This is a fork/continuation of Bill Nesbitt's AutoQuad firmware for multicopter flight control.
- AutoQuad Project Site
- AutoQuad Documetation
- AutoQuad Forums
- AutoQuad Downloads Page
- AutoQuad Public FTP: ftp://ftp.autoquad.org/3/334693_22529/
USE AT YOUR OWN RISK!!! ABSOLUTELY NO RESPONSOBILITY IS ASSUMED BY THE AUTHORS OR PUBLISHERS OF THIS FIRMWARE. SEE LICENSE FILE FOR FULL TERMS.
master
branch is current stable version.next
branch is to integrate all proposed changes for holistic testing before being committed tomaster
.- Numbered branches (eg.
6.8
) are for older versions. - All other branches are "feature" branches used for testing individual changes before integration into
next
.
Pull requests should typically be submitted against the next
branch, unless it is an important fix for something which affects master
as well, or some other similarly good reason.
Pre-compiled firmware versions can be found at the AutoQuad public FTP site: ftp://ftp.autoquad.org/3/334693_22529/aq-firmware/forks/mpaperno/aq_flight_control/. The structure is organized by repository branch and then hardware version.
If you already have a Git client installed (or are willing to learn), the easiest method is to clone this repository to your local machine. If you do not want to deal with Git, you may also download zip archives of the necessary projects.
This repository contains Git submodules (for MAVLink headers) which must be initialized and updated. This is a simple process but you will get compile errors if you don't do it.
If you use a GUI Git client (TortoiseGit, SourceTree, etc) then look for options such as recursive during cloning and commands like "Update Submodules". This is usually an option when (or after) you do a clone/checkout command. Refer to the program's help if necessary. After checking out the code, make sure the lib/mavlink/include
folder exists.
It is also very easy to use the command line for clone, update, and checkout.
Here's a complete example starting with fresh copy of the repo, then checking out the next
branch, and the submodule init:
git clone https://github.com/mpaperno/aq_flight_control.git
cd aq_flight_control
git checkout next
git submodule update --init
If you already have a clone of the repo and you only want to do a pull of the latest changes, run something like this (example uses the master
branch and assumes "origin" for the remote name of this GitHub repo, which is a typical default):
git checkout master
git pull --recurse-submodules origin master
git submodule update --init
As you may have gathered by now, the point is to run git submodule update
after cloning or updating the code from this repository. The --init
option is only necessary the first time, but it doesn't hurt to include it.
Unfortunately GitHub makes this a bit more complicated than it should be. To download a snapshot of the current code on any branch:
- In the default GitHub Code tab view, find the Branch menu and select the branch you want to download.
- To the right of the Branch menu, click the Download ZIP link and save the file (it will be named something like "aq_flight_control_master.zip")
- While still in the Code view, click on the
lib
folder. - To the right of the
mavlink
folder there is an ID like "67a140b" or similar (7 hex digits). Click on that. It will take you to a different code repository (AutoQuad/mavlink_headers) and to a specific commit in a specific branch (this is important). - Now click the Download Zip link on this new page. Save the file (it will be named "mavlink_headers-" with a long string of numbers at the end).
- Unzip the "aq_flight_control_master.zip" file into wherever you want to keep the firmware source code (preferably a directory path w/out spaces).
- Unzip the "mavlink_headers-xxxxx.zip" file into the
lib/mavlink
folder of the firmware source code tree. So the final result should be alib/mavlink/include
folder with 2 subfolders and some .h files inside.
Download GNU ARM Embedded Toolchain and follow its readme.txt
to install the toolchain on your system.
Note: You will need Java to run Eclipse.
-
Download and install Eclipse CDT.
-
Install the GNU MCU Eclipse plug-ins.
