Zigbee hackaday electricity history pdf

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It seems that [Jason] learned this while decoding the wireless conversation between his mass-market quad and its controller. The quad in question, a Yuneec Q500, is one of those mid-range, ready-to-fly drones that’s targeted at those looking to get in the air easily and take some cool pictures. Unsure how the drone and controller were gas engineer salary talking, [Jason] popped the covers and found a Zigbee chipset within. With the help of a $14 Zigbee USB dongle and some packet sniffing software from TI, [Jason] was able to see packets flowing, but decoding them was laborious. Luckily, the sniffer app can be set up to stream packets to another device, so [Jason] wrote a program to receive and display packets. He used that to completely characterize each controller input and the data coming back from the drone. It’s a long and strange toolchain, but the upshot is that he’s now able to create KML in real time and track the drone on Google Earth as it flies. The video below shows the build and a few backyard test flights.

Back in the early days of Arduino proliferation (and before you ask, yes we realize there was a time before that too), wireless was a strange and foreign beast. IR communication was definitely a thing. And if you had the gsa 2016 calendar funds there was this cool technology called ZigBee that was available, often in funny blue house-shaped XBee boards. With even more funds and a stomach for AT commands you could even bolt on a 2G cell radio for unlimited range. WiFi existed too, but connecting it to a hobbyist ecosystem of boards was a little hairier (though maybe not for our readership).

But as cell phones pushed demand for low power wireless forward and the progression of what would become the Internet of marking Terms (the IoT, of course) began, a proliferation of options appeared for wireless communication. Earlier this week we came across a great primer on some of the major wireless technologies which was put together by Digikey earlier in the year. Let’s not bury the lede. This table is the crux of the piece:

You’re unlikely to go from zero to custom wireless solution without getting down into the mud with the available dev boards for a few different common protocols, but which ones? The landscape has changed so rapidly over the years, it’s easy to get stuck in one comfortable technology and miss the appearance of the next big thing gaz 67b tamiya 1 35 (like how LoRaWAN is becoming new cool kid these days). This guide is a good overview to help catch you up and help decide which dev kits are worth a further look. But of course we still want to hear from you below about your favorite wireless gems — past, present, and future — that didn’t make it into the list (we’re looking at you 433 MHz). Posted in Wireless Hacks Tagged 6lowpan, ble table d gaskets, bluetooth, bluetooth LE, LoRaWAN, NB-IoT, NFC, reference, sigfox, wifi, z-wave, zigbee

DSSS transmits binary values as a set called a chip. The chip for digital 1 might be 11100010010 with the digital 0 being the inverse of that. You can see this in the slide at the top of this article. Normal DSSS decoding compares the signal to expected values, using a correlation algorithm that multiplies the two and gives a score. If the score is high enough, 11 in this example, then a bit has been detected.

To reverse engineer this it is necessary to center on the correct frequency and then detect the chip encoding. GNU radio is the tool of choice for processing a DSSS capture from a SPOT Connect module designed to push simple messages to a satellite communication network. The first math trick is to multiply the signal by itself and then look at spectrum analysis to see if there is a noticeable electricity and circuits class 6 ppt spike indicating the center of the frequency. This can then be adjusted with an offset and smaller spikes on either side will be observed.

When visualized in a constellation view you begin to observe a center and two opposite clusters. The next math trick is to square the signal (multiply it by itself) and it will join those opposite clusters onto one side. What this accomplishes is a strong periodic component (the cycle from the center to the cluster and back again) which reveals the chip rate.

Detecting symbols within the chip is another math trick. Subtract each successive value in the signal from the last and you will mostly end up with zero (high signal minus high signal is zero, etc). But every time the signal spikes you’re looking at a transition point and the visualization begins to look like logic traced out e85 gas stations in iowa on an oscilloscope. This technique can deal with small amounts of noise but becomes more robust with a bit of filtering.

Running his sample file through with increasing levels of noise added, the script was rock solid on detecting the parameters of the signal. Interestingly, it is even measuring the 3 parts per million difference between the transmitter and receiver clocks in the detected chip rate value. What isn’t rock solid is the actual bit information, which begins to degrade as the noise is increased. But just establishing the parameters of the protocol being used is the biggest part of the battle and this is a dependable solution for doing that quickly and automatically.

