We now live in an era where complex electronics can be dwarfed by their power supply. This is illustrated, in this case, by an WiFi-enabled ESP8285 chip which has been mounted on a tiny printed circuit board. It is designed to be connected and mounted to a 9-volt battery.
The board is set up to monitor environmental conditions including temperature, pressure, humidity, and ambient light. According to creator Pesky Products (which sells other interesting gadgets on Tindie as well) they can be conveniently placed on top of door thresholds to monitor conditions in a room.
Making this board even more interesting is that it has several general purpose input output (GPIO) pins that you can use to expand its sensing capabilities, or perhaps even add output functionality.
Although an incredible board, one thing that might limit some uses is the fact that it only lasts around 60 hours while powered by 9-volt battery. Possibly offsetting this, however, is the fact that it can go into “deep sleep” mode, saving power for when you really need it. The board’s creator is still experimenting with power-saving strategies; perhaps this time limit can be pushed out significantly in the future!
This tiny puck is so jam-packed with features, a bullet point list is the only way to give you a rundown or else we will quite literally be here all day. A Kickstarter campaign is currently underway and at the time of writing it has reached nearly five times its goal of £20,000. There’s only three days left to back the project if you want to get your hands on one as soon as possible! It’s from Gordon Williams, a Tindie seller with some excellent hardware in his store. We can’t wait to see the puck there someday too.
In this tiny puck you get:
Bluetooth Low Energy version 5.0 which gives 80M range in open space.
You can write Javascript code in a browser and have it update on the device in real-time. No special software is required. Imagine how much easier this will make debugging!
It’s got a boat load of sensors — light, temperature, magnetism, capacitance, and a tactile switch that turns the puck itself into a button.
Still not satisfied with the amount of sensors? There are 6 GPIOs broken out to 0.1″ pins. This also gives you access to a 12 bit ADC, SPI, I2C and UART.
You can control the puck from a browser or from an app on your phone. Pair this with the 6 GPIO pins and you could make a robot or any of about a million other things.
The puck can be configured as a slave if you want to control it externally or alternatively it can act as a master. In master mode it can appear as a Bluetooth HID device meaning it can act as a keyboard or a mouse without having to install drivers on your PC.
The puck runs Espruino, a JavaScript interpreter for micro-controllers. Espruino has TCP/IP and HTTP magic built-in so you can connect your puck to the Internet via Bluetooth.
It’s all open source. You can check out the latest design revisions over on GitHub.
That’s the quick and dirty rundown of what this ingenious little puck has to offer. For a complete list of its features and example applications, check out the Kickstarter campaign linked at the top. The video is particularly interesting as it shows some really interesting things you can do with it. If you miss out on the Kickstarter campaign, you’ll see this puck on Tindie once all of the backers have received their pucks but why wait that long?
Electromagnetic Field is a camping festival for makers, builders, hackers, artists, and Engineers alike. If you were to draw a Venn diagram of people interested in Tindie and people going to EMF, it would probably just be a circle.
Both Tindie and Hackaday writers will be at the event and we want to invite you to a show and tell happy hour on Friday at the OxHack main tent. It’s going to run from 6-8pm and we are interested in seeing absolutely any and all projects you’ve been working on. If you are a Hackaday Prize entrant, have a project up on Hackaday.io or have a product up on Tindie, we would jump at the chance to see it in the flesh. Of course we will have some Tindie/Hackaday swag to give away and some snacks.
Once again thats 6-8pm, Friday, OxHack main tent. Brink a hack and have a snack. Be there or be square!
Knowing your power usage is incredibly useful information when it comes to implementing energy saving measures. With the Internet of Things slowly but surely finding its way into every possible gadget, your electricity bill will drop as the house you live in gets smarter. The day of the smart home is still a pipe dream for the average consumer but the fact you are reading this Tindie blog means you don’t have to wait! For the next few years ‘Smart’ homes will consist of engineers cramming sensors all over the house and hooking them up to a WiFi or Bluetooth radio. Followed by bragging to anyone that will listen about how hi-tech their house is.
