3D Robotics

ArduPilot (Legacy) main page

 

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[This original ArduPilot board, now called the "Legacy ArduPilot" is no longer produced or officially supported by the DIY Drones dev team, and this page is maintained just for historic reasons. However, there are still many users of it out there and it still works fine. The user group for Legacy ArduPilot users, for both thermopile and IMU use, is here.]

 

ArduPilot is a full-featured autopilot based on the Arduino open-source hardware platform. It uses infrared (thermopile) sensors or an IMU for stabilization and GPS for navigation. It is the autopilot used to win the 2009 Sparkfun Autonomous Vehicle Competition.

The hardware is available from Sparkfun for $24.95. An expansion board ("Shield") kits that includes an airspeed sensor, a 3.3v power regulator for 3.3v GPS modules and other sensors and cables and connectors for easy attachment of the XY and Z sensors, is available from our own store for $57.20.

 

User f

ArduPilot features include:

  • Can be used for an autonomous aircraft, car or boat.
  • Built-in hardware failsafe that uses a separate circuit (multiplexer chip and ATTiny processor) to transfer control from the RC system to the autopilot and back again. Includes ability to reboot the main processor in mid-flight.
  • Multiple 3D waypoints (limited only by memory)
  • Altitude controlled with the elevator and throttle
  • Comes with a 6-pin GPS connector for the 4Hz uBlox5 or 1hz EM406 GPS modules.
  • Has six spare analog inputs (with ADC on each) and six spare digital input/outputs to add additional sensors
  • Supports addition of wireless modules for real-time telemetry
  • Based on a 16MhZ Atmega328 processor. Total onboard processing power aprox 24 MIPS.
  • Very small: 30mm x 47mm
  • Can be powered by either the RC receiver or a separate battery
  • Four RC-in channels (plus the autopilot on/off channel) can be processed by the autopilot. Autopilot can also control four channels out.
  • LEDs for power, failsafe (on/off), status and GPS (satellite lock).


Resources:

ArduPilot requires the free Arduino IDE to edit and upload the code to the ArduPilot board.



The code is currently optimized for the Mutiplex EasyStar three-channel powered glider and FMA sensors, but can be modified for other aircraft and sensors. It uses the rudder/ailerons and elevator to maintain level flight and navigate to GPS waypoints. It supports a desktop setup utility and ground station software. It also includes a "fly-by-wire" mode that simply stabilizes RC flight. The main code is ArduPilot2.x.zip in the download section of our Google Code repository, where x is the latest version.

What you need to make a fully-functional autopilot:


Open source extras:

  • If you want to build your own board from scratch, the necessary files and component lists are here.
  • [Note: you shouldn't need this, since this code is loaded on the ArduPilot board at the factory] Latest multiplexer code (for the board's second processor, an Attiny, which runs the failsafe system) is here.
    Instructions for loading this code are here.



Recommended UAV setup:

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Airframe option one: Hobbico SuperStar (49" wingspan, $95, shown above). This is an inexpensive, good flying high-wing trainer with ailerons. It can be hand launched in a park or take off from a runway, and replacement parts are readily available in case of a crash. If you want much better performance with this aircraft, you can upgrade it to a brushless motor, speed controller and a LiPo battery. [If you don't already have one, you'll also need a balancing charger and power supply.] Note: any stable aircraft with both ailerons (for stabilization) and rudder (for navigation) can work, so feel free to experiment with what you've got.

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Airframe option two (recommended for ArduPilot 2.x): EasyStar (shown above). Performance can be improved with the modifications described in this post.

You'll also need:

  • A six or seven channel RC transmitter and receiver, with at least one toggle switch (ideally three-position but two-position will work, too, although you will have to mix channels to have access to both autopilot modes in the air), such as the Futaba 7C.
  • Some servos (at least three for ArduPilot 1.0; at least two for ArduPilot 2.x) and at least three female-to-female servo cables to connect the RC receiver to ArduPilot.


Cool optional extras for your UAV:

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Comments

  • Developer
    Chris,

    Is the same way you are saying. =) The problem in futaba is that one switch will completely low the PWM, so will disable the autopilot not matter the position of the second switch (RTL/WP). ;-)
  • How I do the conections to radio receiver?!
  • 3D Robotics
    Yes, that's a better way to put it!
  • Developer
    Danilo,

    So basically what you going to do is, one switch will enable/disable the Autopilot and the other switch will select the mode (WP or RTL). I was able to that with your Futaba 6 EX long time ago.

    Regards.
  • 3D Robotics
    There is no EXA as far as I know, but if you mean the EX, it has two toggle switches (5 & 6). You need to program the TX to mix them (see the instruction manual), so that, for example, 6 down and 5 up is "5 middle" and 6 up and 5 up is "5 up".
  • Hi Chris!!!

    I have a Futaba 6 EXA control , how I do to use the 3 modes of ardupilot?!

    Regards.
  • @Peter, you're welcome

    @Doug
    has Jordi said there was a trouble in this version with latitude and longitude away from the ones Jordi tried (am i right??)

    this is correced in the last 2.3 beta code,
    there will be a stable release of this version later on...


    regards
    fefenin
  • Developer
    Hi Everybody,

    I have been going through the 2.2.3 code and have found a very confusing point in the navigation calculations. Before I PM'd Jordi I figured I'd throw the question out and maybe someone else can answer it.

    I found that in the calculation of the bearing to the next waypoint the answer returned was not what I expected. For a required course of north the calc_bearing function returns a value of 90. After looking at the code and researching the calculation I think this is correct and you can see why if you look at the definition of the atan2 function at wikipedia (http://en.wikipedia.org/wiki/Atan2). East is zero degrees, north is 90 degrees, west is 180 and south is 270, so degrees increase counterclockwise instead of clockwise as per normal mapping conventions.

    I do not see anything in the gps code that changes ground_course from the normal convention of north being zero degrees and degrees increasing clockwise. My question is - Does the normal GPS convention for ground course differ from standard mapping conventions and have east at zero degrees, etc?
  • got it so with walk mode on, the sensors are disabled. This should work perfect for cars and boats. Thanks Fefenin....

    -Peter
  • Peter,
    sorry for the late answer but it looks like we have quite a big difference between night and days!!

    i just set the walk mode on to disable the sensor,

    and most of all, i reduced the "head_P" gain to 0.6 (could have done a little more) avoid druck drive effect,

    nothing more it just works perfectly,

    my boat is in fact an air boat since i had no propeller and shaft for a boat,
    the steering is done by the stock water rudder :

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