Over on YouTube Tech Minds has uploaded a new video where he shows how he can use his HackRF SDR with the SDRAngel software to easily transmit voice to a local ham radio repeater. If you are unfamiliar with ham radio, a ham repeater is simply a radio station that receives voice or other signals on a certain ham radio frequency, and re-transmits the signal with stronger power on another frequency. This allows communications to be receivable over a much larger distance.
SDRAngel is a very nice piece of SDR software that has controls for TX capable SDR's like the HackRF. In the video Tech Minds shows the HackRF being used as a transmitter, with it transmitting to a repeater at 145.137 MHz. An RTL-SDR is then used to listen to the repeater output at 145.737 MHz. With this set up he is able to contact a friend via the repeater easily.
It doesn't appear that Tech Minds is using any sort of external amplifier, so this shows that the HackRF is powerful enough to hit local repeaters just by itself.
A few weeks ago we posted about the MFJ1708SDR automatic relay switch and how it can be used to combine an RX only SDR with a transmit capable radio. An automatic antenna relay switch is used to automatically ground the SDR's antenna input whenever the TX capable radio transmits in order to protect the SDR's front end from blowing up due to high TX power.
In this YouTube video Pete Sobye shows us the MFJ1708SDR working together with an Icom IC7300 HF radio and an SDRplay which is being used as a panadapter. For software Pete uses HDSDR and Omnirig which allows the PC to control the IC7300.
We are currently looking for a dev or engineer to work on a short project that will involve developing easy to use software for passive radar and direction finding applications. The hardware will utilize low cost phase coherent RTL-SDR's. The project is paid and will probably last about a month (depending on your speed on work). It would suit a student, researcher or hobbyist with some spare time. If you are familiar with RTL-SDR's, C/C++/Python, have DSP experience, and ideally have experience with direction finding please apply with a short bio, CV and relevant experience to [email protected] for more information. If the project is successful there may be future work. Thanks!
Back in March of this year we posted about Nexmon SDR which is code that you can use to turn a Broadcom BCM4339 802.11ac WiFi chip into a TX capable SDR that is capable of transmitting any arbitrary signal from IQ data within the 2.4 GHz and 5 GHz WiFi bands. In commercial devices the BCM4339 was most commonly found in the Nexus 5 smartphone.
Recently Nexmon have tweeted that their code now supports the BCM43455c0 which is the WiFi chip used in the recently released Raspberry Pi 3B+. They write that the previous Raspberry Pi 3B (non-plus) cannot be used with Nexmon as it only has 802.11n, but since the 3B+ has 802.11ac Nexmon is compatible.
Combined with RPiTX which is a Raspberry Pi tool for transmitting arbitrary RF signals using a GPIO pin between 5 kHz to 1500 MHz, the Raspberry Pi 3B+ may end up becoming a versatile low cost TX SDR just on it's own.
We are proud to announce that #nexmon now turns Raspberry Pi B3+ computers' Wi-Fi chips (BCM43455c0) into software-defined radios. Visit https://t.co/wku9Go9kRt to try it out! The RPi3 cannot be supported due to its 802.11n PHY which is incapable of raw transmissions.
Balint Seeber from security research firm Bastille has recently disclosed a major security vulnerability found in wirelessly controlled emergency sirens called "SirenJack". These sirens are used in many states and cities within the USA to warn large populations of disasters or other dangers, although at the moment only sirens by ATI System in San Francisco have been identified as vulnerable. The vulnerability stems from the fact that the wireless protocol used to activate the sirens is not encrypted, so a bad actor could record the monthly test activation transmissions, analyze them and forge control signals of his own. This would allow a hacker to take control the sirens at will using a simple $30 handheld radio and a laptop, or a transmit capable software defined radio.
This security research release comes after the Dallas tornado siren hack, which occurred in early 2017. During that hack a hacker activated 156 tornado sirens placed around the city of Dallas, Texas. In contrast to SirenJack, the Dallas siren hack was most likely caused by a more standard replay or brute force attack, since simple DTMF tones are used to activate Dallas' siren system.
ATI Systems have indicated that they have already patched the vulnerability as Bastille responsibly disclosed the vulnerability to them 3 months prior. However, it is likely that sirens created by other contractors in other states may have the same or similar vulnerabilities.
In the video below Balint shows the SirenJack vulnerability in action on a test siren setup. During the test he is able to take control of the siren and transmit any arbitrary audio to it using a software defined radio. Several other SirenJack video are available on Bastille's YouTube channel.
The software is based on the set up from this excellent tutorial, which creates scripts and a crontab entry that automatically activates whenever a NOAA weather satellite passes overhead. Once running, the script activates the RTL-SDR and APT decoder which creates the weather satellite image. He then uses some of his owns scripts in Twython which automatically posts the images to a Twitter account. His Twython scripts as well as a readme file that shows how to use them can be found in his Google Drive.
Over on YouTube user AE0AI has uploaded a video where he explains how he uses an RTL-SDR and a home made noise source as a poor man's network analyzer. A network analyzer is a tool that allows you to analyze the response of RF devices, such as filters. By using a noise source together with an RTL-SDR the same functionality as a network analyzer can be obtained, however of course with less accuracy.
In the video AE0AI shows us his home made noise generator, which is a based on a simple circuit that he found online. He then shows the noise generator connected to the RTL-SDR, which shows that his home made generator works up to about 40 MHz. Later in the video he tests a home made 40m filter with the noise source and RTL-SDR, and the response is easily visible. With the response visible he is able to tune the filter by adjusting the inductor windings.
Later in the paper they also show how to eliminate intermodulation effects by enabling the MW/AM notch filters on the SDRplay RSP1A unit, and by carefully choosing the LO frequency.
The RSP1A covers the spectrum from 1kHz to 2GHz, and phantom signals can be a menace for all wideband SDR receivers. More and more is being published about the most obvious culprit which is inter-modulation caused by very strong interferers such as MW/FM broadcast transmitters – indeed, all the current SDRplay RSPs have built in filters to help reduce the problems caused by that.
But the reality is, particularly at HF and below, that a phantom signal may occur for other reasons such as higher order mixing effects. Sometimes, it can be difficult to know what is the cause of the phantom signal. If you can understand the cause, there are additional steps you can take to overcome it.
We’ve just published this white paper to explain the difference between intermodulation and higher-order mixing effects, and what practical steps you can take to reduce the latter in particular. Our example uses an RSP1A operating at frequencies below 60MHz.