A Discone is a wideband antenna that is a great starting antenna for general RTL-SDR use. Over on instructables.com, user cyfus has created an instructable showing how to build a 55 MHz+ home made discone antenna for his RTL-SDR dongle. His instructions show how to build it out of parts and tools sourced entirely from hardware and electronics stores.
Using this antenna cyfus was able to receive signals from 25 MHz to around 900 MHz.
A Ukrainian developer has released his new RTL-SDR Panoramic Spectrum Analyzer software. The software utilizes the command line rtl_power software for its backend processing, so it is essentially a GUI for rtl_power.
The developer has uploaded two videos to YouTube showing the software in action. The software can be downloaded from here.
An alternative program similar to this one is RTLSDR Scanner.
Dump1090 is a popular command line ADS-B decoder which many people believe has superior decoding performance compared to other decoding software. Previously it has only been available for Linux and Mac operating systems, however recently it has been updated with a Windows command line version. The most up to date branch of dump1090 can be downloaded from GitHub here.
To install dump1090 on Windows follow these steps:
The batch file starts a dump1090 webserver which can be viewed in any browser by going to http://localhost:8080. You may wish to edit the batch file and add extra flags such as –aggressive and/or –fix to improve decoding.
SeeDeR is a new software defined radio GUI program that supports the RTL-SDR. It also supports the Funcube Dongle and BladeRF. Currently it is in an early beta release.
SeeDeR contains features specifically developed for decoding radio data transmissions from satellites – in particular the crowdfunded SkyCube satellite – such as a built-in AX.25 decoder, and a satellite pass predictor.
SeeDeR requires a PC with Windows 7+, 1+ GB RAM, 2+ GHz dual-core CPU, 20 MB HD space. The executable is 32-bit.
We need to note that SeeDeR has been a cause of some friction with the author (Youssef) of SDR# and may be part of the reason why SDR# was temporarily removed. Youssef is claiming that SeeDer has illegally used licenced code from SDR#, however the author of SeeDer refutes that claim.
Previously we posted about how it was possible to listen in on Mexican (or Brazilian?) military satellite radio pirates’ SSTV communications using an RTL-SDR. Now over on YouTube user legion elmelenas has uploaded a video showing some more Brazilian pirates using these military Fleetsatcom satellites for voice and data communications. To receive these signals he used a turnstile antenna.
Over on YouTube user SilverXiaify has uploaded a video of a project he completed for a class in his electrical engineering school. His project involves controlling a remote controlled car using a ham radio. The remote control car carries on board an RTL-SDR for signal reception and an Raspberry Pi for data processing and control. The communications protocol they used is a naive version of AFSK700.
The RTLSDR scanner software has been updated and now supports connection to an external GPS receiver. With a GPS receiver attached to a laptop, the RTL-SDR can be used to make signal strength maps by driving around in a car and monitoring the radio spectrum with RTLSDR Scanner running. The signal strength map can then be viewed in Google Earth, a GIS program or any image viewer.
On his website, David has posted a page showing his results with an “Itty Bitty Radio Telescope” connected to an RTL-SDR dongle. The Itty Bitty Radio Telescope is a small radio telescope that can be used for simple and educational radio astronomy experiments. The telescope consists of an 18 inch directv satellite dish with low noise block (LNB), a satellite finder and an RTL-SDR dongle connected to a laptop.
The LNB converts input frequencies of 12.2 GHz to 12.7 GHz down to 950 MHz to 1.45 GHz which is a range that the RTL-SDR can receive. In his YouTube video posted below David points his Itty Bitty Radio Telescope at the sun and shows the associated increase in the noise floor on SDR# due to solar radio emissions. More information and possible experiments with the Itty Bitty Radio Telescope can be found in this PDF.