Now that you’re filled in on the smart home situation, let’s take a look at the NodeMCU energy monitor board made by Whatnick Inc. NodeMCU is open-source firmware that runs on the ESP8266 WiFi chip. It allows you to program the ESP8266 using the LUA programming language, which is easy to get started with. There are a boatload of examples over on the NodeMCU website to get you going. All of this combined with the ADS1115 Analog to Digital converter from Texas Instruments gives you an Internet connected mains power monitor.
Power usage is calculated by multiplying current times voltage, so you must sample both of them at the same time. This board comes with a clip-on current transducer for measuring current and an isolation transformer for sampling voltage. The obvious advantage of buying a pre-designed PCB is you reduce the risk of making a mistake and letting mains voltage get somewhere it shouldn’t. Like your heart for example.
Whatnick Inc has some great example usage over on the documentation page. Using the ESP8266 it is a couple lines of LUA code to send your mains power usage over to ThingSpeak for graphing.
If you want to turn a light on at a certain time every night, then a simple mechanical timer from your preferred hardware or general merchandise store is probably a good choice. If, however, you need extremely detailed control over when and how long to trigger a light, bell, production line equipment, or really anything you need to switch at a set interval, then the Tick Tock Timer by 8Bit Automation is what you want.
Timing patterns, as seen in the video below, can be set via a built-in touch screen. Up to 20 scheduled events can be set up, along with 5 holiday periods where the relay does not come on. It can also be actuated manually, and response to this input can be customized. If that wasn’t enough, it has a security feature that allows for three levels of access.
The housing is 3D-printed, and comes in red, grey, or blue. Though this might seem nice from an aesthetics point of view, I could also see this being important if you want to color coordinate several of these switches for easy access.
As a kid, you probably played a game called “Connect Four,” where you drop your colored cylinder into a slot with the goal of connecting four pieces. This “Four in a Row” game is played in much the same way, with one big difference. Neither side’s pieces are colored, but are instead clear acrylic disks.
As shown in the video below, once a disk is dropped into a slot, the game recognizes this and lights it up in your color. It’s programmed to recognize and highlight a win, and even allows you to reposition a disk if you make a mistake. If that weren’t enough, when the game is not being played, it acts as a customizable scrolling text display.
[vimeo 174857562 w=640 h=360]
As you probably know, this isn’t the only thing that can be made out of acrylic and RGB LEDs. The Est store also lists in “Interactive light effect tower,” which appears to be fun for all ages. The light pattern can be changed via three infrared sensors, and it can act as a three-dimensional audio view meter.
Measuring pulse is a tricky business due to the low amplitude of the signals involved which are usually only a few milli-volts. Photoplethysmogram (PPG) is a method of detecting pulse which works using an IR LED and an IR photo-detector. IR light is shone into the skin and the amount reflected back changes as the blood pulses through the body.
The signal from the photo-detector needs to be amplified before it can be effectively sampled by an Analog to Digital Converter like the ones found in most micro-controllers. This is where the Easy Pulse Plugin steps in to save the day. It uses the MCP6004 Quad Op Amp made by Microchip for amplification. From reading the documentation page, it’s clear that a lot of work has gone into the circuit design to get the cleanest possible signal out. The board is also Arduino compatible, designed to plug directly into an Arduino’s header pins. It can also be plugged into a breadboard for use with whatever microcontroller you work with.
Unless you’re already in the know, “Tindie” is perhaps a term you’re not really that familiar with. Though I had a passing familiarity of it as sort of an Etsy platform for electronics, before I started writing here, I didn’t really know what kind of things were sold and who was selling. After a month or so of browsing, perhaps I can help fill you in.
How Did it Start?
As seen in the video below, founder Emile Petrone noticed a steady uptick in Arduino and Raspberry Pi interest. In 2012, he put the question out there: would people support a marketplace for custom electronics? From that humble idea came the idea for this site.
As far as the name, per this interview, it’s derived from “Indie Tech” and “Tech Indie,” leading naturally to “Tindie.”
