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So far I have been testing PID values at random just starting with Pterm at .1 and increasing till my quadcopter starts to oscillate. Then i start messing with the ITerm and Dterm. But I really do not know exactly what i am doing? I got my quadcopter to stabilize but it takes a long time. Here is a video https://www.dropbox.com/s/nuflvl88r09pyao/DSC_0137.MOV. Its like 1-2 mins long. Please watch and tell me what you think. The PID algorithm I am using is found here https://github.com/grantmd/QuadCopter/blob/master/PID.cpp.

Any help is greatly appreciated

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This question would probably be better suited for one of the hundreds of RC-pilot forums, because those guys have the correct experience. They're most often really helpful, too, as long as you read the introduction and FAQ ;) –  arne Oct 23 '13 at 6:18
Thank you arne I knew I was taking a long shot but i really need the help –  EngineerBro Oct 23 '13 at 15:45
try posting on robotics.stackexchange.com instead –  dm76 Jan 15 '14 at 13:54
Check out the Ziegler-Nichols method, which is the technique most industrial and controls engineers use to tune a PID. To me, it sounds your P is too high. Another intuitive way of doing it is to set P to a value just before it oscillates. Then if you want to make the quadcopter respond faster when it's far from equilibrium but slowly when it's close to equilibrium, add some D. I would then leave I=0 unless there is a long-term drift. –  dm76 Jan 15 '14 at 13:59

2 Answers 2

The PID regulator consists of three terms. Easy explanation: The P-term is linear (difference of two values). The I-term is an integral (sum of the difference over time) and the D-term a derivation of the change of two values (velocity).

This is why one should start with the linear component (P-term). The other components are harder to adjust, because with I or D-term the robot starts to react completely different. E.g. the I-term (if not too high) has just a small effect if the difference is high, but existing just for a short time. However it is compensating even small differences if they persist for a long time. The other way round with the D-term.

I believe for most applications the PI-term is enough.

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Actually you will have multiple pids in your quad for both angle stabilization and rotation rate stabilization. Basically the purpose of pid is to translate the difference between your stick angle and measured quad angle into difference in thrust.

So first you need to calculate angles of your sticks in degrees, then angles of your copter (pitch, roll, yaw). Then you need to feed the difference between desired value (stick angle) and measured quadcopter angle (from accelerometer and gyro) into the pid. You first need to combine accelerometer and gyro using some kind of filter so that you get a very stable angle measurement. Complementary filter works as a good starting point (mAccPitch = 0.98 * (mAccPitch + gyro_deg_per_sec) + 0.02 * accel_calculated_pitch_in_degrees);

What you get from this pid is desired thrust. Your P value will control how much the error is multiplied by to get the difference in thrust. You can use this value to scale thrust and make it stronger for smaller errors. Your I value will control how much the copter is able to respond to small "steady errors" so that even if there is a very small error the copter will correct itself and stay level. Your D value determines how much damping is applied to the curve once it approaches desired value. When P and D work together, you copter will quickly thrust towards desired angle and stop exactly when it reaches it. This is a well tuned pid controller - no oscillations - just quick response and quick convergence.

The second pid is called "rate pid" and is used to further adjust the desired thrust based on current rotation rate of the quad measured by the gyro. It basically makes the copter faster pick up speed and faster come to a halt once it reaches it's correct orientation. So first pid gives it desired rotation speed - second step makes it quickly accelerate into this rate and follow this rate curve produced by the first step as closely as possible.

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