adpated paramters and PID

vscode/Unendlichkeitsmaschine/include/main.hpp

@@ -2,7 +2,7 @@
 #define MAIN_HPP
 
 //#define MACHINE_RESTART
-//#define DUMMY_DATA
+#define DUMMY_DATA
 
 #define EEPROM_NAME_TICK "hall_tick"
 #define EEPROM_NAME_TIMESTAMP "timestamp"
@@ -103,10 +103,10 @@ const uint8_t HALL8_PIN = 14;
 
 const uint8_t TIME_PER_ROUND_VALS = 10;
 
-const uint16_t MIN_SPEED = 800;
+const uint16_t MIN_SPEED = 500;
 const uint16_t MAX_SPEED = 5000;
-const uint8_t MAX_ESC_SPEED = 100;
-const uint8_t MIN_ESC_SPEED = 10;
+const uint8_t MAX_ESC_SPEED = 180;
+const uint8_t MIN_ESC_SPEED = 0;
 const uint16_t MAX_POTI_VALUE = 4095;
 const uint16_t JITTER_POTI_PERCENT = 10;
 

vscode/Unendlichkeitsmaschine/src/main.cpp

@@ -21,9 +21,10 @@ volatile double goal_speed = 0;
 volatile double current_speed = 0;
 volatile double err = 0;
 volatile double output = 0.0;
-double kp = 0.005;
-double ki = 0.0008;
-double kd = 0.0001;
+double kp = 0.03;
+double ki = 0.01;
+double kd = 0.002;
+
 
 //bei 2000 als speed:  values: kp=0.020000 ki=0.005000 kd=0.000100
 
@@ -44,7 +45,7 @@ void data_init();
 void speed_get();
 void speed_set();
 void PID();
-double time_per_round_calc();
+unsigned long  time_per_round_calc();
 void count_secs(time_t* run_time);
 
 void get_serial_cmd();
@@ -63,16 +64,6 @@ void setup()
 
   display.begin();
 
-    /*
-    display->setTextAlignment(TEXT_ALIGN_CENTER);
-    display->setFont(ArialMT_Plain_16);    
-    display->drawString(64, 2, "Init controller");
-    display->setFont(ArialMT_Plain_10);
-    display->drawString(64, 40, "You may hear some beeps.");
-    display->drawString(64, 52, "That's OK! ;-)");
-    display->display();  
-    */
-
   capportal.begin();
   html_content = "<!DOCTYPE html><html><head><meta http-equiv=\"refresh\" content=\"0; url='/_ac'\" /></head><body></body></html>";  
 
@@ -101,13 +92,7 @@ void setup()
   delay(1000);  
   data_init();
 
-  // Initialise  timer
-  /*
-  timer = timerBegin(0, 80, true); // Timer 0, Prescaler 80, zähle im Up-Modus
-  timerAttachInterrupt(timer, &ISR_onTimer, true); // Setze den Interrupt-Handler und aktiviere den Interrupt auf steigende Flanke
-  timerAlarmWrite(timer, 1000000/8, true); // Setze den Alarm auf 1/4 Sekunde und aktiviere ihn
-  timerAlarmEnable(timer); // Aktiviere den Alarm
-  */
+  #ifndef DUMMY_DATA
 
   pinMode(39, INPUT_PULLDOWN);
   pinMode(HALL1_PIN, INPUT);
@@ -129,6 +114,8 @@ void setup()
   attachInterrupt(digitalPinToInterrupt(HALL7_PIN), ISR_HALL7, FALLING);
   attachInterrupt(digitalPinToInterrupt(HALL8_PIN), ISR_HALL8, FALLING);  
 
+  #endif
+
   Serial.println(" Auf gehts ... ");
  
 }
@@ -167,74 +154,60 @@ void count_secs(time_t* run_time)
   }
 }
 
-double speed_map(double x, double in_min, double in_max, double out_min, double out_max) {
-    const double dividend = out_max - out_min;
-    const double divisor = in_max - in_min;
-    const double delta = x - in_min;
-    if(divisor == 0){
-        log_e("Invalid map input range, min == max");
-        return -1; //AVR returns -1, SAM returns 0
-    }
-    return (delta * dividend + (divisor / 2)) / divisor + out_min;
-}
-
 void PID()
 {
   current_speed = HallData[0].value;
 
