The Internet of Things will kill us all and is the worst idea anyone has ever had. However, just because something could be labeled an ‘Internet of Things thing’ doesn’t mean it’s a bad idea. The Hackaday Prize’s Internet of Useful Things challenge was all about finding the Internet of Useful things, and one of these projects is so simple yet so elegant, we’re surprised no one has thought of it yet.
[David]’s entry to the Hackaday Prize is effectively an Internet of Things doorbell. You might think an IoT doorbell would just consist of a device sending push notifications to your phone. That’s part of the project, but it gets so much better.
The brilliant part of this build boils down to a simple relay. On command, [David] can turn his doorbell off. This means no ringing doorbell interrupting meals or naps. By sending a command to the ESP32 in this little device, [David] can enable or disable his doorbell. Of course, this doorbell also sends push notifications to his phone, so if the UPS guy throws a package at his front door and manages to hit the doorbell, [David] will still hear it even if he’s upstairs, in the garage, or in the backyard.
This is the simplest and most brilliant Internet of Things device ever created. It solves an obvious problem with surprisingly little hardware. The only data this device collects is the state of a doorbell, and even if this device was completely hacked by balaclava-wearing hackers, they still can’t F5 the doorbell. This is the best the Internet of Things has to offer, and we’re proud to have the Internet of Doorbells make it to the finals of the Hackaday Prize.
We just closed out the Internet of Useful Things round of the Hackaday Prize, which means we’re neck deep in judging projects to move onto the final round this fall. Last week, everyone on Hackaday.io was busy getting their four project logs and illustrations ready for the last call in this round of the Hackaday Prize. These projects are the best of what the Internet of Things has to offer because this is the Internet of Useful things.
We’re not sure how [Matthias]’ project will rank. It’s an Internet of Things fidget spinner. Yeah, we know, but there are some interesting engineering challenges in building an Internet-connected fidget spinner.
This is a PoV fidget spinner, which means the leading edges of this tricorn spinner are bedazzled with APA102 LEDs. Persistence-of-vision toys are as old as Hackaday, and the entire idea of a fidget spinner is to spin, so this at least makes sense.
These PoV LEDs are driven by an ESP8285, or an ESP8266 with onboard Flash. This is probably the smallest wireless microcontroller you can find, an important consideration for such a small build. Power comes from a tiny LiPo, and additional peripherals include an accelerometer to measure wobble and an optical switch to measure the rotation speed.
These electronics are fairly standard, and wouldn’t look out of place in any other project in The Hackaday Prize. The trick here is mechanical. [Matthias] needs to mount a skateboard bearing to a PCB, and no one has any idea how he’s going to do that. A fidget spinner should be well-balanced, and again [Matthias] is running into a problem. Has anyone here ever done mass and density calculations on PCBs and lithium cells? Is it possible to 3D print conformal counterweights? Has science gone too far?
Will the Internet of Things PoV Fidget Spinner make it to the finals round of The Hackaday Prize? We’ll need to wait a week or so to find out. One thing is for certain, though: you’re going to see this on AliBaba before September.
[Uri Shaked]’s lamentation over the breaking of his smart bulb was brief as it was inspiring — now he had a perfectly valid excuse to hack it into a magic light bulb.
The first step was disassembling the bulb and converting it to run on a tiny, 130mAh battery. Inside the bulb’s base, the power supply board, Bluetooth and radio circuits, as well as the LED board didn’t leave much room, but he was able to fit in 3.3V and 12V step-up voltage regulators for the LiPo battery.
[Shaked]’s self-imposed bonus round was to also wedge a charging circuit — which he co-opted from a previous project — into the bulb instead of disassembling it every time it needed more juice. Re-soldering the parts together: easy. Fitting everything inside a minuscule puzzle-box: hard. Kapton tape proved eminently helpful in preventing shorts in the confined space.
Continue reading “A Magic Light Bulb For All Your Bright Ideas”
[Paul] has put together an insanely small yet powerful tracker for monitoring all the things. The USB TinyTracker is a device that packages a 48MHz processor, 2G modem, GPS receiver, 9DOF motion sensor, barometer, microphone, and micro-SD slot for data storage. He managed to get it all to fit into a USB thumb drive enclosure, meaning that you can program it however you want in the Arduino IDE, then plug it into any USB port and let it run. This enables things like remote monitoring, asset tracking, and all kinds of spy-like activity.
One of the most unusual aspects of his project, though, is this line: “Everything came together very nicely and the height of parts and PCBs is exactly as I planned.” [Paul] had picked out an enclosure that was only supposed to fit a single PCB, but with some careful calculations, and picky component selection, he managed to fit everything onto two 2-layer boards that snap together with a connector and fit inside the enclosure.
