HIPPIE/Hippie.cpp

#include "Arduino.h"

#include "Hippie.h"
#include <Oscillator.h>



void Hippie::init(int YL, int YR, int RL, int RR, int Buzzer) {
  
  servo_pins[0] = YL;
  servo_pins[1] = YR;
  servo_pins[2] = RL;
  servo_pins[3] = RR;

  attachServos();
  isHippieResting=false;

  
  for (int i = 0; i < 4; i++) servo_position[i] = 90;


  //Buzzer & noise sensor pins: 
  pinBuzzer = Buzzer;

  pinMode(Buzzer,OUTPUT);
}

///////////////////////////////////////////////////////////////////
//-- ATTACH & DETACH FUNCTIONS ----------------------------------//
///////////////////////////////////////////////////////////////////
void Hippie::attachServos(){
    servo[0].attach(servo_pins[0]);
    servo[1].attach(servo_pins[1]);
    servo[2].attach(servo_pins[2]);
    servo[3].attach(servo_pins[3]);
}

void Hippie::detachServos(){
    servo[0].detach();
    servo[1].detach();
    servo[2].detach();
    servo[3].detach();
}


///////////////////////////////////////////////////////////////////
//-- BASIC MOTION FUNCTIONS -------------------------------------//
///////////////////////////////////////////////////////////////////
void Hippie::_moveServos(int time, int  servo_target[]) {

  attachServos();
  if(getRestState()==true){
        setRestState(false);
  }

  if(time>10){
    for (int i = 0; i < 4; i++) increment[i] = ((servo_target[i]) - servo_position[i]) / (time / 10.0);
    final_time =  millis() + time;

    for (int iteration = 1; millis() < final_time; iteration++) {
      partial_time = millis() + 10;
      for (int i = 0; i < 4; i++) servo[i].SetPosition(servo_position[i] + (iteration * increment[i]));
      while (millis() < partial_time); //pause
    }
  }
  else{
    for (int i = 0; i < 4; i++) servo[i].SetPosition(servo_target[i]);
  }
  for (int i = 0; i < 4; i++) servo_position[i] = servo_target[i];
}


void Hippie::oscillateServos(int A[4], int O[4], int T, double phase_diff[4], float cycle=1){

  for (int i=0; i<4; i++) {
    servo[i].SetO(O[i]);
    servo[i].SetA(A[i]);
    servo[i].SetT(T);
    servo[i].SetPh(phase_diff[i]);
  }
  double ref=millis();
   for (double x=ref; x<=T*cycle+ref; x=millis()){
     for (int i=0; i<4; i++){
        servo[i].refresh();
     }
  }
}


void Hippie::_execute(int A[4], int O[4], int T, double phase_diff[4], float steps = 1.0){

  attachServos();
  if(getRestState()==true){
        setRestState(false);
  }


  int cycles=(int)steps;    

  //-- Execute complete cycles
  if (cycles >= 1) 
    for(int i = 0; i < cycles; i++) 
      oscillateServos(A,O, T, phase_diff);
      
  //-- Execute the final not complete cycle    
  oscillateServos(A,O, T, phase_diff,(float)steps-cycles);
}



///////////////////////////////////////////////////////////////////
//-- HOME = Hippie at rest position -------------------------------//
///////////////////////////////////////////////////////////////////
void Hippie::home(){

  if(isHippieResting==false){ //Go to rest position only if necessary

    int homes[4]={90, 90, 90, 90}; //All the servos at rest position
    _moveServos(500,homes);   //Move the servos in half a second

    detachServos();
    isHippieResting=true;
  }
}

bool Hippie::getRestState(){

    return isHippieResting;
}

void Hippie::setRestState(bool state){

    isHippieResting = state;
}


///////////////////////////////////////////////////////////////////
//-- PREDETERMINED MOTION SEQUENCES -----------------------------//
///////////////////////////////////////////////////////////////////

//---------------------------------------------------------
//-- Hippie movement: Jump
//--  Parameters:
//--    steps: Number of steps
//--    T: Period
//---------------------------------------------------------
void Hippie::jump(float steps, int T){

  int up[]={90,90,150,30};
  _moveServos(T,up);
  int down[]={90,90,90,90};
  _moveServos(T,down);
}


//---------------------------------------------------------
//-- Hippie gait: Walking  (forward or backward)    
//--  Parameters:
//--    * steps:  Number of steps
//--    * T : Period
//--    * Dir: Direction: FORWARD / BACKWARD
//---------------------------------------------------------
void Hippie::walk(float steps, int T, int dir){

  //-- Oscillator parameters for walking
  //-- Hip sevos are in phase
  //-- Feet servos are in phase
  //-- Hip and feet are 90 degrees out of phase
  //--      -90 : Walk forward
  //--       90 : Walk backward
  //-- Feet servos also have the same offset (for tiptoe a little bit)
  int A[4]= {30, 30, 20, 20};
  int O[4] = {0, 0, 4, -4};
  double phase_diff[4] = {0, 0, DEG2RAD(dir * -90), DEG2RAD(dir * -90)};