“Low run electronics” is the obvious answer, but there is much more available here. Some items aren’t really electronic at all. Perhaps you could say that the primary things sold here are items that would appeal to the segment of the population that really geeks out on electronics, photography, 3D-printing, and other technological pursuits. Also, musical devices like MIDI controllers or synthesizers are quite popular, and unique LED light sculptures and jewelry seem to be popping up recently.
To put it another way, things like knitted sweaters or paintings might not fit in here. On the other hand, a robot or innovative tool to help with either pursuit would certainly be a welcome addition! Tindie is the place you go to find bleeding edge electronics without having to wait for those products to make it all the way through the cycle. It’s like getting an inside line on knowledgable-consumer-ready prototypes of the hottest stuff.
Who is Selling?
Like Etsy, Tindie aims to make it easy to go to market with a product before you’re to prove a huge market for the device. According to my interview with Iqaudio founder Gordon Garrity, they had no idea how to sell things on the internet, but “Tindie makes it easy, real easy.” Now that they have a better feel for things, and have tested their market, they have their own independent online presence. Whether you want to stay small, or have bigger plans and just want to get started, there’s a place for you on Tindie.
What’s the Story with the dog?
The dog’s name is “Ohm.” There is also a flea featured here as sort of the mascot of Tindie’s “Flea Market”. Although I haven’t been told officially, I’d have to assume that they are not friends.
This LORA/GPS board designed by Dragino Tech is made for the Raspberry Pi and opens up a host of cool projects for that most popular of Single Board Computers. LORA (which stands for Long Range Radio) is a unique type of modulation that is best described as a frequency modulated FM chirp. Other types of modulation you may have heard of are PSK(Phase Shift Keying) and FSK( Frequency Shift Keying). LORA has advantages over those modulation schemes in that it increases the possible range and the receiver sensitivity.
The creators of LORA are a company called Semtech and they pitch it as the as a solution for IoT and M2M( Machine to Machine) networks. Currently GSM is used widely in M2M applications. IoT devices communicate with standards like Bluetooth or WiFi. GSM has the advantage of high speed data transfer and long range but the power used to send and receive is too large to use with batteries for any decent length of time. Standards like Bluetooth and WiFi are lower in power usage, have good data transfer rates, but are limited by range. LORA combines low power usage with the long range of several kilometers, at the cost of speed.
The highest possible speed with LORA is around 38 kbps. To put this speed in context, it would take 11 minutes to transfer a 3MB file (average mp3 file roughly). Speed isn’t what LORA is designed for and the benefits from having low power use and long range are huge. In applications with remote sensors( e.g. environment sensors, water level sensors, movement sensors), they only need to transmit a few bytes quite infrequently e.g. a sensor reading a few times per hour. LORA really shines here and could theoretically transmit for years on a single battery charge.
The chip that the LORA/GPS board uses for communication is the SX1276/SX1278 transceiver IC made by Semtech. The combinations of GPS with LORA open up the possibility of some really interesting projects like long range remote monitoring and tracking for example. You have long range, it can last for years on a single charge, and you know your exact location. What would you make?
OSHCHIP combines an ARM cortex M0 processor and a Bluetooth Low Energy radio on a tiny PCB that is breadboard compatible. This board is great for those looking to get a start in ARM development especially since it comes with great documentation showing you how to hook everything up and some example code that you can compile yourself using the mbed online compiler.
The ARM processor and radio are combined into a single Nordic Semi nRF51822. The ARM processor runs at 16MHz and has 256Kb of Flash and 32Kb of SRAM. The radio included is a multi-protocol 2.4GHz compatible device. It works with the famous NRF24L series chips as well as supporting Bluetooth Low Energy (AKA Bluetooth Smart).
The OSHCHIP comes with 3 on board LEDs, a 10 bit ADC, and 14 GPIO pins to play with. The chip is programmed using the SWD (Serial Wire Debug) protocol. There is a SWD programmer available from OSHCHIP that is compatible with the Keil IDE and gives you some nice debugging options like breakpoints, examining memory, stepping through code etc.
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