Discovery Drive Campaign Launching Soon

Our Discovery Drive campaign will be launching soon, so make sure to sign up for updates on the pre-launch page!

Discovery Drive is an automatic antenna rotator that is designed to be used with our Discovery Dish product, as well as similarly sized antennas such as Wi-Fi grid and Yagi antennas.

A motorized rotator, such as Discovery Drive, enables precise tracking of fast-moving polar orbiting satellites using a satellite dish or directional antenna. Examples of polar orbiting weather satellites include METEOR-M2, METOP, and FENGYUN. Depending on your location, you may also have access to other interesting satellites that dump data over specific regions.

Apart from public weather data, operators and enthusiasts might be interested in using Discovery Drive to track CubeSats, and amateur radio operators may wish to track amateur radio satellites.

Amateur radio astronomy hobbyists can map the galaxy in the hydrogen line spectrum using Stellarium, or custom software to aim a Discovery Dish with H-Line feed, allowing you to scan multiple parts of the sky in one night.

Please check out our promo video below!

Discovery Drive Promo Video

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Echo iOS KiwiSDR & OpenWebRX App now in Beta Testing

Back in January, we first posted about "Echo", an upcoming iOS app designed for browsing global web-based KiwiSDR and OpenWebRX software-defined radios.

Mark now notes that Echo is now in beta, and has been released to testers via TestFlight. He notes that new users can access the beta by making a small donation on his Ko-fi page. Mark writes:

Users have already reported being able to listen to some euro ham chat on their bike ride today. Where they’d usually have to put their entire iPhone in that locked guided access mode to block touch inputs on Safari, Echo allows multitasking & lock screen playback. For every SDR, any frequency. Someone else throwing the phone in their pocket & taking their walk with AirPods in their ear listening to CW. This was truly the most requested feature by far.

I’ve made several improvements since we last talked, even added support for not just Kiwi & OpenWebRX but also WebSDR & FM-DX. All built in. Over 2000+ global tuners at people’s fingertips. 11,000+ frequencies in a categorized database.

If you were unaware, OpenWebRX is a piece of server software that allows you to access and share SDRs over a network connection, such as the internet, via a web browser interface. OpenWebRX is a core component of the KiwiSDR, an SDR designed to operate as a shared receiver over a network connection. Around the world, many people have set up public KiwiSDR, RTL-SDR, and other SDR systems accessible via OpenWebRX. Echo is designed to make it easy to search for and view public OpenWebRX receivers on iOS devices.

EchoSDR Beta Screenshots
Echo iOS Beta Screenshots
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Khanfar Software: Analog Radio Hunter

Recently, M. Khanfar released a new free program, "Analog Radio Hunter," described as a "professional RF analysis and monitoring application built around GNU Radio and Fosphor." The software currently supports RTL-SDR, Airspy, and HackRF. Khanfar writes:

Analog Radio Hunter is a professional RF analysis and monitoring application built around GNU Radio and Fosphor.

It is designed to scan large RF spans, quickly lock onto active signals, and monitor analog transmissions with NFM, AM, or WFM audio demodulation.

  • Real-time FFT + waterfall spectrum display
  • Fast scan with dwell, pause-on-squelch, and skip-ignored channels
  • Detection list with hits, timestamps, and smart deactivation
  • Favorites profiles with monitor and favorites-only scan modes
  • Built-in recorder with auto-record and event log
  • Dedicated WFM broadcast receiver with presets
  • Multi-SDR device support (RTL-SDR, Airspy, HackRF) with auto-detect and device switching
  • NFM and AM audio demodulation (in addition to WFM)
  • Peak-follow in span (auto-tune to strongest signal inside the current MS/s window)
  • Frequency list filtering to skip/mute ignored channels
  • Scan and detection profiles (save/load named presets)
  • PPM correction for RTL-SDR calibration
  • Spectrum interaction controls (cursor readout, click-to-tune, wheel step, drag-pan)
  • Recorder options (record when muted, timestamp/frequency in filename, beep on favorite)
  • WFM de-emphasis selection (50/75 µs) and preset management
  • Audio Output menu with refresh (route audio to speakers, VB-Cable, or USB output)
  • Signal Stability Filter with Min Open + Grace timing and per-target routing
  • Histogram IQ Rec with live IQ follow controls and inspectrum integration
  • Auto Squelch Calibrate (noise floor + margin) for faster field setup
  • Smart Deactivate dual-layer logic (time-based + hit-rate busy rule)
  • Favorites cooldown auto-reactivation for busy channels
  • Favorite TX tones (Tone 1-9), edge selection, and tone test buttons
  • Learning Mode hover guidance for faster onboarding
  • Status bar live metrics for Last, Active, Favorite, Peak SNR, and Level
Unique scanning and detection approach: Traditional sweep scanners only see the center frequency they step to. Analog Radio Hunter monitors an entire chunk of spectrum at once and reacts to peaks inside it. That is a major differentiator.
 