  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps);  
}


//---------------------------------------------------------
//-- Hippie gait: Turning (left or right)
//--  Parameters:
//--   * Steps: Number of steps
//--   * T: Period
//--   * Dir: Direction: LEFT / RIGHT
//---------------------------------------------------------
void Hippie::turn(float steps, int T, int dir){

  //-- Same coordination than for walking (see Hippie::walk)
  //-- The Amplitudes of the hip's oscillators are not igual
  //-- When the right hip servo amplitude is higher, the steps taken by
  //--   the right leg are bigger than the left. So, the robot describes an 
  //--   left arc
  int A[4]= {30, 30, 20, 20};
  int O[4] = {0, 0, 4, -4};
  double phase_diff[4] = {0, 0, DEG2RAD(-90), DEG2RAD(-90)}; 
    
  if (dir == LEFT) {  
    A[0] = 30; //-- Left hip servo
    A[1] = 10; //-- Right hip servo
  }
  else {
    A[0] = 10;
    A[1] = 30;
  }
    
  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps); 
}


//---------------------------------------------------------
//-- Hippie gait: Lateral bend
//--  Parameters:
//--    steps: Number of bends
//--    T: Period of one bend
//--    dir: RIGHT=Right bend LEFT=Left bend
//---------------------------------------------------------
void Hippie::bend (int steps, int T, int dir){

  //Parameters of all the movements. Default: Left bend
  int bend1[4]={90, 90, 62, 35}; 
  int bend2[4]={90, 90, 62, 105};
  int homes[4]={90, 90, 90, 90};

  //Time of one bend, constrained in order to avoid movements too fast.
  //T=max(T, 600);

  //Changes in the parameters if right direction is chosen 
  if(dir==-1)
  {
    bend1[2]=180-35;
    bend1[3]=180-60;  //Not 65. Hippie is unbalanced
    bend2[2]=180-105;
    bend2[3]=180-60;
  }

  //Time of the bend movement. Fixed parameter to avoid falls
  int T2=800; 

  //Bend movement
  for (int i=0;i<steps;i++)
  {
    _moveServos(T2/2,bend1);
    _moveServos(T2/2,bend2);
    delay(T*0.8);
    _moveServos(500,homes);
  }

}


//---------------------------------------------------------
//-- Hippie gait: Shake a leg
//--  Parameters:
//--    steps: Number of shakes
//--    T: Period of one shake
//--    dir: RIGHT=Right leg LEFT=Left leg
//---------------------------------------------------------
void Hippie::shakeLeg (int steps,int T,int dir){

  //This variable change the amount of shakes
  int numberLegMoves=2;

  //Parameters of all the movements. Default: Right leg
  int shake_leg1[4]={90, 90, 58, 35};   
  int shake_leg2[4]={90, 90, 58, 120};
  int shake_leg3[4]={90, 90, 58, 60};
  int homes[4]={90, 90, 90, 90};

  //Changes in the parameters if left leg is chosen
  if(dir==-1)      
  {
    shake_leg1[2]=180-35;
    shake_leg1[3]=180-58;
    shake_leg2[2]=180-120;
    shake_leg2[3]=180-58;
    shake_leg3[2]=180-60;
    shake_leg3[3]=180-58;
  }
  
  //Time of the bend movement. Fixed parameter to avoid falls
  int T2=1000;    
  //Time of one shake, constrained in order to avoid movements too fast.            
  T=T-T2;
  T=max(T,200*numberLegMoves);  

  for (int j=0; j<steps;j++)
  {
  //Bend movement
  _moveServos(T2/2,shake_leg1);
  _moveServos(T2/2,shake_leg2);
  
    //Shake movement
    for (int i=0;i<numberLegMoves;i++)
    {
    _moveServos(T/(2*numberLegMoves),shake_leg3);
    _moveServos(T/(2*numberLegMoves),shake_leg2);
    }
    _moveServos(500,homes); //Return to home position
  }
  
  delay(T);
}


//---------------------------------------------------------
//-- Hippie movement: up & down
//--  Parameters:
//--    * steps: Number of jumps
//--    * T: Period
//--    * h: Jump height: SMALL / MEDIUM / BIG 
//--              (or a number in degrees 0 - 90)
//---------------------------------------------------------
void Hippie::updown(float steps, int T, int h){

  //-- Both feet are 180 degrees out of phase
  //-- Feet amplitude and offset are the same
  //-- Initial phase for the right foot is -90, so that it starts
  //--   in one extreme position (not in the middle)
  int A[4]= {0, 0, h, h};
  int O[4] = {0, 0, h, -h};
  double phase_diff[4] = {0, 0, DEG2RAD(-90), DEG2RAD(90)};
  
  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps); 
}


//---------------------------------------------------------
//-- Hippie movement: swinging side to side
//--  Parameters:
//--     steps: Number of steps
//--     T : Period
//--     h : Amount of swing (from 0 to 50 aprox)
//---------------------------------------------------------
void Hippie::swing(float steps, int T, int h){