-
Open Eclipse and click
File
->New
->Makefile Project with Existing Code
. In the popup window, select the project folder inExisting Code Location
. And selectARM Cross GCC
in theToolchain for Indexer Settings
list. The clickFinish
. -
Right click the project and click
Properties
. SelectC/C++ Build
on the left, then de-selectUse default build command
and setBuild command
tomake BUILD_TYPE=Debug MAV_VER=2 PROJ_ROOT=${CWD}
. -
(Optional) Click
C/C++ General
->Preprocessor Include Paths
in the Properties window. Switch toProviders
tab. In the list of providers, clickCDT Cross GCC Built-in Compiler Settings
. UnderCommand to get compiler specs
, replace the text inCommand to get compiler specs
witharm-none-eabi-gcc ${FLAGS} -E -P -v -dD "${INPUTS}"
. Then clickCDT GCC Build Output Parser
and replace the text inCompiler command pattern
witharm-none-eabi-(g?cc)|([gc]\+\+)|(clang)
. -
Right click the project and click
Build Project
to build.
- By default a release binary is built. Run
make BUILD_TYPE=Debug
to build debug firmware. - To change the AQ hardware version, pass
BOARD_VER
andBOARD_REV
arguments tomake
. Eg.make BOARD_VER=8 BOARD_REV=6
to build for M4 rev 6 (M4 v2). Read theMakefile
for full list of versions and revisions available.
- Read the Makefile comments for more options, full list of build targets, and other information.
- Use
-jX
for faster (parallel) compilation, where "X" equals the number of CPUs/cores/threads on your computer. If you havemake
version 4+, also add the-O
option for better progress output during compilation. Eg.make -j8 -O
for a quad-core CPU. - The
Makefile.user
file is the right place to specify build options you typically want, then you can avoid entering them on the command-line each time, or editing the mainMakefile
. You can also set any variable in the environment andmake
will use it instead of the default in theMakefile
. Command-line options always override all other variables. - All directory paths are relative to the location of the
Makefile
. You can use relative or absolute paths for most options. - You can easily set up a local environment and specify build options using a batch or shell file. This is especially useful for Windows so you can specify a local
PATH
variable w/out having to change the system-widePATH
(and need to restart Windows). The order of thePATH
entries also affects how Windows searches for commands (making it easy to, for example, override Windows'mkidir
with GNU toolsmkdir
). Here is a basic example batch file to initiate a build (this also shows using environment variables to set all the build options):
@echo off
set PATH=c:\devel\gcc-arm-none-eabi\bin;c:\devel\GnuWin\bin;C:\Windows\system32;C:\WINDOWS;C:\WINDOWS\System32\Wbem
set BUILD_TYPE=Release-M4.r6
set BOARD_VER=8
set BOARD_REV=6
make bin
You will need some GNU (Unix/Linux) tools installed and in your PATH
. Make sure to install them on a path with no spaces (eg. c:/GnuWin/
) There are several good sources for these, including GnuWin32 CoreUtils and ezwinports. The following utilities are required:
sh, make, gawk, mv, echo, rm, mkdir, expr, zip
.
Most distributions include an older version of 'make' (3.x). Version 4.x offers some improvements for parallel builds. Windows versions are available from ezwinports (get a "w/out guile" version) or Equation Solution (64 or 32 bit version, depending on your Windows type).
Note that all directory paths used by make
should have forward slashes (/
) instead of typical Windows backslashes (\
).
- Download and install OpenOCD from this repo.
- Build the firmware in Eclipse.
- Click
Run
->Debug Configurations
and double clickGDB OpenOCD Debugging
. The a new target will be created underGDB OpenOCD Debugging
, click the new target. - Check the elf binary is correct in the
Main
tab. - Switch to
Debugger
tab, check theStart OpenOCD locally
option and select the executable path for OpenOCD. Type-f openocd.cfg
in theConfig options
text field. Note that theopenocd.cfg
in this repo is for ST-Link v2 only. If you are using other debug probes, theopenocd.cfg
should be revised. - Click
Apply
button to save the configuration. The clickDebug
button to start a debug session.