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この誤作動はArduino に処理をさせすぎているせいでしょうか?

Arduinoで二輪でバランスをとるロボットを作り,さらにそれを無線ラジコン化しようとしています.二輪でバランスを取るとこまで作りました.後は,USB ホストシールドをつけて無線で入力電圧を指示すれば完成です.

しかし,USBホストシールドのプログラムを書くと暴走します.そんなに重いコードは書いていませんが,どうしてでしょうか.具体的には以下です.

二輪のコードはイカつく見えますがほとんどはセンサーの処理です.メインループだけ参照ください.車体と車輪の角度,角速度情報をフィードバックで入力にしているだけです.そしてこれだけならロボットは普通に動きます.

しかし,USBホストシールド用のプログラムの各変数宣言,メインループを,二輪のプログラムに組み込むと暴走します.

https://github.com/felis/USB_Host_Shield_2.0/blob/master/examples/Bluetooth/PS4BT/PS4BT.ino

不思議なのは,USBホストシールド用のプログラムはそもそもコントローラと通信を開始しなければ if文がtrueにならずに起動もしないはずなのに.つまりコントローラ接続なしの時はif 文を毎ループチェックする程度の容量なのに,メインループに組み込むと二輪が暴走します.

以下にコードを添付します.「二輪でバランス(正常),USBホストシールド(正常)」の順です.暴走するプログラムは,二つを単純にコピペで足し算しただけです.

最後に,なぜ,処理落ちによる暴走かと思ったかと言うと,,USBホストシールドのメーンループのUsb.Task(); よりも下のコードをコメントアウトすると二輪ロボットは通常に立ちます.(もちろん,コントローラからの信号処理文をのぞいた事になりますので,ラジコンにはなりませんが).つまり,信号処理文からのif文が重くて二輪バランスの指示が狂って暴走するのかなと思いました

//——-二輪でバランス————

#include <Wire.h>
#include <TimerOne.h>
#include <TimerThree.h>

#define ACC_CONV 1671.8 //acceleration converter
#define GYRO_CONV 131.1 //deg/s converter
volatile uint8_t data[14]; 
volatile float ay=0; // acc y data from acc
volatile float az=0; //acc z data from acc
volatile float db_ang=0; //gyro x data from gyro
volatile float roll=0; // ang x of acc data
volatile float gyro_x=0; // ang x of gyro data
volatile float b_ang=0; // ang x 
volatile float PREb_ang=0; // old ang x 
volatile float loop_period ;
volatile unsigned long Timer;

const float VREF = 7.2; 
const int PWM_MAX = 255; // PWM 100%
const int PWM_MIN = 0; // PWM 0%
volatile float Tlp=0.02;
const int threshold_ON =1;
const int threshold_OFF =0;


volatile float Lroll=0;
volatile float Lroll_old=0;
int control_loop_count=0;
volatile float OFFSET=12.0;


#define PWM 9 // Motor1 PWM
#define DI  7 // Motor1 Direction
#define PIN_ENCA 2// Encoder Motor1
#define PIN_ENCB 3// Encoder Motor1
int valA,valB;
int stateA,stateB;
int edgeA,edgeB;
volatile int value = 0; 
volatile float w_ang=0;
volatile float w_ang_old=0;
volatile float dw_ang=0;
volatile float dw_ang_old=0;
volatile float ang_ref=0;
volatile float dang_ref=0;
volatile float error=0;
volatile float error_itg = 0;
volatile float uref=0;
volatile float U = 0.0;
volatile float u = 0.0; 

volatile float dW_ang=0;
volatile float W_ang=0;


#define l_PWM 10 // Motor2 PWM
#define l_DI 8// Motor2 Direction
#define EN  4 // Wake up motors
#define l_PIN_ENCA 18  // Encoder Motor2
#define l_PIN_ENCB 19 // Encoder Motor2
int  l_valA,l_valB;
int l_stateA,l_stateB;
int l_edgeA,l_edgeB;
const float l_threshold_ON=1;
const float l_threshold_OFF=0;
volatile int l_value = 0; 
volatile float l_w_ang=0;
volatile float l_w_ang_old=0;
volatile float l_dw_ang=0;
volatile float l_dw_ang_old=0;
volatile float l_ang_ref=0;
volatile float l_error=0;
volatile float l_error_itg = 0;
volatile float l_uref=0;
volatile float l_U = 0.0;
volatile float l_dang_ref=0;
volatile float l_u = 0.0; 


volatile float Gain[4]={0.91287093, 428.77955813,   1.70594309,  83.01679013}; 




