195 lines
7.0 KiB
C
195 lines
7.0 KiB
C
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/**********************************************************************************************
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* Arduino PID Library - Version 1.2.1
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* by Brett Beauregard <br3ttb@gmail.com> brettbeauregard.com
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* Modified by Fabien Poussin <fabien.poussin@gmail.com> for ChibiOS.
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*
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* This Library is licensed under the MIT License
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**********************************************************************************************/
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#include "pid.h"
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#include "osal.h"
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#define TIME_MS ((osalOsGetSystemTimeX() * 1000) / OSAL_ST_FREQUENCY )
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/*Constructor (...)*********************************************************
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* The parameters specified here are those for for which we can't set up
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* reliable defaults, so we need to have the user set them.
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***************************************************************************/
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void pid_create(pidc_t* p, float* Input, float* Output, float* Setpoint,
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float Kp, float Ki, float Kd, int POn, int Direction)
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{
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p->output = Output;
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p->input = Input;
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p->setPoint = Setpoint;
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p->inAuto = false;
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pid_setOutputLimits(p, 0, 4095); // default output limit corresponds to
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// the 12 bit dac limit
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p->sampleTime = 100; // default Controller Sample Time is 100ms
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pid_setDirection(p, Direction);
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pid_setTunings(p, Kp, Ki, Kd, POn);
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pid_initialize(p);
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p->lastTime = TIME_MS - p->sampleTime;
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}
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/* Compute() **********************************************************************
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* This, as they say, is where the magic happens. this function should be called
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* every time "void loop()" executes. the function will decide for itself whether a new
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* pid Output needs to be computed. returns true when the output is computed,
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* false when nothing has been done.
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**********************************************************************************/
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bool pid_compute(pidc_t* p)
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{
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if(!p->inAuto) return false;
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unsigned long now = TIME_MS;
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unsigned long timeChange = (now - p->lastTime);
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if(timeChange >= p->sampleTime)
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{
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/* Compute all the working error variables */
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float input = *p->input;
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float error = *p->setPoint - input;
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float dInput = (input - p->lastInput);
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p->outputSum += (p->ki * error);
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/* Add Proportional on Measurement, if PID_ON_M is specified */
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if(!p->pOnE) p->outputSum -= p->kp * dInput;
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if(p->outputSum > p->outMax) p->outputSum = p->outMax;
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else if(p->outputSum < p->outMin) p->outputSum = p->outMin;
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/* Add Proportional on Error, if P_ON_E is specified */
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float output;
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if(p->pOnE) output = p->kp * error;
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else output = 0;
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/* Compute Rest of PID Output */
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output += p->outputSum - p->kd * dInput;
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if(output > p->outMax) output = p->outMax;
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else if(output < p->outMin) output = p->outMin;
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*p->output = output;
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/* Remember some variables for next time */
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p->lastInput = input;
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p->lastTime = now;
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return true;
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}
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else return false;
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}
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/* SetTunings(...)*************************************************************
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* This function allows the controller's dynamic performance to be adjusted.
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* it's called automatically from the constructor, but tunings can also
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* be adjusted on the fly during normal operation
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******************************************************************************/
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void pid_setTunings(pidc_t* p, float Kp, float Ki, float Kd, int POn)
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{
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if (Kp < 0 || Ki < 0 || Kd < 0) return;
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p->pOn = POn;
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p->pOnE = POn == PID_ON_E;
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p->dispKp = Kp;
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p->dispKi = Ki;
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p->dispKd = Kd;
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float SampleTimeInSec = ((float)p->sampleTime) / 1000.0;
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p->kp = Kp;
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p->ki = Ki * SampleTimeInSec;
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p->kd = Kd / SampleTimeInSec;
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if(p->direction == PID_REVERSE)
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{
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p->kp = (0 - p->kp);
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p->ki = (0 - p->ki);
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p->kd = (0 - p->kd);
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}
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}
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/* SetSampleTime(...) *********************************************************
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* sets the period, in Milliseconds, at which the calculation is performed
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******************************************************************************/
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void pid_setSampleTime(pidc_t* p, int NewSampleTime)
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{
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if (NewSampleTime > 0)
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{
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float ratio = (float)NewSampleTime / (float)p->sampleTime;
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p->ki *= ratio;
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p->kd /= ratio;
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p->sampleTime = (unsigned long)NewSampleTime;
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}
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}
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/* SetOutputLimits(...)****************************************************
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* This function will be used far more often than SetInputLimits. while
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* the input to the controller will generally be in the 0-1023 range (which is
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* the default already,) the output will be a little different. maybe they'll
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* be doing a time window and will need 0-8000 or something. or maybe they'll
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* want to clamp it from 0-125. who knows. at any rate, that can all be done
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* here.
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**************************************************************************/
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void pid_setOutputLimits(pidc_t* p, float Min, float Max)
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{
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if(Min >= Max) return;
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p->outMin = Min;
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p->outMax = Max;
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if(p->inAuto)
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{
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if(*p->output > p->outMax) *p->output = p->outMax;
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else if(*p->output < p->outMin) *p->output = p->outMin;
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if(p->outputSum > p->outMax) p->outputSum = p->outMax;
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else if(p->outputSum < p->outMin) p->outputSum = p->outMin;
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}
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}
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/* SetMode(...)****************************************************************
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* Allows the controller Mode to be set to manual (0) or Automatic (non-zero)
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* when the transition from manual to auto occurs, the controller is
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* automatically initialized
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******************************************************************************/
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void pid_setMode(pidc_t* p, int Mode)
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{
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bool newAuto = (Mode == PID_AUTOMATIC);
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if(newAuto && !p->inAuto)
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{ /* we just went from manual to auto */
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pid_initialize(p);
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}
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p->inAuto = newAuto;
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}
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/* Initialize()****************************************************************
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* does all the things that need to happen to ensure a bumpless transfer
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* from manual to automatic mode.
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******************************************************************************/
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void pid_initialize(pidc_t* p)
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{
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p->outputSum = *p->output;
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p->lastInput = *p->input;
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if(p->outputSum > p->outMax) p->outputSum = p->outMax;
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else if(p->outputSum < p->outMin) p->outputSum = p->outMin;
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}
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/* SetControllerDirection(...)*************************************************
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* The PID will either be connected to a DIRECT acting process (+Output leads
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* to +Input) or a REVERSE acting process(+Output leads to -Input.) we need to
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* know which one, because otherwise we may increase the output when we should
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* be decreasing. This is called from the constructor.
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******************************************************************************/
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void pid_setDirection(pidc_t* p, int Direction)
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{
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if(p->inAuto && Direction != p->direction)
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{
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p->kp = (0 - p->kp);
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p->ki = (0 - p->ki);
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p->kd = (0 - p->kd);
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}
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p->direction = Direction;
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}
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