# Initial Solution

stalled_pwm_output = PWM / | ΔE |

PWM = Max PWM value

ΔE = last_error - new_error

The initial relationship successfully ramps up the PWM output based on the **lack of change** in the motor. See the graph below for the sample output.

This approach makes since for the situation where the non-aggressive PID stalled. However, it has the unfortunate (and obvious) issue that when the non-aggressive PID is capable of achieving the setpoint and attempts to slow, the stalled_pwm_output ramps up. This ramp up causes a large overshoot when traveling to a non-loaded position.

# Current Solution

## Theory

**stalled_pwm_output = (kE * PID_PWM) / | ΔE |**

kE = Scaling Constant

PID_PWM = Current PWM request from the non-agressive PID

ΔE = last_error - new_error

My current relationship still uses the 1/ΔE concept, but uses the non-aggressive PID PWM output to determine the stall_pwm_output. This allows the PID to throttle back the stall_pwm_output when it starts getting close to the target setpoint, yet allows 100% PWM output when stalled. The scaling constant kE is needed to ensure the PWM gets into the saturation point (above 10,000 in graphs below).

## Pseudo Code

Note that the result from the cal_stall_pwm is **added** to the PID PWM output in my current control logic.

```
int calc_stall_pwm(int pid_pwm, int new_error)
{
int ret = 0;
int dE = 0;
static int last_error = 0;
const int kE = 1;
// Allow the stall_control until the setpoint is achived
if( FALSE == motor_has_reached_target())
{
// Determine the error delta
dE = abs(last_error - new_error);
last_error = new_error;
// Protect from divide by zeros
dE = (dE == 0) ? 1 : dE;
// Determine the stall_pwm_output
ret = (kE * pid_pwm) / dE;
}
return ret;
}
```

## Output Data

*Stalled PWM Output*

Note that in the stalled PWM output graph the sudden PWM drop at ~3400 is a built in safety feature activated because the motor was unable to reach position within a given time.

*Non-Loaded PWM Output*