Tasmota/lib/lib_div/ProcessControl/PID.cpp

/**
 * Copyright 2018 Colin Law
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 *
 * See Timeprop.h for Usage
 *
 **/


#include "PID.h"

PID::PID() {
  m_initialised = 0;
  m_last_sample_time = 0;
  m_last_pv_update_time = 0;
  m_last_power = 0.0;
}

void PID::initialise( double setpoint, double prop_band, double t_integral, double t_derivative,
  double integral_default, int max_interval, double smooth_factor, unsigned char mode_auto, double manual_op ) {

  m_setpoint = setpoint;
  m_prop_band = prop_band;
  m_t_integral = t_integral;
  m_t_derivative = t_derivative;
  m_integral_default = integral_default;
  m_max_interval = max_interval;
  m_smooth_factor= smooth_factor;
  m_mode_auto= mode_auto;
  m_manual_op = manual_op;

  m_initialised = 1;

}


/* called regularly to calculate and return new power value */
double PID::tick( unsigned long nowSecs ) {
  double power;
  double factor;
  if (m_initialised && m_last_pv_update_time) {
    // we have been initialised and have been given a pv value
    // check whether too long has elapsed since pv was last updated
    if (m_max_interval > 0  &&  nowSecs - m_last_pv_update_time > m_max_interval) {
      // yes, too long has elapsed since last PV update so go to fallback power
      power = m_manual_op;
    } else {
      // is this the first time through here?
      if (m_last_sample_time) {
        // not first time
        unsigned long delta_t = nowSecs - m_last_sample_time;  // seconds
        if (delta_t <= 0 || delta_t > m_max_interval) {
          // too long since last sample so leave integral as is and set deriv to zero
          m_derivative = 0;
        } else {
          if (m_smooth_factor > 0) {
            // A derivative smoothing factor has been supplied
            // smoothing time constant is td/factor but with a min of delta_t to stop overflows
            int ts = m_t_derivative/m_smooth_factor > delta_t ? m_t_derivative/m_smooth_factor : delta_t;
            factor = 1.0/(ts/delta_t);
          } else {
            // no integral smoothing so factor is 1, this makes smoothed_value the previous pv
            factor = 1.0;
          }
          double delta_v = (m_pv - m_smoothed_value) * factor;
          m_smoothed_value = m_smoothed_value + delta_v;
          m_derivative = m_t_derivative * delta_v/delta_t;
          // lock the integral if abs(previous integral + error) > prop_band/2
          // as this means that P + I is outside the linear region so power will be 0 or full
          // also lock if control is disabled
          double error = m_pv - m_setpoint;
          double pbo2 = m_prop_band/2.0;
          double epi = error + m_integral;
          if (epi < 0.0) epi = -epi;    // abs value of error + m_integral
          if (epi < pbo2  && m_mode_auto) {
            if (m_t_integral <= 0) {
              // t_integral is zero (or silly), set integral to one end or the other
              // or half way if exactly on sp
              if (error > 0.0) {
                m_integral = pbo2;
              } else if (error < 0) {
                m_integral = -pbo2;
              } else {
                m_integral = 0.0;
              }
            } else {
              m_integral = m_integral + error * delta_t/m_t_integral;
            }
          }
          // clamp to +- 0.5 prop band widths so that it cannot push the zero power point outside the pb
          // do this here rather than when integral is updated to allow for the fact that the pb may change dynamically
          if ( m_integral < -pbo2 ) {
            m_integral = -pbo2;
          } else if (m_integral > pbo2) {
            m_integral = pbo2;
          }
        }

      } else {
        // first time through, initialise context data
        m_smoothed_value = m_pv;
        // setup the integral term so that the power out would be integral_default if pv=setpoint
        m_integral = (0.5 - m_integral_default)*m_prop_band;
        m_derivative = 0.0;
      }

      double proportional = m_pv - m_setpoint;
      if (m_prop_band == 0) {
        // prop band is zero so drop back to on/off control with zero hysteresis
        if (proportional > 0.0) {
          power = 0.0;
        } else if (proportional < 0.0) {
          power = 1.0;
        } else {
          // exactly on sp so leave power as it was last time round
          power = m_last_power;
        }
      }
      else {
        power = -1.0/m_prop_band * (proportional + m_integral + m_derivative) + 0.5;
      }
      // set power to disabled value if the loop is not enabled
      if (!m_mode_auto) {
        power = m_manual_op;
      }
      m_last_sample_time = nowSecs;
    }
  } else {
    // not yet initialised or no pv value yet so set power to disabled value
    power = m_manual_op;
  }
  if (power < 0.0) {
    power = 0.0;
  } else if (power > 1.0) {
    power = 1.0;
  }
  m_last_power = power;
  return power;
}

