# PID controller integral term causing extreme instability

I have a PID controller running on a robot that is designed to make the robot steer onto a compass heading. The PID correction is recalculated/applied at a rate of 20Hz.

Although the PID controller works well in PD mode (IE, with the integral term zero'd out) even the slightest amount of integral will force the output unstable in such a way that the steering actuator is pushed to either the left or right extreme.

Code:

``````        private static void DoPID(object o)
{
// Bring the LED up to signify frame start
BoardLED.Write(true);

// We just got the IMU heading, so we need to calculate the time from the last correction to the heading read
// *immediately*. The units don't so much matter, but we are converting Ticks to milliseconds
int deltaTime = (int)((LastCorrectionTime - DateTime.Now.Ticks) / 10000);

// Calculate error
// (let's just assume CurrentHeading really is the current GPS heading, OK?)

// We calculated the error, but we need to make sure the error is set so that we will be correcting in the
// direction of least work. For example, if we are flying a heading of 2 degrees and the error is a few degrees
// to the left of that ( IE, somewhere around 360) there will be a large error and the rover will try to turn all
// the way around to correct, when it could just turn to the right a few degrees.
// In short, we are adjusting for the fact that a compass heading wraps around in a circle instead of continuing
// infinity on a line
if (error < -180)
error = error + 360;
else if (error > 180)
error = error - 360;

// Add the error calculated in this frame to the running total

// We need to allow for a certain amount of tolerance.
// If the abs(error) is less than the set amount, we will
// set error to 0, effectively telling the equation that the
// rover is perfectly on course.
if (MyAbs(error) < AllowError)
error = 0;

LCD.Lines[2].Text = "Error:   " + error.ToString("F2");

// Calculate proportional term
float proportional = Kp * error;

// Calculate integral term
float integral = Ki * (SteadyError * deltaTime);

// Calculate derivative term
float derivative = Kd * ((error - PrevError) / deltaTime);

// Add them all together to get the correction delta
// Set the steering servo to the correction
Steering.Degree = 90 + proportional + integral + derivative;

// We have applied the correction, so we need to *immediately* record the
// absolute time for generation of deltaTime in the next frame
LastCorrectionTime = DateTime.Now.Ticks;

// At this point, the current PID frame is finished
// ------------------------------------------------------------
// Now, we need to setup for the next PID frame and close out

// The "current" error is now the previous error
// (Remember, we are done with the current frame, so in
// relative terms, the previous frame IS the "current" frame)
PrevError = error;

// Done
BoardLED.Write(false);
}
``````

Does anyone have any idea why this is happening or how to fix it?

-
120-character-long lines? 80 (79) please. – Nick T Oct 11 '10 at 14:22
What are you running this on? PID is a real-time application but C# on .Net Micro is not real-time capable, and most targets do not have an FPU, so the floating point implementation may be il advised too. – Clifford Oct 11 '10 at 19:40

It looks like you are applying your time base to the integral three times. Error is already the accumulated error since the last sample so yo don't need to multiply deltaTime times it. So I would change the code to the following.

` SteadyError += error ;`

SteadyError is the integral or sum of error.

So the integral should just be SteadyError * Ki

`float integral = Ki * SteadyError;`

Edit:

I have gone through your code again and there are several other items that I would fix in addition to the above fix.

1) You don't want delta time in milliseconds. In a normal sampled system the delta term would be one but you are putting in a value like 50 for the 20Hz rate this has the effect of increasing Ki by this factor and decreasing Kd by a factor of 50 as well. If you are worried about jitter then you need to convert delta time to a relative sample time. I would use the formula instead.

`float deltaTime = (LastCorrectionTime - DateTime.Now.Ticks) / 500000.0 `

the 500000.0 is the number of expected ticks per sample which for 20Hz is 50ms.

2) Keep the integral term within a range.

``````if ( SteadyError > MaxSteadyError ) SteadyError = MaxSteadyError;
``````

3) Change the following code so that when error is around -180 you do not get a step in error with a small change.

``````if (error < -270) error += 360;
if (error >  270) error -= 360;
``````

4) Verify Steering.Degree is receiving the correct resolution and sign.

