Receive and decode TST-507 TPMS signals.
The TST (Truck Systems Technologies) 507 Series TPMS is an aftermarket TPMS system for trucks & RV's. It uses 2 types of valve stem screw-on sensors, one a "cap" type and the other a "flow-thru" type. The sensors are read via a small dash mounted receiver.
(https://tsttruck.com/shop/kit-sales-us.html)
Specifications:
- Temp range = 40F-176F / -40C-80C
- Pres range = 0-198psi / 0-13.5bar
- Temp accuracy = +/- 3F
- Pres accuracy = +/- 3psi, 0.2bar
The system uses a radio frquency of 433.92Mhz. Each sensor has a 6 character ID, known to the user and needed to setup the receiver. Sensors transmit at varying intervals, at least every 5 minutes, or when measurements change, and do transmit when not moving.
This project uses RadioLib (https://github.com/jgromes/RadioLib)
Heltec WiFi LoRa 32 (V2) modules were used initially because of their large bang for the buck. Each module has ESP32 + SX127x + WiFi + BLE + LiPo management + on board display. the SX1278 is capable of LoRa, FSK, and OOK. We need OOK for this TPMS system. This is an Arduino based module.
The sensors transmit data periodically on 443.92Mhz using OOK modulation. The 8 byte data packet contains a checksum, sensor ID, and measurement data. The data packet is encoded with Manchester I (IEEE 802.3).
The data packet looks like this:
URH analog view:
URH demodulated view:
URH NRZ bits:
URH Manchester I hex:
From this we can see:
- 32 bits of preamble (1010...)
- checksum of 0xE5 (byte 0)
- sensor ID of 0x563ED9 (bytes 1-3)
- data of 0x2C4B0001
Decoding the data portion we get:
- pressure = 2nd nibble of byte 7 + byte 4 = 0x012C
- 0x012C / 0.4 = 750 kPa
- 750 / 6.895 = 108.8 psi
- temperature = byte 5 = 0x4B
- 0x4B - 50 = 25 deg C
- (25 * 1.8) + 32 = 77 deg F
- checksum = (sum of bytes 1-7) % 256
Flags:
- Byte 6
- 0x10 = Fast Leak
- 0x20 = Low Battery
This module has a bit synchronizer and a packet engine. I wanted to make the module do as much work as possible. The bit synchronizer looks for the preamble (successive 1010...). The default settings look for 2 bytes of preamble. The packet engine will then look for a sync byte. Since the TST-507 doesn't really have a sync byte, we can fake it out by using a sync byte of 0xA9. The raw data stream looks like this:
1010101010101010101010101010101001...
Since there is always a "01" after the last preamble nibble of "1010", we can call this our "sync byte", 0xA9. This means we have to put the "01" back into the data stream before processing because the packet engine strips whatever we call the sync byte from the stream. This is done by shifting the stream right by 2 bits and prepending "01".
TST-507 encodes the stream using Manchester I. However, the SX1278 only performs Manchester II. So, we use NRZ encoding and do the Manchester I in code. After that, we convert the measurement data to human usable form using the formulas above.
This is a very common FSK/OOK radio module. It can be attached to most microcontrollers. It has been tested using a Heltec WiFi ESP32 module as the controller, but the code should work with any ESP32 module. It also has a packet engine that can detect the preamble and sync word.
Improve performance of the CC1101 example. It seems to only see about a third of the packets the Heltec LoRa module does.