// call to pass in new process value
void PID::setPv( double pv, unsigned long nowSecs ){
  m_pv = pv;
  m_last_pv_update_time = nowSecs;
}

// methods to modify configuration data
void PID::setSp( double setpoint ) {
  m_setpoint = setpoint;
}

void PID::setPb( double prop_band ) {
  m_prop_band = prop_band;
}

void PID::setTi( double t_integral ) {
  m_t_integral = t_integral;
}

void PID::setTd( double t_derivative ) {
  m_t_derivative = t_derivative;
}

void PID::setInitialInt( double integral_default ) {
  m_integral_default = integral_default;
}

void PID::setDSmooth( double smooth_factor ) {
  m_smooth_factor = smooth_factor;
}

void PID::setAuto( unsigned char mode_auto ) {
  m_mode_auto = mode_auto;
}

void PID::setManualPower( double manual_op ) {
  m_manual_op = manual_op;
}

void PID::setMaxInterval( int max_interval ) {
  m_max_interval = max_interval;
}


double PID::getPv() {
  return(m_pv);
}

double PID::getSp() {
  return(m_setpoint);
}

double PID::getPb() {
  return(m_prop_band);
}

double PID::getTi() {
  return(m_t_integral);
}

double PID::getTd() {
  return(m_t_derivative);
}

double PID::getInitialInt() {
  return(m_integral_default);
}

double PID::getDSmooth() {
  return(m_smooth_factor);
}

unsigned char PID::getAuto() {
  return(m_mode_auto);
}

double PID::getManualPower() {
  return(m_manual_op);
}

int PID::getMaxInterval() {
  return(m_max_interval);
}
as taken from https://github.com/colinl/Sonoff-Tasmota/tree/pid_branch 2021-01-04 09:29:12 +00:00			`/**`
			`* Copyright 2018 Colin Law`
			`*`
			`* Licensed under the Apache License, Version 2.0 (the "License");`
			`* you may not use this file except in compliance with the License.`
			`* You may obtain a copy of the License at`
			`*`
			`* http://www.apache.org/licenses/LICENSE-2.0`
			`*`
			`* Unless required by applicable law or agreed to in writing, software`
			`* distributed under the License is distributed on an "AS IS" BASIS,`
			`* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.`
			`* See the License for the specific language governing permissions and`
			`* limitations under the License.`
			`*`
			`* See Timeprop.h for Usage`
			`*`
			`**/`


			`#include "PID.h"`

			`PID::PID() {`
			`m_initialised = 0;`
			`m_last_sample_time = 0;`
			`m_last_pv_update_time = 0;`
			`m_last_power = 0.0;`
			`}`

			`void PID::initialise( double setpoint, double prop_band, double t_integral, double t_derivative,`
			`double integral_default, int max_interval, double smooth_factor, unsigned char mode_auto, double manual_op ) {`

			`m_setpoint = setpoint;`
			`m_prop_band = prop_band;`
			`m_t_integral = t_integral;`
			`m_t_derivative = t_derivative;`
			`m_integral_default = integral_default;`
			`m_max_interval = max_interval;`
			`m_smooth_factor= smooth_factor;`
			`m_mode_auto= mode_auto;`
			`m_manual_op = manual_op;`

			`m_initialised = 1;`

			`}`


			`/* called regularly to calculate and return new power value */`
			`double PID::tick( unsigned long nowSecs ) {`
			`double power;`
			`double factor;`
			`if (m_initialised && m_last_pv_update_time) {`
			`// we have been initialised and have been given a pv value`
			`// check whether too long has elapsed since pv was last updated`
			`if (m_max_interval > 0 && nowSecs - m_last_pv_update_time > m_max_interval) {`
			`// yes, too long has elapsed since last PV update so go to fallback power`
			`power = m_manual_op;`
			`} else {`
			`// is this the first time through here?`
			`if (m_last_sample_time) {`
			`// not first time`
			`unsigned long delta_t = nowSecs - m_last_sample_time; // seconds`
			`if (delta_t <= 0 \|\| delta_t > m_max_interval) {`
			`// too long since last sample so leave integral as is and set deriv to zero`
			`m_derivative = 0;`
			`} else {`
			`if (m_smooth_factor > 0) {`
			`// A derivative smoothing factor has been supplied`
			`// smoothing time constant is td/factor but with a min of delta_t to stop overflows`
			`int ts = m_t_derivative/m_smooth_factor > delta_t ? m_t_derivative/m_smooth_factor : delta_t;`
			`factor = 1.0/(ts/delta_t);`
			`} else {`
			`// no integral smoothing so factor is 1, this makes smoothed_value the previous pv`
			`factor = 1.0;`
			`}`
			`double delta_v = (m_pv - m_smoothed_value) * factor;`
			`m_smoothed_value = m_smoothed_value + delta_v;`
			`m_derivative = m_t_derivative * delta_v/delta_t;`
			`// lock the integral if abs(previous integral + error) > prop_band/2`
			`// as this means that P + I is outside the linear region so power will be 0 or full`
			`// also lock if control is disabled`
			`double error = m_pv - m_setpoint;`
			`double pbo2 = m_prop_band/2.0;`
			`double epi = error + m_integral;`
			`if (epi < 0.0) epi = -epi; // abs value of error + m_integral`
			`if (epi < pbo2 && m_mode_auto) {`
			`if (m_t_integral <= 0) {`
			`// t_integral is zero (or silly), set integral to one end or the other`
			`// or half way if exactly on sp`
			`if (error > 0.0) {`
			`m_integral = pbo2;`
			`} else if (error < 0) {`
			`m_integral = -pbo2;`
			`} else {`
			`m_integral = 0.0;`
			`}`
			`} else {`
			`m_integral = m_integral + error * delta_t/m_t_integral;`
			`}`
			`}`
			`// clamp to +- 0.5 prop band widths so that it cannot push the zero power point outside the pb`
			`// do this here rather than when integral is updated to allow for the fact that the pb may change dynamically`
			`if ( m_integral < -pbo2 ) {`
			`m_integral = -pbo2;`
			`} else if (m_integral > pbo2) {`
			`m_integral = pbo2;`
			`}`
			`}`