We’ve followed [Paul’s] progress on this project with an earlier iteration of his GSM GPS Tracker, which used a Teensy and fit snugly into a handlebar, but this one is much more versatile.
Don’t forget to get your connected device entered in the Hackaday Prize by Monday morning. The current challenge is IuT ! IoT, a clever tilt at the Internet of Things, which is so hot right now. We don’t just want things to connect, we want that connection to be useful, so save your Internet Toasters and Twittering Toilets for another round.
So what are we looking for here? Any device that communicates with something else and thereby performs a service that has meaningful value. The Hackaday Prize is about building something that matters.
We’ve been covering a lot of great entries. HeartyPatch is an open source heart rate monitor and ECG that communicates through a smart phone. We’ve seen an affordable water level measuring station to help track when water levels are rising dangerously fast in flood prone areas. And the heads-up display for multimeters seeks to make work safer for those dealing with high voltages. Get inspired by all of the IuT ! IoT entries.
There’s $20,000 at stake in this challenge alone, as twenty IuT projects will be named finalists, awarded $1000 each, and move on to compete for the top prizes in the finals.
If you don’t have your project up on Hackaday.io yet, now’s the time. Once your project is published, entering is as easy as using the dropdown box on the left sidebar of your project page. [Shulie] even put together a quick video showing how to submit your entry. Check to make sure “Internet of Useful Things” is listed on your project’s sidebar and if not, use that dropdown to add it.
ITEAD’s Sonoff line is a range of Internet-of-Things devices based around the ESP8266. This makes them popular for hacking due to their accessibility. Past projects have figured out how to reflash the Sonoff devices, but for [mirko], that wasn’t enough – it was time to reverse engineer the Sonoff Over-The-Air update protocol.
[mirko]’s motivation is simple enough – a desire for IoT devices that don’t need to phone home to the corporate mothership, combined with wanting to avoid the labor of cracking open every Sonoff device to reflash it with wires like a Neanderthal. The first step involved connecting the Sonoff device to WiFi and capturing the traffic. This quickly turned up an SSL connection to a remote URL. This was easily intercepted as the device doesn’t do any certificate validation – but a lack of security is sadly never a surprise on the Internet of Things.
After capturing the network traffic, [mirko] set about piecing together the protocol used to execute the OTA updates. After a basic handshake between client and server, the server can ask the client to take various actions – such as downloading an updated firmware image. After determining the messaging format, [mirko] sought to create a webserver in Python to replicate this behaviour.
There are some pitfalls – firmware images need to be formatted slightly differently for OTA updates versus the usual serial upload method, as this process leaves the stock bootloader intact. There’s also the split-partition flash storage system to deal with, which [mirko] is still working on.
Nevertheless, it’s great to see hackers doing what they do best – taking control over hardware and software to serve their own purposes. To learn more, why not check out how to flash your Sonoff devices over serial? They’re just an ESP8266 inside, after all.
The Internet of Things, as originally envisioned in papers dating to the early to mid-90s, is a magical concept. Wearable devices would report your location, health stats, and physiological information to a private server. Cameras in your shower would tell your doctor if that mole is getting bigger. Your car would monitor the life of your cabin air filter and buy a new one when the time arrived. Nanobots would become programmable matter, morphing into chairs, houses, and kitchen utensils. A ubiquity of computing would serve humans as an unseen hive mind. It was paradise, delivered by ever smaller computers, sensors, and advanced robotics.
The future didn’t turn out like we planned. While the scientists and engineers responsible for asking how they could make an Internet-connected toaster oven, no one was around to ask why anyone would want that. At least we got a 3Com Audrey out of this deal.
Fast forward to today and we learn [Christopher Hiller] just put his toilet on the Internet. Why is he doing this? Even he doesn’t know, but it does make for a great ‘logs from a toilet’ pun.
The hardware for this device is a Digistump Oak, a neat little Arduino-compatible WiFi-enabled development board. The Digistump Oak is able to publish to the Particle Cloud, and with just five lines of code, [Chris] is able to publish a flush to the Internet. The sensor for this build is a cheap plastic float switch. There are only three components in this build, and one of them is a 4k7 resistor.
Right now, there are a few issues with the build. It’s battery-powered, but that’s only because [Chris]’ toilet isn’t close enough to a wall outlet. There’s a bit of moisture in a bathroom, and clingfilm solves the problem for now, but some silly cone carne would solve that problem the right way. [Chris] also has two toilets, so he’ll need to build another one.