-  //current_speed = map(HallData[0].value, MIN_SPEED, MAX_SPEED, MIN_ESC_SPEED, MAX_ESC_SPEED); 
+  if(ki==0)
+  {
+    integ = 0;
+  }
+  if(kd==0)
+  {
+    derivative = 0;
+  }
 
-  double int_err = goal_speed - current_speed;
-  double int_integ = ki>0?integ + int_err:0;
-  double int_derivative = kd>0?(int_err - last_error):0;
-  double int_output = kp * int_err + ki * int_integ + kd * int_derivative;
-  if( int_output <= MIN_ESC_SPEED)
-  {
-    output = MIN_ESC_SPEED;
-  }
-  else if( int_output > MAX_ESC_SPEED)
-  {
-    output = MAX_ESC_SPEED; 
-  }
-  else if((int_output >= MIN_ESC_SPEED) && (int_output <= MAX_ESC_SPEED))
-  {
-    err = int_err;
-    integ = int_integ;
-    derivative = int_derivative;
-    output = int_output;
-  }
+  err = goal_speed - current_speed;
+  integ = ki>0?integ + err:0;
+  derivative = kd>0?(err - last_error):0;
+  output = kp * err + ki * integ + kd * derivative;
   esc_output = constrain(output, MIN_ESC_SPEED, MAX_ESC_SPEED);
-  //Serial.printf("PID ... (goal: %f, current: %06.3f, err: %06.3f, integ: %06.3f, derive: %06.3f) output=%06.3f \n", goal_speed, current_speed, err, integ, derivative, output);
-  //Aktualisierung der letzten Fehler- und Zeitwerte
   last_error = err;
 }
 
-double time_per_round_calc()
+unsigned long time_per_round_calc()
 {
-  double mid_time = 0;
-  double min_time = -1;
-  double max_time = 0;
+  unsigned long mid_time = 0;
+  unsigned long min_time = 0;
+  unsigned long max_time = 0;
   uint8_t nr_times = 0;
   for(uint8_t i = 0; i < TIME_PER_ROUND_VALS; i++)
   {
-    if(time_per_round_ms[i] >= 0)
+    unsigned long time_round_ms = time_per_round_ms[i]/HALL_NR_TURN;
+    if(time_round_ms > 0)
     {
-      if(time_per_round_ms[i] < min_time || min_time == -1)
+      if(time_round_ms < min_time || min_time == 0)
       {
-        min_time = time_per_round_ms[i];
+        min_time = time_round_ms;
       }
-      else if(time_per_round_ms[i] > max_time)
+      if(time_round_ms > max_time)
       {
-        max_time = time_per_round_ms[i];
+        max_time = time_round_ms;
       }
       nr_times++;
-      mid_time = mid_time + time_per_round_ms[i];
+      mid_time = mid_time + time_round_ms;
     }
   }
   if(nr_times >= 3)
   {
     mid_time = (mid_time - max_time  - min_time)/(nr_times - 2);
   }
+  static unsigned long last_mid_time = millis();
+  if(millis() - last_mid_time > 500)
+  {
+    Serial.printf(">turn_time_ms:%d\n", mid_time);
+    last_mid_time = millis();
+  }
   return(mid_time);
 }
 