			`} else {`
			`// first time through, initialise context data`
			`m_smoothed_value = m_pv;`
			`// setup the integral term so that the power out would be integral_default if pv=setpoint`
			`m_integral = (0.5 - m_integral_default)*m_prop_band;`
			`m_derivative = 0.0;`
			`}`

			`double proportional = m_pv - m_setpoint;`
			`if (m_prop_band == 0) {`
			`// prop band is zero so drop back to on/off control with zero hysteresis`
			`if (proportional > 0.0) {`
			`power = 0.0;`
			`} else if (proportional < 0.0) {`
			`power = 1.0;`
			`} else {`
			`// exactly on sp so leave power as it was last time round`
			`power = m_last_power;`
			`}`
			`}`
			`else {`
			`power = -1.0/m_prop_band * (proportional + m_integral + m_derivative) + 0.5;`
			`}`
			`// set power to disabled value if the loop is not enabled`
			`if (!m_mode_auto) {`
			`power = m_manual_op;`
			`}`
			`m_last_sample_time = nowSecs;`
			`}`
			`} else {`
			`// not yet initialised or no pv value yet so set power to disabled value`
			`power = m_manual_op;`
			`}`
			`if (power < 0.0) {`
			`power = 0.0;`
			`} else if (power > 1.0) {`
			`power = 1.0;`
			`}`
			`m_last_power = power;`
			`return power;`
			`}`

			`// call to pass in new process value`
			`void PID::setPv( double pv, unsigned long nowSecs ){`
			`m_pv = pv;`
			`m_last_pv_update_time = nowSecs;`
			`}`

			`// methods to modify configuration data`
			`void PID::setSp( double setpoint ) {`
			`m_setpoint = setpoint;`
			`}`

			`void PID::setPb( double prop_band ) {`
			`m_prop_band = prop_band;`
			`}`

			`void PID::setTi( double t_integral ) {`
			`m_t_integral = t_integral;`
			`}`

			`void PID::setTd( double t_derivative ) {`
			`m_t_derivative = t_derivative;`
			`}`

			`void PID::setInitialInt( double integral_default ) {`
			`m_integral_default = integral_default;`
			`}`

			`void PID::setDSmooth( double smooth_factor ) {`
			`m_smooth_factor = smooth_factor;`
			`}`

			`void PID::setAuto( unsigned char mode_auto ) {`
			`m_mode_auto = mode_auto;`
			`}`

			`void PID::setManualPower( double manual_op ) {`
			`m_manual_op = manual_op;`
			`}`

			`void PID::setMaxInterval( int max_interval ) {`
			`m_max_interval = max_interval;`
			`}`
add get functions 2021-01-06 20:19:39 +00:00

			`double PID::getPv() {`
			`return(m_pv);`
			`}`

			`double PID::getSp() {`
			`return(m_setpoint);`
			`}`

			`double PID::getPb() {`
			`return(m_prop_band);`
			`}`

			`double PID::getTi() {`
			`return(m_t_integral);`
			`}`

			`double PID::getTd() {`
			`return(m_t_derivative);`
			`}`

			`double PID::getInitialInt() {`
			`return(m_integral_default);`
			`}`

			`double PID::getDSmooth() {`
			`return(m_smooth_factor);`
			`}`

			`unsigned char PID::getAuto() {`
			`return(m_mode_auto);`
			`}`

			`double PID::getManualPower() {`
			`return(m_manual_op);`
			`}`

			`int PID::getMaxInterval() {`
			`return(m_max_interval);`
			`}`