void setup() {

    Serial.begin(115200);
    pinMode(PIN_ENCA, INPUT);
    pinMode(PIN_ENCB, INPUT);
    attachInterrupt(0, updateEncoder, CHANGE); 
    attachInterrupt(1, updateEncoder, CHANGE);
    pinMode(PWM,OUTPUT);
    pinMode(DI,OUTPUT);


    pinMode(l_PIN_ENCA, INPUT);
    pinMode(l_PIN_ENCB, INPUT);
    attachInterrupt(4, l_updateEncoder, CHANGE); 
    attachInterrupt(5, l_updateEncoder, CHANGE);
    pinMode(l_PWM,OUTPUT);
    pinMode(l_DI,OUTPUT);


    
    pinMode(EN,OUTPUT);
    digitalWrite(EN, HIGH);

    Wire.begin(); //Starts I2C
    i2cWriteReg(0x68,0x6b,0x00); //Turn on a sensor
    i2cWriteReg(0x68,0x1b,0x00); //-250 < deg/s <250
    i2cWriteReg(0x68,0x1c,0x00); // -2g < acc <2g


  Timer3.initialize(1000); 
  Timer3.attachInterrupt(l_locate); 

}


void i2cWriteReg(uint8_t ad, uint8_t reg, volatile uint8_t data ){
  Wire.beginTransmission(ad); //starts transmission
  Wire.write(reg); //select reg
  Wire.write(data); //write data
  Wire.endTransmission(); //ends transmission
}


void updateEncoder(){
  valA=digitalRead(PIN_ENCA);
  valB=digitalRead(PIN_ENCB);

  edgeA=0;


  if((valA==threshold_ON)&&(stateA==0)){
    stateA=1; edgeA=1;
  } //rising

 

if((valA==threshold_OFF)&&(stateA==1)){
    stateA=0, edgeA=-1;
  } //faling


  edgeB=0;
 

  if((valB==threshold_ON)&&(stateB==0)){
    stateB=1; edgeB=1;
  } //rising

  if((valB==threshold_OFF)&&(stateB==1)){
    stateB=0; edgeB=-1;
  } //faling




  if (edgeA==1){
    if(stateB==0){
      value++;
    }
    else{
      value--;
    }
  }
  


  if (edgeA==-1){
    if(stateB==1){
      value++;
    }
    else{
      value--;
    }
  }


   if (edgeB==1){
    if(stateA==1){
      value++;
    }
    else{
      value--;
    }
  }


  if (edgeB==-1){
    if(stateA==0){
      value++;
    }
    else{
      value--;
    }
  }
  
}



void l_updateEncoder(){
  l_valA=digitalRead(l_PIN_ENCA);
  l_valB=digitalRead(l_PIN_ENCB);

  l_edgeA=0;


  if((l_valA==l_threshold_ON)&&(l_stateA==0)){
    l_stateA=1; l_edgeA=1;
  } //rising

 

if((l_valA==l_threshold_OFF)&&(l_stateA==1)){
    l_stateA=0, l_edgeA=-1;
  } //faling


  l_edgeB=0;
 

  if((l_valB==l_threshold_ON)&&(l_stateB==0)){
    l_stateB=1; l_edgeB=1;
  } //rising

  if((l_valB==l_threshold_OFF)&&(l_stateB==1)){
    l_stateB=0; l_edgeB=-1;
  } //faling




  if (l_edgeA==1){
    if(l_stateB==0){
      l_value++;
    }
    else{
      l_value--;
    }
  }
  


  if (l_edgeA==-1){
    if(l_stateB==1){
      l_value++;
    }
    else{
      l_value--;
    }
  }


   if (l_edgeB==1){
    if(l_stateA==1){
      l_value++;
    }
    else{
      l_value--;
    }
  }


  if (l_edgeB==-1){
    if(l_stateA==0){
      l_value++;
    }
    else{
      l_value--;
    }
  }
  
}




void l_locate(){


  

  l_error=l_ang_ref-W_ang;
  l_error_itg += l_error*0.001;


  l_dw_ang=80*(l_w_ang-l_w_ang_old) +  0.9231*l_dw_ang_old;
  l_dw_ang_old=l_dw_ang;
  l_w_ang_old=l_w_ang;


  dw_ang=80*(w_ang-w_ang_old) +  0.9231*dw_ang_old;
  dw_ang_old=dw_ang;
  w_ang_old=w_ang;

  dW_ang=l_dw_ang/2+dw_ang/2;