5) Lastly yo can probably just drop deltaTime all together and calculate the differential term the following way.

``````float derivative = Kd * (error - PrevError);
``````

With all of that your code becomes.

``````private static void DoPID(object o)
{
// Bring the LED up to signify frame start
BoardLED.Write(true);

// Calculate error
// (let's just assume CurrentHeading really is the current GPS heading, OK?)

// We calculated the error, but we need to make sure the error is set
// so that we will be correcting in the
// direction of least work. For example, if we are flying a heading
// of 2 degrees and the error is a few degrees
// to the left of that ( IE, somewhere around 360) there will be a
// large error and the rover will try to turn all
// the way around to correct, when it could just turn to the right
// a few degrees.
// In short, we are adjusting for the fact that a compass heading wraps
// around in a circle instead of continuing infinity on a line
if (error < -270) error += 360;
if (error >  270) error -= 360;

// Add the error calculated in this frame to the running total

LCD.Lines[2].Text = "Error:   " + error.ToString("F2");

// Calculate proportional term
float proportional = Kp * error;

// Calculate integral term
float integral = Ki * SteadyError ;

// Calculate derivative term
float derivative = Kd * (error - PrevError) ;

// Add them all together to get the correction delta
// Set the steering servo to the correction
Steering.Degree = 90 + proportional + integral + derivative;

// At this point, the current PID frame is finished
// ------------------------------------------------------------
// Now, we need to setup for the next PID frame and close out

// The "current" error is now the previous error
// (Remember, we are done with the current frame, so in
// relative terms, the previous frame IS the "current" frame)
PrevError = error;

// Done
BoardLED.Write(false);
}
``````
-
While an error, that shouldn't cause saturation like he observes. – Nick T Oct 11 '10 at 14:24
I'm not sure why you are zero'ing out the error when it is within AllowError of the setpoint. This introduces a dead zone and will cause the course to wander back and forth when near zero (since there is no error signal to correct things). In particular, the integral term really wants this small error to keep things exactly on track. It adds up the small errors as the system begins to veer away from the setpoint and pulls it back in. The proportional term can't do this. – sbass Oct 12 '10 at 11:56
The `if (MyAbs(error) < AllowError) error = 0;` was in the original code, but yes, using that in conjunction with an integral term kind of defeats the purpose. – Nick T Oct 12 '10 at 13:05
I agree even though it was after the error was added to the integral and it came from the original code I removed it. – uɐƃoן xǝᴚ Oct 12 '10 at 14:36
As far as "dead zones" and PID controllers go, maybe the intent (though somewhat removed) was to have the vehicle point in whatever direction then shut off... That logic doesn't really seem to come through at all, but maybe it was like that then "cleaned up" by some other unwitting coder. – Nick T Oct 12 '10 at 15:28

I'm not sure why your code isn't working, but I'm almost positive you can't test it to see why, either. You might inject a timer service so you can mock it out and see what's happening:

``````public interace ITimer
{
long GetCurrentTicks()
}

public class Timer : ITimer
{
public long GetCurrentTicks()
{
return DateTime.Now.Ticks;
}
}

public class TestTimer : ITimer
{
private bool firstCall = true;
private long last;
private int counter = 1000000000;

public long GetCurrentTicks()
{
if (firstCall)
last = counter * 10000;
else
last += 3500;  //ticks; not sure what a good value is here

//set up for next call;
firstCall = !firstCall;
counter++;

return last;
}
}
``````

Then, replace both calls to `DateTime.Now.Ticks` with `GetCurrentTicks()`, and you can step through the code and see what the values look like.

-

Are you initializing `SteadyError` (bizarre name...why not "integrator")? If it contains some random value on start-up it might never return to near zero (`1e100 + 1 == 1e100`).

You might be suffering from integrator windup, which ordinarily should go away, but not if it takes longer to diminish than it does for your vehicle to complete a full rotation (and windup the integrator again). The trivial solution is to impose limits on the integrator, though there are more advanced solutions (PDF, 879 kB) if your system requires.

Does `Ki` have the correct sign?

I would strongly discourage the use of floats for PID parameters because of their arbitrary precision. Use integers (maybe fixed point). You will have to impose limit checking, but it will be much more sane than using floats.

-
use of floating point for PID calcs is the norm, not sure why you object. There are no arbitrary precision types here. – David Heffernan Aug 7 '11 at 7:25

The integral term is already accumulated over time, multiplying by deltaTime will make it accumulate at a rate of time-squared. In fact since SteadyError is already erroneously calculated by multiplying error by deltaTime, that is time-cubed!

In SteadyError, if you are trying to compensate for an aperiodic update, it would be better to fix the aperiodicity. However, the calculation is flawed in any case. You have calculated in units of error/time whereas you want just error units. The arithmentiaclly correct way to compensate for timing jitter if really necessary would be:

``````SteadyError += (error * 50.0f/deltaTime);
``````

if deltaTime remains in milliseconds and the nominal update rate is 20Hz. However deltaTime would be better calculated as a float or not converted to milliseconds at all if it is timing jitter you are trying to detect; you are needlessly discarding precision. Either way what you need is to modify the error value by the ratio of nominal time to actual time.

A good read is PID without a PhD

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Thanks for the link to PID without a PhD. Exactly what I was looking for. – Drew Noakes Mar 15 '11 at 2:58