High-Impact Capabilities

  • Wide-span reactive scan engine that hunts activity across a full chunk, not one center point at a time.
  • One-click IQ capture and histogram visualization with follow and idle flow controls.
  • Carrier-resilient channel management using Smart Deactivate + favorites cooldown logic.
  • Field-ready setup speed using Auto Cal squelch and persistent live status metrics.
  • Operator-selectable audio routing to speakers, VB-Cable, or USB audio output devices.
  • Operational clarity from GUI color heatmaps, scan debug reasons, and learning-mode tips.

Signal Stability Filter: Logic and Tuning

  • Purpose: reject short squelch flicker and noisy open/close chatter before actions trigger.
  • Min Open (ms): raw squelch must stay open this long before stable-open is accepted.
  • Grace (ms): stable-open is held briefly after raw close to avoid tiny dropouts.
  • Apply targets: Detection, Rec+Alerts, Scan Hold, and optional Audio Out gating.
  • Start values: Min Open 150-250 ms, Grace 40-80 ms, then tune by channel behavior.

Like his other software, which we previously covered, it is free but not open source. Anti-virus programs may flag the software as suspicious due to heuristics. We believe this to be a false position, but please proceed at your own risk.

M Khanfar Analog Radio Hunter
M Khanfar Analog Radio Hunter
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Iridium-Sniffer: A Standalone Iridium Satellite Burst Detector and Demodulator

Thank you to Aaron, who is most well known for creating the DragonOS distribution, for writing in and sharing with us a new open-source program he's recently released over on GitHub.

The program is called 'Iridium-Sniffer', and it is a standalone Iridium satellite burst detector and demodulator written in C. Typically, gr-iridium has been used for Iridium demodulation in the past, but it can be clunky and slow on lower-power embedded systems like the Raspberry Pi, as it requires the large GNU Radio dependency.

The program is compatible with iridium-toolkit, which performs the actual decoding and analysis of the Iridium packets demodulated by iridium-sniffer.

If you're not familiar with it, Iridium is a large global communications satellite constellation that provides services such as voice, messaging, and data. An antenna like our RTL-SDR Blog Active Patch antenna, combined with an SDR, can be used to receive these signals. Some data on Iridium is encrypted, but there is some unencrypted data that can be decoded when combining tools like iridium-sniffer and iridium-toolkit.

Iridium-sniffer is compatible with the HackRF, BladeRF, USRP (UHD), and SoapySDR (which includes RTL-SDR). Note that higher-bandwidth SDRs can receive much more of the ~30 MHz Iridium band, and therefore decode more data at once.

The Iridium Satellite Constellation
The Iridium Satellite Constellation
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xSDR Crowdfunding Campaign Now Live

Back in January, we posted about the upcoming crowdfunding campaign for Wavelet Lab's M.2 form factor xSDR software-defined radio product. The campaign went live a few days ago, with the xSDR priced at US$549 and a delivery date of July 15, 2026.

xSDR is a compact, single-sided M.2 software-defined radio designed for seamless integration into modern computing platforms. The “x” stands for extended; xSDR delivers extended bandwidth in the same minimal footprint as our previous model, uSDR. With 2x2 MIMO RX/TX channels, a wide 30 MHz–3.8 GHz tuning range, and up to 122.88 MSPS sampling and an updated FPGA, xSDR is a flexible platform for embedded RF, wireless research, signal intelligence, and rapid prototyping.