 
  
  l_uref=0.6*l_error + 0.030*l_error_itg -0.01*dW_ang;
  
  l_U=l_uref*(PWM_MAX/VREF);


   int l_mag = constrain(abs(l_U), PWM_MIN, PWM_MAX); 

   if(l_U >= 0){
    digitalWrite(l_DI, HIGH);
    digitalWrite(DI, HIGH);
    analogWrite(l_PWM, l_mag);
    analogWrite(PWM, l_mag);
  
        }
        
   else{
    digitalWrite(l_DI, LOW);
    digitalWrite(DI, LOW);
    analogWrite(l_PWM, l_mag);
    analogWrite(PWM, l_mag);
        }
   

  l_w_ang = float(l_value) * 0.0436;
  w_ang = float(value) * 0.0436;
  
  W_ang=l_w_ang/2 + w_ang/2;

}


void loop() {
  
  loop_period=(millis()-Timer)*0.001;

  l_u= Gain[0]*l_w_ang + Gain[1]*(b_ang-OFFSET) + Gain[2]*l_dw_ang + Gain[3]*db_ang;

  l_dang_ref += l_u *loop_period;
  
  l_ang_ref += l_dang_ref*loop_period;

  
  Timer=millis();

  Wire.beginTransmission(0x68); //Starts transmission
  Wire.write(0x3b); //select data top
  Wire.endTransmission(); //ends transmission
  Wire.requestFrom(0x68,14); //get data from top to 14byte

  uint8_t i =0;
  
  while (Wire.available())
  {
    data[i++]=Wire.read(); //accomodate data
  }
  
  ay= (float)((data[2] <<8 ) | data[3])/ACC_CONV;
  az= (float)((data[4] <<8 ) | data[5])/ACC_CONV;


  db_ang= (float)((data[8] <<8 ) | data[9])/GYRO_CONV+1.25; //depends on tempreture
  

 
  roll=-atan2(az,ay)*RAD_TO_DEG;

  Lroll= 0.3297*roll + 0.6703*Lroll_old;

  Lroll_old=Lroll;


  if(control_loop_count==0){
    
    b_ang= OFFSET;
    control_loop_count +=1;
  }

  else{
    
  b_ang=0.999*(PREb_ang + db_ang*loop_period) +0.001 * Lroll ;
  
  }

  
  PREb_ang=b_ang;

  
}

USBホストシールドのプログラムです.また,これはArduino IDEで、スケッチ>ライブラリをインクルード >ライブラリを管理>USB Host Shield Library 2.0> Bluetooth>PS4BT によっても得られます

//——USBホストシールド用のプログラム————

/*
 Example sketch for the PS4 Bluetooth library - developed by Kristian Lauszus
 For more information visit my blog: http://blog.tkjelectronics.dk/ or
 send me an e-mail:  kristianl@tkjelectronics.com
 */

#include <PS4BT.h>
#include <usbhub.h>

// Satisfy the IDE, which needs to see the include statment in the ino too.
#ifdef dobogusinclude
#include <spi4teensy3.h>
#endif
#include <SPI.h>

USB Usb;
//USBHub Hub1(&Usb); // Some dongles have a hub inside
BTD Btd(&Usb); // You have to create the Bluetooth Dongle instance like so

/* You can create the instance of the PS4BT class in two ways */
// This will start an inquiry and then pair with the PS4 controller - you only have to do this once
// You will need to hold down the PS and Share button at the same time, the PS4 controller will then start to blink rapidly indicating that it is in pairing mode
PS4BT PS4(&Btd, PAIR);

// After that you can simply create the instance like so and then press the PS button on the device
//PS4BT PS4(&Btd);

bool printAngle, printTouch;
uint8_t oldL2Value, oldR2Value;

void setup() {
  Serial.begin(115200);
#if !defined(__MIPSEL__)
  while (!Serial); // Wait for serial port to connect - used on Leonardo, Teensy and other boards with built-in USB CDC serial connection
#endif
  if (Usb.Init() == -1) {
    Serial.print(F("\r\nOSC did not start"));
    while (1); // Halt
  }
  Serial.print(F("\r\nPS4 Bluetooth Library Started"));
}
void loop() {
  Usb.Task();

