This project aims to provides a GPS tracker based on an Arduino Pro mini as the central unit. Battery saving has been incorporated into every step of the design. A custom designed PCB is available to avoid using poorly power efficient boards.
- High autonomy (several weeks with a 1700 mAh battery)
- Automatic acquisition of GPS position
- Dynamically adjusted positions acquisition frequency based on speed and time of the day
- Local buffer of 4095 positions with a 512K EEPROM
- Automatic positions backup to any HTTP server using a GPRS powered network
This project has been build on a ATMega328p for its ease of use, low power consumption and wide support.
On top of that, the several ICs are needed :
- SIM808 : GPRS & GPS.
- DS3231 : Real Time Clock, used for time keeping and battery saving.
- 24LCxxx : EEPROM used to buffer raw data before sending.
This project can be build using standard Arduino boards and shields. For instance, you can start from an Arduino UNO with an Adafruit FONA shield. This should only be done for testing and debugging purpose though, as both are not designed with energy saving in mind, and will rapidly consumes all your battery.
For optimum energy management and maximum autonomy, a double-sided, surface mounted PCB has been created. Taking that path requires either using soldering paste or some fine soldering skills : the SIM808 IC can be quite hard to solder by hand.
The project has been build using Arduino 1.8.5. Ditching Arduino IDE in favor of an advanced IDE (VS Code, Visual Micro) is strongly recommended.
Install the required libraries through the Arduino's Library Manager UI, or run the following script :
#!/bin/sh
arduino --install-library "E24"
arduino --install-library "Low-Power"
arduino --install-library "ArduinoLog"
arduino --install-library "MD_DS3231"
arduino --install-library "SIM808"
Disable unneeded features of MD_DS3231 for the HEX to fit in the ATMega328p by setting ENABLE_12H
, ENABLE_DOW
and ENABLE_DYNAMIC_CENTURY
to 0
in MD_DS3231.h or running sed -E "s/^#define ENABLE_(12H|DOW|DYNAMIC_CENTURY) 1/#define ENABLE_\1 0/" -i MD_DS3231.h
To fully use the project, you will need to adjust some values based on your needs. Each file under src/config can be modified, but the one you'll be most likely interested in are :
- User.h : Dumb, versionned file containing an example of the values in Sensitive.h
- Sensitive.h : Sensitive data that should never be versionned (phone number, web server address)
- Alerts.h : Alerts levels
- BackupNetwork.h : Network backup and configuration
- Sleeps.h : Sleeps duration configuration
If you're using the custom board, set the board to Arduino Pro or Pro Mini
and the processor to ATMega328P (3.3V, 8Mhz)
before hitting Verify
or upload
.
Or simply run arduino --verify --board arduino:avr:pro:cpu=8MHzatmega328 src/GpsTracker.ino
Each loop
execution procedes (roughly) through the following phases :
- Acquisition of current GPS position
- Triggering alerts if needed
- Backuping positions if needed
- Deep sleep until the next
loop
Each one of these phases requires long waits (acquiring GPS signal, registering to the networks, etc). To preserve battery during those waits, all non-essentials devices are turned off, including the main ATMega328p. An interrupt coming from the RTC DS3231 chip (powered by the 3V coin battery) is used to woke up the main unit.
As positions backup can take quite some time, they're only backuped in two cases :
- When stopping for a long time
- When stopped and many positions are not yet backuped
This behaviour prevent the backup from distrupting the rate at which positions will be acquired, and avoid the device to look for the GPRS network while moving, which in some case can be difficult. As a downside, it is obvious that the positions are not backuped in realtime.
For reference, each position is sent in its own request HTTP POST request with a Content-Type
set to text/gpstracker
and a csv encoded body.
Field | Unit / Expression | Notes |
---|---|---|
freeRam | bytes | Read just before sending the position |
signalAttenuation | dBm | Read once before the backup session |
batteryLevel | % | |
batteryVoltage | mV | |
temperature | °c | Expressed as temp*100 as printf cannot deal with floats on Arduino |
fixStatus | SIM808_GPS_STATUS |
|
timeToFix | s |
The rest of the string is the raw string returned by the SIM808 AT+CGNSINF
command. The UTC date & time
field can be used as a key for a given tracker.
You can then do whatever you want with the position, like learning Python and building a Google Timeline like website using OpenStreetMap (one day to be published) to track all your comings and goings during your nine months travel accross New-Zealand 😎.
The downside of using an ATMega328p is a relativly limited space. That space gets filled almost completly by the project in its current state, leaving very few possibilities for further improvments and features. Even adding Serial debugging statements can sometimes be impossible.
An SD card was first intended to be used for logging, data saving and configuration purposes. Due to the limited space available on an ATMega328p (32k), it has been removed early in the development process. Parts of the intended code (using SdFat) is still in the repository, buts its use has been disabled.
Sadly, the SIM808 HTTP stack is unable to achieve reliable HTTPS. Currently, the backup is done with HTTP requests and there is no encryption, signature or authentication header (because without HTTPS, authentication header serves almost no purpose). Any information on how to achieve proper and reliable HTTPS support or at least request signature (with the limited resource of an ATMega328p of course) is welcomed.
One possibility to include additional features would be to split the current firmware into several ones. For instance :
- one "main" firmware
- one "configuration" firmware to read and write EEPROM configuration rather than hardcoded values into the header files
- one "debugging" firmware with additional logging and the ability to run specific parts of the main
loop
indepently
As I was using and needed the device while developing it, I couldn't take such a big risk that would potentionally break things and miss or lost some positions records.