  //-- Both feets are in phase. The offset is half the amplitude
  //-- It causes the robot to swing from side to side
  int A[4]= {0, 0, h, h};
  int O[4] = {0, 0, h/2, -h/2};
  double phase_diff[4] = {0, 0, DEG2RAD(0), DEG2RAD(0)};
  
  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps); 
}


//---------------------------------------------------------
//-- Hippie movement: swinging side to side without touching the floor with the heel
//--  Parameters:
//--     steps: Number of steps
//--     T : Period
//--     h : Amount of swing (from 0 to 50 aprox)
//---------------------------------------------------------
void Hippie::tiptoeSwing(float steps, int T, int h){

  //-- Both feets are in phase. The offset is not half the amplitude in order to tiptoe
  //-- It causes the robot to swing from side to side
  int A[4]= {0, 0, h, h};
  int O[4] = {0, 0, h, -h};
  double phase_diff[4] = {0, 0, 0, 0};
  
  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps); 
}


//---------------------------------------------------------
//-- Hippie gait: Jitter 
//--  Parameters:
//--    steps: Number of jitters
//--    T: Period of one jitter 
//--    h: height (Values between 5 - 25)   
//---------------------------------------------------------
void Hippie::jitter(float steps, int T, int h){

  //-- Both feet are 180 degrees out of phase
  //-- Feet amplitude and offset are the same
  //-- Initial phase for the right foot is -90, so that it starts
  //--   in one extreme position (not in the middle)
  //-- h is constrained to avoid hit the feets
  h=min(25,h);
  int A[4]= {h, h, 0, 0};
  int O[4] = {0, 0, 0, 0};
  double phase_diff[4] = {DEG2RAD(-90), DEG2RAD(90), 0, 0};
  
  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps); 
}


//---------------------------------------------------------
//-- Hippie gait: Ascending & turn (Jitter while up&down)
//--  Parameters:
//--    steps: Number of bends
//--    T: Period of one bend
//--    h: height (Values between 5 - 15) 
//---------------------------------------------------------
void Hippie::ascendingTurn(float steps, int T, int h){

  //-- Both feet and legs are 180 degrees out of phase
  //-- Initial phase for the right foot is -90, so that it starts
  //--   in one extreme position (not in the middle)
  //-- h is constrained to avoid hit the feets
  h=min(13,h);
  int A[4]= {h, h, h, h};
  int O[4] = {0, 0, h+4, -h+4};
  double phase_diff[4] = {DEG2RAD(-90), DEG2RAD(90), DEG2RAD(-90), DEG2RAD(90)};
  
  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps); 
}


//---------------------------------------------------------
//-- Hippie gait: Moonwalker. Hippie moves like Michael Jackson
//--  Parameters:
//--    Steps: Number of steps
//--    T: Period
//--    h: Height. Typical valures between 15 and 40
//--    dir: Direction: LEFT / RIGHT
//---------------------------------------------------------
void Hippie::moonwalker(float steps, int T, int h, int dir){

  //-- This motion is similar to that of the caterpillar robots: A travelling
  //-- wave moving from one side to another
  //-- The two Hippie's feet are equivalent to a minimal configuration. It is known
  //-- that 2 servos can move like a worm if they are 120 degrees out of phase
  //-- In the example of Hippie, the two feet are mirrored so that we have:
  //--    180 - 120 = 60 degrees. The actual phase difference given to the oscillators
  //--  is 60 degrees.
  //--  Both amplitudes are equal. The offset is half the amplitud plus a little bit of
  //-   offset so that the robot tiptoe lightly
 
  int A[4]= {0, 0, h, h};
  int O[4] = {0, 0, h/2+2, -h/2 -2};
  int phi = -dir * 90;
  double phase_diff[4] = {0, 0, DEG2RAD(phi), DEG2RAD(-60 * dir + phi)};
  
  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps); 
}


//----------------------------------------------------------
//-- Hippie gait: Crusaito. A mixture between moonwalker and walk
//--   Parameters:
//--     steps: Number of steps
//--     T: Period
//--     h: height (Values between 20 - 50)
//--     dir:  Direction: LEFT / RIGHT
//-----------------------------------------------------------
void Hippie::crusaito(float steps, int T, int h, int dir){

  int A[4]= {25, 25, h, h};
  int O[4] = {0, 0, h/2+ 4, -h/2 - 4};
  double phase_diff[4] = {90, 90, DEG2RAD(0), DEG2RAD(-60 * dir)};
  
  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps); 
}


//---------------------------------------------------------
//-- Hippie gait: Flapping
//--  Parameters:
//--    steps: Number of steps
//--    T: Period
//--    h: height (Values between 10 - 30)
//--    dir: direction: FOREWARD, BACKWARD
//---------------------------------------------------------
void Hippie::flapping(float steps, int T, int h, int dir){

  int A[4]= {12, 12, h, h};
  int O[4] = {0, 0, h - 10, -h + 10};
  double phase_diff[4] = {DEG2RAD(0), DEG2RAD(180), DEG2RAD(-90 * dir), DEG2RAD(90 * dir)};
  
  //-- Let's oscillate the servos!
  _execute(A, O, T, phase_diff, steps); 
}