Pre-requisite:

1. Polar and Cartesian Coordinates

Objectives:

1. To demonstrate an object launch to a target point

Advance:

1. Target Moving with Random factors

Descriptions:

1. To move your object towards a location,provided targeted location and current location, you can suppose your current location origin and then get the relative position of the target location in polar coordinate.
2. This will give you the direction you need to travel.
3. Given the speed you want the object to travel,

4. Stepped example : (Click mouse to step, Hold down to see the hint, More content under demo 1, please scroll down to view Keynote 0)

   Source

    
   //*******************************************************
   // Global variables
   //*******************************************************
   final int appwidth = 600;
   final int appheight = 600;
   final float stepsize = 10;
   targetedobject myobject;
   //*******************************************************
   // The class of the moving object
   //*******************************************************
   class targetedobject {  // This is the object to move
     int mcurrentx, mcurrenty;  // This will store the current location of the object
     int mtargetx, mtargety;    // This will store the target location of the object
     int mtargetx_t, mtargety_t;  // Step travel
     float mrotation;      // This is the current orientation of this object
     float thisstep;
     boolean demostep;		// The flag whether the helper needs to be displayed or not
     targetedobject( int x, int y, int r ) {  // Initialize with coordinate and orientation
       mcurrentx = x;
       mtargetx = x;
       mcurrenty = y;
       mtargety = y;
       mrotation = r;
       demostep = false;
     }
     void updatedraw() {  // Draws the shape
       pushMatrix();
       translate( mcurrentx, mcurrenty );
       rotate( mrotation );
       noStroke();
       fill( 255, 0, 0 );
       ellipse(0, 0, 40, 40);
       noFill();
       stroke(255);
       strokeWeight(5);
       line( -10, 0, 10, 0 );
       line( 10, 0, 5, -5 );
       line( 10, 0, 5, 5 );
       popMatrix();
       this.drawhelper();
     }
     void drawhelper() {
       if ( this.demostep ) {  // Need draw helper
         float textx, texty;
         noFill();
         strokeWeight(3);
         stroke( 0, 255, 255, 192 );
         line( this.mcurrentx, this.mcurrenty, this.mtargetx, this.mtargety );
         line( this.mtargetx, this.mcurrenty, this.mtargetx, this.mtargety );
         line( this.mcurrentx, this.mcurrenty, this.mtargetx, this.mcurrenty );
         textSize(24);
         textAlign(CENTER, BOTTOM);
         noStroke();
         fill(255);
         textx = (this.mtargetx + this.mcurrentx) / 2;
         texty = this.mcurrenty;
         text( "X2 - X1", textx, texty );
         textAlign(LEFT, CENTER);
         textx = this.mtargetx;
         texty = (this.mtargety + this.mcurrenty) / 2;
         text( "Y2 - Y1", textx, texty );
         textAlign(CENTER, CENTER);
         textx = (this.mtargetx + this.mcurrentx) / 2;
         texty = (this.mtargety + this.mcurrenty) / 2;
         text( "L", textx, texty );
         
         noFill();
         strokeWeight(3);
         stroke(255,0,0);
         arc( this.mcurrentx, this.mcurrenty, 64, 64, 0, this.mrotation );
         textx = this.mcurrentx + 40;
         texty = this.mcurrenty + 40;
         text( degrees(this.mrotation), textx, texty );
       }
     }
     void startstep(int x, int y) {
       float targetlength;
       float temprotation;
       this.demostep = true;
    
   	// Remember target coordinates
       this.mtargetx = x;
       this.mtargety = y;
    
   	// Calculate the distance between the endpoint and start point
       targetlength = sqrt( pow( this.mtargetx - this.mcurrentx, 2 ) + 
         					 pow(  this.mtargety - this.mcurrenty, 2 ) );  //Get the target distance
       if (targetlength <= 0.5) {
         this.mrotation = 0;
         return;  //Do not move
       }
       if (targetlength > stepsize) {  //Calculate step size
         this.thisstep = stepsize;
       }
       else {
         this.thisstep = targetlength;
       }
    
