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Rohan Juneja
Published

Ball Tracking Robot

A robo which follows an object of uniform color using Computer Vision.

IntermediateShowcase (no instructions)76,770
Ball Tracking Robot

Things used in this project

Story

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Schematics

Circuit Diagram

Pseudo code for Computer Vision

Circuit Diagram

Code

Code

Python
Upload in your Raspberry Pi and make a shell script to run it as soon as Raspberry Pi starts.
# import the necessary packages
from picamera.array import PiRGBArray     #As there is a resolution problem in raspberry pi, will not be able to capture frames by VideoCapture
from picamera import PiCamera
import RPi.GPIO as GPIO
import time
import cv2
import cv2.cv as cv
import numpy as np

#hardware work
GPIO.setmode(GPIO.BOARD)

GPIO_TRIGGER1 = 29      #Left ultrasonic sensor
GPIO_ECHO1 = 31

GPIO_TRIGGER2 = 36      #Front ultrasonic sensor
GPIO_ECHO2 = 37

GPIO_TRIGGER3 = 33      #Right ultrasonic sensor
GPIO_ECHO3 = 35

MOTOR1B=18  #Left Motor
MOTOR1E=22

MOTOR2B=21  #Right Motor
MOTOR2E=19

LED_PIN=13  #If it finds the ball, then it will light up the led

# Set pins as output and input
GPIO.setup(GPIO_TRIGGER1,GPIO.OUT)  # Trigger
GPIO.setup(GPIO_ECHO1,GPIO.IN)      # Echo
GPIO.setup(GPIO_TRIGGER2,GPIO.OUT)  # Trigger
GPIO.setup(GPIO_ECHO2,GPIO.IN)
GPIO.setup(GPIO_TRIGGER3,GPIO.OUT)  # Trigger
GPIO.setup(GPIO_ECHO3,GPIO.IN)
GPIO.setup(LED_PIN,GPIO.OUT)

# Set trigger to False (Low)
GPIO.output(GPIO_TRIGGER1, False)
GPIO.output(GPIO_TRIGGER2, False)
GPIO.output(GPIO_TRIGGER3, False)

# Allow module to settle
def sonar(GPIO_TRIGGER,GPIO_ECHO):
      start=0
      stop=0
      # Set pins as output and input
      GPIO.setup(GPIO_TRIGGER,GPIO.OUT)  # Trigger
      GPIO.setup(GPIO_ECHO,GPIO.IN)      # Echo
     
      # Set trigger to False (Low)
      GPIO.output(GPIO_TRIGGER, False)
     
      # Allow module to settle
      time.sleep(0.01)
           
      #while distance > 5:
      #Send 10us pulse to trigger
      GPIO.output(GPIO_TRIGGER, True)
      time.sleep(0.00001)
      GPIO.output(GPIO_TRIGGER, False)
      begin = time.time()
      while GPIO.input(GPIO_ECHO)==0 and time.time()<begin+0.05:
            start = time.time()
     
      while GPIO.input(GPIO_ECHO)==1 and time.time()<begin+0.1:
            stop = time.time()
     
      # Calculate pulse length
      elapsed = stop-start
      # Distance pulse travelled in that time is time
      # multiplied by the speed of sound (cm/s)
      distance = elapsed * 34000
     
      # That was the distance there and back so halve the value
      distance = distance / 2
     
      print "Distance : %.1f" % distance
      # Reset GPIO settings
      return distance

GPIO.setup(MOTOR1B, GPIO.OUT)
GPIO.setup(MOTOR1E, GPIO.OUT)

GPIO.setup(MOTOR2B, GPIO.OUT)
GPIO.setup(MOTOR2E, GPIO.OUT)

def forward():
      GPIO.output(MOTOR1B, GPIO.HIGH)
      GPIO.output(MOTOR1E, GPIO.LOW)
      GPIO.output(MOTOR2B, GPIO.HIGH)
      GPIO.output(MOTOR2E, GPIO.LOW)
     
def reverse():
      GPIO.output(MOTOR1B, GPIO.LOW)
      GPIO.output(MOTOR1E, GPIO.HIGH)
      GPIO.output(MOTOR2B, GPIO.LOW)
      GPIO.output(MOTOR2E, GPIO.HIGH)
     
def rightturn():
      GPIO.output(MOTOR1B,GPIO.LOW)
      GPIO.output(MOTOR1E,GPIO.HIGH)
      GPIO.output(MOTOR2B,GPIO.HIGH)
      GPIO.output(MOTOR2E,GPIO.LOW)
     
def leftturn():
      GPIO.output(MOTOR1B,GPIO.HIGH)
      GPIO.output(MOTOR1E,GPIO.LOW)
      GPIO.output(MOTOR2B,GPIO.LOW)
      GPIO.output(MOTOR2E,GPIO.HIGH)

def stop():
      GPIO.output(MOTOR1E,GPIO.LOW)
      GPIO.output(MOTOR1B,GPIO.LOW)
      GPIO.output(MOTOR2E,GPIO.LOW)
      GPIO.output(MOTOR2B,GPIO.LOW)
     
#Image analysis work
def segment_colour(frame):    #returns only the red colors in the frame
    hsv_roi =  cv2.cvtColor(frame, cv2.cv.CV_BGR2HSV)
    mask_1 = cv2.inRange(hsv_roi, np.array([160, 160,10]), np.array([190,255,255]))
    ycr_roi=cv2.cvtColor(frame,cv2.cv.CV_BGR2YCrCb)
    mask_2=cv2.inRange(ycr_roi, np.array((0.,165.,0.)), np.array((255.,255.,255.)))

