating electricity was to use a friction machine. This consisted of a glass globe rotated at a few hundred RPM while you stroked it with the palms of your hands. This generated electricity on the glass which could then be discharged. Today we call the effect taking place the triboelectric effect, which you can see demonstrated here powering an LCD screen.
Continue reading “History of the Capacitor – The Pioneering Years”