   	// Get the direction (0~180 degree(s))
       temprotation = acos( (this.mtargetx - this.mcurrentx) / targetlength );
       if ( this.mtargety > this.mcurrenty ) {
         this.mrotation = temprotation;
       }else{
         this.mrotation = 2 * PI - temprotation;	// > 180 degrees
       }
       // Calculate the step target
       this.mtargetx_t = (int)(this.thisstep * cos(this.mrotation));
       this.mtargety_t = (int)(this.thisstep * sin(this.mrotation));
     }
     void endstep() {
       this.demostep = false;
   	// Move the object
       this.mcurrentx += this.mtargetx_t;
       this.mcurrenty += this.mtargety_t;
     }
   }
   //*******************************************************
   // Setup the size and the moving object
   //*******************************************************
   void setup() {
     size(appwidth, appheight);
     background(0);
     myobject = new targetedobject( width / 2, height / 2, 0 );
   }
   //*******************************************************
   // Update the draw
   //*******************************************************
   void draw() {
     background(0);
     myobject.updatedraw();
   }
   //*******************************************************
   // When mouse is pressed, start the stepping 
   // Calculation process
   //*******************************************************
   void mousePressed() {
     if (mouseButton == LEFT) {
       myobject.startstep(mouseX, mouseY);
     }
   }
   //*******************************************************
   // After the mouse is released,
   // End the stepping and move the object
   //*******************************************************
   void mouseReleased() {
     if ( myobject.demostep ) {
       myobject.endstep();
     }
   }
   

5. Key note

    
   //Get the target distance
   targetlength = sqrt( pow( this.mtargetx - this.mcurrentx, 2 ) + 
                        pow( this.mtargety - this.mcurrenty, 2 ) );
    
   //Arc cosin adjacent side divide by Hypotenuse
   //OR arc sin subtense divide by Hypotenuse
   //Not using tangent to avoid Divide by Zero
   temprotation = acos( (this.mtargetx - this.mcurrentx) / targetlength );
    
   //In this case, we are using cosin, so for the angle > 180 which means that
   //targety is under currend y
   if ( this.mtargety > this.mcurrenty ) {  //> 180 degrees
       this.mrotation = temprotation;
   }else{
       this.mrotation = 2 * PI - temprotation;
   }
    
   //Now that we have the rotation, we recalculate the x and y we need to travel
   this.mtargetx_t = (int)(this.thisstep * cos(this.mrotation));
   this.mtargety_t = (int)(this.thisstep * sin(this.mrotation));
   
    
   //Finally, move the object
   this.mcurrentx += this.mtargetx_t;
   this.mcurrenty += this.mtargety_t;
   

6. Continuous Example

   Source

    
   final int appwidth = 600;
   final int appheight = 600;
   final float stepsize = 5;
   targetedobject myobject;
   class targetedobject {  // This is the object to move
     int mcurrentx, mcurrenty;  // This will store the current location of the object
     int mtargetx, mtargety;    // This will store the target location of the object
     int mtargetx_t, mtargety_t;  // Step travel
     float mrotation;      // This is the current orientation of this object
     float thisstep;
     boolean demostep;
     targetedobject( int x, int y, int r ) {  // Initialize with coordinate and orientation
       mcurrentx = x;
       mtargetx = x;
       mcurrenty = y;
       mtargety = y;
       mrotation = r;
       demostep = false;
     }
     void updatedraw() {  //Draws the shape
       pushMatrix();
       translate( mcurrentx, mcurrenty );
       rotate( mrotation );
       noStroke();
       fill( 255, 0, 0 );
       ellipse(0, 0, 40, 40);
       noFill();
       stroke(255);
       strokeWeight(5);
       line( -10, 0, 10, 0 );
       line( 10, 0, 5, -5 );
       line( 10, 0, 5, 5 );
       popMatrix();
     }
     void moveto(int x, int y) {
       this.mtargetx = x;
       this.mtargety = y;
       //Get the target distance
       float targetlength = sqrt( pow( this.mtargetx - this.mcurrentx, 2 ) + 
         pow( this.mtargety - this.mcurrenty, 2 ) );
       if(targetlength < 0.5){
         return;
       }
       //Arc cosin adjacent side divide by Hypotenuse
       //OR arc sin subtense divide by Hypotenuse
       //Not using tangent to avoid Divide by Zero
       float temprotation = acos( (this.mtargetx - this.mcurrentx) / targetlength );
       //In this case, we are using cosin, so for the angle > 180 which means that
       //targety is under currend y
       if ( this.mtargety > this.mcurrenty ) {  //> 180 degrees
         this.mrotation = temprotation;
       }
       else {
         this.mrotation = 2 * PI - temprotation;
       }
       if (targetlength > stepsize) {  //Calculate step size
         this.thisstep = stepsize;
       }
       else {
         this.thisstep = targetlength;
       }
       //Now that we have the rotation, we recalculate the x and y we need to travel
       this.mtargetx_t = (int)(this.thisstep * cos(this.mrotation));
       this.mtargety_t = (int)(this.thisstep * sin(this.mrotation));
   
       //Finally, move the object
       this.mcurrentx += this.mtargetx_t;
       this.mcurrenty += this.mtargety_t;
     }
   }
   void setup() {
     size(appwidth, appheight);
     background(0);
     myobject = new targetedobject( width / 2, height / 2, 0 );
     frameRate(30);
   }
   void draw() {
     background(0);
     myobject.moveto( mouseX, mouseY );
     myobject.updatedraw();
   }