ProtoView is a digital signal detection and visualization tool for the Flipper Zero. The Flipper is able to identify a great deal of RF protocols, however when the exact protocol is not implemented (and there are many proprietary ones, such as the ones of the car keys), the curious person is left wondering what the device is sending at all. Using ProtoView she or he can visualize the high and low pulses like in the example image below (showing a Volkswagen key in 2FSK):

This is often enough to make an initial idea about the encoding used and if the selected modulation is correct.

Other than that, ProtoView is able to decode a few interesting protocols:

• TPMS sensors: Renault, Toyota, Schrader, Citroen, Ford.
• Microchip HSC200/300/301 Keeloq protocol.
• Oregon thermometer protocol 2.
• PT2262, SC5262 based remotes.
• ... more will be implemented soon, hopefully. Send PRs :)

The app implements a framework that makes adding and experimenting with new protocols very simple. Check the protocols directory to see how the API works.

The secondary goal of ProtoView is to provide a somewhat-documented application for the Flipper (even if ProtoView is a pretty atypical application: doesn't make use of the standard widgets and other abstractions provded by the framework). Many apps dealing with the subghz subsystem (the Flipper abstraction to work with the CC1101 chip) tend to be complicated and completely undocumented. This is unfortunately true for the firmware of the device itself. It's a shame because especially in the case of code that talks with hardware peripherals there are tons of assumptions and hard-gained lessons that can only be captured by comments and are in the code only implicitly.

However, the Flipper firmware source code is well written even if it lacks comments and documentation, so it is possible to make some ideas of how things work just grepping inside.

In order to show unknown signals, the application attempts to understand if the samples obtained by the Flipper API (a series of pulses that are high or low, and with different duration in microseconds) look like belonging to a legitimate signal, and aren't just noise.

We can't make assumptions about the encoding and the data rate of the communication, so we use a simple but relatively effective algorithm. As we check the signal, we try to detect long parts of it that are composed of pulses roughly classifiable into a maximum of three different classes of lengths, plus or minus 10%. Most encodings are somewhat self-clocked, so they tend to have just two or three classes of pulse lengths.

However often pulses of the same theoretical length have slightly different lengths in the case of high and low level (RF on or off), so we classify them separately for robustness.

The application shows the longest coherent signal detected so far.

• The OK button resets the current signal.
• The UP and DOWN buttons change the scale. Default is 100us per pixel.
• The LEFT and RIGHT buttons switch to settings.

Under the detected sequence, you will see a small triangle marking a specific sample. This mark means that the sequence looked coherent up to that point, and starting from there it could be just noise.

If the protocol is decoded, the bottom-left corner of the screen will show the name of the protocol, and going in the next screen with the right arrow will show information about the decoded signal.

In the bottom-right corner the application displays an amount of time in microseconds. This is the average length of the shortest pulse length detected among the three classes. Usually the data rate of the protocol is something like 1000000/this-number*2, but it depends on the encoding and could actually be 1000000/this-number*N with N > 2 (here 1000000 is the number of microseconds in one second, and N is the number of clock cycles needed to represent a bit).

Things to investigate:

• Many cheap remotes (gate openers, remotes, ...) are on the 433.92Mhz or nearby and use OOK modulation.
• Weather stations are often too in the 433.92Mhz OOK.
• For car keys, try 433.92 OOK650 and 868.35 Mhz in OOK or 2FSK.
• For TPMS try 433.92 in TPMS modulation (FSK optimized for these signals).

• Download the Flipper Zero dev kit and build it:

mkdir -p ~/flipperZero/official/
cd ~/flipperZero/official/
git clone --recursive  https://github.com/flipperdevices/flipperzero-firmware.git  ./
./fbt

• Copy this application folder in official/applications_user.
• Connect your Flipper via USB.
• Build and install with: ./fbt launch_app APPSRC=protoview.

Drop the protoview.fap file you can find in the binaries folder into the following Flipper Zero location:

/ext/apps/Tools

The ext part means that we are in the SD card. So if you don't want to use the Android (or other) application to upload the file, you can just take out the SD card, insert it in your computer, copy the fine into apps/Tools, and that's it.

The code is released under the BSD license.

This application is only provided as an educational tool. The author is not liable in case the application is used to reverse engineer protocols protected by IP or for any other illegal purpose.

A big thank you to the RTL433 author, Benjamin Larsson. I used the code and tools he developed in many ways:

• To capture TPMS data with rtl433 and save to a file, to later play the IQ files and speedup the development.
• As a sourve of documentation for protocols.
• As an awesome way to visualize and understand protocols, via these great web tools.
• To have tons of fun with RTLSDR in general, now and in the past.