  if (PS4.connected()) {
    if (PS4.getAnalogHat(LeftHatX) > 137 || PS4.getAnalogHat(LeftHatX) < 117 || PS4.getAnalogHat(LeftHatY) > 137 || PS4.getAnalogHat(LeftHatY) < 117 || PS4.getAnalogHat(RightHatX) > 137 || PS4.getAnalogHat(RightHatX) < 117 || PS4.getAnalogHat(RightHatY) > 137 || PS4.getAnalogHat(RightHatY) < 117) {
      Serial.print(F("\r\nLeftHatX: "));
      Serial.print(PS4.getAnalogHat(LeftHatX));
      Serial.print(F("\tLeftHatY: "));
      Serial.print(PS4.getAnalogHat(LeftHatY));
      Serial.print(F("\tRightHatX: "));
      Serial.print(PS4.getAnalogHat(RightHatX));
      Serial.print(F("\tRightHatY: "));
      Serial.print(PS4.getAnalogHat(RightHatY));
    }

    if (PS4.getAnalogButton(L2) || PS4.getAnalogButton(R2)) { // These are the only analog buttons on the PS4 controller
      Serial.print(F("\r\nL2: "));
      Serial.print(PS4.getAnalogButton(L2));
      Serial.print(F("\tR2: "));
      Serial.print(PS4.getAnalogButton(R2));
    }
    if (PS4.getAnalogButton(L2) != oldL2Value || PS4.getAnalogButton(R2) != oldR2Value) // Only write value if it's different
      PS4.setRumbleOn(PS4.getAnalogButton(L2), PS4.getAnalogButton(R2));
    oldL2Value = PS4.getAnalogButton(L2);
    oldR2Value = PS4.getAnalogButton(R2);

    if (PS4.getButtonClick(PS)) {
      Serial.print(F("\r\nPS"));
      PS4.disconnect();
    }
    else {
      if (PS4.getButtonClick(TRIANGLE)) {
        Serial.print(F("\r\nTriangle"));
        PS4.setRumbleOn(RumbleLow);
      }
      if (PS4.getButtonClick(CIRCLE)) {
        Serial.print(F("\r\nCircle"));
        PS4.setRumbleOn(RumbleHigh);
      }
      if (PS4.getButtonClick(CROSS)) {
        Serial.print(F("\r\nCross"));
        PS4.setLedFlash(10, 10); // Set it to blink rapidly
      }
      if (PS4.getButtonClick(SQUARE)) {
        Serial.print(F("\r\nSquare"));
        PS4.setLedFlash(0, 0); // Turn off blinking
      }

      if (PS4.getButtonClick(UP)) {
        Serial.print(F("\r\nUp"));
        PS4.setLed(Red);
      } if (PS4.getButtonClick(RIGHT)) {
        Serial.print(F("\r\nRight"));
        PS4.setLed(Blue);
      } if (PS4.getButtonClick(DOWN)) {
        Serial.print(F("\r\nDown"));
        PS4.setLed(Yellow);
      } if (PS4.getButtonClick(LEFT)) {
        Serial.print(F("\r\nLeft"));
        PS4.setLed(Green);
      }

      if (PS4.getButtonClick(L1))
        Serial.print(F("\r\nL1"));
      if (PS4.getButtonClick(L3))
        Serial.print(F("\r\nL3"));
      if (PS4.getButtonClick(R1))
        Serial.print(F("\r\nR1"));
      if (PS4.getButtonClick(R3))
        Serial.print(F("\r\nR3"));

      if (PS4.getButtonClick(SHARE))
        Serial.print(F("\r\nShare"));
      if (PS4.getButtonClick(OPTIONS)) {
        Serial.print(F("\r\nOptions"));
        printAngle = !printAngle;
      }
      if (PS4.getButtonClick(TOUCHPAD)) {
        Serial.print(F("\r\nTouchpad"));
        printTouch = !printTouch;
      }

      if (printAngle) { // Print angle calculated using the accelerometer only
        Serial.print(F("\r\nPitch: "));
        Serial.print(PS4.getAngle(Pitch));
        Serial.print(F("\tRoll: "));
        Serial.print(PS4.getAngle(Roll));
      }

      if (printTouch) { // Print the x, y coordinates of the touchpad
        if (PS4.isTouching(0) || PS4.isTouching(1)) // Print newline and carriage return if any of the fingers are touching the touchpad
          Serial.print(F("\r\n"));
        for (uint8_t i = 0; i < 2; i++) { // The touchpad track two fingers
          if (PS4.isTouching(i)) { // Print the position of the finger if it is touching the touchpad
            Serial.print(F("X")); Serial.print(i + 1); Serial.print(F(": "));
            Serial.print(PS4.getX(i));
            Serial.print(F("\tY")); Serial.print(i + 1); Serial.print(F(": "));
            Serial.print(PS4.getY(i));
            Serial.print(F("\t"));
          }
        }
      }
    }
  }
}

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