Designed to fit the M.2 2230 A+E-key form factor (30 mm × 22 mm), xSDR plugs directly into laptops, tablets, smartphones, and embedded computers. When paired with the wsdr.io web platform, it enables instant creation, control, and sharing of RF applications right from a browser, with no complex drivers or software setup required.

We note that sSDR, their higher end software defined radio product is due to be released for crowdfunding in March.

xSDR - A tiny, single-sided M.2 software-defined radio with 2× RX / TX channels up to 3.8 GHz

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Multimon Pager Decoding on Android

Sarah (aka SignalsEverywhere) has recently released another open-source Android app that enables the multi-signal decoder Multimon-ng to be used on Android. Multimon-ng is a commonly used decoding app, that supports various protocols such as POCSAG/FLEX pagers, as well as DTMF, ZVEI, EAS and more.

The app requires the SDR++ Android app to be running in the background with an SDR like an RTL-SDR connected. The role of SDR++ is to receive the signal and send the demodulated audio over a network connection to the Multimon-NG app, which performs the final decoding.

The app APK can be downloaded from Sarah's website via a minimum $0 donation, or alternatively, built and installed from source.

Multimon-ng on Android!

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Setting RF Based Atomic Clocks via Computer Speakers

Over on YouTube, Jeff Geerling has uploaded an interesting video showing how RF-based atomic clocks can be set via signals generated from a computer speaker. In the USA, RF-based atomic clocks typically receive their atomic time signal from the WWVB 60 kHz longwave radio station, operated near Fort Collins, Colorado. In other countries, different time signal transmitters operate on different frequencies. However, these time signals cannot be received everywhere due to interference or geographic limitations, making RF atomic clocks useless in these situations. 

As Jeff points out, a Time Station Emulator program can be used to locally emulate the WWVB or other time signals, which, while not providing atomic time accuracy, could still make these clocks useful again.

Most interestingly, the emulator program requires no special RF transmission hardware. Instead, it simply uses your computer speakers to broadcast the time signal.

By carefully crafting a waveform at a specific audio frequency (out of normal human hearing range), the digital-to-analog converter will generate higher frequency RF harmonics, and one harmonic will match the time signal frequency required by the RF-based atomic clock. The wires running to the speakers, and the speakers themselves, will act as antennas, leaking these harmonics into the surrounding environment. This means that cheaper unshielded speakers, such as those found in phones and tablets, tend to work better.  

In the video, Jeff uses a HydraSDR and an upconverter to receive the time signal generated by the speakers. While the time signal cannot be seen on the spectrum itself, in the demodulated audio, you can hear the signal's pulses.

Van Eck Phreaking time to atomic clocks

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Pocket 25: An Android P25 Phase 1 Digital Voice Radio Decoder

Thank you to reader "EN53" for submitting news about a newly released open source Android app called Pocket 25. Pocket 25 is an Android-based APCO Project 25 (P25) phase 1 digital voice decoder based on the DSD-Neo decoder engine. It was developed by Sarah Rose (aka SignalsEverywhere), whose other software we have posted about in the past.

APCO P25 phase 1 trunked digital voice systems are commonly used in the United States, Canada, Australia, and other countries by emergency services. As long as the P25 network is unencrypted, it is commonly decoded to audio with an RTL-SDR and decoding software such as DSDPlus or SDRTrunk.

Pocket 25 allows users to now decode P25 signals on portable Android devices. An RTL-SDR can be connected to an Android device via a USB-OTG cable, or a remote networked RTL-SDR can be used via an rtl_tcp connection. The app also supports RadioReference accounts, automatic GPS site hopping, smart filtering, and logging.

In the readme, Sarah also notes that, because Pocket 25 is based on the DSD-Neo engine, it supports additional digital voice protocols, including DMR, NXDN, and others. However, the interface is designed around P25, so non-P25 systems may show incorrect metadata.

The software is open source and code can be found on the GitHub. There is also an active discussion about the app on RadioReference.

Pocket25 | Running DSD-Neo on Android!

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