    mask = mask_1 | mask_2
    kern_dilate = np.ones((8,8),np.uint8)
    kern_erode  = np.ones((3,3),np.uint8)
    mask= cv2.erode(mask,kern_erode)      #Eroding
    mask=cv2.dilate(mask,kern_dilate)     #Dilating
    #cv2.imshow('mask',mask)
    return mask

def find_blob(blob): #returns the red colored circle
    largest_contour=0
    cont_index=0
    contours, hierarchy = cv2.findContours(blob, cv2.RETR_CCOMP, cv2.CHAIN_APPROX_SIMPLE)
    for idx, contour in enumerate(contours):
        area=cv2.contourArea(contour)
        if (area >largest_contour) :
            largest_contour=area
           
            cont_index=idx
            #if res>15 and res<18:
            #    cont_index=idx
                              
    r=(0,0,2,2)
    if len(contours) > 0:
        r = cv2.boundingRect(contours[cont_index])
       
    return r,largest_contour

def target_hist(frame):
    hsv_img=cv2.cvtColor(frame, cv2.COLOR_BGR2HSV)
   
    hist=cv2.calcHist([hsv_img],[0],None,[50],[0,255])
    return hist

#CAMERA CAPTURE
#initialize the camera and grab a reference to the raw camera capture
camera = PiCamera()
camera.resolution = (160, 120)
camera.framerate = 16
rawCapture = PiRGBArray(camera, size=(160, 120))
 
# allow the camera to warmup
time.sleep(0.001)
 
# capture frames from the camera
for image in camera.capture_continuous(rawCapture, format="bgr", use_video_port=True):
      #grab the raw NumPy array representing the image, then initialize the timestamp and occupied/unoccupied text
      frame = image.array
      frame=cv2.flip(frame,1)
      global centre_x
      global centre_y
      centre_x=0.
      centre_y=0.
      hsv1 = cv2.cvtColor(frame, cv2.COLOR_BGR2HSV)
      mask_red=segment_colour(frame)      #masking red the frame
      loct,area=find_blob(mask_red)
      x,y,w,h=loct
     
      #distance coming from front ultrasonic sensor
      distanceC = sonar(GPIO_TRIGGER2,GPIO_ECHO2)
      #distance coming from right ultrasonic sensor
      distanceR = sonar(GPIO_TRIGGER3,GPIO_ECHO3)
      #distance coming from left ultrasonic sensor
      distanceL = sonar(GPIO_TRIGGER1,GPIO_ECHO1)
             
      if (w*h) < 10:
            found=0
      else:
            found=1
            simg2 = cv2.rectangle(frame, (x,y), (x+w,y+h), 255,2)
            centre_x=x+((w)/2)
            centre_y=y+((h)/2)
            cv2.circle(frame,(int(centre_x),int(centre_y)),3,(0,110,255),-1)
            centre_x-=80
            centre_y=6--centre_y
            print centre_x,centre_y
      initial=400
      flag=0
      GPIO.output(LED_PIN,GPIO.LOW)          
      if(found==0):
            #if the ball is not found and the last time it sees ball in which direction, it will start to rotate in that direction
            if flag==0:
                  rightturn()
                  time.sleep(0.05)
            else:
                  leftturn()
                  time.sleep(0.05)
            stop()
            time.sleep(0.0125)
     
      elif(found==1):
            if(area<initial):
                  if(distanceC<10):
                        #if ball is too far but it detects something in front of it,then it avoid it and reaches the ball.
                        if distanceR>=8:
                              rightturn()
                              time.sleep(0.00625)
                              stop()
                              time.sleep(0.0125)
                              forward()
                              time.sleep(0.00625)
                              stop()
                              time.sleep(0.0125)
                              #while found==0:
                              leftturn()
                              time.sleep(0.00625)
                        elif distanceL>=8:
                              leftturn()
                              time.sleep(0.00625)
                              stop()
                              time.sleep(0.0125)
                              forward()
                              time.sleep(0.00625)
                              stop()
                              time.sleep(0.0125)
                              rightturn()
                              time.sleep(0.00625)
                              stop()
                              time.sleep(0.0125)
                        else:
                              stop()
                              time.sleep(0.01)
                  else:
                        #otherwise it move forward
                        forward()
                        time.sleep(0.00625)
            elif(area>=initial):
                  initial2=6700
                  if(area<initial2):
                        if(distanceC>10):
                              #it brings coordinates of ball to center of camera's imaginary axis.
                              if(centre_x<=-20 or centre_x>=20):
                                    if(centre_x<0):
                                          flag=0
                                          rightturn()
                                          time.sleep(0.025)
                                    elif(centre_x>0):
                                          flag=1
                                          leftturn()
                                          time.sleep(0.025)
                              forward()
                              time.sleep(0.00003125)
                              stop()
                              time.sleep(0.00625)
                        else:
                              stop()
                              time.sleep(0.01)

                  else:
                        #if it founds the ball and it is too close it lights up the led.
                        GPIO.output(LED_PIN,GPIO.HIGH)
                        time.sleep(0.1)
                        stop()
                        time.sleep(0.1)
      #cv2.imshow("draw",frame)    
      rawCapture.truncate(0)  # clear the stream in preparation for the next frame
         
      if(cv2.waitKey(1) & 0xff == ord('q')):
            break

GPIO.cleanup() #free all the GPIO pins

Credits

Rohan Juneja
1 project • 54 followers
I am a student of IIITD, Delhi, India majoring in Electronics and Communication Engineering. Keen intersts: Computer Architecture, Embedded Systems and IoT.

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