You can give the script a try. It is part of [Michael’s] Clock Recovery repo. This talk was recorded and you should add it to your reminder list for after the con when talks begin to be published. To hold you over until then, we suggest you take a look at his RF Design workshop from the 2015 Hackaday Superconference. Posted in cons, Slider, Wireless Hacks Tagged DEF CON, defcon 25, Direct Sequence Spread Spectrum, DSSS, gnu radio, gps, michael ossmann, reverse engineering, Wireless Hacking Village, zigbee

French hacker [akila] is building up a home automation system. In particular electricity 101 powerpoint, he’s been working with the “SmartHome” series of gadgets made by Chinese smartphone giant, Xiaomi. First, he started off by reverse-engineering their very nicely made temperature and humidity sensor. (Original in French, hit the translate button in the lower right.) With that under his belt, he opened up the PIR motion sensor unit to discover that it has the same debugging pinouts and the same processor. Almost too easy.

While trolling gas laws worksheet through the SDK, he found some interesting firmware called “JennicSniffer”. Well, that was easy. There’s a demo version of a protocol analyzer that he used. It would be cool to get this working with Wireshark, but that’s a project for another day. [Akila] got far enough with the demo analyzer to discover that the packets sent by the various devices in the home network are encrypted. That’s good news for the security-conscious out there and stands as the next open item on [akila]’s to-do list.

We don’t see as many ZigBee hacks as we’d expect, but they’ve definitely got a solid niche in home automation because of commercial offerings like Philips Hue and Wink. And of course, there’s the XBee line of wireless communications modules. We just wrote up a ZigBee hack that aims to work with the Hue system, though, so maybe times are changing? Posted in Wireless Hacks Tagged hack, home automation, sniffer, zigbee

For some folks, tea is a simple pleasure – boil water, steep tea, enjoy. There are those for whom tea is a sacred ritual, though, and the precise temperature control they demand requires only the finest electricity towers health risks in water heating technology. And then there are those who take things even further by making a PID-controlled electric tea kettle an IoT device with Amazon Echo integration.

Nothing worth doing isn’t worth overdoing, and [luma] scores points 1 unit electricity cost in andhra pradesh for that. Extra points too for prototyping an early iteration of his design on a RadioShack Electronics Learning Lab – the one with a manual written by Forrest Mims. [luma] started out using an Arduino with a Zigbee shield but realized the resulting circuit would have to live in an external enclosure. Switching to an ESP8266, the whole package – including optoisolators, relays, and a small wall-wart – is small enough to fit inside the kettle’s base. The end result is an MQTT device that publishes its status to his SmartThings home automation system, and now responds when he tells Alexa it’s time for tea.

The Philips Hue range is a great way to add wirelessly controllable lighting to your home, but the protocol is proprietary which makes it difficult to add our own custom hardware. [Peter] found a way to create his own Hue compatible devices based on cheap JN5168 modules that are able to connect to the Hue bridge. This means you can roll out your own lamps using cheap RGB or White LEDs, a power supply and the JN5168 Zigbee Light Link module.

He started off by trying to clone a Zigbee Light Link device to a MeshBee — Seeed studio’s open source Zigbee Pro module based on the NXP JN5168. Even though the MeshBee used the same s gashi device as a Hue lamp, it would not connect to the Hue bridge. But another clone lamp called Innr that he purchased from the local hardware store did connect quite easily. Using NXP’s open source tools, he was able to download the flash and EEPROM contents from the Innr and copy them to the MeshBee which did the trick.

After the EEPROM transfer trick, he figured out how to modify the two keys used for the ZigBee gas in dogs causes protocol — one for Home Automation and the other for the Light Link. With this final discovery he is able to take the ZigBee Light Link demo project, edit it using Beyond Studio, and then load the binaries on the MeshBee device so it can connect to the Hue bridge.

All of this work culminates in two custom firmware binaries; one for white dimmable lights and another for RGB dimmable ones. It even runs on these cheap JN5168 breakout kits he found for a few bucks. With all of the software taken care of, and having cheap ZigBee Light Link compatible modules on hand, building low cost Hue compatible lights becomes pretty straight forward.