Xyla Foxlin is a Mechatronics engineer, entrepreneur, and beauty queen who amongst many other titles is also a STEM YouTuber. In her latest YouTube video Xyla sends her Miss America crown that she received as winner of Miss Greater Cleveland 2018 to space on a high altitude balloon.
In the video she explains her beauty queen journey, shows the balloon prep, launch and recovery and well as the video of the crown ascending into space via an onboard camera. Whilst not specifically mentioned in the video, in the description of her video she also notes that the scientific payload of the balloon was an RTL-SDR.
The scientific payload was an RTL SDR radio receiver recording spectrum data from FM broadcast stations as it ascended. This was a collaboration with my friend (and PhD candidate in Electrical Engineering) Kristina Collins, with the goal of submitting a paper to HamSCI eventually. (Collaboration means she did most of the payload and I did most of the get-it-to-the-stratosphere part)
We were able to track the payload in real time all the way to 112,00 feet because we flew an APRS transmitter using my Amateur Radio Callsign. This let anyone following me watch it in real time as well, it even flew over one of my fan's houses! If you plan on launching a weather balloon, I HIGHLY recommend getting your HAM license so you can fly with APRS.
Over on his YouTube channel Tech Minds has uploaded a video where he tests out a cheap US$90 automatic antenna switch with DC-160 MHz range that he purchased from Chinese goods retailer Banggood. An automatic antenna switch like this is required when wanting to use an SDR such as an RTL-SDR as a panadapter with a transmit capable radio. The switch will automatically switch the SDR to ground when transmitting, so that high power does not enter the SDR via the shared antenna and destroy it.
In the video Tech Minds shows how to set the switch connections up and then demonstrates the switch in action with a Yaesu FT-991A and SDRplay SDR. He notes that this cheap Chinese version is actually built better than the MFJ-1708 antenna switch which until recently was the only commercial option available. It is also half the price.
PANADAPTER For Any Radio DC - 160 MHz SDR Antenna Switch
Over on their blog Trend Micro have uploaded a post describing how they evaluated the security of LoRaWAN communications using an RTL-SDR. LoRaWAN is a wireless communications technology that allows for Internet of Things (IoT) connectivity at a much lower cost compared to cellular infrastructure. However, as described in their post LoRaWAN incorporates very little security, making connected devices an easy target for hackers.
The researchers at Trend Micro used an RTL-SDR together with the LoRaPWN software tool which is an improved version of the LoRa Craft Project. With LoRaPWN the researchers were able to intercept uplink and downlink packets. Then when combined with a brute force dictionary attack, they were then able to recover the encryption keys allowing them to decode the data. Finally they were also able to demonstrate a denial of service attack which results in a device being unable to send further data.
For more information the technical paper (pdf) describing their full setup and tests is available, as well as an older post describing possible LoRaWAN attacks. There is also a YouTube video from "The Things Conference" which we have embedded below. In the video researcher Sebastian Dudek presents some of his findings on LoRaWAN security.
LoRaPWNing: Practical radio attacks on LoRaWAN - Sebastian Dudek (Trend Micro)
Scanner School is an online site providing tutorials, podcasts and reviews all about the radio scanning hobby. They are currently planning a Webinar for February 23, 2021 titled "Why Every Scanner User Needs an SDR: The #1 Underrated Tool that should be in your setup". You can sign up to the webinar here. In addition to the upcoming webinar they have also already released episode 165 of their podcast titled "This is Why You Need an SDR". The topics covered in the podcast are listed below.
An SDR means that anything normally handled by the hardware of the radio is now handled by the computer, and the physical hardware serves as an interface.
The only limitation on the SDR hardware you buy is the frequency range and the amount of RF it can digest.
SDR receivers have come a long way since they were first hacked into existence.
SDRs used to be difficult to set up, but that’s no longer true.
You don’t need advanced computer skills to run SDR software.
SDR software can run on PC, Linux, Mac, Raspberry PI, and even Android.
An SDR is more flexible and less expensive than a traditional radio.
You can turn a $30 USB stick into something as powerful as an SDS200 in an afternoon.
All you need to get started is an SDR USB stick, a computer, and the free starter software SDR Sharp.
Once you get set up with FM broadcast stations, aviation, and other analog systems, Phil’s SDR course will go into how to set up digital reception.
If you download DSD+ Fast Lane or Unitrunker you can monitor trunking systems.
Aside from these results, Steve's post goes on to explain how he gathers and stores these analytics and an example of using the Graphs1090 software for producing nice plots of the aircraft receive. One important tip that he mentions is to be careful when constantly logging ADS-B data to the SD card as the card can easily get corrupted over time since there are read/write cycle limits.
The FL2K project allows us to turn a cheap USB 3.0 dongle into a fully transmit capable SDR (filters still required for high power work). We have posted about the FL2k project several times on this blog since early 2018.
IK1XPV, author of the code notes that the current code is only tested on the Windows driver branch, via compilation on Visual Studio 2019 at the moment. The main contributed code can be found in \src\fl2k_noise.c.
In the past we've posted several times about how 1.42 GHz Hydrogen Line amateur radio telescopes used with RTL-SDRs or other SDRs for Hydrogen line observations of the galaxy. Recently Hackaday ran a post highlighting a project from "PhysicsOpenLab" describing an 11.2 GHz radio telescope that uses an Airspy SDR as the receiver.
Celestial bodies emit radio waves all across the radio spectrum and typically observations can be made anywhere between 20 MHz to 20 GHz. Choosing an optimal frequency it is a tradeoff between antenna size, directivity and avoiding man made noise. For these reasons, observations at 10-12 GHz are most suitable for amateur radio telescopes.
The posts by PhysicsOpenLab are split into two. The first post highlights the hardware used which includes a 1.2m prime focus dish, and 11.2 GHz TV LNB, a wideband amplifier, a SAW filter, a bias tee, and the Airspy SDR. The LNB converts the 11.2 GHz signal down to 1.4 GHz which can be received by the Airspy. Once at 1.4 GHz it's possible then to use existing commercial filters and amplifiers designed for Hydrogen line observations.
The second post explains the GNU Radio based software implementation and the mathematical equations required to understand the gathered data. Finally in this post they also graph some results gathered during a solar and lunar transit.
Finally they note that even a 1.2m dish is quite small for a radio telescopic, but it may be possible to detect the emissions from the Milky Way and other celestial radio sources such as nebulae like Cassiopeia A, Taurus A and Cygnus A a radio galaxy.