@@ -252,6 +225,7 @@ void speed_set()
     else
     {
       ESC.write(ser_esc_output);
+      ser_esc_output = -1;
     }
     last_esc_write_ms = millis();
   }
@@ -325,7 +299,7 @@ void data_init()
   speed = 0;
   for (uint8_t i= 0; i < TIME_PER_ROUND_VALS; i++)
   {
-    time_per_round_ms[i] = -1;
+    time_per_round_ms[i] = 0;
   } 
   unsigned long current_millis = millis();
   for (uint8_t i = 0; i < ALL_DATA_COUNT; i ++)
@@ -372,10 +346,10 @@ void data_check()
   {
     if( 0 == nr)
     {
-      double mid_time = time_per_round_calc();
+      unsigned long mid_time = time_per_round_calc();
       if( mid_time != 0)
       {
-        HallData[nr].value = HallData[nr].unit_factor / (mid_time/HALL_NR_TURN);
+        HallData[nr].value = HallData[nr].unit_factor / mid_time;
       }
     }
     else{
@@ -414,6 +388,7 @@ void get_serial_cmd()
             Serial.printf("Set kp to %f\n", kp);
         }
         else if(command.startsWith("ki=")){
+            integ = 0.0;
             ki = command.substring(command.indexOf("=")+1).toDouble();
             Serial.printf("Set ki to %f\n", ki);
         }
@@ -422,6 +397,7 @@ void get_serial_cmd()
             Serial.printf("Set speed to %f\n", ser_speed);
         }
         else if(command.startsWith("kd=")){
+            derivative = 0.0;
             kd = command.substring(command.indexOf("=")+1).toDouble();
             Serial.printf("Set kd to %f\n", kd);
         }
@@ -457,6 +433,7 @@ void get_serial_cmd()
             err = 0.0;
             last_error = 0.0;
             integ = 0.0;
+            derivative = 0.0;
             Serial.printf("Reset PID variables.\n");
         }
 
@@ -469,6 +446,7 @@ void get_serial_cmd()
   }
 }
 
+#ifndef DUMMY_DATA
 void IRAM_ATTR ISR_HALL1()
 {
   const uint8_t hallnr = 0;
@@ -545,6 +523,7 @@ void IRAM_ATTR ISR_HALL8()
   HallData[hallnr].timestamp = run_time;
   HallData[hallnr].act_update_ms = millis();
 }
+#endif
 
 //this code is just for generating dummy data - in normal use not needed
 void data_generate()
@@ -552,7 +531,9 @@ void data_generate()
   #ifdef DUMMY_DATA
 
   static unsigned long _last_updated_ms = 0; 
-  speed = 1000 + random(-250,150);
+
+  speed = map(esc_output, MIN_ESC_SPEED, MAX_ESC_SPEED, MIN_SPEED, MAX_SPEED) + random(-50,50);
+
   unsigned long _wait_ms = map( speed, MIN_SPEED, MAX_SPEED, 60000/MIN_SPEED/4, 60000/MAX_SPEED/4);
   //Serial.printf("Speed is : %lu and _wait_ms is %lu\n", speed, _wait_ms);
 
@@ -571,17 +552,31 @@ void data_generate()
       {
         HallData[i].ticks++;
         HallData[i].period_ticks++;
-        HallData[i].last_update_ms = millis();
         HallData[i].timestamp = run_time;
+
+        // each 4 ticks is one turn
+        // so we calculate speed each 4 ticks... just in case we check for bigger ... 
+        if(HallData[i].period_ticks >= (HALL_NR_TURN * HALL_TICKS_PER_TURN))
+        {
+          unsigned long time_ms = millis();
+          HallData[i].period_ticks = 0;
+          time_per_round_ms[time_per_round_pointer] = time_ms - HallData[i].act_update_ms;
+          Serial.printf(">tick_time:%d\n", time_per_round_ms[time_per_round_pointer]);
+          HallData[i].act_update_ms = time_ms;
+          time_per_round_pointer++;
+          if(time_per_round_pointer > TIME_PER_ROUND_VALS)
+          {
+            time_per_round_pointer = 0;
+          }
+        }
       }
       else
       {
         //Serial.printf("i=%d HallData[i-1].ticks=%lu %4 = %d\n" , i, HallData[i-1].ticks , HallData[i-1].ticks % 4);
-        if (HallData[i].last_update_ms != HallData[i-1].last_update_ms && HallData[i-1].ticks % 4 == 0)
+        if (HallData[i].act_update_ms != HallData[i-1].act_update_ms && HallData[i-1].ticks % 4 == 0)
         {
           HallData[i].ticks++;
-          HallData[i].period_ticks++;
-          HallData[i].last_update_ms = HallData[i-1].last_update_ms;
+          HallData[i].act_update_ms = HallData[i-1].act_update_ms;
           HallData[i].timestamp = run_time;
         }
       }